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Es werden Schwingkreismodelle angegeben, deren Säkulargleichungen mit denen formal identisch sind, die sich bei der Anwendung der Methode der Moleküleigenfunktionen auf das Problem der π -Elektronenzustände in Molekülen ungesättigter und aromatischer Kohlenwasserstoffe ergeben. Damit ergibt sich die Möglichkeit, die quantenmechanischen Säkularprobleme durch Messung der Eigenfrequenzen der Modelle zu bestimmen.
The ribonucleic acid of reovirus was extracted with 2 M sodium perchlorate solution and spread by the protein monolayer technique. Areas of the monolayer were transferred to support films, rotary shadowed, and observed in the electron microscope. Filaments of RNA obtained by extraction prior to spreading were similar in appearance and in distribution of contour lengths (0.2 to 1.2 μ) to those obtained by phenol extraction of the virus. Most of the filaments resulting from extraction of the virus suspension during spreading on a sodium perchlorate solution, however, were longer than 1 μ. The lengths of the longest filaments exceeded the 5 μ length predicted from chemical data for one single piece of complementary-stranded RNA in the reovirus particle.
The short filaments, 1.2 μ and less in length, fell into a tri-modal pattern of length distribution with peaks at 0.35 μ, 0.60 μ and 1.10 μ. These shorter lengths probably resulted from breakage of the intact RNA during the extraction procedures. The consistently observed pattern of length distribution suggests that they represent relatively stable subunits of the molecule.
Sodium perchlorate extracted reovirus RNA was thermally denatured in formaldehyde prior to spreading by the protein monolayer technique. Length distributions and relative numbers of filaments in the peaks of the tri-modal distribution pattern were similar to those found for unheated material when extracted prior to spreading. This similarity indicates that heating subsequent to extraction produced no further filament breakage. The thin, kinky appearance of the heated filaments, and the appearance of congruent pairs, indicated that heating had separated the strands of the complementary-stranded RNA subunits.
LANGEVIN equations of the type dn× (t)/dtn+...+c × (t)=K (t) constitute the starting point of a phenomenological fluctuation theory of irreversible processes. These equations are not constructed from transport equations (as in the older theory), but via a generalized MASTER equation from phase space mechanics. The MARKOFF processes of first and higher order defined by the various LANGEVIN equations are studied by the prediction theory of stationary stochastic processes. Instead of the variation principle of the ONSAGEB–MACHLUP theory one has the minimization of the prediction error. The mean relaxation path and the entropy of the considered processes are calculated. It is shown that the entropy consists of one part which is given by the relaxation path and another which is determined by the prediction error.
Thermal denaturation of RNA free coat proteins of tobacco mosaic virus (TMV) was studied for wildtype TMV (vulgare) and the temperature-sensitive mutant, Ni 118. The ability to form soluble aggregates as well as the optical properties (ORD, UV-difference spectra), and the sedimentation behavior were used as criteria for the native state.
At pH 7.5, I= 0.02 denaturation is reversible for both proteins. The ORD data indicate that the denatured proteins contain residual secondary structure. The “melting temperatures”, as defined by ORD measurements (cp = 0.02 mM), are 39.5 ± 1°C for vulgare and 27 ± 1°C for Ni 118 at pH 7.5, I= 0.02. By means of the aggregation test (cp = 0.05 mM) somewhat lower melting temperatures were found under the same solvent conditions. The difference between the primary structures of vulgare and Ni 118 proteins being a proline → leucine (pos. 20) replacement, the results suggest the cyclic structure of proline (20) to have a specific stabilizing function in the three dimensional protein structure. This conclusion is supported by preliminary experiments on a temperature-sensitive mutant with a threonine residue in pos. 20.
On the basis of the results obtained in a previous paper it is shown that in the thermodynamic limit the analogues of the Massieu-Plandc functions are linked with each other by means of the Legendre transformation. The existence of the limiting function φk(∞) implies the existence of the limiting function φl(∞) (l<k) under the same assumptions. Passage to the limit and derivation with respect to all independent variables commute. A statistical derivation of the thermodynamic stability condition in its most general form is given which leads naturally to a statistical interpretation of the concept of thermodynamic stability.
Within the framework of the eigenchannel reaction theory above the two-particle thresholdcluster channels are introduced. The eigenchannels of the S-matrix are used, i. e. continuum stateswhich diagonalize both the S-matrix and the nuclear Hamiltonian and represent for each reactionenergy a discrete set of coupled channel wave functions with a common (eigen-) phase. Especiallythe emission of a deuteron is discussed. It is shown that the cluster channels supplement the energy-correlated channels describing the energy partition £1 + e2 = E —Ef and that asymptotic channelorthogonality holds. The characteristic feature of the cluster channels as compared to the energy-correlated channels is that their final state interaction is not limited to a finite matching volumecomparable to nuclear sizes.
It is shown that, for all conceivable ensembles of statistical thermodynamics, at the thermodynamic limit, the frequency function of the fluctuations of macroscopic extensive parameters equals a Gaussian. The proof is based on a generalisation of Khinchin's method using the concept of "smoothed frequency functions."
The relations of the theory of real gases which have first been derived by Mayer and his co-workers can be obtained in a simple way by the functional method. In this case the assumption of the pairwise additivity of the intermolecular potential can be dropped. Apart from some new relations for distributions functions the expansion of the direct correlation functions is obtained as a power series in density with coefficients consisting of integrals over Husimi functions.
The interactions between human haptoglobin, Hp II (genetic types 2 - 1 and 2-2), and bovine hemoglobin, Hb, were investigated taking inhibition of complex formation and complex dissociation in various solvent media as criteria.
As shown by relative peroxidase activity and gel chromatography, complex dissociation occurs at high concentrations of guanidine HCl, urea, sodium chloride, dioxane, and formaldehyde, while in case of sodium dodecylsulfate a low molar ratio (SDS/Hb -Hp<5) is sufficient to split the complex. In general the formation of the complex stabilizes the structure of its constituents.
Excluding solvent conditions which lead to denaturation (as measured by optical rotation), ionpairs and H-bonds seem to prevail in the stabilization of the complex, while hydrophobic interactions should be of minor importance. Chemical modification of histidine and tyrosine with diazonium-1-H-tetrazole and N-acetylimidazole, respectively, prove histidyl-groups in Hb and tyrosylgroups in Hp to participate in the Hb-Hp contact, thus confirming earlier results.
Expectation values of kinetic and potential energy are calculated for some lower antibonding orbital states of simple diatomic molecules using H2+ and HeH2+ as test cases. Common LCAO-MO theory and a scaling procedure are applied which allow an analysis of atomic orbital interactions in terms of RUEDENBERG'S1 promotion and interference effect at various internuclear distances. Contributions to the total energy at different regions of interatomic separations are discussed in detail. A characteristic increase of the kinetic energy is observed for antibonding linear combinations at distances where chemical bonding occurs.
In systems containing singlet-oxygen and aromatic fluorescers energy transfer from singletoxygen dimers to the dye should be observable by emission of the fluorescer. In order to prove this hypothesis, externally generated singlet-oxygen (1Δg) was bubbled through the solutions of dyes (chlorophyll a, eosin y, rhodamine b, luminol, rubrene and acridine orange) in organic solvents.
Luminescence could be observed and its spectral distribution analyzed by sharp cut-off filters and interference filters (rubrene) . Spectra, rates of oxidation, addition of quenchers and the long lasting time dependence of the reported reactions lead to the conclusion that the observed afterglow is due to chemical oxidation mechanisms producing a chemiluminescence. Therefore an excitation of the substances investigated in these experiments by simple physical energy transfer seems not to be predominant.
The electron paramagnetic resonance of copper (II)-tetrammine nitrate in solution of methanol and water has been investigated. The data obtained from the spectra at room temperature and 97 °K together with the optical transition energies determined from single crystal polarized absorption spectra at 77 °K by other authors were used to calculate the LCAO-MO bonding parameters. The bonding orbital of the ammonia molecule cannot be described by the concept of sp2 hybridization which was exclusively used in the theory. Therefore a calculation of the overlap integral S(n) for α bonding and of the superhyperfine splitting was carried out in terms of an arbitrary hybridization parametern. For ammonia, n was taken from the Duncan-Pople hybrid wave function for the lone pair orbital. The o bonding and the out-of-plane π bonding appear to have a moderate degree of covalency (α = Ϭ = 0.91; α’= 0.49). The covalent in-plane n bonding is somewhat stronger (β = 0.87) but is by no means so strongly covalent as is observed in compounds with ligands which do not exclusively coordinate through the lone pair electrons.
At low temperature nine ligand nuclear superhyperfine structure lines corresponding to the interaction of four magnetically equivalent nitrogen nuclei have been observed. The value of α' derived from the superhyperfine splitting is in excellent agreement with that obtained from the copper nucleus hyperfine structure.
The triplet state of acridine orange dissolved in methanol/water matrix was investigated by ESR. In absence of oxygen a strong temperature dependence of the spectra was observed. At low temperature (100 °K) the zero-field splitting parameters calculated from the triplet spectrum are: X/hc = 0.0050 cm-1, Y/hc= 0.0342 cm-1, Z/hc=0.0387 cm-1 , at higher temperature (140 °K) : X*(hc=0.0056 cm-1, Y*/hc=0.0206 cm-1, Z*/hc = 0.0262 cm-1 . It was assumed that the low temperature spectrum is caused by isolated molecules in the triplet state while the high temperature spectrum must be attributed to the triplet exciton state of the acridine orange dimer. From the theory of the ESR triplet exciton spectra it can be shown that in the dimer state of acridine orange the molecular planes form an angle of 50° or 130°. However, it cannot be excluded that the dimer configuration differs in the ground or excited singlet state from the triplet state.
The association of Schlen k’s hydrocarbon was studied by means of osmometric and magnetic measurements. The mixed chain-ring-association can be explained satisfactorily assuming that two different dimers and four monomer species participate in the equilibria, including a monomeric diamagnetic ring. The equilibria existing between the different species are discussed. For the equilibria between the monomer and dimer species, which can be detected in solutions of normal viscosity by means of ESR-measurements, the unexpected values of ΔH=0 for the enthalpie of association and ΔS= +19.7 e. u. for the entropie of association were found.
Singlet oxygen (1Δg) was generated by a microwave discharge and bubbled through a solution of chlorophyll-a in dibutylphtalate at approximately 10-20 torr. It not only excited the dye to its first singlet state but also produced oxidized species which generated a very long lasting weak chemiluminescence. From quenching experiments for the generation of the excited species could computer simulation.
The photoelectron (PE) spectra of dicyano methane and of its dimethyl derivative are tentatively assigned on the basis of a simple MO model. The interactions defined therein between the two cyano groups as well as with the R2C-framework can be parametrized using the PE data. Thus the hyperconjugation πCN/πCR₂ is estimated to amount to 1.7 eV in both compounds. Hyperconjugative effects in methane derivatives H3CX and H2CX2 with X = Br, Cl and CN are compared.
Excitation of CO molecules into the lowest vibrational level of the B1Σ+ electronic state by absorption of the (B 1Σ+υ′=0 →X 1Σ+ ,υ′′=0) resonance band at 1150 Å has been studied under various experimental conditions by observing the steady state fluorescence of the (B 1Σ+→A1Π) Angstrom bands. Stern-Volmer plots of the fluorescence intensities at the addition of various foreign gases yielded straight lines whose slopes k̃qм = kqм · τeff were strongly dependent on the CO sample pressure. This effect was found to be due to changes of the effective radiative lifetime of the B 1Σ+υ′=0 because of resonance trapping of the (0,0) band of the (B → X) fluorescence. The CO(B 1Σ+υ′=0) molecules are found to be quenched by He, Ne, Ar, H2 and D2 with effective collision cross sections of 0.23, 0.48, 22.4, 10.7, and 11.4 Å2, respectively, at 298 °K. In addition, an approximate value for the ratio ABA/ (ABA+ABX)of the radiative transition probabilities of the (B → A) and (B → X) transitions could be derived from the measurements.
The solvent dependence of the photooxidation of tryptophan and 3,4-benzopyrene in aqueous solutions was studied by quantum yield measurements. When the hydrocarbon is dissolved in aqueous solution of caffeine, the quantum yields indicate a 3,4-benzopyrene photosensitized tryptophan oxidation instead of a photocooxidation, which is indicated in aqueous solution of sodium dodecylsulfate. The same photosensitized oxidation as in caffeine solution is observed, when urea ( 6 m) is added to the soap solution, while the fluorescence and absorption spectra indicate no change in the solvation state of the hydrocarbon, comparable to the change from hydrophobic solubilization by the detergent to dipole — induced dipole complex solubilization by caffeine. It is concluded that the difference in the reaction pathways is caused by different solvation states of the excited or reacting oxygen. In the discussion of the results it is referred to reactions of inhibitors.
The cooperative problem for a lattice gas on a plane, square lattice and on a simple cubic lattice is solved by a system of two coupled, transcendental equations, derived by a combinatorial method, which describes a homogeneous or periodical particle density on the lattice as a function of the temperature and the chemical potential of the lattice-gas.
For the particle interaction a Hard-Core potential (nearest neighbour exclusion) with a soft long-range tail is assumed. The zero-component of the Fourier-transform of this long-range interaction part can be positive or negative.
The system of transcendental equations is solved by a graphic method. As a result, the complete pressure-density state diagram and the pressure-temperature phase diagram can be drawn.
The lattice-gas exists in three stable phases: gas, liquid and solid. Three phase changes are possible: condensation, crystallization and sublimation.
Critical points of condensation and freezing are examined. The number of possible phases and phase changes at a fixed temperature depends on the geometric structure of the particle interaction.
Spectrophotometric investigation of the kinetics of the spontaneous reduction of the central metal ion in K2[Mn (IV)-2-α-hydroxyethyl-isochlorine e4] acetate in aqueous alkaline solution in the absence of any reducing agent reveals that it is a pseudo-first order reaction which is specifically hydroxide ion catalyzed. The pKα-value of the acid-base equilibrium has been estimated to be 14.4.
Electron transfer to the central metal ion is the rate limiting step. The measurements of its temperature dependence yields an activation enthalpy of ∆H‡ = 12 kcal/mol and an entropy of activation ∆S‡ = - 30 e.u. thus indicating that the electron transfer step is a bimolecular reaction. The most likely reactant is water. The reduction reaction does not take place with appreciable reaction rates at physiological pH. Thus, when bound to a suitable ligand of the chlorin type, Mn (IV)-compounds are sufficiently stable with respect to autoxidation to play some role in biological redox reactions as postulated recently for the photoreactivation process of the water splitting system in photosynthesis.
A new NAD⊕-isomer was prepared, in which the ᴅ-ribose of the adenosine moiety was sub stituted by the enantiomeric ʟ-ribose. As compared to nicotinamide-adenine-dinucleotide (NAD⊕) and NADH the coenzyme isomer (ᴅ,ʟ)-NAD⊕ and its dihydroform (ᴅ,ʟ)-NADH are far less tightly bound to lactate dehydrogenase and alcohol dehydrogenase from horse liver. In the presence of the second substrate (ᴅ,ʟ)-NAD⊕ and (ᴅ,ʟ)-NADH act as hydrogen acceptor and hydrogen donator, respectively, with lactate dehydrogenase and alcohol dehydrogenases from horse liver and yeast. Compared to NAD⊕ and NADH the Michaelis constants are always increased, the catalytic constants (V/Et) were found to be decreased except for the dihydroform reacting with alcohol dehydrogenase from liver.
Sulfhydryl Groups, Methylmercury Containing Inactivator, Coenzyme Analogue Nicotinamide-(S-methylmercury-thioinosine) dinucleotide was formed by reaction of nicotin amide-(6-thiopurine) dinucleotide with methylmercury chloride. The compound exhibits coenzyme properties in the test with LDH (Km=1.5 × 10-4 м , Vmax=12500) and LADH (Km=1.7 × 10-4 м, Vmax=27) and inactivates YADH and GAPDH. From incubations with LDH and LADH the mercury containing coenzyme could be regained by column chromatography. The compound seems to be qualified for the X-ray structure analysis of the coenzyme-enzyme complex for some dehyrogenases based on the proportion of the heavy metal.
The mass spectrum and the ion molecule reactions of phosphirane and of mixtures of phosphirane with NH3 , NH2D, NHD2 and ND3 have been studied by ion cyclotron resonance spectrometry. Almost all important product ions are formed by PH-group transfer reactions, where ethene is generated as the neutral particle. Only two of the more abundant ions, the protonated molecule, H2P(CH2)2+ and the ion m/e=63, P2H+, are formed via other reaction pathways. Secondary, tertiary and quarternary product ions with the general formula R(PH)n+ (R: phosphirane fragment, n-1, 2, 3) have been detected.
The molecular ion is proved to have a cyclic structure. Two possible structures of the product ions with two and three phosphorus atoms are discussed: a structure with an open phosphorus chain, leaving the phosphirane ring intact and a ring extended structure, produced by a ring extension reaction of the PH-group.
Several rate constants of the ion molecule reactions of the phosphirane molecular ion are given.
Photoelectron (PE) spectra of ethylene and vinylene carbonates and thiocarbonates as well as of methylene trithiocarbonate and some open-chain derivatives are reported.
The low energy bands, well separated in the unsaturated compounds, are assigned to lone pair and π type ionizations. The assignment is based on comparison of PE spectra, modified CNDO calculations, and sulfur Κβ emission spectra. The pronounced substituent effects due to which the first ionization potential varies from 8.4 eV to 11.1 eV are discussed.
Testosterone, Androst-4-en-3,17-dione, Enzyme Induction, S trep to m yces hydrogenans After cultivation of S trep to m yces hydrogenan s in the presence of 3H-labelled testosterone, radio active steroids were extracted separately from the cytosolic, ribosomal and cell wall-membrane fraction of the cells and from the culture medium, respectively.. The separation of the steroids was performed by one-and two-dimensional thin layer chromatography (TLC). The identification of the main metabolites was achieved by crystallization to constant specific radioactivity, specific staining procedures and acetylation. The oxidation of testosterone to androst-4-en-3,17-dione is by far the predominating reaction, which is almost finished after 3 h cultivation. Androst-4-en-3,17-dione is mainly transferred into the culture medium and partly accumulated within the cell wall-membrane fraction. High polar steroid metabolites and androstane derivatives are present in very small amounts only.
The low temperature IR stretching vibrations of difluorodisulfane (FSSF) and thiothionylfluoride (SSF2), in the solid phase and in a cyclohexane matrix, of the mixtures FSSF -SSF2, FSSF-OSF2 and SSF, -OSF2, and of solid difluorotrisulfane (FS3F) have been investigated. While SSF, forms no distinct oligomers, a dimer with absorption bands at 635 and 682 cm-1 has been detected in the case of FSSF. These differences between FSSF and SSF, are rationalized by the different S-F bond lengths. A structure of the FSSF dimer similar to that of the sulfur tetrafluoride dimer is proposed. The low temperature spectrum of FS3F shows 3 bands in the frequency range between 460 and 1000 cm-1: 590, 605 and 680 cm-1, due to associated molecules. FS3F decomposes on warming. The main decomposition products containing fluorine are FSSF and SSF2. Mechanisms for the rearrangement and decomposition of the three compounds studied are discussed.
The mass spectra and the ion molecule reactions of methylphosphine, dimethylphosphine and dimethyldeuterophosphine have been studied by ion cyclotron resonance spectrometry. About 50 ion molecule reaction are observed for each compound. The product ions can be classified as ions with two phosphorus atoms: P2R5+, P2R3+, P2R2+ and P2R+ (R = CH3 or H), as phosphonium and phosphinium ions and ions resulting from collision dissociations and charge exchange reactions. Tertiary ions with three phosphorus atoms like CH3P3H2+ (from CH3PH2) and (CH3)4P3H2 (from (CH3)2PH) have also been detected. The mechanisms of the ion molecule reactions, rearrangements, P -H- and C-H-reactivities and product ion structures are discussed, using in the case of dimethylphosphine the results obtained with the deuterated compound. Rate constants of formation of the more abundant product ions from the molecular ion and the CH3P+ ion, both odd electron particles, have been determined. The reactions with dimethylphosphine have much smaller rate constants than the reactions with methylphosphine.
The kinetics of the photodynamic desactivation of lysozyme in presence of acridine orange as the sensitizer have been investigated in detail varying oxygen, protein, dye concentration, ionic strength and pH value. The kinetics can be approximately described as an over all pseudo-first- order rate process. Changing the solvent from water to D2O or by quenching experiments in presence of azide ions it could be shown that the desactivation of lysozyme is caused exclusively by singlet oxygen. The excited oxygen occurs via the triplet state of the dye with a rate constant considerably lower than that to be expected for a diffusionally controlled reaction. Singlet oxygen reacts chemically (desactivation, k=2.9 × 107 ᴍ-1 sec-1) and physically (quenching process, k = 4.1 × 108 ᴍ-1sec-1) with the enzyme. The kinetical analysis shows that additional chemical reactions between singlet oxygen and lysozyme would have only little influence on the kinetics of the desactivation as long as their products would be enzymatically active and their kinetical constants would be less than about 1 × 108 ᴍ-1 sec-1.
Two routes for the preparation of (CH3)2SnS2N2 are given, which are kinetically controlled reactions. The molecule (CH3)2SnS2N2 was characterized by X-ray analysis. It is an interesting starting material for the preparation of S2N2CO and S3N2O. The latter reacts with iminosulfur oxides and isocyanates under the formation of S3N3SO2F and S3N3SO2CF3. The structure of S3N3SO2F was established by X-ray analysis. The bonding properties are discussed.
The cleavage of thin-nitrogen derivatives with S3N2Cl2 yields also five membered sulfurnitrogen rings. The structure and properties of P3N3F5NS3N2 and C3N3F2NS3N2 are reported. Six, eight and ten membered rings are formed by the reactions of (CH3)3Si–N = S = N–Si (CH3)3 with FSO2–N=S=O, these are S4N4O2 and S5N5+S3N3O4, respectively. The cation S5N5+ is a planar molecule, while the oxygen containing species are puckered. In S4N4O2 the oxygens are attached to one sulfur atom, which has a tetrahedral configuration.
The structure of the silicon containing cyclic and bicyclic rings (CH3)2Si(NSN)2Si(CH3)2 and CH3Si(NSN)3SiCH3 were determined.
Antiserum against crystallized 20β-hydroxysteroid dehydrogenase from Streptomyces hydrogenans was used for different immunodiffusion and immunoprecipitation tests to quantify the bacterial enzyme in cell-free supernatants of the microorganism. After immunoprecipitation and gel electrophoresis the molecular weight of the subunits of 20β-hydroxysteroid dehydrogenase was calculated to be 27 300 ± 700.
The photodynamic deactivation of lysozyme in presence of acridine orange is caused by a reaction between singlet oxygen formed via the dye triplet state and the protein. In order to identify the region where the singlet oxygen reacts with the protein we have investigated the kinetics of the deactivation in presence ofthe inhibitor of the enzymatic reaction N-acetylglucosamine (GlcNAc). The overall experimental rate constant becomes slower with increasing saccharide concentrations. As we can exclude experimentally that this kinetical effect is caused in presence of the saccharide by a physical quenching of singlet oxygen or of the dye triplet state it has to be assumed that GlcNAc protects the surrounding of its bindings place at subsite C of the enzymatic center sterically against an attack of singlet oxygen. In this region three tryptophan residues are located, which could be sensitive against singlet oxygen. Surprisingly, however, it has been found that only those species are protected, in which a second saccharide molecule is bound to the protein, probably at subsite E at the enzymatic center, where no sensitive amino acid side chains are located.
The hypothesis of GLIKMAN and ZABRODA (Biochemistry [USSR] 84,, 239 [1969]) that the primary electron donor during photoreduction of manganese(III) in Mn(III)-hydroxychlorin compounds in oxygen free aqueous alkaline solutions is the axially bound OH- ion was tested with Mn(III)-2-a-hydroxyethyl-isochlorin e4. It has been shown that
1) the primary generation of OH radicals upon irradiation of the complex is highly improbable,
2) light is not essential for the reduction reaction,
3) the kinetics of photoreduction of the Mn(III)-compound in 2 N NaOH clearly is not compatible with OH radical formation.
Levels of the purine nucleoside triphosphates are de creasing towards the end of log phase growth of Streptomyces hydrogenans. Induction of 20β-hydroxysteroid dehy-drogenase by addition of 11β,21-dihydroxy-4,17 (20) -pregna-dien-3-one to the growth medium leads to a pronounced drop in purine nucleoside triphosphate levels with is irreversible in contrast to the initial loss and later accumulation of RNA.
The gas phase ion chemistry of the simplest known phosphorus ylide, trimethylmethylenephosphorane, has been studied in the mass range m/e=2 - 186 and the pressure range 10-7-10-4 Torr. The most abundant product ion, m/e = 104, (CH3)2C2H5PCH2'+ is formed by a methylene group transfer reaction of the molecular ion. Almost all of the other product ions formed from the molecular ion can be subsumed under the general formula (CH3)3PCHPRn+ (R = H, CH3; n=1,2,3). The reactions indicate that the molecular ion has lost its ylide character almost completely. The protonated molecule is formed almost exclusively by a reaction of the fragment ion m/e = 75. This reaction and the CH3PH group transfer reaction indicate a cyclic structure (CH3) HP(CH2)2+ for this ion. A cyclic structure is also assumed for the ion m/e = 73, PC3H6+, which undergoes P and PH transfer reactions. The reactions of the ion m/e = 47 are consistent with the structure CH3PH+. The ICR and mass spectra are given, some metastable decompositions are discussed.
In this paper equilibrium models for the calculation of the excess Gibbs free energy of binary liquid mixtures are developed, the component A of which undergoes chain-forming self-association whilst the component B acts as an 'inert' solvent. It is shown that the extension of the well-known chain-association model of Mecke and Kempter, in which the probability of chain prolongation is assumed to be independent of chain length, is unable to establish satisfactory results because it does not exhibit sufficient unsymmetry. Reduction of the probability of chain growth with in-creasing chain length leads to an improved model with the geometric series replaced by the exponential series. This model, in which only two parameters are used, i. e. the equilibrium constants K for mutual solvation of A and B, and ρ for self-association of A, allows fitting of isothermal experimental GE /R T literature data on cycloalkanol-cycloalkane, alkanol-alkane, and NMF -CCl4 systems within the limits of experimental error. Compared with the two-parameter Wilson equation which gives equally small standard deviations, our equilibrium model has the advantage of allowing passage from GE to HE data and of being applicable to liquid-liquid equilibria.
Nuclear magnetic resonance measurements were carried out on neutron activated 20F(T1/2=11s) nuclei in a single crystal of KZnF3. The quadrupolar splitted NMR spectrum, detected via the 20F β-radiation asymmetry, could be observed using a radio frequency modulation technique. The quadrupole coupling constant was determined to e2 q Q/h= + (12.0 ± 1.5) MHz at room temperature. The sign of e2 q Q was obtained from a simultaneous γ-ray anisotropy measurement on the succeeding 20Ne transition. Utilising a calculated field gradient of the fluorine atom, an fQ = 4.6% is determined. This value is compared with literature data of similar compounds.
Diadamantyldioxetane, trim ethyldioxetane and tetram ethyldioxetane were photolyzed b y light of A > 260 nm . The spectral distribution o f the quanta emitted during photoinduced decom position of dioxatenes was found to be different from fluorescence and phosphorescence o f ketones. Flash photolysis experim ents showed the absorption of an short-lived interm ediate. It was concluded, therefore, that photolysis o fdioxetanes is not a concerted process but involves at least one precursor o f the final product ketone.
ncubation of class II chloroplasts of spinach with copper in the light at pH = 8 in concentrations that inhibit oxygen evolution results in the formation of a copper (II) protein complex with the photosynthetic membrane. The EPR spectra indicate that the four nearest ligands to Cu(II) consist of three oxygen atoms and one nitrogen atom. The copper (II) protein appears to be pre dominantly associated with photosystem II. The formation of this protein as measured by the EPR signal amplitude of its room temperature spectrum correlates with the inhibition of oxygen evolution and of electron transport within photosystem I. This result indicates that the inhibition of photosynthetic electron transport by copper may be due to the formation of a copper (II) chelate with a membrane protein.
The thermal decomposition of 1,2-diadamantyldioxetane was studied by kinetic and spectroscopic methods. Spectra of the chemiluminescence emitted during the thermally induced decomposition of 1,2-diadamantyldioxetane, tetramethyldioxetane and trimethyldioxetane were obtained and the influence of quenchers and radical-scavengers, and the presence of "heavy atoms" in the surrounding of the emitting species was investigated. The kinetics of the decay mechanism was followed by measuring the time dependence of the chemiluminescence. The influence of radical-scavengers, quenchers and "external heavy atoms" on the kinetics was assessed. Experimental results were discussed in terms of a biradical decay mechanism.
Intoxication of class II chloroplasts of spinach with Cu(II) leads to inhibition of millisecond luminescence. The degree of inhibition depends on Cu (II) -concentration. The investgation of the pH dpendence of the inhibition curve of luminescence revealed that (1) there is an inhibition site of copper on the donor side of photosystem II, (2) copper (II) does not act as an uncoupler of photophosphorylation, (3) a protonation equilibrium is involved in the inhibition mechanism, and (4) copper (II) binds to a dissociated residue of a membrane protein.
Some physical and chemical properties of the cancerostat cyclophosphamide (generic name: ENDOXAN) and its basic constituents H3PO4 and nor-N-mustard have been calculated with the help of a modified CNDO/S-method. The spectroscopic data of the H3PO4 , which is the starting-point for a corresponding calculation of cyclophosphamide, has been studied by taking account of the 3 d electron of the phosphorus. Nor-N-mustard is a very reactive compound, characterized by the ability to split off chloride ions and to act as an alkylating agent. The binding of the nor-N-mustard to the cyclic phosphate ester (cyclophosphamide) modifies the chemical reactivity of the mustard group in an essential way, and the 3d electron of the phosphorus plays an important role with respect to the excitability of the C -Cl bonds. Cyclophosphamide must be metabolized in a suitable way to develop the same alkylating activity as the nor-N-mustard. The computation of the excited states of cyclophosphamide revealed a similar term scheme as it was found by Clar in the case of the carcinogenic polycyclic hydrocarbons.
3,17 β-Hydroxysteroid dehydrogenase has been enriched and purified from cytosol of Streptomyces hydrogenans. After ammonium sulfate precipitation and filtration on Sephadex G-100 the enzyme was finally purified by preparative gel electrophoresis and DEAE-Sephadex A-50 chromatography. Polyacrylamide gel electrophoresis in the presence of sodium dodecylsulfate gave a single band of mobility corresponding to molecular weight of 70 200 ± 2 500. 3 β-. 17 β- as well as 20 β-hydroxy steroids were dehydrogenated by the enzyme in the presence of NAD+. The dehydrogenation proceeded faster than the reduction of the corresponding ketosteroids in the presence of NADH. The enzyme does not accent NADP+ or NADPH as co-substrates. The apparent Km values were calculated to be 11 μᴍ for 5 α-dihydrotestosterone, 20 μᴍ for testosterone ana 68 μᴍ for epiandrosterone in the NAD+-driven reaction, 1.8 x 10-4 m for NADH+ and 1.9 x 10-4 ᴍ for NADH. The catalytic activity was influenced by the ratio of NAD+/ATP. The inhibition by ATP appears to be of a competitive type with respect to NAD+ (Ki 1.15 x 10-3 ᴍ).
After sucrose gradient centrifugation in a preparative ultracentrifuge the enzyme sediments with 4.1 ± 0.1 S as estimated in comparison to other proteins of known sedimentation coefficient. The isoelectric point was determined to be 3.9 with the LKB preparative isoelectric focusing column (pH 2-11) and 4.1 with the analytical flat bed polyacrylamide isofocusing (pH 3 - 5). The number of SH groups was determined to be 2 mol/mol enzyme. In the presence of 6 M urea the figure inceases to 3 mol SH/mol enzyme. In the presence of an excess of p-chloromercuribenzoate the enzyme activity decreases only partially.
The effect of NH4Cl on the kinetics of the back reaction of photosystem II as derived from luminescence measurements was investigated in dark adapted Chlorella in the presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) at different temperatures. The kinetics of the back reaction which, under these conditions, leads to the reduction of the S2 state by the primary electron acceptor Q- of photosystem II was observed to be considerably slowed down in the presence of NH4Cl.
Analysis of the kinetic results in the light of the theory of the back reaction developed by Mar and Roy (J. Theor. Biol. 48, 257-281 (1974)) revealed two opposite effects of NH4Cl to be present simultaneously:
1) The enthalpy of activation of the back reaction was lowered (catalyzing effect of NH4Cl)
2) The frequenca factor which indicates the number of collisions of the reacting molecules in the membrane per second is largely decreased (inhibitory effect of NH4Cl).
This reduction of the mobility of the recombining species of the back reaction is the predominant effect of NH4Cl. It is suggested that this effect is due to a change of the conformational state of the membrane induced by dissolution of relative large amounts of NH? within the lipid phase of the thylakoid membrane. This hypothesis is supported by the observation that the value of the exciton yield of the back reaction changes upon addition of NH4Cl.
Photosystem II
It is shown that the kinetics of the back reaction of photosystem II in the seconds time range as derived from the luminescence decay curve in the presence of DCMU is controlled by the internal pH of the thylakoids. Modifications of the conformational state of the photosynthetic membrane while leaving the internal pH unchanged, however, reaction.
Methods are described for an enzymatic preparation of 14C-labeled terpenoids. With a cell-free system of a white mutant of Phycomyces blakesleeanus (Mucoraceae) [14C]squalene and [14C- cis]phytoene can be synthesized from [2-14C]mevalonate. The application of norflurazon, a phenyl- pyridazinone herbicide, helps to increase the yield of squalene. Furthermore, the liquid endosperm of Echinocystis lobata (Cucurbitaceae) was used for the formation of either [14C(-)]kaurene from [14C]mevalonic acid or [14C-/ra/w]geranylgeranyl pyrophosphate in the presence of Amo 1618.
The hydrocarbons formed were purified by alumina-column chromatography and preparative thin-layer chromatography (TLC). Geranylgeranyl pyrophosphate was separated by DE-column chromatography followed by TLC.
Potential energy and dipole moment functions have been calculated for the ground states of the NeH+ (1.0 ≦ R ≦ 15 a. u.) and the KrH+ (1.6 ≦ R ≦ 20 a. u.) ion from highly correlated SCEP/VAR and SCEP/CEPA electronic wave functions. The following spectroscopic constants have been derived: Ne20H+ re = 0.996 ± 0.003 Å, ωe = 2896 ± 20cm-1 , D0(Ne + H+) = 2.10 ± 0.05 eV; Kr84H+ re = 1.419 ± 0.003 Å, ωe = 2561 ±20 cm-1 , D0(Kr + H+) = 4.65 ±0.05 eV. The Einstein transition probability coefficients of spontaneous emission have been calculated for all transitions v ≦ 5 of Ne20H+, Ne20D+, Kr84H+ and Kr84D+, respectively.
For a certain class of ocean models describing the exchange of inorganic carbon between the atmosphere and the surface layer of the ocean as well as between the surface layer and the deep sea the dynamical airborne fraction is evaluated analytically under the assumption that the growth rate of the atmospheric source term (fossil fuel plus net biogenic carbon input into the atmosphere) is slowly variable with time. Each of these models exhibits a certain uptake capacity of the deep ocean which is quantified. Considerations are made as to whether the terrestrial biota are to be regarded as a source or a sink for additional atmospheric CO2 depending on the modelling of the deep ocean. It is shown that a global one-dimensional box-diffusion ocean model with a depth dependent eddy diffusivity K(z) - K(0) exp[-z/z*], with an adjustable parameter set {K(0), z*}, provides a fairly well fit to the prebomb 14C ocean distribution and to an appreciable net biogenic carbon transfer into the atmosphere. The range of future atmospheric CO2 partial pressures is estimated for a given fossil input.
Membrane-Phloretin Interaction, Infrared Raman, ESR Spectroscopy The transport inhibitor phloretin was bound to human red cell membrane and the concomitant structural changes were observed by spectroscopic methods. By the spin labeling method a decrease in fluidity of the membrane was found at 1 and 10 |iM concentrations of the reagent. This result was obtained with the 2-(3-Carboxypropyl)-4,4-dimethyl-2-tridecyl-3-oxazolidinyloxyl, and the 2-(14-Carboxytetradecyl)-2-ethyl-4,4-dimethyl-3-oxazolidinyloxyl lipid spin labels. Infrared spectroscopy of modified membranes revealed an intensity increase of the POO~ band at about 1250 cm-1. Moreover, a shift of the peak at 1050 cm -1 to 1100 cm-1 was observed in the presence of phloretin. Raman spectroscopy of the membranes did not contradict the results found with infrared and ESR spectroscopy: In the phloretin modified membrane we observed a lack of the band at 1085 cm-1, which leads to suggest that the POO" and/or C-C regions are less fluid. Changes of the extracted red cell membrane lipids were less characteristic, and the results differed from those found in red cell membrane.
The influence of temperatur and pressure on the fluorescence quantum yield of N-methylacridone (9,10-dihydro-9-oxo-10-methyl-acridine) in toluene in the range of 283-313 K and 1 bar to 2.5 kbar, respectively, has been investigated. Treatment of the data in terms of the Eyring transition-state theory leads to a consistent interpretation of the observed effect. The unusually large increase of the quantum yield with increasing pressure is attributed to a positive volume of activation, ⊿V≠, for the thermally activated S1-T2 intersystem crossing which is known to be the only deactivation process (of the Si-state) competing with fluorescence. Comparison of the values for ⊿H≠, the activation enthalpy of this process, determined at various pressures, indicates a decrease in ⊿H≠ at elevated pressures. Since ⊿H≠ can be associated with the S1-T2 energy gap involved in intersystem crossing, this result further confirms the conclusion that the change in Franck-Condon factors alone cannot account for the decrease in the intersystem crossing rate with increasing pressure.
The crystal structure of the low temperature phase of anilinium bromide, C6H5NH3⊕Br⊖, was studied by neutron diffraction at T = 100 K. The refinement supports an ordered structure. The structures of the low and high temperature phases are compared and the mechanism of the phase transformation is discussed.
The application of laser induced fluorescence (LIF) in the uv to monitor tropospheric OH concentrations is limited for several reasons. In general the sensitivity of this method increases with the laser intensity. But at the low OH concentrations present in the atmosphere the beginning nonlinearity of the absorption (saturation effect) severely restricts the use of higher laser intensities. The high sensitivity of the LIF technique can be further compromised by the presence of an OH interference signal. This signal is generated by the monitoring laser light itself from laser photolysis of ambient ozone and the succeeding reaction of the photolysis product O (1D) with water to produce hydroxyl radicals. The results of the calculations are presented in a diagram from which the range of laser parameters can be deduced, which can be applied with confidence to monitor OH by the LIF method. The maximum number of signal counts for these working conditions is in the range of 10-3 per laser pulse.
The crystal structure of the high temperature phase of anilinium bromide, C6H5NH3⊕Br⊖ , was studied by X-ray and neutron diffraction at T = 343 K. The refinement supports disordered positions of the -NH3⊕ group. A split-atom model is proposed which includes disorder of the benzene ring. The thermal parameters, hydrogen bond distances, and other experimental data (NMR, NQR, inelastic neutron scattering) are in accordance with this model.
pH-titrations with NADH show two ionizable groups in mitochondrial and cytoplasmic malate dehydrogenase, the first with a pKa in the range 6.8 -8.3 for the mitochondrial and 6.4-7.8 for the cytoplasmic enzyme, the second with a lower limit at 10.2 resp. 11. Comparison with bis-(dihydronicotinamide)-dinucleotide and dihydronicotina-mide-ribosyl-P2-ribose-pyrophosphate instead of NADH indicates that the second alkaline ionization is caused by a residue placed near the adenine binding site of the active centre of the two isoenzymes. Binding studies with NADH and NAD+ give evidence for the participation of a group in the mitochondrial enzyme with pKa 6.8, deprotonation of which is necessary for detectable association of NAD+. In contrast the fixation of NAD+ to the cytoplasmic enzyme is independent of pH.
Stimulated emission from chemically formed excited iodine molecules has been observed. The emission originates from the vibrational state ν′ = 55 of I2(B 3 II). The excited molecules are produced by a three body recombination reaction.
The photochemical cleavage of the endoperoxides of anthradichromene and benzodixanthene into the parent hydrocarbon and oxygen is shown to be an adiabatic photoreaction originating from an upper excited singlet state. This photochemical behaviour is described by a theory for the photochemistry of endoperoxides developed by Kearns and Khan.
Influence of rotational relaxation on tropospheric OH laser induced fluorescence measurements
(1982)
Rotational relaxation of OH molecules in the 2II electronic ground state has been observed to occur in collisions with water molecules with gas kinetic probability. It causes an additional contribution to the already well known sources of interference when LIF is used to monitor tropospheric OH. As the laser generated OH is originally produced mostly in high rotational states, the fast relaxation phenomenon leads to a further population of OH in low rotational states. These states are used to monitor tropospheric OH by spectroscopic methods. The observed effect therefore increases the interference. A mathematical analysis is presented, revealing the effect of all relevant parameters.
The crystal structure of C12H11N2SiCl3 (monoclinic, P21/m, Z = 2, with a: 9.284(4), b: 7.226(2), c: 10.832(5) Å, β = 115.14(3)°) was refined to R(F) =0.035 from 1228 independent reflections. A trigonal bipyramidal, pentacoordinate silicon is observed. The chelated complex shows two different Si−N bonds, a coordinative bond (1.984(2) Å) between Si and N on the axial position and a Si−N single bond (1.737(3) A, equatorial plane), introduced by chemical reaction. The coordinative bond is 14.2% longer than the Si−N single bond. The lengthening of the coordinative bond in the present case is compared with distances in other extracoordinated silicon compounds.
Studies on the transport of anions and zwitterions of acidic amino acids in Streptomyces hydrogenans
(1983)
n Streptomyces hydrogenans, acidic amino acfds are taken up either as anions by a specific transport system or as zwitterions via a nonspecific one. Variations in the zwitterion concentration caused by changes in pH influence the uptake and exchange diffusion by the nonspecific system. Differences in pH-optima for ʟ-glutamate and ʟ-aspartate transport are due to the different pK2-values of these amino acids. The anion transport by the specific system is accompanied by a short hyperpolarization of the membrane potential followed by a secondary influx of potassium ions into the cells.
The order-disorder phase transition which occurs at Tc = 296.9 K in anilinium bromide, C6H5NH3Br, is studied by inelastic neutron time-of-flight measurements. Data are taken from hydrogenated and partially deuterated samples (C6D5NH3Br and C6H5ND3Br) below and above the transition temperature. From the inelastic scattering data the phonon frequency distribution in the range of the intermolecular vibrations is calculated. The assignment of bands is given and changes in the spectra with temperature are discussed. The analysis of the quasielastic line revealed substantial broadening due to rotational diffusion of the -NH3⊕ group. These jump diffusion processes were observed in the orthorhombic high temperature and - with markedly diminished rate - in the monoclinic phase below Tc. From the correlation times at different temperatures the activation energies are estimated for both phases. Comparison with calculated elastic incoherent structure factors suggests jumps of 60° for hindered rotation.
[4-(3-Bromoacetylpyridinio)-butyl]adenosine pyrophosphate as a structural analog of NAD+ reacts covalently with the sulfhydryl groups of thiopropyl agarose. 10-20 μmol can be bound to 1 ml gel. Stabilization of the insoluble coenzym e is attained by treatment with sodium boro hydride (NaBH4). This complex when applied to column chromatography, allow s the separation of various dehydrogenases as a result of their different complex stability coefficients. Alcohol dehydrogenase from liver, lactate dehydrogenase, and adenylate kinase, which all bind to the ADP-analog residues of the gel matrix, can thus be separated by different salt gradients. Alcohol dehydrogenase from yeast, however, does not form a complex and can easily be eluted from the column with phosphate buffer. Glyceraldehyde-3 phosphate and aldehyde dehydrogenases can be eluted by the addition of NAD+ or NADH to the buffer. The uncharged 1,4-dihydropyridin ring of the reduced coenzyme produces a more stable complex with the dehydrogenases than the oxidized form.
Near equilibrium potential energy and dipole moment functions have been calculated for the electronic ground state of the XeH+ ion from highly correlated SCEP/CEPA electronic wavefunctions. The following spectroscopic constants for 132XeH+ are obtained: Re= 1.611 ± 0.005 Å, ωe = 2313 ± 50cm-1, ωexe = 41 ± 5cm-1 and D0(Xe+ + H) = 3.90 ± 0.1 eV.
Infrared transition dipole matrix elements and probability coefficients for 132XeH+ and 132XeD+ are given. The electric dipole moment functions of the protonated rare gas atoms HeH+ to XeH+ are discussed.
The thermal and the photochemical reactions of the endoperoxide of Tetrabenzo(bc,fg.lm,pq)- pentacene have been investigated with respect to its photochromic properties. The thermal yield of irreversible rearrangement reactions was determined to be Adec = 0.045. From the activation parameters of the thermal cycloreversion. forming the parent hydrocarbon and oxygen, a half life time of 114 years at 20 °C has been extrapolated. For the quantum yield of the irreversible photochemical rearrangement a value of Qdec = 0.03 was obtained. As can be seen from the wavelength dependence of the photocycloreversion quantum yield Q1, cycloreversion occurs not only from the thermalized S2(πccπ*cc) but from higher excited states too. The maximum quantum yield was found at 302 nm to be (Q1 = 0.15. From our results it follows that this endoperoxide is of high quality in respect to the colour change colourless/blue and to thermal stability, whereas the reversibility is only moderate.
The recently developed stereospecific sodium salt glycosylation procedure has been successfully applied to the synthesis of the β-ᴅ-2′-deoxyribofuranosides of benzimidazole, 5,6-dihalogeno benzimidazoles, and some 2-substituted analogues in high yield. The 5,6-dibromo analogue was obtained by bromination of the parent nucleoside. These have all been characterized by spectroscopic methods, including 1H NMR, which permitted analyses of their solution conformations and comparison with those of the corresponding ribofuranosides. Some biological aspects, including preliminary results on cytotoxicity and antiviral activity, are briefly considered.
By means of differential thermoanalysis, the miscibility of the main polar tetraether lipid of Thermoplasma acidophilum with two ester lipids, dipalmitoyl phosphatidylcholine and dipalmitoyl phosphatidylglycerol, resp., in the presence of excess water was studied. It is shown that with increasing fraction of tetraether lipid in the mixture, the transition range of dipalmitoyl phosphatidylcholine is broadened and the temperature of the maximum heat flow (Tm) is shifted to lower temperatures; furthermore, the enthaply change (ΔH) of the transition declines. Similar results were obtained with mixtures of tetraether lipid with dipalmitoyl phosphatidylglycerol. It is therefore concluded that the main polar tetraether lipid of Thermoplasma acidophilum , which essentially forms monomolecular layers, is able to form stable common phases with bilayer-forming ester lipids. Miscibility of the tetraether lipid with dipalmitoyl phosphatidylglycerol, which are both monovalent anions at neutral pH, is also observed in the presence of high proton or calcium ion concentrations.
The bipolar main tetraether lipid (MPL) of Thermoplasma acidophilum has been shown to form typical liquid expanded films at the air-water interface. The limiting molecular area at the collaps pressure is approximately Ac=73 Å2 per molecule. Monopolar aiphytanyl diether lipids were found to occupy the same area at high surface pressure as MPL. Thus, it was concluded that in the monofilm only one of the two polar headgroups of the MPL molecules is hydrated, i.e. that the single MPL molecules arc oriented upright. The packing properties of MPT. in the monofilm are determined by the properties of the branched alkyl chains only; the polar head groups do not contribute to the space requirement in the film. The collaps pressure of the MPL film is approximately 39 mN m-1 at 8°C. At a surface pressure of π = 30 mN m-1 and 20 °C the film is stable for many hours.
Potential energy, dipole moment, and electronic transition moment functions for the A 3Πand X3Σ- states of PH have been calculated from highly correlated electronic wavefunctions. The electric dipole moments in the vibrational ground state of PH are calculated to be 0.637 Debye (A 3Π) and 0.403 Debye (X3Σ-). The predicted rates of spontaneous emission between low lying vibrational states of the X state lie in the range of 46 to 109 sec-1 (PH) and 12 to 30 sec-1 (PD). The calculated radiative lifetime of the v' = 0 level in the A 3Π state of 400 ns is lower by about 10 percent than the most recent experimental value. The classical intersection of the 5Σ- and the A 3Πstate has been calculated to lie between v' = 2 and 3 with an expected uncertainty of about 500 cm−1, whereas the onset of the rotationally dependent predissociation lies at v' = 0, J' = 11.
Organodisulfide radical cations R2S2′⊕ and R2C2S2 ′⊕ can be generated from aliphatic as well as aromatic cyclic polysulfides in AlCl3/H2CCl2 solutions and characterized by their ESR spectra. Examples presented are the oxidations of 1,2,3-trithiolanes to 1.2-dithiolane radical cations, in which energetically favored planarized 3 electron/2 center bonds are formed.
Lactate dehydrogenase from pig heart is inactivated by the NAD+ -analog P1-N6-(4-azidophenylethyl)adenosine-P2-[4-(3-azidopyridinio)butyl]diphosphate (6) upon irradiation with UV light of wavelengths in the range from 300 to 380 nm. The decrease in enzyme activity can be prevented by the addition of NAD+ and oxalate. The modified enzyme shows a reduced binding capacity for its coenzyme as compared to native lactate dehydrogenase. The amount of incorporated coenzyme is deduced from the ribose content of inactivated enzyme. Tryptic digestion of the modified protein and separation of the peptides by HPLC yields 5 ribose-containing fractions. One of them, fraction 6 6 , is split by treatment with nucleotide pyrophosphatase into two subfractions, 63 and 58. Only subfraction 63 contains ribose. Whereas peptide 58 shows a UV absorption spectrum similar to that of 4-(3-aminopyridinio)-butyl phosphate (3). Amino acid analyses of the peptides indicate that the inactivator forms covalent bonds with different parts of the protein: Peptide 63 is characterized by a great portion of hydrophobic amino acids whereas peptide 58 shows a high degree of hydrophilicity.
Photofragmentation spectroscopy—the study of "half collisions" with polarized light of subdoppler line width—opens a window to look into the structure of molecules. The energy partitioning among the particular degrees of freedom of the products of the fragmentation reaction is described by the scalar properties, the direction and magnitude of a particular type of motion is described by the vector properties. The measurement of the scalar and vector properties allows a pictorial view of the intermediate state. The forces which make the fragments fly apart or rotate and vibrate can be "seen" from the line shapes. Information on the unstable intermediate state is gained from the stable fragments long after the dissociation of the parent molecule. In particular, information on the "lifetime" of the intermediate on a femtosecond time scale can be obtained.
A number of molecules, mainly three and four atomic, have been studied by this technique. Hydrogen peroxide has shown up as a textbook example. A complete analysis was possible including not only correlation of different types of fragment motion but also a correlation of the two coincident particles formed from the same parent molecule. The experimental results are in full agreement with recent calculations of the dynamics of the fragmentation on newly obtained potential energy surfaces. Hydrogen peroxide shows a strong dependence of its potential energy on the dihedral angle in the two electronic states amenable to laser excitation. This experiment further demonstrates that an analysis is also possible if two states are excited simultaneously.
Another good example is the fragmentation of hydrazoic acid for which also coincident pair correlation has been treated. Here again the results agree excellently with a qualitative picture which can be drawn from recently calculated ab initio potential energy surfaces. The HN3 example is much more complicated than the former one due to its higher structured upper potential energy surface. Strong rotational excitation is observed in the N2 fragment leaving the NH fragment rotationally cold.
The treatment of vector correlations in molecular photofragmentation is a powerful tool for the study of the dynamics of molecular dissociation reactions.
The sesquiterpenoic alcohol nerolidol was separated into its 4 stereoisomers by MPLC of the diastereomeric (1 S, 4 R)-camphanoates.
An analytical GC method was found by which both the enantiomeric pairs of (Z)- and (E)-nerolidol are resolved on a chiral cyclodextrin stationary phase. The olfactoric properties of the nerolidol stereoisomers were investigated.
By a comparative thin layer chromatographic screening of the methanol-soluble leaf exudates from more than 400 Aloe plants (183 species), 5-hydroxyaloin A was identified in 20 species. Whilst 13 of the 20 species revealed interindividual variations concerning to the occurrence of 5-hydroxyaloin A, this anthrone-C-glucosyl was unambiguously detected in each individual of 6 Aloe species. In the leaf exudates from A. marlothii Berger 5-hydroxyaloin A was only traceable in the aloin-containing chemivars. The complete anthrone-C-glucosyl pattern of these 7 clearly characterized species has been determined additionally by qualitative and quantitative high performance liquid chromatography: The results obtained demonstrate that 5-hydroxyaloin only occurs in the more stable A-configuration (10 R, 1′S), thus being till now the only anthrone-C-glycosyl which has not been found as diastereomeric pair genuinely in plants. As well, 5-hydroxyaloin A characterizes a quantitatively significant hydroxylating pathway in biosynthesis of anthranoids. It is discussed as a chemotaxonomic marker of the genus Aloe, especially of the sections Pachydendron and Eualoe.
The radiative lifetimes of the C3Il-X3II transition of the CSi radical have been calculated from highly correlated electronic wavefunctions and compared with available experimental data. For this transition, the Franck-Condon approximation fails due to the strong R-dependency of the transition moment function.
New reactive coenzyme analogues for affinity labeling of NAD+ and NADP+ dependent dehydrogenases
(1995)
Reactive coenzyme analogues ω-(3-diazoniumpyridinium)alkyl adenosine diphosphate were prepared by reaction of ω-(3-aminopyridinium)alkyl adenosine diphosphate with nitrous acid. In these compounds the nicotinamide ribose is substituted by hydrocarbon chains of varied lengths (n-ethyl to n-pentyl). The diazonium compounds are very unstable and decompose rapidly at room temperature. They show a better stability at 0 °C. L actate and alcohol dehydrogenase do not react with any of the analogues. Glyceraldehyde-3-phosphate dehydrogenase reacts rapidly with the diazonium pentyl compound. Decreasing the length of the alkyl chain significantly decreases the inactivation velocity. 3α,20β-Hydroxysteroid dehydrogenase reacts at 0 °C with the ethyl homologue and slowly with the propyl compound. The butyl-and pentyl analogues do not inactivate at 0 °C. Tests with 14C -labeled 2-(3-diazoniumpyridinium)ethyl adenosine diphosphate show that complete loss of enzyme activity results after incorporation of 2 moles of inactivator into 1 mole of tetrameric enzyme. 4-(3-Acetylpyridinium)butyl 2 ′-phospho-adenosine diphosphate, a structural analogue of NADP +, was prepared by condensation of adenosine-2,3-cyclophospho-5′-phosphomorpholidate with (3-acetylpyridinium)butyl phosphate, followed by hydrolysis of the cyclic phosphoric acid ester with 2 ′:3′-cyclonucleotide-3′-phosphodiesterase. Because of the redox potential (-315 mV) and the distance between the pyridinium and phosphate groups, this analogue is a hydrogen acceptor and its reduced form a hydrogen donor in tests with alcohol dehyd rogenase from Thermoanaerobium brockii. The reduced form of the coenzyme analogue also is a hydrogen donor with glutathione reductase. With other NADP +-dependent dehydrogenases the com pound has been show n to be a competitive inhibitor against the natural coenzyme. The acetyl group reacts with bromine to form the bromoacetyl group. This reactive bromoacetyl analogue is a specific active-site directed irreversible inhibitor of isocitrate dehydrogenase.
A non-radioactive cell-free assay was developed to quantitatively determine inhibition of plant-type phytoene desaturase by bleaching herbicides. An active desaturase was prepared from an appropriately cloned E. coli transformant. Another E. coli transformant was used to produce the required phytoene. Phytofluene and t-carotene, the products of the desaturase reaction, were either determined by HPLC or optical absorption spectra. Enzyme kinetics and inhibition data for the bleaching tetrazole herbicide WL110547 are presented as an example.
To investigate the contribution of hydrophobic residues to the molecular recognition of cytochrome c with cytochrome oxidase, we mutated several hydrophobic amino acids exposed on subunit II of the Paracoccus denitrificans oxidase. KM and kcat values and the bimolecular rate constant were determined under steady- or presteady-state conditions, respectively. We present evidence that Trp-121 which is surrounded by a hydrophobic patch is the electron entry site to oxidase. Mutations in this cluster do not affect the binding of cytochrome c as the KM remains largely unchanged. Rather, the kcat is reduced, proposing that these hydrophobic residues are required for a fine tuning of the redox partners in the initial collisional complex to obtain a configuration optimal for electron transfer.
A detailed analysis of the chemical constituents of a Caribbean specimen of Aiolochroia crassa was performed. Five brominated products (1 -5) were isolated and one of these was a new bromotyrosine metabolite. The structure of the new compound 1 has been established from spectral studies. Compounds 1 and 2, which are the major brominated metabolites and have not been previously identified in any Aiolochroia species, could be usefully employed as chemotaxonomic markers.
Photoinduced electron transfer from organic dye molecules to semiconductor nanoparticles is the first and most important reaction step for the mechanism in the so called “wet solar cells” [1]. The time scale between the photoexcitation of the dye and the electron injection into the conduction band of the
semiconductor colloid varies from a few tens of femtoseconds to nanoseconds, depending on the specific electron transfer parameters of the system, e.g., electronic coupling or free energy values of donor and acceptor molecules [2–10]. We show that visible pump/ white light probe is a very efficient tool to investigate the electron injection reaction allowing to observe simultaneously the relaxation of the excited dye, the injection process of the electron, the cooling of the injected electron and the charge recombination reaction.
The effect of a single site mutation of Arg-54 to methionine in Paracoccus denitrificans cytochrome c oxidase was studied using a combination of optical spectroscopy, electrochemical and rapid kinetics techniques, and time-resolved measurements of electrical membrane potential. The mutation resulted in a blue-shift of the heme a alpha-band by 15 nm and partial occupation of the low-spin heme site by heme O. Additionally, there was a marked decrease in the midpoint potential of the low-spin heme, resulting in slow reduction of this heme species. A stopped-flow investigation of the reaction with ferrocytochrome c yielded a kinetic difference spectrum resembling that of heme a(3). This observation, and the absence of transient absorbance changes at the corresponding wavelength of the low-spin heme, suggests that, in the mutant enzyme, electron transfer from Cu(A) to the binuclear center may not occur via heme a but that instead direct electron transfer to the high-spin heme is the dominating process. This was supported by charge translocation measurements where Deltapsi generation was completely inhibited in the presence of KCN. Our results thus provide an example for how the interplay between protein and cofactors can modulate the functional properties of the enzyme complex.
The Na+-F1F0-ATPase operon ofAcetobacterium woodii was recently shown to contain, among eleven atp genes, those genes that encode subunita and b, a gene encoding a 16-kDa proteolipid (subunit c 1), and two genes encoding 8-kDa proteolipids (subunits c 2 andc 3). Because subunits a,b, and c 1 were not found in previous enzyme preparations, we re-determined the subunit composition of the enzyme. The genes were overproduced, and specific antibodies were raised. Western blots revealed that subunits a,b, and c 1 are produced and localized in the cytoplasmic membrane. Membrane protein complexes were solubilized by dodecylmaltoside and separated by blue native-polyacrylamide gel electrophoresis, and the ATPase subunits were resolved by SDS-polyacrylamide gel electrophoresis. N-terminal sequence analyses revealed the presence of subunitsa, c 2, c 3,b, δ, α, γ, β, and ε. Biochemical and immunological analyses revealed that subunitsc 1, c 2, andc 3 are all part of the c-oligomer, the first of a F1F0-ATPase that contains 8- and 16-kDa proteolipids.
The core of photosystem I (PS1) is composed of the two related integral membrane polypeptides, PsaA and PsaB, which bind two symmetrical branches of cofactors, each consisting of two chlorophylls and a phylloquinone, that potentially link the primary electron donor and the tertiary acceptor. In an effort to identify amino acid residues near the phylloquinone binding sites, all tryptophans and histidines that are conserved between PsaA and PsaB in the region of the 10th and 11th transmembrane alpha-helices were mutated in Chlamydomonas reinhardtii. The mutant PS1 reaction centers appear to assemble normally and possess photochemical activity. An electron paramagnetic resonance (EPR) signal attributed to the phylloquinone anion radical (A(1)(-)) can be observed either transiently or after illumination of reaction centers with pre-reduced iron-sulfur clusters. Mutation of PsaA-Trp(693) to Phe resulted in an inability to photo-accumulate A(1)(-), whereas mutation of the analogous tryptophan in PsaB (PsaB-Trp(673)) did not produce this effect. The PsaA-W693F mutation also produced spectral changes in the time-resolved EPR spectrum of the P(700)(+) A(1)(-) radical pair, whereas the analogous mutation in PsaB had no observable effect. These observations indicate that the A(1)(-) phylloquinone radical observed by EPR occupies the phylloquinone-binding site containing PsaA-Trp(693). However, mutation of either tryptophan accelerated charge recombination from the terminal Fe-S clusters.
In der vorliegenden Arbeit werden Verfahren der Mathematik und Informatik entwickelt und eingesetzt, um Struktur, Dynamik und biologische Aktivität aus NMR spektroskopischen und empirischen Parametern zu bestimmen. Dolastatin 10 und Epothilon A sind potentielle Wirkstoffe gegen Krebs, da sie durch Wechselwirkung mit Tubulin die Zellteilung unterbinden. Die 3D Struktur beider Wirkstoffe in Lösung und die Struktur von an Tubulin gebundenem Epothilon A wird aus NMR spektroskopischen Parametern bestimmt. Dolastatin 10 liegt in einem konformationellen Gleichgewicht zwischen der cis -- und trans -- Konformation in der ungewöhnlichen Aminosäure DAP vor. Beide Konformationen des flexiblen Pentapeptids können bestimmt werden mit RMSD = 1.423 Å für das cis -- Konformer und RMSD = 1.488 Å für das trans -- Konformer. Während das trans -- Konformer gestreckt vorliegt, faltet das cis -- Konformer am DAP zurück. Epothilone A ist durch einen Makrozyklus weniger flexibel und sowohl die an Tubulin gebundene Struktur (RMSD = 0.537 Å) als auch freie Form (RMSD = 0.497 Å) kann mit geringen RMSD -- Werten bestimmt werden. Die Struktur der freien Form, welche in Lösung hauptsächlich vorliegt, ist mit der Röntgenstruktur weitgehend identisch. In der an Tubulin gebundenen Form wird eine essentielle Umorientierung der Seitenkette beobachtet, die für die Wechselwirkung mit Tubulin entscheidend ist. Dipolare Kopplungen eines Proteins sind geeignet, eine 3D Homologiesuche in der PDB durchzuführen, da die relative Orientierung von Sekundärstrukturelementen und Domänen durch sie beschrieben wird 85 . Die frühe Erkennung 3D homologer Proteinfaltungen eröffnet die Möglichkeit, die Bestimmung von Proteinstrukturen zu beschleunigen. Eine Homolgiesuche unter Nutzung dipolarer Kopplungen ist in der Lage, Proteine oder zumindest Fragmente mit ähnlicher 3D Struktur zu finden, auch wenn die Primärsequenzhomologie gering ist. Darüber hinaus wird eine Transformation für experimentelle dipolare Kopplungen entwickelt, die die indirekte Orientierungsinformation eines Vektors relativ zu einem externen Tensor in den möglichen Bereich für den Projektionswinkel zwischen zwei Vektoren und somit in eine intramolekulare Strukturinformation übersetzt. Diese Einschränkungen können in der Strukturbestimmung von Proteinen mittels Molekulardynamik genutzt werden 92 . Im Gegensatz zu allen existierenden Implementierungen wird die Konvergenz der Rechnung durch die auf diese Weise eingeführten dipolare Kopplungsinformation kaum beeinflusst. Die dipolaren Kopplungen werden trotzdem von den errechneten Strukturen erfüllt. Auch ohne die Nutzung bereits bekannter Protein oder Fragmentstrukturen kann so ein erheblicher Teil der NOE -- Information substituiert werden. Die Dynamik des Vektors, der die beiden wechselwirkenden Dipole verbindet, beeinflusst den Messwert der dipolaren Kopplung. Dadurch wird Information über die Dynamik von Molekülen auf der µsZeitskala zugänglich, die bisher nur schwer untersucht werden konnte. Die Messung dipolarer Kopplungen für einen Vektor in verschiedenen Orientierungen erlaubt die Analyse seiner Bewegung 89 . Im besonderen ist die Ableitung eines modellfreien Ordnungsparameters 2 S möglich. Weiterhin lassen sich ebenso modellfrei eine mittlere Orientierung des Vektors, axialsymmetrische Anteile und nichtaxialsymmetrische Anteile der Dynamik ableiten und auswerten. Die Anwendung der so entwickelten Protokolle auf experimentelle Daten 90 lässt Proteine deutlich dynamischer erscheinen als auf der Zeitskala der Relaxationsexperimente zu erkennen ist. Der mittlere Ordnungsparameter sinkt von 0.8 auf 0.6. Dies entspricht einer Erhöhung des Öffnungswinkels der Bewegung von ca. 22 ° auf ca. 33°. Die Bewegungen weichen teilweise bis zu 40% und im Mittel 15% von der Axialsymmetrie ab. Neuronale Netze erlauben eine schnelle (ca. 5000 chemische Verschiebungen pro Sekunde) und exakte (mittleren Abweichung von 1.6 ppm) Berechnung der 13 C NMR chemischen Verschiebung 115 . Dabei kombinieren sie die Vorteile bisher bekannter Datenbankabschätzungen (hohe Genauigkeit) und Inkrementverfahren (hohe Geschwindigkeit). Das 13 C NMR Spektrum einer organischen Verbindung stellt eine detaillierte Beschreibung seiner Struktur dar. Resultate des Strukturgenerators COCON können durch den Vergleich des experimentellen mit den berechneten 13 C NMR Spektren auf ca. 1 o/oo der vorgeschlagenen Strukturen eingeschränkt werden, die eine geringe Abweichung zum experimentellen Spektrum haben 122 . Die Kombination mit einer Substrukturanalyse erlaubt weiterhin die Erkennung wahrscheinlicher, geschlossener Ringsysteme und gibt einen Überblick über die Struktur des generierten Konstitutionssubraumes. Genetische Algorithmen können die Struktur organischer Moleküle ausgehend von derer Summenformel auf eine Übereinstimmung mit dem experimentellen 13 C NMR Spektrum optimieren. Die Konstitution von Molekülen wird dafür durch einen Vektor der Bindungszustände zwischen allen Atom -- Atom Paaren beschrieben. Selbige Vektoren sind geeignet, in einem genetischen Algorithmus als genetischer Code von Konstitutionen betrachtet zu werden. Diese Methode erlaubt die automatisierte Bestimmung der Konstitution von Molekülen mit 10 bis 20 Nichtwasserstoffatomen 123 . Symmetrische neuronale Netze können fünf bzw. sieben dimensionale, heterogene Parameterrepräsentationen der 20 proteinogenen Aminosäuren unter Erhalt der wesentlichen Information in den dreidimensionalen Raum projizieren 134 . Die niederdimensionalen Projektionen ermöglichen eine Visualisierung der Beziehungen der Aminosäuren untereinander. Die reduzierten Parameterrepräsentationen sind geeignet, als Eingabe für ein neuronales Netz zu dienen, welches die Sekundärstruktur eines Proteins mit einer Genauigkeit von 66 % im Q 3 -- Wert berechnet. Neuronale Netzte sind aufgrund ihrer flexiblen Struktur besonders geeignet, quantitative Beziehungen zwischen Struktur und Aktivität zu beschreiben, da hier hochgradig nichtlineare, komplexe Zusammenhänge vorliegen. Eine numerische Codierung der über 200 in der Literatur beschriebenen Epothilonderivate erlaubt es, Modelle zur Berechnung der Induktion der Tubulin Polymerisation (R = 0.73) und der Inhibierung des Krebszellenwachstums (R = 0.94) zu erstellen 136 . Die trainierten neuronalen Netze können in einer Sensitivitätsanalyse genutzt werden, um die Bindungsstellen des Moleküls zu identifizieren. Aus der Berechnung der Aktivität für alle Moleküle des durch die Parameter definierten Strukturraums ergeben sich Vorschläge für Epothilonderivate, die bis zu 1 000 mal aktiver als die bisher synthetisierten sein könnten.
Aging and age-related diseases are becoming more and more important for our society and our health care system. Alzheimer's disease (AD) is a disorder that destroys some parts of the brain and is characterized by global cognitive decline including a progressive irreversible loss of memory, orientation, and reasoning. “Healthy aging”, therefore, is one of the major aims for modern medicine. Apoptosis, or programmed cell death, plays an important role for example in fetal development, as well as for learning processes. T-lymphocytes usually undergo apoptosis in order to terminate an acute inflammation. The aim of this thesis was to explore the changes in the apoptotic mechanism of peripheral lymphocytes from Alzheimer’s disease (AD) patients in contrast to physiological aging. The experiments were conducted with lymphocytes of healthy volunteers of different ages, AD patients and young and aged mice. Moreover, transgenic mice carrying familiar AD-related mutations were examined. The aging study of peripheral cells of ‘healthy’-aged volunteers revealed an age-related increase of basal apoptosis. In addition, spontaneous apoptosis as well as apoptosis induced by oxidative stress (ROS) or by Fas engagement were enhanced in aging. A closer look at the subcellular basis of the lymphocytes (e.g. B-, NK-, CD4+-, and CD8+-T cells) determined that all lymphocyte subsets were affected by aging. Therefore, it could be concluded that the regulation of apoptosis is generally impaired in lymphocytes of aged persons. The increased susceptibility to oxidative stress supports the ‘Free radical theory of aging’ that claims the radicals to be the cause for the aging-process. In mice an increase of basal, spontaneous and ROS-induced apoptosis was detected in T cells from the spleen, as well. An oral treatment over two weeks with the Ginkgo biloba extract EGb761 showed a clear reduction of ROS-induced apoptosis in the treated group. Interestingly, basal and spontaneous apoptosis, e.g. physiological apoptosis, were not effected by the plant extract. This is an important benefit for therapy since physiological apoptosis has a great relevance in the elimination of cancer-cells for example. In conclusion, the antidementive drug EGb761 reduces specifically ROS-induced apoptosis that a plays an important role in aging as shown in this thesis. Based on the data found in healthy aging, lymphocytes from AD patients were assessed for apoptosis. The cells show enhanced levels of basal, spontaneous, and Fas-induced apoptosis. In subsequent experiments it was demonstrated that mainly the T cells were responsible for the findings. However, the NK-cells provided an important impact as well. In concordance with AD-affected neurons, peripheral lymphocytes of AD patients show clear signs of apoptotic cell death. In addition, basal apoptosis of T cells and the CD4/CD8-ratio showed a correlation with the severity of the dementia. Therefore, it could be speculated that apoptosis is due to activation-induced cell death (AICD) that occurs in acute and chronic activation of adaptive immunity. In AD there is a chronic neuroinflammation in the CNS triggering degeneration of neural tissue. In order to explore this, the experimental model of lymphocyte’s activation was established in healthy aging first. The study included the detection of various events of lymphocyte’s activation on the basis of the T cell subsets (CD4+ and CD8+). The inducibility to mitogenic stimulation clearly decreased in both subsets in aging. In contrast, T lymphocytes from AD patients showed an enhanced activation subsequent to mitogenic stimulation compared with age-matched nondemented persons. Only proliferation of CD8+ T cells was clearly reduced in AD. This data could be clues that an increased generation of memory T cells due to chronic neuroinflammation might be evident in AD. Memory T lymphocytes show increased inducibility upon mitogenic activation. Interestingly, CD8+ memory T cells display decreased prolifertive capacity. Due to activation, cells die by apoptosis later on. It could be concluded that AD patients display an increased amount of memory T cells compared to controls. The data implicate that there could be a cross talk between inflammatory within the brain and inflammatory cells of the periphery. This is an interesting point since the brain used to be assumed as immune-privileged zone. According to the experiment, the information of the diseased brain is transferred to white blood cells. The connection of those two compartments might raise the opportunity to observe and probably to influence easily not-accessible regions like the brain. Transgenic mice carrying mutations in familiar AD-relevant genes (Amyloid-Precursor-Protein, Presenilin-1, respectively) displayed enhanced levels of apoptotic T cells from the spleen, as well. It seems that those mutated proteins influence the regulation of apoptosis. Probably, they are involved in the increased cell death of T- and NK-cells, as well. Animals overexpressing Presenilin-1 showed reduced levels of apoptotic cell death. It was demonstrated with molecuar biology tools that Presenilin-1, processed during apoptosis, has an anti-apoptotic effect.
Diese Zusammenfassung ist in zwei Abschnitte gegliedert. Im Abschnitt 6.1. wird die physiologische Bedeutung der Glutamatrezeptoren (GluR) und ihr biologischer Hintergrund kurz erklärt. Am Ende dieses Abschnitts wird der Stand der Strukturanalyse des GluR-B Ionenkanals zu Beginn des Projektes zusammengefasst. Im nachfolgenden Abschnitt 6.2. sind die wesentlichen Ergebnisse der hier vorgelegten Arbeit zusammengefasst. 6.1. Die Bedeutung von Glutamatrezeptoren - Stand der Strukturanalyse zum Beginn dieser Arbeit Die Kommunikation zwischen Nervenzellen erfolgt vorwiegend an hochspezialisierten Kontaktstellen den chemischen Synapsen. Der enge Raum zwischen sendender und empfangender Nervenzelle wird auch als synaptischer Spalt bezeichnet. Der Prozess der synaptischen Übertragung beruht auf der präsynaptischen Freisetzung von chemischen Botenstoffen, sogenannten Neurotransmittern in den synaptischen Spalt. Die Aminosäure L- Glutamat (Glu) ist der wichtigste erregende Neurotransmitter im menschlichen Gehirn und Rückenmark. Dementsprechend bedeutend ist die Rolle der ionotropen Glutamatrezeptoren (iGluRs), die sie bei der elektrochemischen Erregungsübertragung am synaptischen Spalt spielen (Seeburg, 1993), (Hollmann and Heinemann, 1994), (Dingledine et al., 1999). Die Freisetzung von Neurotransmittern wird durch ein elektrisches Signal (Aktionspotential) ausgelöst, das sich entlang der Nervenfaser, dem Axon, bis zur Nervenendigung, der Synapse, fortpflanzt. Nach der Freisetzung diffundieren die Neurotransmitter durch den synaptischen Spalt und binden an sogenannte Rezeptoren. Ionotrope Glutamatrezeptoren sind Ionenkanäle, die in die Membran der nachgeschalteten (postsynaptischen) Nervenzelle eingebaut sind. Sie zählen deshalb zu den Membranproteinen. Als ligandgesteuerte kationenselektive Ionenkanäle machen Glutamatrezeptoren (GluRs) die postsynaptische Membran nach Aktivierung durch Ligandbindung für bestimmte Kationen durchlässig. Der Einstrom von Ionen bewirkt eine Änderung des Membranpotentials. Die Stärke der synaptischen Übertragung ist lebenslang modulierbar; die sogennante synaptische Plastizität wird als eine entscheidende Grundlage für die Erklärung von Lernen und Gedächtnis angesehen. Drei synthetische Agonisten aktivieren die GluRs selektiv und wurden deshalb für die Klassifizierung der ionotropen Glutamatrezeptoren herangezogen. Bei den Agonisten handelt es sich um -Amino-3-hydroxy-5-methyl-4-isoxazol-4-propionat (AMPA), Kainat and N- Methyl-D-Aspartat (NMDA). Die ersten beiden Subtypen werden auch als non-NMDA- Rezeptoren zusammengefasst. Die Aktivierung und Desensitivierung der non-NMDA Rezeptoren ist schneller als die der NMDA-Rezeptoren. Aus molekularbiologischer Sicht (siehe Kapitel 1.3.2.) zeigen die drei Klassen der ionotropen Glutamatrezeptoren eine beträchliche Diversität. So gibt es vier verschiedene Unterheiten vom AMPA-Subtyp, nämlich GluR-A, GluR-B, GluR-C und GluR-B. In dieser Arbeit steht die Strukturanalyse eines aus GluR-B Untereinheiten bestehenden AMPA-Rezeptors im Vordergrund. (Die weitere Unterteilung der NMDA- und Kainatrezeptoren kann dem Kapitel 1.3.2. auf Seite 6 entnommen werden.) Bestimmte Abschnitte der Aminosäurensequenz von Glutamatrezeptoren sind durch hydrophobe Bereiche gekennzeichnet ((M1-M4) in Abbildung 6.1.A (A.)). Das durch verschiedene Untersuchungen etablierte Modell der Glutamatrezeptor-Topologie zeigt 3 Transmembrandomänen (M1, M3 und M4) und eine Membranschleife (M2) (Hollmann et al., 1994), (Kuner et al., 1996). Der Aminoterminus ist extrazellulär, der Carboxyterminus hingegen intrazellulär. Daraus ergibt sich die in Abbildung 6.1.A (B.) abgebildete Topologie (Paas, 1998). S1 und S2 kennzeichnen die Ligandbindungsdomäne. Glutamatrezeptoren (GluR) sind Oligomere, die sich mit grosser Wahrscheinlichkeit aus vier Untereinheiten (Rosenmund et al., 1998), (Ayalon and Stern-Bach, 2001) zusammensetzen (siehe Kapitel 1.3.3.). Die Zusammenlagerung verschiedener Untereinheiten zu einem funktionellen Kanal setzt voraus, dass die Untereinheiten zum gleichen Subtyp gehören, d.h. AMPA Untereinheiten können nur mit anderen AMPA Untereinheiten einen Ionenkanal bilden. Das gleiche gilt für die Zusammensetzung von NMDA und Kainat-Rezeptoren. Das Modell eines tetrameren Glutamatrezeptors ist im Bild C. der Abbildung 6.1.A zu sehen. Die Bestimmung der Quartärstruktur eines vollständigen Glutamatrezeptors ist bislang nicht veröffentlicht. Die strukturelle Analyse von Proteinen erfordert die Isolierung von reinem und funktionellem Protein. Im Vergleich zu den meisten löslichen Proteinen erfordert die Isolierung von Membranproteinen oft besonderer Optimierung. Falls das Vorkommen des Proteins in natürlichem Gewebe gering ist, so kann die strukturelle Analyse durch rekombinante Expression in einem geeigneten Wirtsorganismus zugänglich gemacht werden. Die Isolierung von Milligramm-Mengen eines rekombinanten homomeren GluR-B Rezeptors aus dem entsprechenden Baculovirusexpressionssystem (Keinänen et al., 1994) wurde in unserem Labor etabliert (Safferling et al., 2001) und wurde im ersten Jahr dieses Projektes fortgeführt. Durch zonale Ultrazentrifugation konnte gezeigt werden, dass die molekulare Masse des GluR-B Proteinkomplexes ca. 495 kD beträgt. Dieser Wert liegt in der Nähe des theoretischen Molekulargewichts eines tetrameren Ionenkanals, dessen Molmasse sich aus vier GluR-B Untereinheiten (104 kD) und einer Detergenzmizelle von ca. 63-97 kD zusammensetzt (Safferling et al., 2001). Die elektronenmikroskopische Analyse des Proteinkomplexes von W. Tichelaar aus unserer Gruppe erfolgte 1999 durch Negativfärbung. Für die Strukturanalyse mit Hilfe der Software IMAGIC wurden 10 000 Proteinteilchen selektiert. Das Ergebnis der Bildrekonstruktion ist in der folgenden Abbildung 6.1.B gezeigt. Die projezierten Dimensionen des Models entsprechen einem Molekül mit den Dimensionen 17 nm × 11 nm × 14 nm. Das Model zeigt keine ausgezeichnete Symmetrie, die auf die Stöchiometrie des GluR hinweisen könnte. Das Molekül zeigt mit Färbemittel gefüllte Vertiefungen und innere Strukturen, die vielleicht an der Ionenleitung beteiligt sind. 6.2. Funktionelle und strukturelle Charakterisierung des GluR-B Ionenkanals In der Fortsetzung des oben beschriebenen Projektes wurden für die rekombinante Expression desselben Rezeptors (GluR-B homomer) stabil transformierte Insektenzellen eingesetzt. Dazu wurde die für die GluR-B Untereinheit kodierende und in Plasmiden enthaltene DNA in Insektenzellen transformiert (siehe APPENDIX A.2.2.). Im Vergleich zu dieser auf Dauerhaftigkeit angelegten Integration der Rezeptor DNA wird die Proteinexpression beim Baculovirusexpressionssystem durch Infektion mit rekombinanten Baculoviren initiiert. Der Vergleich zeigte, dass die mit Baculoviren erzielten Ausbeuten bei GluR-B etwa doppelt so hoch waren als bei stabil transformierten Zellen. Allerdings fallen bei stabil transformierten Zellen die eventuellen Nachteile der viralen Belastung auf die zellulären Sekretionsprozesse weg. Im Verlauf der elektronenmikroskopischen Analyse von baculoviral erzeugtem GluR-B Protein hat sich gezeigt, dass Proteine viralen Ursprungs unter Umständen selbst doppelt aufgereinigte GluR-B Proben verunreinigen können (siehe APPENDIX A.2.1.). Dieser Punkt ist bei einer Einzelbildverarbeitung von grosser Relevanz, falls die virusspezifischen Proteinverunreinigungen eine ähnliche Grösse haben wie das eigentliche Zielprotein. Das Hauptziel dieser Arbeit war es, das Potenzial stabil transformierter Insektenzellen für die Expression von homomeren GluR-B Ionenkanälen zu bewerten und dabei die Stöchiometrie der Untereinheiten in diesem Ionenkanal aufzuklären. Zu diesem Zweck wurden biochemische und elektronenmikrosopische Techniken eingesetzt. Zur Isolierung des GluR-B Ionenkanals aus stabil transformierten Insektenzellen wurde das bestehende Aufreinigungsprotokoll für die Affinitätchromatographie an immobilisierten Metallionen (IMAC) (Safferling et al., 2001) optimiert, indem das Chargenverfahren durch das Durchflussverfahren ersetzt wurde (zur genaueren Erklärung der Optimierung siehe RESULTS 4.1.2.). Abbildung 6.C zeigt ein silbergefärbtes Gel mit den Eluaten der IMAC und Eluaten der abschliessenden Affinitätschromatographie mit immobilisiertem M1-Antikörper. Die auf den Bahnen 5-8 aufgetragen GluR-B Proben wurden auch für die Einzelteilchenanalyse mittels Elektronenmikroskopie verwendet. Die Ligandbindungsaktivität von GluR-B wurde durch Filterbindungsexperimente mit dem Radioliganden [3H]-AMPA vor und nach der Isolierung aus den Membranfragmenten bestimmt. Die KD-Werte sind für beide Proben ähnlich gross. Der Bmax-Werte ist für die aufgereinigte Probe wie erwartet sehr viel (mehr als 200×) höher. Die Ergebnisse der Ligandbindungsexperimente sind im Kapitel 4.2.1 tabellarisch zusammengefasst. Die oligomere Struktur des isolierten Ionenkanals wurde durch Quervernetzungsexperimente (Cross-linking) und Einzelteilchenanalyse von negativ gefärbten Proteinmolekülen bewertet. Die Quervernetzungsexerimente selbst erbrachten kein eindeutiges Ergebnis im Hinblick auf oligomere Struktur des komplett zusammengesetzten Rezeptors. Kontrollexperimente mit dem Lysat vom Rattenhippocampus zeigten, dass mit DTSSP ein geeigneter Cross-Linker verwendet wurde (siehe RESULTS 4.3.2.). Neben einem aus 4 Banden bestehenden Muster (siehe RESULTS 4.3.1.) lieferten die Quervernetzungsexperimente mit isoliertem GluR-B aber einen deutlichen Hinweis auf die Stabilität von dimeren GluR-B Strukturen, die im Einklang mit einer jüngst veröffentlichten Arbeit stehen (Ayalon and Stern-Bach, 2001). Diese Veröffentlichung liefert zusätzliche (Armstrong et al., 1998) Hinweise auf die Bedeutung von Dimeren in der Glutamatrezeptorstruktur und postuliert, dass sich ein kompletter Glutamaterezeptor aus einem Dimer-Paar zusmmensetzt, wobei die Dimere zuerst gebildet werden. Die nachfolgende Abbildung 6.2.B zeigt negativ gefärbte GluR-B Ionenkanäle bei einer 46000× Vergrösserung. Die Aufnahme stammt von einem Philips EM 400 Elektronenmikroskop. Für die 3D Rekonstruktion wurden 500 der in Abbildung 6.2.B gezeigten Rezeptormoleküle ausgewählt. Dieser relativ kleine Datensatz besteht aus GluR-B Ionenkanälen deren Präservierung in Uranylacetat als besonderes vielversprechend eingeschätzt wurde. Dieser positive Effekt wurde auf die Verwendung frisch von einer Wasseroberfläche aufgefischter Kohlefilme zurückgeführt (siehe RESULTS 4.4.3.3.). Während der Klassifizierung dieses Datensatzes fiel auf, dass die beim Band-Pass-Filtern für die niedrigen Frequenzen gesetzten Cut-offs einen deutlichen Einfluss auf die erste Klassifizierung der unterschiedlichen zweidimensionalen Ansichten des Proteinkomplexes haben (siehe RESULTS 4.4.3.4.). Aus diesem Grund wurde der gleiche Datensatz mit 5 verschiedenen low-frequency cut-offs (LFCO) gefiltert (siehe Table 4.4.3.4.) und getrennt klassifiziert. Von den 5 resultierenden Klassifikationen wurden 3 (LFCO 0,005, 0,03 und 0,05) für die weiterführende 3D Rekonstruktion ausgewählt. Die Evaluierung der resultiernden 3D Modelle ergab, dass der mit einem LFCO von 0,03 gefilterte Datensatz eine Klassifikationen erlaubte, die zu einem 3D Modell (Modell GluR-BII/a siehe RESULTS Figure 4.4.3.4.H) führte, das im Vergleich zu den beiden anderen Rekonstruktionen konsistenter war. Am stärksten spricht für dieses Modell die Übereinstimmung der Input-Projektionen mit den Reprojektionen der 3D Rekonstruktion (siehe siehe RESULTS Figure 4.4.3.4.H). Zur Verfeinerung des Modells GluR-BII/a wurden die beiden Projektionen mit der höchsten Standardabweichung vom Klassendurchschnitt (class average) eliminiert. Die verbleibenden 11 Projektionen bildeten die Input-Projektionen für die Berechung eines verfeinerten Modells, GluR-BII/b, das auf einer neuen Zuordnung der Euler-Winkel beruht. Das Ergebnis dieser Berechung ist in der nachfolgenden Abbildung gezeigt. Das Modell in Abbildung 6.2.C zeigt einen zentralen Kanal und hat die Dimensionen 18 nm × 14 nm × 11 nm. Die Stöchiometrie der Untereinheiten ist aus dem Modell, das mit grosser Wahrscheinlichkeit einen komplett zusammengesetzten GluR darstellt, nicht ablesbar. Ebensowenig zeigt das Modell eine eindeutig vierzählige oder fünfzählige Symmetrie. Allerdings ist die erkennbare zweizählige Symmetrie im Einklang mit dem vorgeschlagenen Pair-of-Dimer Modell (Ayalon and Stern-Bach, 2001), das auf eine teramere Struktur des oligomeren Ionenkanals schliessen lässt. Die Ergebnisse dieser Arbeit zeigen, dass stabil transifzierte Insektenzellen eine durchaus geeignete Quelle für GluR-B Ionenkanäle sind. Nachteilig sind die geringen Ausbeuten. Allerdings kann durch weitere Selektion der Zellen die GluR Expression noch gesteigert werden (siehe APPENDIX A.2.2.). Bei höheren GluR-B Ausbeuten könnte zukünftig auch die Detektion des Rezeptors in vitrifizierten Proben in Verbindung mit Kryo-Elektronen- mikroskopie und auch die 2D-Kristallisation gelingen. Die während dieses Projekts gemachten Kristallisationsexperimente (siehe APPENDIX A.3.) und Kryo-Experimente mit GluR-B Protein aus dem Baculovirusexpressionssystem (siehe RESULTS 4.4.1. und 4.4.2.) ergaben negative Ergebnisse. Das Potential der Kryo-Methode konnte allerdings in Kontrollexperimenten mit Tabak-Mosaik-Virus (TMV) gezeigt werden. Kryo-Daten von GluR-B würden die Berechnung eines genaueren Strukurmodells erlauben. Die Reprojektionen des hier besprochenen Strukturmodells GluR-BII/b aus der Abbildung 6.2.C könnten als Referenzen für das Alignment der vitrifizierten GluR Ionenkanäle dienen. Für das langfristige Ziel der Rekonstituition des Rezeptors in Liposomen sollte die Delipidierung des Membranproteins während der Aufreinigung möglichst reduziert werden. Hier erscheinen zwei Ansätze sinnvoll. Die Aufreinigung des Proteins in einem Schritt durch die Erweiterung des tags am Carboxyterminus von nur 6 auf 10 Histidin-Reste. Ausserdem gibt es Hinweise, dass die Anwesenheit von Lipiden während der Aufreinigung für seine Rekonstituierbarkeit förderlich ist (Huganir and Racker, 1982).
The shortage of functional information compared to the abundance of sequence information characterizes today’s situation in functional genomics. For many years the knock-down of a gene’s product has been the most powerful way of analysing its function. In addition to the complete knock-out by homologous recombination, several different techniques have been developed to temporarily knock down gene expression through methods based on specific sequence recognition, such as knockdown by antisense oligonucleotides, ribozymes, aptamers or RNAi.
The ESF workshop on ‘Impact of Nucleic Acid Chemistry on Gene Function Analysis’ brought together researchers who use techniques that are different but highly related. It offered an opportunity for an in-depth discussion of recent progress and common problems. Antisense oligonucleotides aptamers and ribozymes are techniques that have been used successfully for many years to validate targets. However, recent developments, such as increased tightness of binding (e.g. locked nucleic acids) or the combination of different methods (e.g. using aptamers to design ribozymes), have continued to improve the existing techniques. RNA interference (RNAi) is a defence mechanism of the cell against viruses. Since the exact mechanism of action within the cell is still unclear, RNAi was a particularly exciting topic at the workshop and was addressed in the largest number of presentations. Predictability of positional effects (accessibility of RNA) is a problem shared by all techniques using sequence-specific recognition and was the subject of quite controversial debates.
The meeting comprised over 50 people from 14 countries (13 European countries and the USA).
The light-harvesting chlorophyll a/b protein complex (LHC-II) is the major collector of solar energy in all plants and it binds about half of the chlorophyll in green plants. LHCII is a trimer in the photosynthetic membrane; each monomer consists of 232 amino acids, binds and orients a minimum of 12 chlorophyll molecules and three caroteinoids (two luteins and one neoxanthin) for light-harvesting and energy transfer. Although, the structure of LHC-II has been determined at 3.4 Å resolution by electron microscopy of two-dimensional crystals (Kühlbrandt et al., 1994), this is not sufficient to allow a complete understanding of the mechanism of energy transfer from LHC-II to the reaction centre, since the effective resolution in the z dimension is 4.9 Å. In fact, the chemical difference between Chl a and Chl b, which has a formyl group instead of the methyl group at the 7-position in the chlorin ring, is too small to be detected at this level of resolution. In addition, the orientation of the chlorophyll tetrapyrroles have not been determined unambiguously. This information is essential for a detailed understanding of the energy transfer within the complex and to the reaction centres of photosystem II and I (PSII and PSI). X-ray crystallography of three dimensional (3D) crystals may yield a more complete structure at high resolution. 3D crystals have been grown from LHC-II isolated from pea leaves using a standard purification procedure (Burke et al., 1978). The thylakoid membranes are solubilised in Triton X-100 and further purified by sucrose gradient ultra centrifugation. The LHC-II fraction is salt precipitated and pellets resuspended at the chlorophyll a/b ratio 2.8 mg/ml in 0.9 % Nonyl-glucoside. Crystals are currently obtained by vapour diffusion in hanging drops. These crystals are thin hexagonal plates, have a fairly large unit cell and diffract quite weakly. The high level of the background is due both to the detergent, necessary for protein solubilisation, and lipids, required for the trimer and crystals formation. However, three data sets, each from one single crystal have been collected up to 3.2 Å resolution over a rotation range of 135°. The crystals were exposed to a very highly collimated and brilliant beam (ID-14 EH1 at ESRF, Grenoble, France) and were kept under a stream of cold nitrogen to prevent radiation damage. Data were successfully integrated using the program XDS by Kabsch (1993). The crystals were found to belong to the space group P6 22 3 and have unit cell dimensions of a=128.45, b=128.45, c=135.32, a= ß=90º, ?=120. The solution of the phase problem was tackled by molecular replacement using, as a search model, the LHC-II structure solved by electron cryo-microscopy studies of twodimensional crystals (Kühlbrandt et al. 1994). Three different programs were tested: the most used AMoRe (Navaza et al., 1994) and the brute force based program Brute (Fujinaga
Human epidermal-type fatty acid binding protein (E-FABP) belongs to a family of intracellular non-enzymatic 14-15 kDa lipid binding proteins (LBP) that specifically bind and facilitate the transport of fatty acids, bile acids or retinoids. Their functions have also been associated with fatty acid signalling, cell growth, regulation and differentiation. As a contribution to better understand the structure-function relationship of this protein, the features of its solution structure determined by NMR spectroscopy are reported here. Both unlabeled and 15N-enriched samples of recombinant human E-FABP were used for multidimensional high-resolution NMR. The sequential backbone as well as side-chain resonance assignments have been completed. They are reported here and are also available at the BioMagResBank under the accession number BMRB-5083. The presence of six cysteines in the amino acid sequence of human E-FABP is highly unusual for LBPs. Four of the six cysteines are unique to the E-FABPs: C43, C47, C67 and C87. In the three-dimensional structure of E-FABP, two cysteine pairs (C67/C87 and C120/C127) were identified by X-ray analysis to be close enough to allow disulfide bridge formation, but a S-S bond was actually found only between C120 and C127 [Hohoff et al., 1999]. Since the exclusion of a disulfide bridge between C67 and C87 improved the Rfree factor of the crystallographic model, the existence of a covalent bond between these two side- chains was considered unlikely. This agrees with the NMR data, where SCH resonances have been observed for the cysteine residues C43, C67 (tentative assignment) and C87, thus excluding the possibility of a second disulfide bridge in solution. Based on the NOE and hydrogen exchange data, an ensemble of 20 energy-minimized conformers representing the solution structure of human E-FABP complexed with stearic acid has been obtained. The analysis of homonuclear 2D NOESY and 15N-edited 3D NOESY spectra led to a total of 2926 NOE-derived distance constraints. Furthermore, 37 slow- exchanging backbone amide protons were identified to be part of the hydrogen-bonding network in the >-sheet and subsequently converted into 74 additional distance constraints. Finally, the disulfide bridge between C120 and C127 was defined by 3 upper and 3 lower distance bounds. The structure calculation program DYANA regarded 998 of these constraints as irrelevant, i.e., they did not restrict the distance between two protons. Out of the remaining 2008 non-trivial distance constraints, 371 were intraresidual (i = j), 508 sequential (|i - j| = 1), 233 medium-range (1 < |i - j| £ 4), and 896 long-range (|i - j| > 4) NOEs. The protein mainly consists of 10 antiparallel -strands forming a >-barrel structure with a large internal cavity. The three-dimensional solution structure of human E-FABP has been determined with a root-mean-square deviation of 0.92 ± 0.11 Å and 1.46 ± 0.10 Å for the backbone and heavy atoms, respectively, excluding the terminal residues. Without the portal region (i.e., for residues 4-26, 40-56, 63-75 and 83-134; the portal region apparently represents the only opening in the protein surface through which the fatty acid ligand can enter and exit the internal binding cavity), an average backbone RMSD of 0.85 ± 0.10 Å was obtained, thus reflecting the higher conformational dispersion in the portal region. Superposition with the X-ray structure of human E-FABP (excluding the terminal residues) yielded average backbone RMSD values of 1.00 ± 0.07 Å for the entire residue range and 0.98 ± 0.06 Å without the portal region. This indicates a close similarity of the crystallographic and the solution structures. The structure coordinates have been deposited at the RCSB data bank under PDB ID code 1JJJ. The measurement of 15N relaxation experiments (T1, T2 and heteronuclear NOE) at three different fields (500, 600 and 800 MHz) provided information on the internal dynamics of the protein backbone. Nearly all non-terminal backbone amide groups showed order parameters S2 > 0.8, with an average value of 0.88 ± 0.04, suggesting a uniformly low backbone mobility in the nanosecond-to-picosecond time range throughout the entire protein sequence. Moreover, hydrogen/deuterium exchange experiments indicated a direct correlation between the stability of the hydrogen-bonding network in the >-sheet structure and the conformational exchange (Rex) in the millisecond-to-microsecond time range. The features of E-FABP backbone dynamics elaborated here differ from those of the phylogenetically closely related heart-type FABP and the more distantly related ileal lipid binding protein. The results on protein dynamics obtained in this work allow to conclude that the different LBP family members E-FABP, H-FABP and ILBP are characterized by varying stabilities in the protein backbone structures. Hydrogen/deuterium exchange experiments displayed significant differences in the chemical exchange with the solvent for the backbone amide protons belonging to the hydrogen-bonding network in the >-sheets. The >-barrel structure of H- FABP appears to be the most rigid, with exchange processes presumably slower than the millisecond-to-microsecond time range. ILBP, on the other hand, shows the fastest hydrogen exchange as well as a significant number of exchange parameters (Rex), implying a decreased stability in the >-sheet structure. E-FABP, finally, appears to rank between these two proteins based on the hydrogen/deuterium exchange, with Rex terms in the >-strands indicating millisecond-to-microsecond exchange processes like in ILBP.
Resonance Raman and Fourier transform infrared spectroscopies have been used to study the aa(3)-type cytochrome c oxidase and the Y280H mutant from Paracoccus denitrificans. The stability of the binuclear center in the absence of the Tyr(280)-His(276) cross-link is not compromised since heme a(3) retains the same proximal environment, spin, and coordination state as in the wild type enzyme in both the oxidized and reduced states. We observe two C-O modes in the Y280H mutant at 1966 and 1975 cm(-1). The 1975 cm(-1) mode is assigned to a gamma-form and represents a structure of the active site in which Cu(B) exerts a steric effect on the heme a(3)-bound CO. Therefore, the role of the cross-link is to fix Cu(B) in a certain configuration and distance from heme a(3), and not to allow histidine ligands to coordinate to Cu(B) rather than to heme a(3), rendering the enzyme inactive, as proposed recently (Das, T. K., Pecoraro, C., Tomson, F. L., Gennis, R. B., and Rousseau, D. L. (1998) Biochemistry 37, 14471-14476). The results provide solid evidence that in the Y280H mutant the catalytic site retains its active configuration that allows O(2) binding to heme a(3). Oxygenated intermediates are formed by mixing oxygen with the CO-bound mixed-valence wild type and Y280H enzymes with similar Soret maxima at 438 nm.
We have isolated and characterized the cDNA encoding a Ca(2+)-dependent nucleoside diphosphatase (EC ) related to two secreted ATP- and ADP-hydrolyzing apyrases of the bloodsucking insects, Cimex lectularius and Phlebotomus papatasi. The rat brain-derived cDNA has an open reading frame of 1209 bp encoding a protein of 403 amino acids and a calculated molecular mass of 45.7 kDa. The mRNA was expressed in all tissues investigated, revealing two major transcripts with varying preponderance. The immunohistochemical analysis of the Myc-His-tagged enzyme expressed in Chinese hamster ovary cells revealed its association with the endoplasmic reticulum and also with pre-Golgi intermediates. Ca(2+)-dependent nucleoside diphosphatase is a membrane protein with its catalytic site facing the organelle lumen. It hydrolyzes nucleoside 5'-diphosphates in the order UDP >GDP = IDP >>>CDP but not ADP. Nucleoside 5'-triphosphates were hydrolyzed to a minor extent, and no hydrolysis of nucleoside 5'-monophosphates was observed. The enzyme was strongly activated by Ca(2+), insensitive to Mg(2+), and had a K(m) for UDP of 216 microm. Ca(2+)-dependent nucleoside diphosphatase may support glycosylation reactions related to quality control in the endoplasmic reticulum.
Zwei der wichtigsten Leistungen eines sich entwickelnden Embryos sind der Aufbau des Blutkreislauf- und des Nervensystems. Beide Systeme sind hierarchisch organisierte Strukturen, deren Verzweigungen nahezu alle Teile des Körpers erreichen. Es gibt eine zunehmende Zahl von Hinweisen darauf, dass ihre Entwicklung eng miteinander verknüpft ist, nach ähnlichen Prinzipien verläuft und verwandte molekulare Mechanismen verwendet. Die Entstehung eines funktionellen vaskulären Netzwerks erfordert Signale, die Prozesse wie die Lenkung und die Verzweigung von Gefäßen in den Zielgeweben kontrollieren. Ähnliche Anforderungen werden an wachsende Axone bei der Knüpfung der Verbindungen des Nervensystems während der Embryonalentwicklung gestellt. Einige der Faktoren, die die Lenkung der Axone kontrollieren, spielen auch eine ähnliche Rolle in der vaskulären Entwicklung. Lenkungsmoleküle, die eine Richtungsinformation vermitteln, sind für die Wegfindung der Axone besonders wichtig. Die größte Familie solcher Lenkungsmoleküle wird durch die Semaphorine gebildet. Semaphorine können in acht Klassen unterteilt werden, deren gemeinsames Merkmal eine konservierte Semaphorin-Domäne ist und die unterschieden werden anhand ihrer Klassen-spezifischen carboxyterminalen Domänen. Die Semaphorin-Familie umfasst sowohl sekretierte als auch membrangebundene Proteine. Die am besten charakterisierten hiervon sind die sekretierten Klasse 3 Semaphorine. Eine Kombination von in vitro und in vivo Ansätzen zeigte, dass die Klasse 3 Semaphorine an der Steuerung der Axon- und Dendritenlenkung, der Bildung von Axonbündeln und der neuronalen Migration während der Entwicklung des Nervensystems beteiligt sind. Sie agieren hauptsächlich als repulsiv wirkende Signale, die Axone aus Regionen ausschließen, von den Geweben weg, in denen sie exprimiert sind. Diese Wirkung wird über die Semaphorin-Domäne vermittelt. Verschiedene Hinweise deuten auf eine Beteiligung von Semaphorinen an der Entwicklung des vaskulären Systems. Sowohl homozygote Sema3a- als auch Sema3c-Mausnullmutanten sterben nach der Geburt aufgrund kardiovaskulärer Defekte. Darüber hinaus binden die Rezeptoren für die Klasse 3 Semaphorine, Neuropilin-1 (Nrp-1) und –2 (Nrp-2), einige Isoformen des vaskulären endothelialen Wachstumsfaktors (Vascular Endothelial Growth Factor, VEGF). Neuropilin-1 und Neuropilin-2-defiziente Mäuse und Neuropilin-1/-2-Doppelmutanten weisen Defekte des Gefäßsystems auf, wie z.B. eine Rückbildung der neuralen Vaskularisierung und Abweichungen in der Entwicklung des Herzens und der großen Gefäße. Die membrangebundenen Semaphorine sind bisher nur wenig untersucht, da zuverlässige in vitro Assays fehlen. Somit ist ein genetischer Ansatz der beste Weg, die physiologische Funktion dieser Proteine zu untersuchen. Aus diesen Gründen war die Zielsetzung dieser Arbeit, durch homologe Rekombination in embryonalen Stammzellen eine Mauslinie herzustellen, die ein Nullallel des membrangebundenen Sema5a-Gens trägt. Für diesen Ansatz wurde ein Mitglied der Klasse 5 Semaphorine gewählt, da es nur zwei Mitglieder dieser Klasse im Mausgenom gibt, die weitgehend komplementäre Expressionsmuster aufweisen. Damit unterscheiden sie sich von den anderen Klassen der Semaphorine, deren Mitglieder stark überlappende Expressionsmuster zeigen. Dies verringert die Wahrscheinlichkeit einer gegenseitigen funktionellen Kompensation nach Mutation eines Gens. Die Klasse 5 Semaphorine sind auch deshalb besonders interessant, da sie die einzigen sind, die sowohl in Vertebraten als auch in Invertebraten vertreten sind. Sie sind gekennzeichnet durch sieben carboxyterminale Typ 1-Thrombospondinmodule (TSP) in ihrer extrazellulären Domäne. TSPs wurden ursprünglich in den Proteinen Thrombospondin 1 und 2 gefunden, in denen sie das Auswachsen von Neuriten verschiedener Nervenzelltypen fördern. Dies lässt vermuten, dass Klasse 5 Semaphorine sowohl inhibierende als auch stimulierende Effekte haben könnten, in dem sie unterschiedliche Rezeptoren mit der Semaphorin-Domäne oder der TSPs aktivieren. Das Expressionsmuster von Sema5A und die bekannte Funktion von Semaphorinen in der Ausbildung neuronaler Verbindungen lassen es sinnvoll erscheinen, bei der Untersuchung der mutanten Tiere den Schwerpunkt auf die Entwicklung des Nerven- und des Gefäßsystems zu legen. Aufgrund technischer Schwierigkeiten konnte innerhalb der Bearbeitungszeit dieser Doktorarbeit nur der Phänotyp des vaskulären Systems untersucht werden. Die Inaktivierung des Sema5a-Gens wurde durch die Verwendung eines ‚Targeting’-Vektors erreicht, welcher die Exone 4 und 5 des Sema5a-Gens durch eine Neomycin-Selektionskassette ersetzte. Aus 144 untersuchten ES-Zellklonen wurden drei ES-Zellinien mit einem rekombinierten Sema5a-Locus identifiziert. Zwei der positiven Klone wurden zur Herstellung einer chimären Maus durch die Morula-Aggregationsmethode verwendet. Mit einem der Klone konnte eine männliche Chimäre erzeugt werden, die nach Kreuzung mit NMRI-Wildtyptieren die Mutation an die Nachkommen weitergab. Der Verlust der Proteinexpression in homozygoten Sema5a-Mutanten wurde durch Westernblot-Analyse von Zellmembranpräparationen homozygoter Embryonen unter Verwendung eines Antikörpers gegen das zytoplasmatische Ende von Sema5A bestätigt. Dieses Ergebnis bestätigte, dass die Deletion des vierten und fünften Exons des Sema5a-Gens ein Nullallel hervorbringt. Nach Verpaarungen heterozygoter Mutanten konnten keine Neugeborenen identifiziert werden, die homozygot für das mutierte Allel waren. Homozygte Mutanten starben zwischen E11,5 und E12,5 der Embryonalentwicklung, der Verlust von Sema5A ist also embryonal letal. Die Morphologie der homozygoten Tiere zeigte keinen offensichtlichen Unterschied zu den heterozygoten Embryonen oder zu Wildtyp-Geschwistern auf. Frühe embryonale Musterbildungsprozesse in Sema5a-Nullmutanten sind also nicht gestört. Ein Tod bei dieser Entwicklungsstufe deutet auf einen Defekt in der Entwicklung des Blutgefäßsystems hin, da die Embryonalstadien zwischen E9 und E13 besonders wichtig für die Ausbildung dieser Gefäße sind und viele Mutationen, die Herz und Blutgefäßen beeinträchtigen, den Tod der Embryonen in diesem Stadium bewirken. Das embryonale Blutgefäßsystem in E10,5 und E11,5 Embryonen wurde durch immunhistochemische Färbungen ganzer Embryonen unter Verwendung eines spezifischen gegen das Platelet Endothelial Cell Adhesion Molecule (PECAM) gerichteten Antikörpers dargestellt, welches in vaskulären Endothelzellen exprimiert ist. Die allgemeine Architektur des Gefäßsystems war in homo- und heterozygoten Mutanten ähnlich und wies weder an E10,5 noch an E11,5 besondere Abweichungen auf. Es wurden bei der Lage und der Anzahl intersomitischer Gefäße, der Entwicklung der dorsalen Aorta oder der Vaskularisierung der Extremitätenanlagen keine Abweichungen festgestellt. Morphologische Defekte konnten jedoch bei E10,5 in den Verästelungen der Blutgefäße detektiert werden, die von den Hauptvenen der Cranialregion abzweigen. Die Verzweigungen waren geringer ausgeprägt als in heterozygoten oder Wildtyp-Vergleichstieren. Insbesondere zeigte sich eine Verringerung der Anzahl sekundärer und tertiärer Verzweigungen. In dem sich entwickelnden Embryo führt die wiederholte Verzweigung von Ästen der Hauptvenen zu einem hierarchisch gegliederten Netzwerk großer Gefäße in der Region des medialen Kopfes. Während die Ausbildung dieses Netzwerkes in den Sema5a-/--Tieren beeinträchtigt ist, erscheint die Organisation der kleinen Gefäße in den mehr dorsal und peripher gelegenen Regionen des Kopfes normal. In heterozygoten und homozygoten Mutanten bilden die kleineren Gefäße ein dicht verzweigtes Netzwerk. Die Verminderung der Komplexität der größeren Gefäße konnte in allen untersuchten Nullmutanten beobachtet werden. Es variierte jedoch die Penetranz des Phänotyps. In allen Fällen war die Anzahl primärer Verzweigungen unverändert, während die Anzahl der sekundären und der tertiären Verzweigungen zu unterschiedlichen Graden reduziert war. Im Gegensatz dazu zeigte sich im Verzweigungsmuster von heterozygoten Mutanten und beim Wildtyp nur eine geringe Variabilität zwischen individuellen Embryonen. Dies belegt, dass die Verminderung des Verzweigungsgrades größerer Gefäße nicht innerhalb der normalen Variabilität liegt, sondern durch die Inaktivierung des Sema5a-Gens verursacht wird. Dieser Phänotyp ist in späteren Stadien sogar deutlicher ausgeprägt. In E11,5 Embryonen waren die Stämme der großen Blutgefäße in den Nullmutanten weniger komplex und in einigen Fällen trat sogar eine Reduzierung der Anzahl primärer Verzweigungen auf. Diese spätere Verminderung der Anzahl bereits ausgebildeter primärer Verzweigungen legt nahe, dass der Phänotyp durch eine Rückbildung von Verzweigungen aufgrund möglicher Defizite in deren Reifung und/oder Stabilisierung erfolgt. Die interessanteste Besonderheit der vaskulären Defekte in den Nullmutanten liegt in ihrer regionalen Spezifität. Bis hier ist das Netzwerk großer Gefäße, welches der anterioren Hauptvene entspringt, das einzige Gefäßsystem, in dem Abweichungen entdeckt wurden. Dieses Netzwerk wird durch die strukturelle Umbildung des primären kapillaren Plexuses gebildet. Zwischen E9,5 und E12 sprießen Zweige rostral aus der Hauptvene, um ein hierarchisch organisiertes Netzwerk von Gefäßen zu bilden. Die Umbildung des primären kapillaren Plexus in den mehr rostral und ventral gelegenen Kopfregionen führt zu der Bildung eines hochverzweigten vaskulären Netzwerkes, welches jedoch bei E10,5 noch nicht hierarchisch organisiert erscheint. Die Signale, die für diesen unterschiedlichen Ablauf der Musterbildung während der Entwicklung des Gefäßsystems des Kopfes verantwortlich sind, sind noch unbekannt. Die besonderen Defekte in der stereotypischen Organisation der cranialen Gefäße in Sema5a-Mutanten legt nahe, dass Sema5A eines dieser Signale sein könnte. Es könnte Teil eines Rezeptor/Ligandenkomplexes sein, welcher positionelle Signale für das Verzweigen und das Wachstum großer Gefäße in rostraler Richtung liefert. Sema5A könnte die Bildung von Verzweigungen durch die Regulierung der Wanderung endothelialer Zellen, ihrer Proliferation oder ihrer Interaktion mit unterstützenden Zellen oder der extrazellulären Matrix kontrollieren. Sema5A könnte Teil eines neuen Signalweges sein oder als Teil eines der bekannten Signalwegs wirken, welcher die Entwicklung des Gefäßsystems reguliert. Einer der Signalwege, die essentiell für die Gefäßbildung sind, wird durch VEGF und Angiopoietin (Ang-1) reguliert. Sowohl in VEGF-, als auch in Ang-1-Mutanten ist die Gefäßumbildung im Kopf beeinträchtigt. Insbesondere erscheint das Netzwerk kleiner Gefäße in den Ang-1 Nullmutanten als nur nur teilweise restrukturiert und die großen Gefäße als weniger komplex. Das Verzweigungsmuster der großen Gefäße in den Ang-1- Nullmutanten ähnelt auffallend dem der Sema5a-Nullmutanten. Eine zweite Ähnlichkeit in den Phänotypen von Ang-1- und Sema5a-Mutanten zeigt sich in der Reduzierung der primären Verzweigungen, welche in den Sema5a-Nullmutanten bei E11,5 beobachtet wird. Hier könnte die Verminderung aus einer Rückbildung von Gefäßen resultieren, wie sie auch typischerweise in Mutanten für Ang-1 oder dessen Rezeptor auftritt. Diese Beobachtung legt nahe, dass Sema5A ein neuer Teilnehmer innerhalb des Ang-1-Signalweges ist, welcher die Auswirkung von Ang-1 auf die endothelialen Zellen der großen Gefäße entweder vermittelt oder moduliert und dadurch das spezifische Muster der Blutgefäße des Kopfes beeinflußt. Mit dieser Doktorarbeit wird zum ersten Mal eine funktionelle Untersuchung des Klasse 5 Semaphorins Sema5A vorgestellt. Die phänotypische Untersuchung von Mäusen, die Nullallele für Sema5a-Gens tragen ergab, dass dieses membrangebundene Protein essentiell für die embryonale Entwicklung ist. Es ist an der Musterbildung des Gefäßsystems beteiligt. Seine Aufgabe besteht möglicherweise darin, die Bereitstellung positioneller Signale für die Ausbildung von Gefäßverzweigungen zu gewährleisten. Einige grundlegende Fragen werden durch diesen Phänotyp aufgeworfen. Sowohl die Ursache für die embryonale Sterblichkeit als auch die zellulären Prozesse, welche in den Sema5a-Nullmutanten beeinträchtigt sind, müssen noch beschrieben werden. Unbekannt ist ebenfalls, ob zusätzlich zu der hier beschriebenen Rolle von Sema5A in der Gefäßbildung dieses an der Entwicklung des Nervensystems beteiligt ist. Die ersten Daten über die physiologische Rolle von Sema5A, welche mit dieser Arbeit vorgelegt werden, öffnen den Weg für weitergehende Untersuchungen über die Funktion des Proteins während der Embrionalentwicklung. Das hier erstmals vorgestellte Modellsystem ermöglicht es, Sema5A regulierte zelluläre Mechanismen zu untersuchen. Zusätzlich stellt es ein Werkzeug zur Verfügung, um die funktionelle Beziehung zwischen der Entwicklung des kardiovaskulären Systems und des Nervensystems zu untersuchen. Damit können die Aufgaben der Semaphorin-Proteinfamilie, die an diesen beiden wichtigen Prozessen beteiligt sind, näher charakterisiert werden.
The conditionally-lethal pso4-1 mutant allele of the spliceosomal-associated PRP19 gene allowed us to study this gene’s influence on pre-mRNA processing, DNA repair and sporulation. Phenotypes related to intron-containing genes were correlated to temperature. Splicing reporter systems and RT–PCR showed splicing efficiency in pso4-1 to be inversely correlated to growth temperature. A single amino acid substitution, replacing leucine with serine, was identified within the N-terminal region of the pso4-1 allele and was shown to affect the interacting properties of Pso4-1p. Amongst 24 interacting clones isolated in a two-hybrid screening, seven could be identified as parts of the RAD2, RLF2 and DBR1 genes. RAD2 encodes an endonuclease indispensable for nucleotide excision repair (NER), RLF2 encodes the major subunit of the chromatin assembly factor I, whose deletion results in sensitivity to UVC radiation, while DBR1 encodes the lariat RNA splicing debranching enzyme, which degrades intron lariat structures during splicing. Characterization of mutagen-sensitive phenotypes of rad2{Delta}, rlf2{Delta} and pso4-1 single and double mutant strains showed enhanced sensitivity for the rad2{Delta} pso4-1 and rlf2{Delta} pso4-1 double mutants, suggesting a functional interference of these proteins in DNA repair processes in Saccharomyces cerevisiae.
Mitogen activated protein kinases (MAPKs) are found in all eukaryotic cells and represent crucial elements in the signal transduction from the plasma membrane to the nucleus. Although a broad variety of extracellular stimuli activate MAPKs, they evoke very distinct cellular responses. The amplitude and duration of MAPK activation determine signal identity and ultimately cell fate. A tight and finely tuned regulation is therefore critical for a specific cellular response. The role and the regulation of extracellular signal-regulated kinase 5 (ERK5), a MAPK with a large and unique C-terminal tail, were studied in different cellular systems. The study highlights two aspects of ERK5 regulation: control of the phosphorylation state and regulated protein stability. In analogy to other MAPKs ERK5 is activated by dual phosphorylation of threonine and tyrosine residues in its activation motif. A first part of the study concentrates on whether and how the protein tyrosine phosphatase PTP-SL is involved in the downregulation of the ERK5 signal. The direct interaction of both proteins is shown to result in mutual modulation of their enzymatic activities. PTP-SL is a substrate of ERK5 and, independent of its phosphorylation, binding to the kinase enhances its catalytic phosphatase activity. On the other hand, interaction with PTP-SL does not only downregulate enzymatic ERK5 activity but also effectively impedes its translocation to the nucleus. The second part of this study focuses on the interaction of ERK5 with c-Abl and its oncogenic variants Bcr/Abl and v-Abl. In this study these tyrosine kinases are demonstrated to regulate ERK5 by two mechanisms: first, by induction of kinase activity and secondly, by stabilisation of the ERK5 protein. Stabilisation involves the direct interaction of unique ERK5 domains with Abl kinases and is independent of MAPK cascade activation. The level of ERK5 and its intrinsic basal activity – rather than its activation – are essential for v-Abl-induced transformation as well as for survival of Bcr/Abl-positive leukaemia cells. Stabilisation of ERK5 thus contributes to cell survival and should therefore be considered as an additional aspect in therapy of chronic myeloid leukaemia. Taken together, the results obtained in this study demonstrate that diverse pathways regulate ERK5 signalling by affecting kinase activity, localisation and protein stability. While the phosphatase PTP-SL is involved in negative regulation of ERK5, Abl kinases potently activate ERK5 and increase its half-life. Protein stabilisation thus is presented as a novel mechanism in the regulation of MAPKs.
In the recent years, high-resolution conditions have been established in solid-state NMR by the combination of magic angle spinning, state-of-the-art r.f. pulse schemes and the introduction of ultra-high magnetic fields. Similar to what is now routine in solution-state NMR, this has opened the way for structure determination by HR-SSNMR methods. Complete structural or dynamical characterization of the biomolecule of interest is most easily achieved if multiple or even uniformly [13C, 15N]-labeled versions are studied. In a first step, experiments that allow the complete assignment of the 13C and 15N resonances have been recently designed. To date, nearly complete chemical shift assignments were reported for two well-ordered proteins, the ±-spectrin SH3 domain and the Crh protein. The SSNMR analysis of the later protein has been presented in Section 4.1. For SSNMR applications, not the molecular size or solubility, but the spectral resolution can be of crucial importance. Experimental parameters and sample inherent conditions such molecular disorder may reduce the overall spectral dispersion. In these circumstances, techniques that allow for spectral simplification without the need of elaborated biochemical procedures (of isotopelabeling) are of special importance. In Section 2, several spectral editing methods have been proposed. These methods not only select resonances due to changesin the physical and chemical environment of the nucleus but they can also directly probe molecular properties such as dynamics and conformational heterogeneity. Once the chemical shifts are available for the biomolecule of interest, methods that permit to obtain structural restraints can be applied. In the case of multiply isotope labeled proteins, such techniques can in principle result in multiple structural parameters. In Section 3.1, we have shown that, similar to solution-state NMR, secondary chemical shifts can be readily employed to study the local backbone conformation. Inaddition, distance constraints between protons may be encoded in high-resolution on rare spins like 13C and 15N and measured. Finally, carbon-carbon constraints may be probed by employing frequency selective r.f. pulse schemes. These dihedral and distance constraints may subsequently lead to the determination of protein secondary to tertiary structure from a single protein sample. In Section 4.2,we have shown that high-affinity ligand binding to membrane proteins can be investigated with solid-state NMR. Here, the neuropeptide neurotensin which binds to the Gprotein coupled receptor NTS1 in sub-nanomolar affinity was investigated.Except for the case of rhodopsin, there is currently no information on the high-resolution structure of any other GPCR or a corresponding high-affinity ligand.Our SSNMR results identify, for the first time, a distinct binding mode of neurotensin that could be of considerable relevance for further pharmacological studies. As exemplified in section 4.3, HR-SSNMR based structural studies can also assist in refining existing (X-ray or solution-state NMR) membrane-protein structures. The presented results provide, for the first time, direct experimental evidence for a double occupancy of the Q0 binding site in the ubiquinone-bc1 complex and may provide the basis for the complete 3D structural determination of the ubiquinone binding pocket. Advancements regarding sample preparation (for example, including modular labeling, in vitro expression and intein technology) and improvements in NMR hardware instrumentation could open up new areas of solid-state NMR research such as the investigation of large protein-protein complexes or the complete 3D characterization of larger membrane proteins. Solid-state NMR studies of multiply-labeled biomolecules will furthermore profit from improved procedures for calculating 3D structures, in particular in the presence of ambiguousor a limited number of structural constraints. Unlike X-ray crystallography, protein motion does not hinder solid-state NMR methods. In fact, complementary to solution-state NMR, it may provide a very efficient means to study protein folding, flexibility and function under biologically relevant conditions. Hand in hand with solution-state techniques and crystallographic methods, solid-state NMR could provide insight into protein function and the chemistry of life with unprecedented accuracy and flexibility.