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- Biochemie und Chemie (55) (entfernen)
In the present work, the photo-protection mechanisms in plants and purple bacteria were investigated experimentally at the molecular level. For this purpose, several spectroscopic methods were combined and applied to elucidate the function of carotenoids, pigments of the photosynthetic apparatus, in photo-protection. The experiments were focused on the mechanisms involved in quenching of singlet and triplet states of the electronically excited (bacterio)chlorophylls. This photosynthetic reaction events occur on an ultrafast time-scale. Measuring such short-lived events, and understanding the underlying principles, demand some of the most precise experiments and exact measurement technologies currently available. This implies certain requirements for the light source used: a suitable wavelength within the absorption band of the sample, sufficient power, and, most importantly, a pulse duration short compared to the studied reaction. Nowadays, we can achieve all this requirements using femtosecond-spectroscopic systems, which produce laser pulses shorter than 100 femtoseconds (fs). Transient absorption spectroscopy provides important information on molecular dynamics interrogating electronic transitions. The technique is based on photochemical generation of transient species with femtoseconds pump pulses and measuring transient absorption changes of the sample using a second, time delayed probe pulse which in this case is a spectrally broad white-light pulse.
The function of APOBEC3G in the innate immune response against the HIV infection of primary cells
(2008)
In the past few years the regulation of HIV-1 replication by cellular cofactors has been a major topic of ongoing research. These factors potentially represent new targets for antiviral therapy as resistance will be minimized. However this requires a better understanding of the interaction of HIV-1 with these cellular factors and the immune system. The virus infects the cells of the immune system, beginning with macrophages and dendritic cells as primary target cells during transmission. The cellular cofactor, APOBEC3G was found to be an antiviral factor in macrophages, dendritic cells and primary T cells. APOBEC3G is a cytidindeaminase which causes G->A hypermutations in the HIV-Genome. Another protein which has a strong inhibitory effect on the HIV infection is Interferon alpha (IFN-alpha), however the exact reason for this has not yet been elucidated. The bacterial protein, Lipopolysaccharide (LPS) also induces a strong antiviral state in macrophages. In micro-array analysis it was shown that APOBEC3G was upregulated after the stimulation with both IFN-alpha and LPS in macrophages. The goal of this work was to investigate the role of APOBEC3G in the innate immune response to APOBEC3G. For this, the expression of APOBEC3G was examined in HIV-1 target cells after stimulation with IFN-alpha or LPS and the effect of the protein on the viral infection was examined. In the first experiments it could be shown through real time quantitative PCR that APOBEC3G was overexpressed after the stimulation with IFN-alpha or LPS. This result could be shown in monocytes derived macrophages from different blood donors. It was also shown that the overexpression of APOBEC3G correlated directly with the concentration of IFN-alpha. Through mutational analysis it could be then shown that the overexpressed APOBEC3G protein was also functional in the cells. In order to show that this was the result of APOBEC3G, the protein was the regulated through lentiviral vectors. After transduction of cell lines with lentiviral vectors containing APOBEC3G, the infection was inhibited by up to 70%. The infection was restored after the addition of shRNAs against APOBEC3G. For the further experiments, CD34+ stem cells were used. The cells were transduced the day after thawing with lentiviral vectors containing an eGFP marker gene and either APOBEC3G or shRNAs against APOBEC3G. The CD34+ cells were then cultivated and differentiated to macrophages. The cells transduced with Lentiviral vectors containing APOBEC3G had a very high expression of APOBEC3G in the cells, however the cells transduced with shRNA against APOBEC3G did not show a reduction in the protein expression. The infectivity of the transduced CD34+ and CD34 derived macrophages was then examined. It was expected that the cells transduced with APOBEC3G would show a reduced HIV-1 infection, and the cells transduced with shRNA against APOBEC3G would show an increase in infection. After the transduction and differentiation the CD34+ cells from the 3 donors were stimulated and infected with wild type HIV-1 and Vif defective HIV-1 virus. Vif is a viral protein that can bind to APOBEC3G leading it to the proteasome for degradation. The cells from the first donor transduced with APOBEC3G, were very difficult to infect. In general the shRNA against APOBEC3G had little effect on the course of infection; presumably, the shRNA against APOBEC3G was not active in most of these cells. Only the cells from the first donor showed an increase in HIV infection after the transduction with the shRNAs against APOBEC3G, this was most notably the case in the cells stimulated with IFN-alpha, which usually show very little infection. This work showed that APOBEC3G plays an important role in the innate immune response to HIV-1. The effect of APOBEC3G is both cell type as well as donor dependent. Recently, an interesting study also showed that there is a correlation between the expression of APOBEC3G in HIV infected individuals and their progression to AIDS. A better understanding of the role that APOBEC3G plays in the innate immune response would help in the search of new therapeutic possibilities. This could be done by inhibiting the Vif-APOBEC3G interaction in order to increase the amount of active APOBEC3G in the cells or increasing the APOBEC3G concentration in the cells in some manner.
2-Aminopyrimidinium picrate
(2008)
The geometric parameters of the title compound, C4H6N3+·C6H2N3O7-, are in the usual ranges. While two nitro groups are almost coplanar with the aromatic picrate ring [dihedral angles 3.0 (2) and 4.4 (3)°], the third is significantly twisted out of this plane [dihedral angle 46.47 (8)°]. Anions and cations are connected via N-H...O hydrogen bonds. The molecules crystallize in planes parallel to (1\overline{2}1). Key indicators: single-crystal X-ray study; T = 173 K; mean σ(C–C) = 0.002 Å; R factor = 0.036; wR factor = 0.099; data-to-parameter ratio = 10.9.
The title compound, C16H14N2O2, was derived from 1-(2-hydroxyphenyl)-3-(2-methoxyphenyl)propane-1,3-dione. The molecule is essentially planar (r.m.s. deviation for all non-H atoms = 0.089 Å). Two intramolecular hydrogen bonds stabilize the molecular conformation and one N-H...O hydrogen bond stabilizes the crystal structure. Key indicators: single-crystal X-ray study; T = 173 K; mean σ(C–C) = 0.003 Å; R factor = 0.035; wR factor = 0.091; data-to-parameter ratio = 9.3.
The focus of this thesis has been to further advance and develop existing NMR techniques for the study of protein folding. In order to do so, experimental as well as theoretical approaches have been pursued. From the theoretical side, a successful attempt to the development of a general theory for the treatment of residual dipolar couplings in the case of unfolded proteins has been undertaken. Information contained in residual dipolar couplings is especially valuable due to its long-range nature. The dynamic character of unfolded states of proteins, which may be composed of distinct subsets of conformations, renders reliable interpretation of data a non-trivial task. Statistical-coil-based approaches have been shown to be powerful in data interpretation. A consistent theory based on fundamental polymer physics, however, had not been presented so far. The herein presented model addresses this problem building on the original work by Annila and co-workers. In this work, several shortcomings have been identified. These shortcomings have been corrected here leading to a general approach for the treatment of residual dipolar couplings of unfolded proteins. More specifically, it is shown that, in the case of fully unfolded proteins aligned by a steric mechanism, basic dependencies of dipolar couplings such as on chain length and location with in the chain can be analysed in simple analytical terms. The main predictions of the model are compared to experimental data showing reasonable agreement. The presented mathematical framework is principally suited for various improvements which could include the treatment of long-range interactions and of the actual geometry of the given aligment medium. From the experimental side, bovine alpha-lactalbumin has been chosen as a model system for the development of improved time-resolved 1D NMR methods aiming at the observation of conformational transitions by kinetic means. The presented results show that high-quality data can now be obtained at protein concentrations as low as 100uM. Rate constants characterising distinct conformational transitions of up to 8/s have been measured. These are the fastest rate constants which have been reported so far for protein folding events. The NMR data supplemented by complementary biophysical data furthermore demonstrate that the folding of bovine alpha-lactalbumin is more complex than has been anticipated. All data are consistent with a triangular folding mechanism involving parallel pathways of folding for formation of the native state of the protein. Interestingly, such a folding mechanism has also been found for the highly structurally homologous protein lysoyzme from hen egg white. Evidence is presented that the guiding role of long-range interactions in the unfolded state of lysoyzme for mediating intersubdomain interactions during folding is replaced in the case of bovine alpha-lactalbumin by the Ca2+ binding site.
Pulsed electron-electron double resonance (PELDOR) is a well established method concerning nanometer distance measurements involving two nitroxide spin-labels. In this thesis the applicability of this method to count the number of spins is tested. Furthermore, this work explored the limits, up to which PELDOR data obtained on copper(II)-nitroxide complexes can be quantitatively interpreted. Spin counting provides access to oligomerization studies – monitoring the assembly of homo- or hetero-oligomers from singly labeled compounds. The experimental calibration was performed using model systems, which contain one to four nitroxide radicals. The results show that monomers, dimers, trimers, and tetramers can be distinguished within an error of 5% in the number of spins. Moreover, a detailed analysis of the distance distributions in model complexes revealed that more than one distance can be extracted from complexes bearing several spins, as for example three different distances were resolved in a model tetramer – the other three possible distances being symmetry related. Furthermore, systems exhibiting mixtures of oligomeric states complicate the analysis of the data, because the average number of spin centers contributes nonlinearly to the signal and different relaxation behavior of the oligomers has to be treated explicitly. Experiments solving these problems are proposed in the thesis. Thus, for the first time spin counting has been experimentally calibrated using fully characterized test systems bearing up to four spins. Moreover, the behavior of mixtures was quantitatively interpreted. In addition, it has been shown that several spin-spin distances within a molecule can be extracted from a single dataset. In the second part of the thesis PELDOR experiments on a spin-labeled copper(II)-porphyrin have been quantitatively analyzed. Metal-nitroxide distance measurements are a valuable tool for the triangulation of paramagnetic metal ions. Therefore, X-band PELDOR experiments at different frequencies have been performed. The data exhibits only weak orientation selection, but a fast damping of the oscillation. The experimental data has been interpreted based upon quantitative simulations. The influence of orientation selection, conformational flexibility, spin-density distribution, exchange interaction J, as well as anisotropy and strains of the g-tensor has been examined. An estimate of the spin-density delocalization has been obtained by density functional theory calculations. The dipolar interaction tensor was calculated from the point-charge model, the extension of the point-dipole approximation to several spin bearing centers. Even assuming asymmetric spin distributions induced by an ensemble of asymmetrically distorted porphyrins the effect of delocalization on the PELDOR time trace is weak. The observed damping of dipolar oscillations has been only reproduced by simulations, if a small distribution in J was assumed. It has been shown that the experimental damping of dipolar modulations is not solely due to conformational heterogeneity. In conclusion the quantitative interpretation of PELDOR data is extended to copper-nitroxide- and multi-spin-systems. The influence of the mean distance, of the number of coupled spins, of the conformational flexibility, of spin-density distribution and of the electronic structure of the spin centers has been analyzed using model systems. The insights on model compounds mimicking spin-labeled biomacromolecules – in oligomeric or metal bound states – calibrate the method with respect to the information that can be deduced from the experimental data. The resulting in-depth understanding allows correlating experimental results (from for example biological systems) with models of structure and dynamics. It also opens new fields for PELDOR as for example triangulation of metal centers and oligomerization studies. In general, this thesis has demonstrated that modern pulsed electron paramagnetic resonance techniques in combination with quantitative data analysis can contribute to a detailed insight into molecular structure and dynamics.
Cellular metabolism can be envisaged by fluorescence lifetime imaging of fluorophores sensitive to specific intracellular factors such as [H+], [Ca2+], [O2], membrane potential, temperature, polarity of the probe environment, and alterations in the conformation and interactions of macromolecules. Lifetime measurements of the probes allow the quantitative determination of the intracellular factors. Fluorescence microscopy taking advantage of time-correlated single photon counting is a novel method that outperforms all other techniques with its single photon sensitivity and picoseconds time resolution. In this work, a time- and space-correlated single photon counting system was established to investigate the behavior of 2-(4-(dimethylamino)styryl)-1-methylpyridinium iodide (DASPMI) in living cells. DASPMI is known to selectively stain mitochondria in living cells. The uptake and fluorescence intensity of DASPMI in mitochondria is a dynamic measure of membrane potential. Hence, an endeavour was made to elucidate the mechanism of DASPMI fluorescence by obtaining spectrally-resolved fluorescence decays in different solvents. A bi-exponential decay model was sufficient to globally describe the wavelength dependent fluorescence in ethanol and chloroform. While in glycerol, a three-exponential decay model was necessary for global analysis. In the polar low-viscous solvent water, a mono-exponential decay model fitted the decay data. The sensitivity of DASPMI fluorescence to solvent viscosity was analysed using various proportions of glycerol/ethanol mixtures. The lifetimes were found to increase with increasing solvent viscosity. The negative amplitudes of the short lifetime component found in chloroform and glycerol at the longer wavelengths validated the formation of new excited state species from the initially excited state. Time-resolved emission spectra in chloroform and glycerol showed a biphasic increase of spectral width and emission maxima. The spectral width had an initial fast increase within 150 ps and a near constant thereafter. A two-state model based on solvation of the initially excited state and further formation of TICT state has been proposed to explain the excited state kinetics and has been substantiated by the de-composition of time-resolved spectra. The knowledge of DASPMI photophysics in a variety of solvents now provides the means of deducing complex physiological parameters of mitochondria from its behavior in living cells. Spatially-resolved fluorescence decays from single mitochondria or only very few organelles of XTH2 cells signified distinctive three-exponential decay kinetics of viscous environment. Based on DASPMI photophysics in a variety of solvents, these lifetimes have been attributed to the fluorescence from locally excited state (LE), intramolecular charge transfer state (ICT) and twisted intramolecular charge transfer (TICT) state. A considerable variation in lifetime among mitochondria of different morphology and within single cell was evident corresponding to the high physiological variations within single cells. Considerable shortening of the short lifetime component (τ1) under high membrane potential condition, such as in the presence of ATP and/or substrate, was similar to quenching and dramatic decrease of lifetime in polar solvents. Under these conditions τ2 and τ3 increased with decreasing contribution. Upon treatment with ionophore nigericin, hyperpolarization of mitochondria resulted in remarkable shortening of τ1 from 159 ps to 38 ps. Inhibiting respiration by cyanide resulted in notable increase of mean lifetime and decrease of mitochondrial fluorescence. Increase of DASPMI fluorescence on conditions elevating mitochondrial membrane potential has been attributed to uptake according Nernst distributions, to de-localisation of π electrons, quenching processes of the methyl pyridinium moiety and restricted torsional dynamics at the mitochondrial inner membrane. Accordingly, determination of anisotropy in DASPMI stained mitochondria in living XTH2 cells, revealed dependence of anisotropy on membrane potential. Such changes in anisotropy attributed to restriction of the torsional dynamics about the flexible single bonds neighboring the olefinic double bond revealed the previously known sub-mitochondrial zones with higher membrane potential along its length. Membrane-potential-dependent changes in anisotropy have further been demonstrated in senescent chick embryo fibroblasts. In conclusion, spectroscopic observations of excited-state kinetics of DASPMI in solvents and its behavior in living cells had revealed for the first time its localisation, mechanism of voltage sensitive fluorescence and its membrane-potential-dependent anisotropy in living cells. The simultaneous dependence of DASPMI photophysics on mitochondrial inner membrane viscosity and transmembrane potential has been highlighted.
5-LO is the key enzyme in the biosynthesis of proinflammatory leukotrienes. It catalyses the conversion of arachidonic acid to the hydroperoxy intermediate 5(S)-hydroperoxy-6- trans-8,11,14-cis-eicosatetraenoic acid (5-HpETE). In a second step 5-LO catalyses a dehydration reaction forming the unstable epoxide intermediate 5(S)-trans-5,6-oxido-7,9- trans-11,14-cis-eicosatetraenoic acid (leukotriene A4 , LTA4). The 5-LO gene is subjected to versatile regulation mechanisms. Apart from regulation by DNA-methylation and histone acetylation / deacetylation 5-LO gene expression can be regulated by the differentiation inducers calcitriol (1,25-dihydroxyvitamin D3) and transforming growth factor beta (TGFβ) 5-LO gene expression. In the myeloid cell lines Mono Mac 6 (MM6) and HL-60, differentiation with both agents caused a prominent upregulation of 5-LO mRNA level, of 5-LO protein expression and of 5-LO activity. Treatment with calcitriol alone already has an impact on 5-LO gene expression which is additionally potentiated by TGFβ treatment. Previous nuclear run-off analysis and reporter gene analysis could not associate the 5-LO promoter with the induction of 5-LO mRNA expression mediated by calcitriol and TGFβ. Inclusion of the 5-LO coding sequence (cds) and inclusion of the 5-LO cds plus the last four introns of the gene (J to M) in the 5-LO promoter construct pN10 led to an enhanced reporter gene activity. The inductions were dependent on vitamin D receptor (VDR) and retinoid x receptor (RXR) cotransfection. Therefore the work was concentrated on identifying elements outside the 5-LO promoter region which contribute to the calcitriol / TGFβ effect on 5-LO mRNA expression. Insertion of the LTA4 hydrolase coding sequence – a coding sequence of similar size - instead of the 5-LO cds led to a loss of the calcitriol / TGFβ effect (pN10LTA4Hcds 1-fold induction). Therewith, it was proven that the presence of the 5-LO cds is crucial for the upregulating effect of calcitriol / TGFβ on 5-LO mRNA level. Cloning of the SV40 promoter instead of pN10 upstream of the 5-LO cds still showed inducibility by treatment with the inducers which argues for a promoter unspecific effect. Insertion of the 5-LO cds in a promoterless basic vector (pGL3cds) displayed same inductions by calcitriol / TGFβ treatment as the 5-LO promoter 5-LO cds construct (pN10cds). Thus, the effect of the inducers is not dependent on the 5-LO promoter under the in vitro conditions of the reporter gene assay. Hence, further cloning was done with promoterless constructs. Through 5-LO cds deletion constructs a positive regulating region in exon 10 to 14 was discovered. To adapt the natural gene context the last four introns (J-M) of the 5-LO gene were inserted in a promoterless construct containing exon 10 to 14 (pGL3cdsΔABInJM). 5end deletion constructs of it revealed putative vitamin D responsive elements (VDREs) in exon 12 and intron M. Mutation of the putative VDREs led to a reduced calcitriol effect –more prominent when the putative VDRE in intron M was mutated (reduction of 40%). Moreover another putative VDRE in exon 10 with an adjacent SMAD binding element (SBE) was detected. SMAD proteins are effector proteins of TGFβ signalling. Gelshift experiments demonstrated in vitro binding of the VDR-RXR heterodimer to those three putative VDREs. By chromatin immunoprecipitation (ChIP) assay in vivo binding of VDR and RXR was shown to the VDRE in the region of exon 10, exon 12 and intron M. 8h and 24h incubation with calcitriol / TGFβ resulted in enhanced expression of VDR in each of the examined regions. The VDR is able to bind to the VDRE without its ligand, whereas this goes along with corepressor recruitment and thus the VDR has a repressive effect on transcription. Histone H4 acetylation was increased when MM6 cells were treated for 8h or 24h with calcitriol or the combination of calcitriol / TGFβ. This finding implies that at that point of time corepressors associated with the VDR are replaced by coactivators. It seems convincing that 5-LO transcription is mainly promoted by calcitriol alone which leads to a more accessible chromatin structure. Previous data indicated that calcitriol and TGFβ upregulate 5-LO RNA maturation and 5- LO transcript elongation. Thus several elongation markers were investigated by ChIP analysis: Histone H3 lysine 36 (H3K36) trimethylation and H4K20 monomethylation were detected in the analysed regions in exon 10, exon 12 and intron M. In region exon 10 the H3K36 trimethylation status was enhanced after 24h calcitriol or calcitriol / TGFβ treatment. An increased H4K20 monomethylation status in all regions was observed when MM6 cells were treated for 24h with calcitriol / TGFβ. 24h treatment with both agents also enhanced the recruitment of the elongation form of RNA polymerase II, which is phosphorylated at serine 2 of the carboxyterminal domain, to the investigated regions. These findings prove the positive regulating role for calcitriol and TGFβ on 5-LO transcript elongation. A putative mechanism of the effect of calcitriol and TGFβ on 5-LO RNA maturation might be the elevated phosphorylation of serine 2 of the RNA Polymerase II which is known to be followed by recruiting polyadenylating factors.
Development of chromium(VI)-free defect etching solutions for application on silicon substrates
(2008)
Presentation of intracellular processed antigens by major histocompatibility (MHC) class I molecules to CD8+ cytotoxic T lymphocytes is mediated by the macromolecular peptide loading complex (PLC). In particular accessory proteins, including the transporter associated with antigen processing (TAP) and tapasin, play a pivotal role in the MHC class I mediated antigen presentation pathway. TAP belongs to the ATP-binding cassette (ABC) superfamily and consists of TAP1 (ABCB2) and TAP2 (ABCB3), each of which possesses a transmembrane and a nucleotide-binding domain (NBD). The ER-resident glycoprotein tapasin promotes the optimal folding and assembly of MHC-peptide complexes, and independently stabilizes the steady state expression level of TAP. In the present thesis recombinant Fv, scFv and Fab antibody fragments to human TAP from a hybridoma cell line expressing the TAP1-specific monoclonal antibody mAb148.3, were generated. The epitope of the mAb148.3 was mapped to the very last five C-terminal amino acid residues of TAP1 on solid-supported peptide arrays. The recombinant antibody fragments were heterologously expressed in E. coli and insect cells, and purified to homogeneity by affinity chromatography. The monoclonal and recombinant antibodies display nanomolar affinity to the last five C-terminal amino acid residues of TAP1 as demonstrated by enzyme linked immunosorbent assay (ELISA) and surface plasmon resonance (SPR). Surprisingly, the recombinant antibody fragments confer thermal stability to the heterodimeric TAP complex in insect cells when incubated at elevated temperature. At the same time, TAP is arrested in a peptide transport incompetent conformation, although ATP and peptide binding to TAP are not affected. Furthermore, the recombinant antibodies were successfully used in the purification of the PLC from a human B-lymphoblastoid cell line and a novel factor, protein disulfide isomerase (PDI), was identified by matrix assisted laser desorption/ionisation-mass spectrometry (MALDI-MS). In the second part of this thesis the tapasin-MHC class I interaction was investigated. It is for this reason, that an in vitro assay had been established for direct measuring tapasin-MHC class I interactions. First, soluble single chain MHC class I molecules were engineered, choosing two MHC class I alleles: HLA-B4402 representing a highly tapasin-dependent allele and with HLA-B4405, a tapasin-independent allele was chosen. Tapasin as well as the two single chain MHC class I constructs, scB4402-b2m and scB4405-b2m, were expressed in insect cells and purified from insect cell supernatants by affinity chromatography. In contrast to the HLA-B4405 allele, which was expressed and secreted at moderate yield, the HLA-B4402 allele was expressed and trapped inside the insect cells instead of secreted into the medium. Peptide-binding and anisotropy measurements with fluorescein-labeled peptides verified the functionality of the scB4405-b2m. For further investigation of the tapasin-MHC class I interaction an in vitro assay was established using surface plasmon resonance spectroscopy. Due to the transient nature of the interaction including the decreased affinity of both interaction partners, kinetic data acquisition was difficult to evaluate. Furthermore, interaction of the scB4405-b2m with the sensor surface itself contributed to the measured interaction. Additionally, to investigate tapasin editing function, tapasin as well as the scB4405-b2m-peptide complex were tethered on fluid chelator lipid bilayers and monitored by reflectance interference (RIf) and total internal reflection fluorescence spectroscopy (TIRFS). Stable immobilization of scB4405-b2m-peptide complex as well as of tapasin was observed, unfortunately no changes in peptide dissociation kinetics monitored in the TIRFS channel were detected. Presumably, the tapasin-independent HLA-B4405 already loaded with a high affinity peptide is not influenced by the peptide-editing function of tapasin. Here, for the first time an in vitro assay was established for direct probing interactions within the various proteins of the PLC.