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In the current work, several well-known pharmaceuticals (1,4-dihydrazinophthalazine sulfate, caffeine, and papaverine hydrochloride) and new organometallic compounds (nickel(II) cupferronato complexes NiL2An, L = PhN2O2-, n = 1, A = o-phenanthroline (1), o,o’-bipyridine (2) and n = 2, A = H2O (3), o-NH2Py (4), o-C6H4(NH2)2 (5); silylene-bridged dinuclear iron complexes [Cp(OC)2Fe]2SiX2 (X = H (6), F (7), Cl (8), Br (9), I (10)); 3-silaoxetane 3,3-dimethyl-2,2,4,4-tetraphenyl-1-oxa-3-silacyclobutane (11) and 3-silathietane 3,3-dimethyl-2,2,4,4-tetraphenyl-1-sila-3-thiacyclobutane (12) compounds), which have successfully been characterized by using vibrational spectroscopy in conjunction with accurate density functional theory (DFT) calculations, are presented. The DFT computed molecular geometries of the species of interest reproduced the crystal structure data very well and in conjunction with IR and Raman measurements helped us to clarify the structures of the compounds, for which no experimental data were available; and this, especially for the new organometallic compounds, where the X-Ray analysis was limited by the non-availability of single crystals (3, 5, 10). Furthermore, a natural population analysis (NPA) and natural bond orbital (NBO) calculations together with a detailed analysis of the IR and Raman experimental as well as calculated spectra of the new organometallic compounds, allowed us to study some special bonding situations (1-12) or to monitor the structural changes observed with the change in temperature during the Raman experiments (11, 12). By combining these two methods (DFT and vibrational spectroscopy), the auspicious results obtained on the organometallic compounds 6-12 and overall in literature, made us confident of the power of theoretical calculations in aiding the interpretation of rich SERS spectra by solving some interesting issues. Consequently, the Raman and SERS spectra of well-known pharmaceuticals (1,4-dihydrazinophthalazine sulfate, caffeine, and papaverine hydrochloride) or new potentially biological active organometallic complexes (1-5), that were synthetized by our coworkers, were discussed with the assistance of the accurate results obtained from DFT calculations (structural parameters, harmonic vibrational wavenumbers, Raman scattering activities), and many previous incomplete assignments have been analyzed and improved. This allowed us to establish the vibrational behavior of these biological compounds near a biological artificial model at different pH values or concentrations (Ag substrate), taking into account that information about the species present under particular conditions could be of great importance for the interpretation of biochemical processes. The total electron density of molecules and the partial charges situated on selected atoms, which were determined theoretically by NPA, allowed us to establish the probability of different atoms acting as an adsorptive site for the metal surface. Moreover, a closer examination of the calculated orbitals of molecules brought further arguments on the presence or absence of the photoproducts at the Ag surface during the irradiation (1,4-dihydrazinophthalazine sulfate). Overall, the results provide a benchmark illustration of the virtues of DFT in aiding the interpretation of rich vibrational spectra attainable for larger polyatomic adsorbates by using SERS, as well as in furnishing detailed insight into the relation between the vibrational properties and the nature of the Ag substrate-adsorbate bonding. Therefore, we strongly believe that theoretical calculations will become a matter of rapidly growing scientific and practical interest in SERS.
The human retina is a multilayered neuroectodermal tissue specialized in the transformation of light energy into electric impulses which can be transmitted to the brain where they are perceived as vision. Since the retina is easily accessible and functional aspects are directly recordable, the study of this tissue has been at the forefront of neuroscience research for over a century. Studies have revealed that the distinct functions of the retina require a large degree of differentiation which is achieved by the coordinated function of approximately 55 different cell types. The highly structured anatomy and the functional differentiation of the retina is a result of its distinctive transcriptome and proteome. Due to the complexity of the retina it has been difficult to estimate the number of genes actively transcribed in this tissue. Great efforts in the elucidation of retinal disease genes have led to the identification of 139 retina disease loci with 90 of the corresponding genes cloned thus far . In contrast to the success in the hereditary disorders, efforts to identify the genetic factors conferring manifestations known as age-related macular degeneration (AMD) have revealed sparse results. AMD is a retinal disease affecting a significant percentage of the older population. This disorder is likely due to exogenic as well as genetic factors. To further our understanding of retinal physiology and facilitate the identification of genes underlying retinal degenerations, particularly AMD, our efforts concentrated on the systematic analysis of the retinal transcriptome. Since approximately half of all retinal degeneration-associated genes identified to date are preferentially expressed in retina, it is plausible that the investigation of gene expression profiles and the identification of retina-expressed transcripts could be an important starting point for characterizing candidate genes for the retinal diseases. The expressed sequence tags approach included the assessment of all retinal expressed sequence tags (EST) clusters indexed in the UniGene database and of 1080 single-pass ESTs derived from an in-house generated human retina suppression subtracted hybridization (SSH) cDNA library. In total, 6603 EST clusters were evaluated during this thesis and detailed in-silico analysis was performed on 750 EST clusters. The expression of the genes was evaluated using reverse transcriptase-polymerase chain reaction (RT-PCR), followed by confirmation using quantitative reverse transcriptase-polymerase chain reaction (qRT-PCR), as well as conventional and virtual Northern blot analysis. The expression profiling of 337 selected EST clusters led to the identification of 111 transcripts, of which 60 are specific or abundant to the retina, 3 are expressed at high levels in the retinal pigment epithelium (RPE), and 48 are expressed in brain as well as in retina. The EST approach used to select candidate transcripts allowed us to assess the effectiveness of the two available resources, the UniGene database and the retinal SSH (retSSH) cDNA library. From the results obtained, it is evident that the generation of suppression subtracted libraries to identify cell-specific transcripts constitutes the most straight-forward and efficient strategy. In addition to the high percentage of candidate genes that are identified from an SSH cDNA library, it has the added benefit that genes expressed at low levels can be identified. Furthermore, comparison of our retina-enriched gene set with previously published studies demonstrated only limited overlap of the identified genes further confirming the valuable source of retinal genes from our retinal SSH cDNA library. The effort of our and other groups has resulted in the establishment of the full-length coding sequence of 55 of the 111 genes uniquely or preferentially expressed in the retina. Using various methods such as bioinformatical analysis, EST assembly, cDNA library screening, and rapid amplification of cDNA ends (RACE) a number of genes were cloned in the scope of this thesis including C1orf32, C4orf11, C7orf9, C12orf7, C14orf29, DAPL1, and GRM7. Bioinformatic analyses and cDNA library screening were used to isolate the full-length cDNA sequence and determine the genomic organization of C7orf9, also identified as RFRP. This 1190 bp retina-specific transcript from chromosome 7p15.3 encodes a precursor protein for at least two small neuropeptides, referred to as RFRP-1 and RFRP-3. Since C7orf9 is localized in the critical region for dominant cystoid macular dystrophy (CYMD) its role in the pathology was investigated. Southern blot analysis and sequencing of samples from two affected individuals of the original pedigree used to localize the disease gene excluded the gene from involvement in this disease. Multiple isoforms of the C12orf7 gene were assembled from a number of clones identified from library screenings, PCR amplifications, and RACE experiments. The gene variants, transcribed from chromosome 12q13.13, have been found to be expressed exclusively in retina. Because of the multiple alternative splicing of the gene, we can only speculate about the nature of the protein it encodes. The longest transcript, which includes all six exons plus the last intervening sequence, encodes a 471 aa protein which contains a nuclear localization signal and five ankyrin repeats. The existence of many isoforms is also observed in mouse suggesting that they may have a relevant role in cellular physiology. Five novel splice variants of the glutamate metabotropic receptor 7 (GRM7) resulting from the use of alternative 3’-end exons were identified and characterized. One of the novel variants, GRM7_v3, encodes a 924 aa protein and is therefore the longest putative GRM7 protein reported to date. Even though they are not retina-specific, the isoforms are preferentially expressed in the nervous system. Although the functional properties of the specific carboxyl-termini are still unclear, it is known that axon targeting of GRM7_v1 is mediated by the last 60 aa of the protein. Hence the novel isoforms may direct the protein to specific subcellular localizations. The C1orf32 gene, preferentially expressed in retina, is organized in 10 exons and is transcribed from chromosome 1q24.1. Bioinformatic analyses of the 639 aa putative protein not only identified the mouse and rat orthologous genes but also the LISCH7 gene as a potential member of the same family. Since the LISCH7 protein has been shown to function as a low density lipoprotein receptor, the C1orf32 protein may be involved in retinal lipid homeostasis. Disturbances in lipid metabolism have been proposed as one of the pathways involved in AMD etiology. Thus, the role of C1orf32 in this complex disease should be investigated. Expression analyses of the death-associated protein-like 1 (DAPL1) gene revealed that it is expressed in both the retina and the RPE at high levels. The 552 bp transcript encodes a 107 aa putative protein and is transcribed from chromosome 2q24.1. In-silico analyses identified an additional 12 related proteins from various species which share high similarity constituting a novel protein family. The similarity to the death-associated-protein (DAP) is particularly interesting since this protein has been found to be indispensable for programmed cell death. Therefore, DAPL1 is an excellent candidate for retinal disease as apoptosis is generally the ultimate cause in retinal degeneration. The retina-specific C4orf11 and C14orf29 genes localized on chromosome 4q21.22 and 14q22.1, respectively, are both transcribed in more than one isoform. The encoded proteins do not contain any known domains but because of their retina-specific expression they may be important for proper retinal physiology. As part of the long-term goals of the project, several of the cloned genes are being genotyped to construct single nucleotide polymorphism (SNP) maps. Projects to investigate haplotype frequencies of candidate genes in large cohorts of controls and AMD patients are ongoing. Thus, by establishing a collection of 111 genes expressed exclusively or preferentially in the retina, the present work has laid the foundation for future research in retinal diseases.
A distinguishing feature of eukaryotic cells is the spatial separation of the site of mRNA synthesis (nucleus) from the site of mRNA function (cytoplasm) by the nuclear envelope. As a consequence, mRNAs need to be actively exported from the nucleus to the cytoplasm. At the time when this study was initiated, both human TAP and yeast Mex67p had been proposed to play a role in this process. Work presented in this thesis (section 2.1) revealed that TAP and Mex67p belong to an evolutionarily conserved family of proteins which are characterized by a conserved modular domain organization. This family was termed nuclear export factor (NXF) family. While the yeast genome encodes only one NXF protein (Mex67p), the genomes of higher eukaryotes encode several NXF proteins. There are two nxf genes in C. elegans and A. gambiae, four in D. melanogaster, and at least four in H. sapiens and M. musculus. It was unclear whether, apart from TAP and Mex67p, other members of this family would also be involved in mRNA export. In the first part of this thesis (2.1), several human NXF members were tested for a possible function in nuclear mRNA export. They were analyzed for their interaction with RNA, nucleoporins and other known TAP partners in vitro, and tested for their ability to promote nuclear export of a reporter mRNA in vivo. Using these assays, human NXF2, NXF3 and NXF5 were all shown to interact with the known NXF partner p15. NXF2 and NXF5 were also found to bind directly to RNA, but only NXF2 was able to bind directly to nucleoporins and to promote the nuclear export of an (untethered) reporter mRNA. Thus NXF2 possesses many and NXF3 and NXF5 possess some of the features required to serve as an export receptor for cellular mRNAs. As NXF2 and NXF3 transcripts were mainly found in testis, and the closest orthologue of NXF5 in mouse has the highest levels of expression in brain, these NXF members could potentially serve as tissue-specific mRNA export receptors. In the second part of this work (2.2), the role of different Drosophila NXF proteins and other export factors in mRNA export was investigated using double-stranded RNA interference (RNAi) in Drosophila Schneider cells. Three of the four predicted Drosophila NXF members (NXF1-3) were found to be expressed in this cell line and could be targeted by RNAi. Depletion of endogenous NXF1 inhibited growth and resulted in the nuclear accumulation of polyadenylated RNA. Fluorescence in situ hybridization revealed that export of both heat shock and non-heat shock mRNAs, including intron-containing and intronless mRNAs, was inhibited. Depleting endogenous NXF2 or NXF3 had no apparent phenotype. These results suggested that NXF1 (but not NXF2-NXF4) mediates the export of bulk mRNA in Drosophila cells. We and others have shown that human NXF proteins function as heterodimers bound to the small protein p15. Accordingly, silencing of Drosophila p15 resulted in a block of mRNA export which was indistinguishable from the export inhibition seen after targeting NXF1. These observations indicated that neither NXF1 nor p15 can promote export in the absence of the other subunit of the heterodimer. NXF1:p15 heterodimers are implicated in late steps of mRNA export, i.e. in the translocation of mRNP export cargoes across the nuclear pore complex. The mechanism by which NXF1:p15 dimers are recruited to the mRNA is unclear. A protein that is thought to play a role in this process is the putative RNA helicase UAP56. Similar to NXF1 and p15, UAP56 was shown to be essential for mRNA export in Drosophila. UAP56 is recruited cotranscriptionally to nascent transcripts and was suggested to facilitate the interaction of NXF1:p15 with mRNPs. Even though both NXF1:p15 heterodimers and UAP56 had been implicated in general mRNA export, it was unclear whether there are classes of mRNAs that require NXF1:p15, but not UAP56 or vice versa. It was also unclear what fraction of cellular mRNAs is exported by NXF1:p15 dimers and UAP56, and whether mRNAs exist that reach the cytoplasm through alternative routes, i.e. by recruiting other export receptors. To address these issues we performed a genome-wide analysis of nuclear mRNA export pathways using microarray technology (2.2.2). We analyzed the relative abundance of nearly half of the Drosophila transcriptome in the cytoplasm of Drosophila Schneider cells depleted of different export factors by RNAi. We showed that the vast majority of transcripts were underrepresented in the cytoplasm of cells depleted of NXF1, p15 or UAP56 as compared to control cells. Only a small number of mRNAs were apparently not affected by the depletions. These observations, together with the wide and similar effects on mRNA levels caused by the depletion of NXF1, p15 or UAP56, indicate that these proteins define the major mRNA export pathway in these cells. We also identified a small subset of mRNAs which appeared to be exported by NXF1:p15 dimers independently of UAP56. In contrast, no significant changes in mRNA expression profiles were observed in cells depleted of NXF2 or NXF3, suggesting that neither NXF2 nor NXF3 play an essential role in mRNA export in Drosophila Schneider cells. Crm1 is a transport receptor implicated in the export of a variety of non-mRNA and protein cargoes. In addition, human Crm1 has been suggested to be involved in the export of a specific mRNA species, serving as a "specialized" mRNA export receptor. A role of human Crm1 in the export of bulk mRNA is considered unlikely. We analyzed the role of Drosophila Crm1 in mRNA export by inhibiting Crm1 with the drug leptomycin B in Schneider cells. Subsequent microarray analysis demonstrated that the inactivation of Crm1 resulted in decreased cytoplasmic levels of less than 1% of all mRNAs, indicating that Crm1 is indeed not a major mRNA export receptor. The genome-wide analysis also revealed a feedback loop by which a block to mRNA export triggers the upregulation of genes involved in this process. This thesis also includes two sections describing projects in which I participated during my Ph.D., but which were not the main focus of this thesis. In section 2.3, the role of the different TAP/NXF1 domains in nuclear mRNA export is discussed. Section 2.4 describes results that were obtained as part of a collaboration using the RNAi technique in Schneider cells to study the function of Cdc37.
Two isoforms of human CD23 (CD23a and CD23b) have been described. They differ by only 6-7 residues in the N-terminal cytoplasmic tail. CD23a is restrictively expressed on B-cells while CD23b is inducible on B-cells, as well as monocytes, eosinophils, macrophages and a variety of other cell types, after IL-4 stimulation. The two isoforms seems to have different functions. CD23a appears to be the isoform associated with endocytosis of IgE immune complexes and mediating antigen presentation on B-cells. CD23b has a phagocytosis motif and seems to be involved in the phagocytosis of IgE-coated particles, cytokine release and the generation of superoxides. Previous studies indicate that the two isoforms connect to different signal transduction pathways. Comparing the cells that express only one or both CD23 isoforms suggests that CD23b is involved in upregulating cAMP and iNOS, whereas CD23a mediates an increase in intracellular calcium. In the main part of the study we investigated how the CD23a B-cell specific expression is regulated. Pax-5 is a B-cell restricted transcription factor with an essential role in early and late B-cell development. Putative Pax-5 binding sites have been predicted in the CD23a proximal promoter. Analyses of the CD23a promoter revealed three putative Pax-5 binding sites with more than 50% homology to the consensus sequence. One of these sites, named CD23-1 can compete a high affinity Pax-5 binding site or can directly bind Pax-5 protein in electrophoretic mobility shift assays. Introducing mutations into this site abrogates the binding. A different approach, in which overlapping peptides covering the length of the CD23a promoter were tested in competition assays against a high affinity binding site, also revealed CD23-1 as the only site that directly binds Pax-5 protein. Expression of Pax-5 in 293 cells resulted in a 7-fold activation of a CD23a core promoter construct. Co-transfection together with STAT6 showed that Pax-5 cooperates with this transcription factor in enhancing the level of transcription of a CD23a extended promoter construct. Most importantly, ectopic expression of Pax-5 in the monocytic cell line U-937 that regularly expresses only the CD23b isoform enabled a significant CD23a expression after stimulation with IL-4 and PMA. Our results suggest that Pax-5 is a key regulator of the B-cell restricted expression of the CD23a isoform. In the second part of the project, we used a yeast two-hybrid system (CytoTrapTM from Stratagene) in order to look for cytoplasmic interaction partners for the CD23 receptor. The system was established in order to reach a high efficiency of transformation and different bait vector constructs were made. The screening was performed using a human spleen library cloned in the target vector of the system. The first bait constructs used (pSosCD23a and pSosCD23b) expressed the very short (22 amino acids) cytoplasmic tails of the isoforms at the C-terminal end of the fusion protein (human SOS). Improved bait constructs, (pSosCD23a+Linker and pSos CD23b+Linker) expressed the cytoplasmic tail of CD23a/b at the N-terminal side of the human SOS and had in consequence the N-terminal part free as a bait, as it occurs in vivo. A flexible linker region separated the fusion proteins in order to make the small amino acid bait chain more obvious. Approximately three million library clones were screened with these various constructs. No “true positive” interaction was detected. A relatively high number of “false positive” clones were obtained and checked in another two-hybrid system. A new bait construct, in which the tyrosine residue in the cytoplasmic tail of CD23a was replaced by a glutamic acid residue will be used for future screening. The system was also used in order to test the interaction between CD23 and p59fyn, a member of the Src family of protein kinases that was mentioned to associate with CD23a. No interaction was detected by using the CytoTrap two-hybrid system. In conclusion, the key result of the study demonstrates that Pax-5 is a main regulator of the B-cell specific expression of the CD23a isoform. In addition, a two-hybrid system was established and employed in order to look for cytoplasmic interaction partners for CD23.
Age related macular degeneration (AMD) is the leading cause of visual impairment in the elderly and the major cause of blindness in the developed world. To date, the molecular mechanisms underlying the disease are not well understood although in recent years a primary involvement of the retinal pigment epithelium (RPE) has become evident. The aim of the present study is to systematically analyse genes which are differentially expressed in the RPE, and to assess their possible association with mechanisms and pathways likely to be related to retinal disease, in particular AMD. Towards this goal, 2379 expressed sequence tags (ESTs) were established from an inhouse generated RPE cDNA library. This library was constructed by using the suppression subtraction hybridization (SSH) technique which normalises redundant sequences and ensures enrichment of rare transcripts. In a first phase, 1002 ESTs were sequenced and subjected to comprehensive alignment with public nucleotide and protein databases. A search of the 1002 ESTs against the human genome draft sequence yielded 168 known genes, 51 predicted genes, 15 unknown transcripts and 41 clones with no significant similarity. Reverse Northern blot hybridization was performed for 318 EST clusters to identify abundantly expressed genes in the RPE and to prioritize subsequent analyses. Representative clones were spotted onto a nylon membrane and hybridized with cDNA probes of driver (heart and liver) and tester (RPE) used in the cDNA library construction. Subsequently, 107 EST clusters were subjected to Northern blot hybridizations. These analyses identified 7 RPE-specific, 3 retina-specific, 7 RPE/retina-specific, and 7 tissue restricted transcripts, while 29 EST clusters were ubiquitously expressed, and evaluation was not possible for another 54 EST clusters. Of the 24 transcripts with specific or restricted expression, 16 clones were selected for further characterization. The predicted gene MGC2477 and 2 novel isoforms of the human transient receptor potential cation channel, subfamily M, member 3 (TRPM3) were cloned and further described in detail. In addition, polymorphic variations for these 2 genes as well as for the human MT-Protocadherin gene were determined. For MGC2477, 15 single nucleotide polymorphisms (SNPs) were identified, with 13 having a frequency of the minor allele greater than 20%. 10 of the 15 SNPs have not been reported in so far in public SNP repertoires. Partial assessment of the TRPM3 gene yielded 35 SNPs. Of these, 30 (85.7%) were highly frequent (0.17-0.5%), and 14 (40%) were novel. The MT-Protocadherin gene revealed 35 SNPs, including 28 (80%) with high frequency of the minor allele. 23 (65.7%) were novel SNPs. These SNPs will be used to construct the most common haplotypes. These will be used in case/control association studies in 400 AMD patients and 200 ethnically and aged matched controls to assess a possible contribution of these genes in the etiology of AMD.
The aim of current work was contribution to the long-term ongoing project on developing human IL-5 agonists/antagonists that intervene with or inhibit IL-5 numerous functions in cell culture and/or in animal disease models. To facilitate design of an IL-5 antagonist variant or low-molecular weight mimetics only capable of binding to the specific receptor alpha chain, but would lack the ability to attract the receptor common β-chain and thus initiate receptor complex activation it is necessary to gain the information on minimal structural and functional epitopes. Such a strategy was successfully adopted in our group on example of Interleukin 4. To precisely localize minimal structural epitope it is essential to have structure of the ligand in its bound form and especially informative would be structure of complex of the ligand and its specific receptor alpha chain. For this purpose large quantities (tens of milligrams), retaining full biological activity IL-5 and extracellular domain of IL-5 specific receptor α-chain were expressed in a bacterial expression system (E.coli). After successful refolding proteins were purified to 95-99% Stable and soluble receptor:ligand complex was prepared. Each established purification and refolding procedures were subjected to optimization targeting maximal yields and purity. Produced receptor:ligand complex was applied to crystallization experiments. Microcrystals were initially obtained with a flexible sparse matrix screening methodology. Crystal quality was subsequently improved by fine-tuning of the crystallization conditions. At this stage crystals of about 800x150x30µm in size can be obtained. They possess desirable visible characteristics of crystals including optical clarity, smooth facecs and sharp edges. Crystals rotate plane polarized light reflecting their well internal organization. Unfortunately relative slimness and sometimes cluster nature of the produced crystals complicates acquisition of high-resolution dataset and resolution of the structure. With some of obtained crystals diffraction to a resolution up to 4Å was observed.
Plants have evolved an elaborate system to cope with a variety of biotic and abiotic stresses. Typically, under stress conditions an appropriate defense response is invoked which is accompanied by changes in the metabolic status of the plant. Photosynthesis is downregulated and sucrose is imported into the tissue, which provides a faster and more constant flux of energy and carbon skeletons to perform the defense response. Interestingly, these processes are co-ordinately regulated and the signal transduction chains underlying these cellular programs appear to share at least some common elements. Both the induction of sink metabolism and defense response is dependent on signal transduction pathways involving protein phosphorylation. Furthermore, regulation of extracellular invertase (INV) and phenylalanine ammonia lyase (PAL) which are markers for sink metabolism and defense response is preceded by the transient activation of MAP kinases. In depth analysis of MAP kinase activation by partial purification led to the discovery that, depending on the stimulus, different subsets of MAP kinases are activated. This differential MAPK activation is likely to possess a signal encoding function. In addition, the partial purification of MAP kinases was found to be suitable to address specific cellular functions to individual MAP kinase isoenzymes. By this way, LpWIPK was identified as the major MAP kinase activity induced after stimulation of tomato cells with different elicitors. LpWIPK is thus considered as a key regulator of defense response together with sink induction in tomato. A study using nonmetabolisable sucrose analogs revealed that the regulation of photosynthesis is not directly coupled to this signal transduction pathway since it is independent of MAP kinase activation. Nonetheless, downregulation is induced by the same stimuli that induce the defense response and sink metabolism and it will therefore be interesting to uncover the branch points of this signalling network in the future. MAP kinases are not only central components regulating the response to biotic stresses. In addition to e.g. pathogens, MAP kinases are as well involved in signal transduction events invoked by abiotic stresses like cold and drought. In a recent study, we could show that a MAP kinase is activated by heat stress, under conditions a plant will encounter in nature. This previously unknown MAP kinase is able to specifically recognise the heat stress transcription factor HsfA3 as a substrate, which supports a role of this MAP kinase in the regulation of the heat stress response. Moreover, the observation that HsfA3 is phosphorylated by the heat activated MAP kinase in vitro provides a promising basis to identify HsfA3 as the first physiological substrate of a plant MAP kinase. Intracellular protons have been implicated in the signal transduction of defense related signals. In a study using Chenopodium rubrum cells, we could show that cytosolic changes in pH values do not precede the regulation of the marker genes INV and PAL. Depending on the stimulus applied, cytosolic acidification or alkalinisation can be observed, which excludes a role for protons as signals in this pathway. Together with the concomitant changes of the pH value of the extracellular space, these variations can thus be considered as terminal part of the defense response itself rather than as a second messenger. WRKY transcription factors have only recently been identified as indirect targets of a central plant MAP kinase cascade. In addition, the identification of cognate binding sites in the promoters of INV and PAL supports a role for these proteins in the co-ordinate regulation of defense response and sink induction. A novel elicitor responsive WRKY transcription factor, LpWRKY1, was cloned from tomato and characterised with respect to its posttranslational modification. This immediate early transcription factor is transiently induced upon pathogen attack and the induction is dependent on phosphorylation. Furthermore, it was shown for the first time with respect to WRKY transcription factors, that LpWRKY1 is phosphorylated in vivo. Analysis of the role of this phosphorylation by in gel assays using recombinant WRKY protein as the substrate revealed two protein kinases that are transiently activated during the defense response to phosphorylate LpWRKY1. This data demonstrates that WRKY proteins require phosphorylation to modulate their DNA binding or transactivating activity.
Cellular proliferation, differentiation and survival in response to extracellular signals are controlled by the signal transduction pathway of Ras, Raf and MAP kinase. The Raf proteins are serine/threonine kinases with essential function in growth/differentiation/survival - related signal transduction events. In mammals, three functional (A-, B-, and C-Raf) genes were described. Biochemical studies suggest overlapping and differential utilization of Raf isozymes. However, the frequent co-expression of Raf isozymes and their multiple activators and effectors impedes the full understanding of their specific roles. The elucidation of these roles is important due to the involvement of the Ras/Raf/MEK/MAP kinase cascade in human disorders especially in tumor development and progression. B-Raf was shown to posses the strongest kinase activity among Raf kinases and display antiapoptotic properties. Mice deficient in B-Raf show overall growth retardation and die between E10.5 and E12.5 of vascular defects caused by excessive death of differentiated endothelial cells. To elucidate the redundancy of Raf isozymes during embryonic development and to rescue B-Raf-/- (KO) phenotype, B-Raf alleles were disrupted by introducing A-Raf cDNA under the control of endogenous B-Raf promoter. The resulting BRaf A-Raf/A-Raf (KIN) phenotype depends on genetic background. The living embryos displaying normal development but size reduction were found with low incidence at E12.5d-16.5d. All of them displayed the rescue of vascular system. One adult p20 mouse without any visible defects in development and behavior was obtained. On the other hand, the processes of neurogenesis and neural precursors migration in survived embryos were disturbed which led in some cases to underdevelopment of different brain compartments. TUNEL and cell proliferation (PCNA staining) assays revealed more apoptotic (E13.5d) and less proliferating(E12.5d cells within ventricular and sub-ventricular zones of brain ventricles and in striatum of KIN embryos. In addition, more apoptotic cells were detected in many other tissues of E13.5d and in lung of E16.5d KIN embryos but not in adult KIN mouse. p20 KIN mouse demonstrated reduced fraction of neural precursor cells in sub-granular zone of hippocampus and mature neurons in olfactory bulb. The other processes of neurogenesis were not disturbed in adult KIN animal. Fibroblasts obtained from KIN embryos demonstrated less proliferative ability and were more susceptible to apoptotic stimuli compared to WT. This was accompanied by the reduction of active ERK and Akt required for survival, and with decrease of inactive phosphorylated BAD. The kinetic of both ERK and Akt phosphorylation upon serum stimulation was delayed. All these data indicate that moderate A-Raf kinase activity can prevent the endothelial apoptosis but is not enough to completely rescue the other developmental consequences.
Soluble guanylyl cyclase (sGC) is the best established receptor for nitric oxide (NO) and regulates a great number of important physiological functions. Surprisingly, despite the wellappreciated roles of this enzyme in regulation of vascular tone, smooth muscle cell proliferation, platelet aggregation, renal sodium secretion, synaptic plasticity, and other functions, extremely little is known about the regulation of sGC activity and protein levels. To date, the only well-proven physiologically relevant sGC regulator is NO. In the present study, some additional possibilities for sGC regulation were shown. Firstly, we evaluated the ability of different NO donors to stimulate sGC. Significant differences in the sGC stimulation by SNP and DEA/NO were found. DEA/NO stimulated sGC much stronger than did SNP. Interestingly, no correlation between the sGC protein and maximal activity distribution was found in rat brain regions tested, suggesting the existence of some additional regulatory mechanisms for sGC. The failure of SNP to stimulate sGC maximally might be one of the reasons why the lack of correlation between the distribution of sGC activity and proteins in brain was not detected earlier. Prolonged exposure of endothelial cells to NO donors produced desensitization of the cGMP response. This desensitization cannot be explained by increased PDE activity, since PDE inhibitors were not able to prevent the NO donor-induced decrease of the maximal cGMP response in endothelial cells. The failure of SH-reducing agents to improve the cGMP response after its desensitization by NO suggests that a SH-independent mechanism mediates NO effects. Demonstration that the potency of the recently described activator of oxidized (heme-free) sGC, BAY58-2667, to stimulate sGC increases after prolonged exposure of the cells to an NO donor, DETA/NO, suggests that oxidation of heme may be a reason for NOinduced desensitization of sGC and decrease in sGC protein level. Indeed, the well-known heme-oxidizing agent ODQ produces a dramatic decrease in sGC protein levels in endothelial cells and BAY58-2667 prevents this effect. Although the mechanism of sGC activation and stabilization by BAY58-2667 is unknown, this substance is an interesting candidate to modulate sGC under conditions where sGC heme iron is oxidized. Very little is known about regulation of sGC by intracellular localization or translocation between different intracellular compartments. In the present study, an increase in sGC sensitivity to NO under membrane association was demonstrated. Treatment of isolated lung with VEGF markedly increased sGC in membrane fractions of endothelial cells. Failure of VEGF to stimulate sGC membrane association in cultured endothelial cells allows us to propose a complex mechanism of regulation of sGC membrane association and/or a transient character of sGC membrane attachment. A very likely mechanism for the attachment of sGC to membranes is via sGCinteracting proteins. These proteins may participate also in other aspects of sGC regulation. The role of the recently described sGC interaction partner, Hsp90, was investigated. Shortterm treatment of endothelial cells with an Hsp90 inhibitor does not affect NO donor or calcium ionophore-stimulated cGMP accumulation in the cells. However, inhibition of Hsp90 results in a rapid and dramatic decrease in sGC protein levels in endothelial cells. These effects were unrelated to changes in sGC transcription, since inhibition of transcription had much slower effect on sGC protein levels. In contrast, inhibitors of proteasomes abolished the reduction in sGC protein levels produced by an Hsp90 inhibitor, suggesting involvement of proteolytic degradation of sGC proteins during inhibition of Hsp90. All these data together suggest that Hsp90 is required to maintain mature sGC proteins. In conclusion, in the present study it was demonstrated that multiple mechanisms are involved in the regulation of sGC activity and its sensitivity to NO. Oxidation of sGC heme by NO seems to be one of the mechanisms for negative regulation of sGC in the presence of high or prolonged stimulation with NO. Another possible means of regulating sGC sensitivity to NO is via the intracellular translocation of the enzyme. It has been also demonstrated here that attachment of sGC to the membrane fraction results in an apparent increase in the enzyme sensitivity to NO. Additionally, Hsp90 was required to maintain sGC protein in endothelial and other cell types. However, we could not find any acute affect of Hsp90 on sGC activity, as reported recently. All these findings demonstrate that the regulation of sGC activity and protein level is a much more complex process than had been assumed earlier.
Elevation of intracellular cAMP in T lymphocytes, induced by agents such as IL-1α, prostaglandins or forskolin, inhibits Th1-type cytokine production but stimulates Th2-type cytokine production. The signaling pathway engaged in cAMP-mediated induction of Th2 lymphokines remains obscure and therefore my doctoral work was focused on the elucidation of cAMP pathway in primary Th lymphocytes. While forskolin treatment of EL-4 cells led both to an activation of Th2 lymphokines and inhibition of Th1 lymphokines, ectopic expression of catalytically active PKA stimulated Th2 lymphokines but failed to inhibit Th1 lymphokine expression. Thus, the PKA activity is selectively involved in the stimulation of Th2 lymphokine expression whereas other cAMP-dependent pathway(s) appears to downregulate Th1 lymphokines. By investigating different types of primary murine Th cells, it was found that active PKA enhanced IL-5 expression only in Th0 and Th2 but not in Th1 cells. This is likely due to the different levels of GATA-3 whose expression is high in Th2, moderate in Th0 and very low in Th1 cells. Ectopic expression of GATA-3 in Th1 cells induced Th2 lymphokine expression which could be further enhanced by increased cAMP levels or PKA activity. Investigations on the role of increased cAMP levels on Th2 lymphokines in D10 cells, a Th2-type cell line, led to the conclusion that elevated cAMP concentrations do not stimulate PKA but p38 activity which, through phosphorylation of GATA-3, appeared to induce IL-5 and IL-13 expression (Chen et al., 2000). While focusing on primary Th lymphocytes, it was observed that expression of the catalytic subunit α of PKA is sufficient for optimal IL-5 expression in primary Th0 cells. In addition, downregulation of IL-5 production in primary Th2 cells by the treatment with low concentrations of H-89, a PKA specific inhibitor, as well as by the ectopic expression of a negatively acting version of regulatory PKA subunit I demonstrates that active PKA plays an important role in IL-5 gene regulation. These findings using different types of primary CD4+ T lymphocytes, including Th2 cells, the one likely to represent the native IL-5 producers in vivo, demonstrates that the adenylyl cyclase/cAMP/PKA signaling pathway plays an important role in IL-5 gene expression in primary Th2 cells. Thus the importance of cAMP/PKA signaling pathway in Th2 effector function was established during this doctoral research work.
During the Mesoproterozoic large volumes of magma were repeatedly emplaced within the basement of NW Namibia. Magmatic activity started with the intrusion of the anorthositic rocks of the Kunene Intrusive Complex (KIC) at 1,385-1,347 Ma. At its south-eastern margin the KIC was invaded by syenite dykes (1,380-1,340 Ma) and younger carbonatites (1,140-1,120 Ma) along ENE and SE trending faults. Older ferrocarbonatite intrusions, the ‘carbonatitic breccia’, frequently contain wallrock fragments, whereas subordinate ferrocarbonatite veins are almost xenolith-free. Metasomatic interaction between carbonatite-derived fluids and the neighbouring and incorporated anorthosites led to the formation of economically important sodalite deposits. Investigated anorthosite samples display the magmatic mineral assemblage of Pl (An37-75) ± Ol ± Opx ± Cpx + Ilm + Mag + Ap ± Zrn. Ilmenite and pyroxene are surrounded by narrow reaction rims of biotite and pargasite. During the subsolidus stage sporadic coronitic garnet-orthopyroxene-quartz assemblages were produced. Thermobarometry studies on amphiboles yield temperatures of 985-950°C whereas the chemical composition of coronitic garnet and orthopyroxene indicate a subsolidus re-equilibration of the KIC at conditions of 760 ± 100°C and 7.3 ± 1 kbar. In the syenites Kfs, Pl, Hbl and/or Cpx crystallized first, followed by a second generation of Kfs, Hbl, Fe-Ti oxides and Ttn. Crystallization of potassium feldspar occurred under temperatures of 890-790°C. For the crystallization of hastingsite pressures of 6.5 ± 0.6 kbar are obtained. In order to constrain the source rocks of the two suites, oxygen isotope analyses of feldspar as well as geochemical bulk rock analyses were carried out. In case of the anorthosites, the general geochemical characteristics are in excellent agreement with their derivation from fractionated basaltic liquids, with the d18O values (5.88 ± 0.19 ‰) proving their derivation from mantle-derived magmas. The results obtained for the felsic suite, provide evidence against consanguinity of the anorthosites and the syenites, i.e. (1) compositional gaps between the geochemical data of the two suites, (2) trace element data of the felsic suite points to a mixed crustal-mantle source, (3) syenites do not exhibit ubiquitous negative Eu-anomalies in their REE patterns, which would be expected from fractionation products of melts that previously formed plagioclase cumulates and (4) feldspar d18O values from the syenites fall in a range of 7.20-7.92 ‰, which, however, is about 1.6 ‰ higher than the average d18O of the anorthosites. Conformably, the crustal-derived felsic and the mantle-derived anorthositic suite are suggested to be coeval but not consanguineous. Their spatial and temporal association can be accounted for, if the heat necessary for crustal melting is provided by the upwelling and emplacement of mantle-derived melts, parental to the anorthosites. In order to constrain the source of the 1,140-1,120 Ma carbonatites and to elucidate the fenitizing processes, which led to the formation of the sodalite, detailed mineralogical and geochemical investigations, stable isotope (C,O,S) analyses and fluid inclusion measurements (microthermometrical studies and synchrotron-micro-XRF analyses) have been combined. There is striking evidence that carbonatites of both generations are magmatic in origin. They occur as dykes with cross-cutting relationships and margins disturbed by fenitic aureoles, and contain abundant flow-oriented xenoliths. The mineral assemblage of both carbonatite generations of Ank + Cal + Ilm + Mag + Bt ± Ap ± pyrochlore ± sulphides in the main carbonatite body and Ank + Cal + Mag ± pyrochlore ± rutile in the ferrocarbonatite veins, their geochemical characteristics and the O and C isotope values of ankerite (8.91 to 9.73 and –6.73 to –6.98, respectively) again indicate igneous derivation, with the 18O values suggesting minor subsolidus alteration. NaCl-rich fluids, released from the carbonatite melt mainly caused the fenitization of both, the incorporated and the bordering anorthosite. This process is characterized by the progressive transformation of Ca-rich plagioclase into albite and sodalite. Applying conventional geothermobarometry combined with fluid-inclusion isochore data, it was possible to reconstruct the P-T conditions for the carbonatite emplacement and crystallization (1200-630°C, 4-5 kbar) and for several mineral-forming processes during metasomatism (e.g. formation of sodalite: 800-530°C). The composition and evolutionary trends of the fenitizing solution were estimated from both the sequence of metasomatic reactions within wallrock xenoliths in the carbonatitic breccia and fluid inclusion data. The fenitizing solutions responsible for the transformation of albite into sodalite can be characterised as of NaCl-rich aqueous brines (19-30 wt.% NaCl eq.), that contained only minor amounts of Sr, Ba, Fe, Nb, and LREE.
This study investigated patterns of arthropod community organisation and the processes structuring these communities on a range of different tree species in a natural West African savannah (Comoé National Park, Côte d'Ivoire). It described and analysed patterns of arthropod distribution on the level of whole communities, on the level of multiple-species interactions, and on the level of individual insect species. Community samples were obtained by applying (i) canopy fogging for mature individuals of three tree species (Anogeissus leiocarpa, Burkea africana, Crossopteryx febrifuga) and (ii) a modified beating technique allowing to sample the complete arthropod communities of the respective study plants for medium-sized (up to 3 m) individuals of two other species (Combretum fragrans, Pseudocedrela kotschyi). General information on ant-plant interactions was retrieved from ant community comparisons of the mature savannah trees. In addition, ant-ant, ant-plant and ant-herbivore interactions were studied in more detail considering the ant assemblages on the myrmecophilic tree Pseudocedrela kotschyi. Herbivore-plant interactions were investigated on a multiple-species level (interrelationships between herbivores and Pseudocedrela trees) and on a species level (detailed studies of interrelationships between herbivorous beetles and caterpillars and the host tree Combretum fragrans). The studies on individual herbivore species were complemented by a study on an abundant ant species, clarifying not only the relationship between host plant and associated animal but allowing also to look at interactive (competitive) aspects of community organisation. The study demonstrated for the first time that (i) the structure of beetle communities on tropical trees can be strongly dependent on the host tree species, (ii) individual trees can host specific arthropod communities whose characteristic structure is stable over years and is strongly determined by the individual tree's attributes, (iii) ants can express a pronounced fidelity to single leaves as foraging area and can thereby determine distribution patterns of other ants, (iv) intraspecifically variable palatability of plants for insect herbivores can be stable over years and can influence the distribution of herbivores that can distinguish between individual hosts according to palatability and (v) intraspecific host plant change can positively affect fitness of herbivores if host plant quality is variable. In general, the present study contributes to our knowledge of anthropogenically unaltered processes affecting community assembly in a natural environment. The fundamental understanding of these processes is crucial for the identification of anthropogenic alterations and the establishment of sustainable management measures. The study points out the important role local factors can play for the distribution of organisms and thereby for community organisation. It emphasises the relevance of small scale heterogeneity of the abiotic and biotic environment to biodiversity and the need to consider these factors for development of effective conservation and restoration strategies.
Summary Myelin protein zero (P0) is a key myelin component in maintaining the integrity and functionality of the peripheral nervous system. Mutated variants are the cause for several disabilitating peripheral neuropathies such as Charcot-Marie-Tooth disease or Dejerine –Sotas syndrome. Using P0 knockout mice - a mouse model for these diseases - together with their wt counterparts on C57BL/6 background we studied the shaping of the T-cell repertoire specific for P0 in the presence and in the absence of this protein during the ontogeny of T-cells. Our approach was to use a series of overlapping 20-mer peptides covering the entire amino acid sequence of P0. This series of P0 peptides was employed for epitope mapping of the H2-Ab restricted T cell response. Thus, P0 peptide 5 (P0 41-60) in the extracellular domain of P0 was identified as the main immunogenic peptide. The immunogenic peptide containing the core immunodominant determinant in the P0 sequence was employed in studies of tolerance, revealing a highly reactive P0 specific T-cell repertoire in P0 ko mice while in wt mice the high avidity repertoire was inactivated in order to ensure self tolerance. In wild type and heterozygous P0 mice tolerance is not dependent on gene dosage. P0 is a tissue specific antigen whose expression is limited to myelinating Schwann cells. The classical view on tolerance to tissue specific antigens attributed this role to peripheral mechanisms. Driven by the finding that intrathymic expression of tissue-specific antigens is a common occurrence, we confirmed that “promiscuous” expression on thymic stroma holds true also for myelin P0. In addition, using bone marrow chimeras we investigated the capacity of bone marrow derived cells versus nonhematopoietic cells to induce tolerance towards P0. Our findings show that bone marrow derived cells although tolerogenic to some degree are not sufficient to mediate complete tolerance. P0 expression on cells with origin other than bone marrow showed to be sufficient and necessary to induce sound tolerance. We identified one cryptic (P0 peptide 8) and two subdominant epitopes (P0 petides 1, and 3). P0 peptide 8 was reactive in both wt and P0 ko mice. Peptides 1 and 3 were immunogenic in P0 ko but not in wt mice. Several P0 peptides including the immunogenic peptide 5 were involved in direct and adoptive transfer EAN studies. None of them induced clinical signs of EAN. Immunization with P0 peptide 3 did induce inflammation of the peripheral nerves reflected by the infiltration of macrophages and CD3 positive cells. More studies involving highly P0 specific T-cell lines are needed to characterize the P0 induced EAN. Our findings may have direct implications for secondary autoimmunity and inflammation in peripheral nerves developing after correcting the P0 genetic defect by gene therapy in aforementioned diseases.
The study deals with the area of the allosteric modulation of the muscarinic M2 receptors. The allosteric modulators have an influence on binding of orthosteric ligands (agonists and antagonists) to the classical orthosteric binding site of the muscarinic M2-receptors. The modulators are able to enhance (positive cooperativity) or decrease (negative cooperativity)the affinity of ligands to the orthosteric binding site. The allosteric binding site is located at the entrance of the receptor binding pocket. It is less conserved than the orthosteric binding site which is located in a narrow cavity created by the seven transmembrane domains. Consequently, development of subtype selective allosteric ligands is easier than subtypeselective muscarinic agonists or antagonists. Furthermore, subtype selectivity can be achieved by differently cooperative interactions between the allosteric and orthosteric ligand at different receptor subtypes. For example, the allosteric modulators that are positively cooperative with ACh at M1 receptors and neutrally cooperative at the other receptor subtypes could be beneficial for treatment of the Alzheimer’s disease. Bisquaternary analogues of the Strychnos alkaloid caracurine V are among the most potent allosteric modulators of muscarinic M2-receptors. The very rigid ring skeleton comprises the pharmacophoric elements of two positively charged nitrogens at an approximate distance of 10 surrounded by two aromatic ring systems in a distinct spatial arrangement. Owing to the close structural relationship of caracurine V salts to the strong muscle relaxants toxiferine and alcuronium, they are likely to exhibit neuromuscular blocking activity, which would limit their usefulness as research tools and make the therapeutical use impossible. Reduction of the caracurine V ring skeletons to structural features responsible for good allosteric potency could possibly lead to compounds with negligible neuromuscular blocking activity and very high affinity to the allosteric binding site at M2 receptor. Thus, the aim of this study was to synthesize and pharmacologically evaluate analogues of a novel heterocyclic ring system, which comprises the pharmacophoric elements mentioned previously. The key step of the synthesis of the desired 6,7,14,15-tetrahydro[1,5]diazocino[1,2-a:6,5-a]-diindole ring system (6) involved the intermolecular double N-alkylation of the bromoethylindole (5), which was prepared from the known indolyl methylacetate (3) by reduction of the ester group to alcohol and subsequent substitution by bromine. 3 could be prepared in three steps involving N,N-dibenzylation of tryptamine followed by introduction of the dimethyl malonate moiety at C-2 of indole ring and a subsequent demethoxycarbonylation. The total synthesis of 6,7,14,15-tetrahydro[1,5]diazocino[1,2-a:6,5-a]diindole ring system (6) is shown in Scheme 24. In order to examine the influence of the length of the side-chain on muscarinic activity,exchange of the ethylamine moieties of 14 by the methylamino groups was planned. This should be accomplished by dimerization of the unsubstituted 2-bromoethylindole (32), and subsequent Mannich aminomethylation of the resulting unsubstituted pentacyclic ring. The total synthesis of the 6,7,14,15-tetrahydro-15aH-azocino[1,2-a:6,5-b]diindole ring system(35) is shown in Scheme 25. 32 was prepared from indole-2-carboxylic acid in six steps involving reduction of the acid to the corresponding alcohol 26, benzoylation of 26 followed by nucleophilic substitution with KCN, hydrolysis of the cyanide 28 to indolyl acetic acid 29,reduction of 29 to the corresponding alcohol 30, and finally bromination of 30 to give the bromide 32. Since dimerization attempts of 32 provided only 2-vinylindole (33), the tosylate 34 was used as starting material for the intermolecular alkylation to give exclusively an isomeric pentacyclic ring system, 7,14,15-tetrahydro-15aH-azocino[1,2-a:6,5-b]diindole (35). The formation of the novel, asymmetric ring skeleton can be explained by the ambident nucleophilic character of the indolyl anion that can be alkylated either at nitrogen or at C-3 of indole ring. 35 was subjected to a Mannich reaction to give 2,13-dimethylaminoalkylated product 37 as well as small amounts of the 13-monosubstituted compound (36). The geometry of novel ring systems 6 was elucidated by means of NMR spectroscopy and semiempirical calculations. The diazocinodiindole ring skeleton of 6 exists in chloroform solution at room temperature in a twisted-boat conformation, as indicated by 600 MHz ROESY experiment, vicinal coupling constants within the eight-membered ring, and AM1 calculations. In order to obtain potent allosteric ligands, the new heterocycles 6 and 37 were quarternized with methyliodide to the corresponding ammonium salts 14 and 38, respectively. Additionally, the N,N -diallylsalts of 37 (compound 39) was prepared. The allosteric effect of 14, 38, and 39 on the dissociation of the orthosteric radioligand [3H]Nmethylscopolamine([3H]NMS) and their effects on [3H]NMS equilibrium binding were studied in homogenates of porcine heart ventricles. The concentration of an allosteric agent for a half-maximum effect on orthosteric ligand dissociation (EC50,diss) corresponds to a 50 % occupancy of the liganded receptors by the respective allosteric test compounds. Due to the presence of two benzyl groups on each nitrogen in the side chains of 14, its binding affinity can be best compared with that of N,N -dibenzylcaracurinium V dibromide (EC50,diss = 69 nM). Compound 14 exhibited the comparable affinity to N,N -dibenzylcaracurinium V dibromide with EC50,diss = 54 nM. This result suggested that replacement of the bulky benzyl groups of 14 by smaller substitutents will probably increase the allosteric potency, since dimethyl- and diallylcaracurinium salts showed a 5-fold increase of binding affinity relative to the dibenzyl analogue. Even though the new azocinodiindole ring system of 38 and 39, is not included in the caracurine V ring skeleton, it comprises the essentially pharmacophoric elements of allosteric potency. Due to the different spatial arrangements of the aromatic rings, as well as to different internitrogen distances in both ring systems, compound 38 and 39 exhibited 4-fold lower M2 binding affinity (EC50,diss = 35 and 48 nM, respectively) than the corresponding caracurine V analogues. This study deals with the synthesis of the first representative (Compound 6) of a novel pentacyclic ring system derived from caracurine V. The high allosteric potency of its dimethyl analogue reveals the [1,5]diazocino[1,2-a:6,5-a]-diindole ring system as a new promising lead structure for allosteric modulators of muscarinic M2 receptors. Future research will be focused on structural modifications of the new ring system in order to increase the affinity to the muscarinic receptors. Furthermore, the binding affinities of the new synthesized compounds to the muscle type of nicotinic ACh-receptor should reveal structural features responsible for the muscarinic/nicotinic selectivity.
Summary Background: In a previous study, nitrate reductase (NR, EC 1.6.6.1) from leaves of Ricinus communis L. showed different regulatory properties from most other higher plants NR's by an unusually strong Mg2+-sensitivity, a different pH-activity profile and only little ATP-dependent inactivation. The aim of this work was to elucidate the deviating properties of Ricinus NR in more details, from both molecular and physiological aspects. For that purpose, the NR gene from R. communis was cloned, expressed heterologously and characterized. Results: The deduced protein sequence showed that Ricinus NR shared high similarity with other NRs, apart from the N-terminal region. In the N-terminal region, the Ricinus NR possesses an acidic stretch which is conserved only in higher plants. Within the Moco-binding domain the Ricinus NR contained few amino acid residues which were unique in comparison with 17 plant NRs, including His103, Gln123, Val266 and Ala284 where other NRs possess asparagine, arginine, aspartate and praline. In the Dimer interface and Hinge 1 regions, the Ricinus NR also had some unique residues like Asn460 and Ala498 where other NRs have isoleucine and glycine instead. The Ricinus NR possesses an Arg482 which provides an additional predicted Trypsin cleavage site within 481KRHK484 (while most of plant-NRs possess KPHK). Additionally, the Ricinus NR contains a serine phosphorylation site (Ser-526) within the potential 14-3-3 binding motif 523KSVS*TP528, which is a common characteristic of nitrate reductases. In the C-Terminus of Ricinus NR a sequence 886CGPPP890 confirmed that Ricinus NR is a NADH-specific enzyme. Functional Ricinus NR protein was expressed in Pichia pastoris and compared with the features of Arabidopsis NR2 synthesized by the same expression system (AtNR2). The recombinant Ricinus NR (RcNR) itself was unresponsive to the incubation with MgATP, and so was AtNR2. As yeast extracts might lack factors required for NR regulation, desalted leaf extracts containing NR kinases and 14-3-3s were prepared from 4-day darkened (and therefore NR-free) leaves of Arabidopsis (ADL), spinach (SDL) and Ricinus (RDL), and added to the assay of RcNR and AtNR2 to check for ATP-dependent inactivation and Mg2+-sensitivity. When RcNR was combined with the NR-free extracts described above, it's unusually high Mg2+-sensitivity was restored only by incubation with RDL, but it remained unresponsive to ATP. In contrast, AtNR2 became inactive when incubated with the protein mixtures and ATP. It is obvious that one or some factors existing in RDL could interact with RcNR and therefore provide its high Mg2+-sensitivity. Interestingly, incubation of AtNR2 with different NR-free leaf extracts gave a significant activation of the enzyme activities, both in Mg2+ and EDTA, which were not observed in the case of RcNR. Moreover, using ammonium sulfate to fractionation the RDL revealed that about 0.2 mg of the protein factor(s) from 0-35% of ammonium sulfate precipitation was sufficient to provide the maximum inhibition of the RcNR. Conclusions: The insensitivity to ATP appears an inherent property of Ricinus NR, whereas the high Mg2+-sensitivity depends on one or several factors in Ricinus leaves. This as yet unknown factor(s) was boiling-sensitive and could be precipitated by ammonium sulfate. It appeared to interact specifically with recombinant Ricinus-NR to provide the Mg2+-sensitivity of the authentic leaf enzyme. Presumably, there is also a positive regulatory factor(s) for nitrate reductase existing in the leaves of higher plants.
Best disease (OMIM 153700) is an early-onset, autosomal dominant maculopathy characterized by egg yolk-like lesions in the central retina. The disease gene, the vitelliform macular dystrophy gene type 2 (VMD2), encodes a 585-aa VMD2 transmembrane protein, termed bestrophin. The protein is predominantly expressed on the basolateral side of the retinal pigment epithelium (RPE) and is thought to be involved in the transport of chloride ions. Bestrophin as well as three closely related VMD2-like proteins (VMD2L1-L3) contain multiple putative transmembrane (TM) domains and an invariant tripeptide (RFP) motif in the N-terminal half of the protein. This and the tissue-restricted expression to polarized epithelial cells are typical features of the VMD2 RFP-TM family. Best disease is predominantly caused by missense mutations, clustering in four distinct „hotspots“ in the evolutionary highly conserved N-terminal region of the protein. To further augment the spectrum of mutations and to gain novel insights into the underlying molecular mechanisms, we screened VMD2 in a large cohort of affected patients. In total, nine novel VMD2 mutations were identified, raising the total number of known Best disease-related mutations from 83 to 92. Eight out of nine novel mutations are hotspot-specific missense mutations, underscoring their functional/structural significance and corroborating the dominant-negative nature of the mutations. Of special interest is a one-basepair deletion (Pro260fsX288) encoding a truncated protein with a deletion of an important functional domain (TM domain four) as well as the entire C-terminal half of bestrophin. For the first time, a nonsense mutation leading to a 50 % non-functional protein has been identified suggesting that on rare occassions Best disease may be caused by haploinsufficiency. Molecular diagnostics strongly requires a reliable classification of VMD2 sequence changes into pathogenic and non-pathogenic types. Since the molecular pathomechanism is unclear at present, the pathogenicity of novel sequence changes of VMD2 are currently assessed in light of known mutations. We therefore initiated a publicly accessible VMD2 mutation database (http://www.uni-wuerzburg.de/humangenetics/vmd2.html) and are collecting and administrating the growing number of mutations, rare sequence variants and common polymorphisms. Missense mutations may disrupt the function of proteins in numerous ways. To evaluate the functional consequences of VMD2 mutations in respect to intracellular mislocalization and/or protein elimination, a set of molecular tools were generated. These included the establishment of an in vitro COS7 heterologous expression assay, the generation of numerous VMD2 mutations by site-directed mutagenesis as well as the development of bestrophin-specific antibodies. Surprisingly, membrane fractionation/Western blot experiments revealed no significant quantitative differences between intact and mutant bestrophin. Irrelevant of the type or location of mutation, incorporation of mutant bestrophin to the membraneous fraction was observed. Thus, impaired membrane integration may be ruled out as causative pathomechanism of Best disease consistent with a dominant-negative effect of the mutations. In a different approach, efforts were directed towards identifying and characterizing the VMD2 RFP-TM protein family in mouse. While clarification of the genomic organization of murine Vmd2 was required as basis to generate Vmd2-targeted animals (see below), the study of closely related proteins (Vmd2L1, Vmd2L2 and Vmd2L3) may provide further clues as to the function of bestrophin. For this, biocomputational as well as RT PCR analyses were performed. Moreover, the novel genes were analyzed by real time quantitative RT PCR, displaying predominant expression in testis, colon and skeletal muscle of Vmd2, Vmd2L1 and Vmd2L3 transcripts, respectively as well as in eye tissue. Interestingly, neither an ORF was determined for murine Vmd2L2 nor was the transcript present in a panel of 12 mouse tissues, suggesting that murine Vmd2L2 may represent a functionally inactive pseudogene. The murine Vmd2L3 gene, as its human counterpart, is a highly differentially spliced transcript. Finally, generating mouse models of Best disease will provide essential tools to investigate the pathophysiology of bestrophin in vivo. We have initiated the generation of two different mouse lineages, one deficient of Vmd2 (knock-out) and the other carrying a human disease-related mutation (Tyr227Asn) in the orthologous murine gene (knock-in). Genetic engineering of both constructs has been achieved and presently, four ES clones harboring the homologous recombination event (Vmd2+/-) have been isolated and are ready for the subsequent steps to generate chimeric animals. The resulting mouse lineages will represent two key models to elucidate the functional role of bestrophin in Best disease, in RPE development and physiology.
Transplantation is now firmly established as a therapeutic approach to extend and improve the life of patients in the final stages of organ failure. It has been demonstrated that transplantation between genetically non-identical individuals leads to the activation of the recipient’s alloimmune response as a major determinant of transplant outcome. T cell recognition of foreign MHC molecules plays a key role in initiating and sustaining allograft rejection. To prevent the risk of rejection, patients are given immunosuppressive drugs, which are non-specific and have major side-effects (infections, malignancies). It has been shown that the alloreactive T cells specifically recognize donor MHC-derived peptides. This implies that it may be possible to develop antigen-specific strategies in order to modulate the alloimmune response by peptide analogues and specifically altered peptide ligands. The purpose of this study was to explore the potential of “recipient-adapted” analogues from the dominant MHC class I peptide to modulate the alloimmune response. Beside the significant role of donor dominant determinants in the rejection process, we tested seven 13-to-24-mer peptides from the Wistar-Furth MHC class I molecule (WF, RT1.Au) for their possible immunogenicity in a fully MHC-mismatched WF to Lewis (LEW, RT1l) rat strain combination. Secondly, the immunodominant allopeptide was selected to generate analogues in order to investigate their modulatory capacity. All peptides were tested in vitro in a standard proliferation assay and in vivo using a heterotopic heart transplantation model. Our findings show that five peptides (P1-P5) were able to induce specific T cell proliferation in LEW responders. Furthermore, we found a hierarchical distribution of the determinants: peptide P1 as a good candidate for the immunodominant determinant, while P2, P3, P4, and P5 as subdominant epitopes and the other two peptides, P6 and P7, as non-immunogenic determinants of WF MHC class I molecule. Furthermore, the dominance of P1 was confirmed by the strong proliferation induced after immunization with a mixture of peptides in the presence of P1. This hierarchical distribution of the proliferative response correlated with the cytokine production. Peptide P1, comprising only 3 allogeneic amino acids (L5, L9, and T10) induced the strongest T cell proliferation and produced high levels of cytokines, especially IL-2 and IFN-g. In addition, the immunodominance of peptide P1 was confirmed by the significant reduction in the allograft survival time in comparison to the non-immunized control animals. Since the TCR Vß repertoire of rejected graft-infiltrating cells in rejected allografts was similar to the profile observed after in vitro restimulation of P1-primed T cells, we concluded that peptide P1 is able to activate the alloreactive T cell population. Our results demonstrate the particular role of the dominant peptide P1 (residues 1-19) in the allograft rejection in WF to LEW rat strain combination. In the second set of experiments, we investigated the fine specificity of the dominant peptide P1-activated T cells using peptide analogues from P1. The “recipient-adapted” analogues were designed by changing the allogeneic RT1.Au amino acids (L5, L9, T10) one-by-one with the correspondent syngeneic RT1.Al amino acids (M5, D9, I10) in the sequence of peptide P1. The six peptide analogues (A1.1-A1.6) consisting of either one or two allogeneic amino acids were able to induce a specific T cell proliferative response and cytokine production. Analogue A1.5 with only one allogeneic amino acid (L5) was of particular interest because it induced a low T cell proliferation and high cytokine levels, especially IL-4 and IL-10. In addition, immunization with A1.5 did not influence the allograft survival time in comparison to the non-immunized LEW recipients. A1.5 was the only analogue able to down-regulate the proliferation of P1-primed T cells. Our results reveal that A1.5 is an MHC competitor as confirmed by the in vitro MHC competition assay and the inhibition of the negative effect of P1 on the allograft survival time when recipients were immunized with a mixture of P1 and A1.5. These findings suggest that it is possible to design peptide analogues, such as A1.5, which do not stimulate the dominant peptide P1-specific T cell population and even more, are able to block its presentation in the MHC molecule. In all, the results indicate that the specific suppression of indirect allorecognition can be achieved by using peptide analogues of the dominant allopeptide.
The high-grade metamorphic Epupa Complex (EC) of north-western Namibia constitutes the south-western margin of the Archean to Proterozoic Congo Craton. The north-eastern portion of the EC has been geochemically and petrologically investigated in order to reconstruct its tectono-metamorphic evolution. Two distinct metamorphic units have been recognized, which are separated by ductile shear zones: (1) Upper amphibolite facies rocks (Orue Unit) and (2) ultrahigh-temperature (UHT) granulite facies rocks (Epembe Unit). The rocks of the EC are transsected by a large anorthosite massif, the Kunene Intrusive Complex (KIC). The Orue Unit and the Epembe Unit were affected by two distinct Mesoproterozoic metamorphic events, as is evident from differences in their metamorphic grade, in the P-T paths and in the age of peak-metamorphism: (1) The Orue Unit consists of a Palaeoproterozoic volcano-sedimentary sequence, which was intruded by large masses of I-type granitoids and by rare mafic dykes. During the Mesoproterozoic (1390-1318 Ma) the Orue Unit rocks underwent upper amphibolite facies metamorphism. The volcano-sedimentary sequence is constituted by interlayered basaltic amphibolites and rhyolitic felsic gneisses, with intercalations of migmatitic metagreywackes, migmatitic metapelites, metaarkoses and calc-silicate rocks. The Orue Unit was subdivided into three parts, which record similar heating-cooling paths but represent individual crustal levels: Heating led to the partial replacement of amphibole, biotite and muscovite through dehydration melting reactions. The peak-metamorphic P-T conditions of c. 700°C, 6.5 +/- 1.0 kbar (south-eastern part), c. 820°C, 8 +/- 0.5 kbar (south-western part) and c. 800°C, 6.0 +/- 1.0 kbar (northern part) correlate well with the mineral assemblage in the metapelites, i.e. Grt-Bt-Sil gneisses and schist in the south-eastern and south-western region and (Grt-)Crd-Bt gneisses in the northern part. Peak-metamorphism was followed by retrograde cooling to middle amphibolite facies conditions. Contact metamorphism, related with the intrusion of the anorthosites, is restricted to the direct contact to the KIC and recorded by massive metapelitic Grt-Sil-Crd felses, formed under upper amphibolite facies conditions (c. 750°C, c. 6.5 kbar). (2) The Epembe Unit consists of a Palaeoproterozoic volcano-sedimentary succession, which was intruded by small bodies of S-type granitoids and by andesitic dykes. All these rocks underwent UHT granulite facies metamorphism during the early Mesoproterozoic (1520-1447 Ma). The volcano-sedimentary succession is dominated by interlayered basaltic two-pyroxene granulites and rhyolitic felsic granulites. Migmatitic metapelites and metagreywackes are intercalated in the metavolcanites. Sapphirine-bearing MgAl-rich gneisses occur as restitic schlieren in the migmatitic metagreywackes. Reconstructed anti-clockwise P-T paths are subdivided into several distinct stages: During prograde near-isobaric heating to UHT conditions at c. 7 kbar biotite- or hornblende-bearing mineral assemblages were almost completely replaced by anhydrous mineral assemblages through various dehydration melting reactions. A subsequent pressure increase of 2-3 kbar led to the formation of the peak-metamorphic mineral assemblages Grt-Opx and (Grt-)Opx-Cpx in the orthogneisses and Grt-Opx, Grt-Sil and (Grt-)(Spr-)Opx-Sil-Qtz in the paragneisses. UHT-Metamorphism is proved by conventional geothermobarometry (970 +/- 70°C; 9.5 +/- 2.5 kbar), by the very high Al content of peak-metamorphic orthopyroxene (up to 11.9 wt.% Al2O3) in many paragneisses and by Opx-Sil-Qtz assemblages in the MgAl-rich gneisses. Post-peak decompression is recorded by several corona and symplectite textures, formed at the expense of the peak-metamorphic phases: Initial UHT decompression of about ca. 2 kbar to 940 +/- 60°C at 8 +/- 2 kbar is mainly evident from the formation of sapphirine-bearing symplectites in the Opx-Sil gneisses. Subsequent high-temperature decompression to 6 +/- 2 kbar at 800 +/- 60°C resulted in the formation of Crd-Opx-Spl, Crd-Opx and Spl-Crd symplectites. Subsequent near-isobaric cooling to upper amphibolite conditions of 660 +/- 30°C at 5 +/- 1.5 kbar led to the re-growth of biotite, hornblende, sillimanite and garnet. During continued decompression orthopyroxene and cordierite were formed at the expense of biotite in several paragneisses. In a geodynamic model UHT metamorphism of the Epembe Unit is correlated with the formation of a large magma chamber at the mantle-crust boundary, which forms the source for the anorthosites of the KIC. In contrast, amphibolite facies metamorphism of the Orue Unit is ascribed to a regional contact metamorphic event, caused by the emplacement of the anorthositic crystal mushes in the middle crust.
Zars and co-workers were able to localize an engram of aversive olfactory memory to the mushroom bodies of Drosophila (Zars et al., 2000). In this thesis, I followed up on this finding in two ways. Inspired by Zars et al. (2000), I first focused on the whether it would also be possible to localize memory extinction.While memory extinction is well established behaviorally, little is known about the underlying circuitry and molecular mechanisms. In extension to the findings by Zars et al (2000), I show that aversive olfactory memories remain localized to a subset of mushroom body Kenyon cells for up to 3 hours. Extinction localizes to the same set of Kenyon cells. This common localization suggests a model in which unreinforced presentations of a previously learned odorant intracellularly antagonizes the signaling cascades underlying memory formation. The second part also targets memory localization, but addresses appetitive memory. I show that memories for the same olfactory cue can be established through either sugar or electric shock reinforcement. Importantly, these memories localize to the same set of neurons within the mushroom body. Thus, the question becomes apparent how the same signal can be associated with different events. It is shown that two different monoamines are specificaly necessary for formation of either of these memories, dopamine in case of electric shock and octopamine in case of sugar memory, respectively. Taking the representation of the olfactory cue within the mushroom bodies into account, the data suggest that the two memory traces are located in the same Kenyon cells, but in separate subcellular domains, one modulated by dopamine, the other by octopamine. Taken together, this study takes two further steps in the search for the engram. (1) The result that in Drosophila olfactory learning several memories are organized within the same set of Kenyon cells is in contrast to the pessimism expressed by Lashley that is might not be possible to localize an engram. (2) Beyond localization, a possibible mechanism how several engrams about the same stimulus can be localized within the same neurons might be suggested by the models of subcellular organisation, as postulated in case of appetitive and aversive memory on the one hand and acquisition and extinction of aversive memory on the other hand.
We present the results of individual-based simulation experiments on the evolution of dispersal rates of organisms living in metapopulations. We find conflicting results regarding the relationship between local extinction rate and evolutionarily stable (ES) dispersal rate depending on which principal mechanism causes extinction: if extinction is caused by environmental catastrophes eradicating local populations, we observe a positive correlation between extinction and ES dispersal rate; if extinction is a consequence of stochastic local dynamics and environmental fluctuations, the correlation becomes ambiguous; and in cases where extinction is caused by dispersal mortality, a negative correlation between local extinction rate and ES dispersal rate emerges. We conclude that extinction rate, which both affects and is affected by dispersal rates, is not an ideal predictor for optimal dispersal rates.