Refine
Year of publication
- 1971 (13) (remove)
Document Type
- Article (13)
Has Fulltext
- yes (13)
Is part of the Bibliography
- no (13) (remove)
Institute
- Biochemie und Chemie (13) (remove)
The coenzyme analogue nicotinamide 5-iodouracil-dinucleotide was synthesized by condensation of the two mononucleotides with dicyclohexylcarbodiimide in aqueous pyridine. The enzymatic properties of this compound were compared with those of the nicotinamide-uracil-dinucleotide. Both coenzyme analogues reacted slowly when functioning as a hydrogen carrier in enzymatic tests. The properties were similar to those of nicotinamide-benzimidazole-dinucleotide. The difference spectrum between the intact coenzyme analogue and its mononucleotides showed that the intramolecular interaction between the functional and non-functional moiety was smaller than that in NAD. The interaction corresponded to that of nicotinamide-benzimidazole-dinucleotide. The fluorescence excitation spectrum did not show any energy transfer from the non-functional iodouracil to the dihydronicotinamide part of the analogue. Difference spectra between the coenzyme - enzymecomplex and the two isolated components indicated that the unfolded dihydrocoenzyme was bound to the active site of lactate- and alcohol-dehydrogenase, respectively. Furthermore, they showed aromatic interaction of the non-functional part with parts of the protein. Introduction of iodine into the nicotinamide-uracil-dinucleotide did not remarkably alter the behavior of the analogues. As the iodine is bound very strongly to the coenzyme analogue, it may be useful for X-Ray-investigations of the dehydrogenases.
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.
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 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.
Pyrosulfonyldifluoride reacts with waterfree hydrazine in a molar ratio of 2 : 3 to give hydrazine -1,2-bis(sulfonylfluoride) in a low yield.. The reaction of N-fluorosulfonylamide and SOCl2 yields NH4⊕⊖ N(SO2F)2. This salt is converted to (C6H5)4P⊕⊖N(SO2F)2 in water by (C6H5)4PCl. (CH3)2NNH2 reacts with PSF3, PSF2Br, PSF2CH3 or PSF2C2H5 to yield the following compounds: (CH3)2NNHPSF2, (CH3)2NN (PSF2)2, (CH3)2NNHPSFCH3 and (CH3)2NNHPSFC2H5. The properties and the chemical behaviour of these substances are described. Results of ir-spectra, as well as 31P-, 19F- and 1H-nmr- and mass-spectra and elemental analysis characterize the compounds.
S4N3Cl reacts with sulfonic acids and imido- bissulfonyl derivatives under HCl-evolution to the following compounds: S4N3SO3CF3, S4N3N (SO2F)2, S4NSO3CH3HSO3CH3, S4N3N (SO2CF3) SO2Cl and S4N3N (SO2CF3) SO2F, They are yellow solids which decompose when heated below the melting point. The compounds are formed in nearly quantitative yield and have been characterized by elemental analysis, nmr and electronic spectra.
It is shown that in the case of metals connected by a first order conductor the decomposition of formic acid is less at the element of lower work function while it is more at the element of higher work function. The metals used were Ni, Cd, Zn. The results correspond to the investigations of other authors 1 who showed that the activation energy on alloys depends on how far the concentration of electrons is from full saturation of the lattice type. This effect is explicable in terms of the development of a contact potential, the conditions in the case of metals being similar to those in the case of alloys