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The reggie protein family consists of two homologous members, reggie-1 and reggie-2, also termed flotillin-2 and flotillin-1, respectively, that are ubiquitously expressed and evolutionarily well conserved, suggesting an important but so far ill-defined function. In various cell types, both reggies have been found to be constitutively associated with lipid rafts by means of acylation modifications and oligomerization. Lipid rafts are glycosphingolipid- and cholesterol-rich membrane microdomains which have been implicated in several cellular processes including membrane transport and signal transduction through growth factor receptors. However, the molecular details of these processes are still poorly understood. With the observation that reggies colocalize with activated glycosylphosphatidylinositolanchored proteins (GPI-APs) and Fyn kinase in rafts, a role for these proteins in signaling events has been suggested. In agreement with that, we have previously shown that reggie-1 becomes multiply tyrosine phosphorylated by Src kinases in response to epidermal growth factor (EGF) stimulation, pointing to a function for reggie-1 in growth factor signaling. Furthermore, overexpression of reggie-1 enhances spreading on fibronectin substrate in a tyrosine-dependent manner, thus revealing a role for reggie-1 in regulation of actin cytoskeleton through growth factor receptors. Due to the similarity shared by reggie proteins at amino acid level and to their ability to form hetero-oligomeric complexes, the first aim of this study was to analyze the putative tyrosine phosphorylation of reggie-2 in growth factor stimulated cells. Similarly to reggie-1, reggie-2 was found to be multiply tyrosine phosphorylated by Src kinase and to exist in a molecular complex with Src, with the degree of co-immunoprecipitation dependent on the activity of Src. Recent studies from us have also shown that administration of EGF results in the endocytosis of reggie-1 from the plasma membrane into endosomes, which is in line with a proposed role for reggies in membrane trafficking processes. In order to characterize in detail the endocytic mechanism that mediates the uptake of reggie-1, the dependency of reggie-1 endocytosis on clathrin and dynamin was investigated by means of overexpressing a variant form of Eps15 or a dominant negative form of dynamin-2. In either case the translocation of reggie-1 into endosomes in response to EGF was not affected, and this, together with the results that reggie-1 colocalized with cholera toxin (CTX) but not with transferrin receptor (TfnR) during EGF signaling, indicates that reggie-1 is taken up by means of a dynaminindependent, raft-mediated pathway. These findings are very well in line with recent data showing the pathway of entry into cells of reggie-2 as a raft-mediated endocytic pathway. The endocytosis of reggie-2 in response to EGF was also analyzed in this study. Similarly to reggie-1, in growth factor stimulated cells reggie-2 underwent a translocation from the plasma membrane to endosomes where the two reggies were found to colocalize with each other, suggesting that epidermal growth factor signaling might trigger the endocytosis of reggie oligomers. In addition, colocalization with both the late endosomal marker LAMP3/CD63 and epidermal growth factor receptor (EGFR) was detected, again indicating a function for reggies in signal transduction through growth factor receptors. EGFR has been reported to localize in rafts but, although this association is thought to be functional during EGF stimulation, how segregation of EGFR into rafts modulates its endocytosis and signaling is still under debate. Since reggie oligomers have recently been suggested to define a raft subtype, a further aim of this study was to investigate whether the depletion of reggies by means of small interfering RNA could interfere with the signaling and the trafficking through EGFR. Knockdown of reggie-2 resulted in an altered tyrosine phosphorylation of EGFR in response to EGF, while the degree of ubiquitination was not affected. Less efficient phosphorylation of tyrosine residues, especially of those which are docking sites for Grb2 and Shc, led in turn to an impaired activation of p38 and ERK1/2 MAPKs. Depletion of reggie-2 did not affect the early trafficking of activated EGFRs, with receptors being endocytosed and delivered to late endosomes as efficiently as in control cells. This would be in line with the normal degree of ubiquitination observed for EGFR, as ubiquitin moieties have been proposed to represent sorting tags that ensure receptor endocytosis into early endosomes and its proper intracellular trafficking. On the contrary, after prolonged EGF stimulation, depletion of reggie-2 resulted in a decreased downregulation of both receptor-bound ligand and EGFR, and in their accumulation in intracellular vesicles, thus pointing to a role for reggie-2 in the degradative pathway. Taken all together, these data ndicate that the association of EGFR with reggie-microdomains is likely to be important for proper receptor trafficking and signaling.
Reggie-1 (flotillin-2) and reggie-2 (flotillin-1) are membrane microdomain proteins which are associated with the membrane by means of acylation. They influence different cellular signaling processes, such as neuronal, T-cell and insulin signaling. Upon stimulation of the EGF receptor, reggie-1 becomes phosphorylated and undergoes tyrosine 163 dependent translocation from the plasma membrane to endosomal compartments. In addition, reggie-1 was shown to influence actindependent processes. Reggie-2 has been demonstrated to affect caveolin- and clathrin-independent endocytosis. Both proteins form homo- and hetero-oligomers, but the function of these oligomers has remained elusive. Moreover, it has not been clarified if functions of reggie-1 are also influenced by reggie-2 and vice versa. The first aim of the study was to further investigate the interplay and the heterooligomerization of reggie proteins and their functional effects. Both reggie proteins were individually depleted by means of siRNA. In different siRNA systems and various cell lines, reggie-1 depleted cells showed reduced protein amounts of reggie-1 and reggie-2, but reggie-2 knock down cells still expressed reggie-1 protein. The decrease of reggie-2 in reggie-1 depleted cells was only detected at protein but not at mRNA level. Furthermore, reggie-2 expression could be rescued by expression of siRNA resistant wild type reggie-1-EGFP constructs, but not by the soluble myristoylation mutant G2A. This mutant was also not able to associate with endogenous reggie-1 or reggie-2, which demonstrates that membrane association of reggie-1 is necessary for hetero-oligomerization. In addition, fluorescence microscopy studies and membrane fractionations showed that correct localization of overexpressed reggie-2 was dependent on co-overexpressed reggie-1. Thus, hetero-oligomerization is crucial for membrane association of reggie-2 and for its protein stability or protein expression. Moreover, the binding of reggie-2 to reggie-1 required tyrosine 163 of reggie-1 which was previously shown to be important for endosomal translocation of reggie-1. Since reggie-2 was implicated to function in clathrin- and caveolin-independent endocytosis pathways, the effect of reggie-2 depletion on reggie-1 endocytosis was investigated. Indeed, reggie-1 was dependent on reggie-2 for endosomal localization and EGF-induced endocytosis. By FRET-FLIM analysis it could be shown that reggie heterooligomers are dynamic in size or conformation upon EGF stimulation. Thus, it can be concluded that reggie proteins are interdependent in different aspects, such as protein stability or expression, membrane association and subcellular localization. In addition, these results demonstrate that the hetero-oligomers are dynamic and reggie proteins influence each other in terms of function. A further aim was the characterization of reggie-1 and reggie-2 function in actindependent processes, where so far only reggie-1 was known to play a role. Depletion of either of the proteins reduced cell migration, cell spreading and the number of focal adhesions in steady state cells. Thus, also reggie-2 affects actin-dependent processes. Further investigation of the focal adhesions during cell spreading revealed that depletion of reggie-1 displayed different effects as compared to reggie-2 knock down. Reggie-1 depleted cells had elongated cell-matrix-adhesions and showed reduced activation of FAK and ERK2. On the other hand, depletion of reggie-2 resulted in a restricted localization of focal adhesion at the periphery of the cell and decreased ERK2 phosphorylation, but it did not affect FAK autophosphorylation. Hence, reggie proteins influence the regulation of cell-matrix-adhesions differently. A link between reggie proteins and focal adhesions is the actin cross-linking protein -actinin. The interaction of -actinin with reggie-1 could be verified by means of co-immunoprecipitations and FRET-FLIM analysis. Reggie-1 binds -actinin especially in membrane ruffles and in other locations where actin remodeling takes place. Moreover, -actinin showed a different localization pattern during cell spreading in reggie-1 depleted cells, as compared to the control cells. These results provide further insights into the function of both reggie proteins. Their interplay and hetero-oligomerization was shown to be crucial for their role in endocytosis. In addition, both reggie proteins influence actin-dependent processes and differentially affect focal adhesion regulation.
The growth of blood vessels is crucial for organ growth in the embryo and repair of wounded tissues in the adult. An imbalance in this process contributes to numerous malignant, inflammatory, ischemic, infectious and immune disorders (Ferrara et al., 2003). Postnatal neovascularization occurs through the recruitment of progenitor cells and angiogenesis. Integrins are heterodimeric cell surface molecules and are the main receptors for extracellular matrix proteins. Regulation of integrin activation is crucial during embryonic development and during adult life. Dysregulation of integrin activity leads to severe diseases. In this study, we have demonstrated that Rap1, a small GTPase regulating integrin activity, and its GEF Epac1 are expressed in both EPC and endothelial cells. Moreover, the pharmacological activator of Epac activates the small GTPase Rap1 in progenitor cells. In parallel the angiogenic growth factors VEGF and bFGF activate Rap1 in endothelial cells. In addition, the regulation of Rap1 activity in EPC and in endothelial cells plays an important role in the regulation of migration and adhesion to matrix proteins, by regulating the activity of different integrins, a mechanism known as integrin inside‐out signaling. Furthermore, regulation of Rap1 activity affects probably indirectly through outside‐in signaling of integrins the activity of several and crucial proteins such PKB/Akt and focal adhesion kinase in endothelial cells. In line with these results, we have demonstrated that Rap1 activity affect angiogenesis, homing of EPC to ischemic tissues and thereby postnatal neovascularization. The understanding how Rap1 regulates integrin activity in endothelial cells is still not completely clear, for example we have demonstrated that the known effectors of Rap1 mediating the increase of integrin activity in T and B cells, such as RAPL and RIAM are, respectively, either not increasing integrin activity or not expressed in endothelial cells. We aim to find the effector of Rap1 promoting integrin activity in endothelial cells and how RAPL regulates integrin functions and angiogenesis. Moreover data from us and others using genetic models and generation of Rap1a or Rap1b deficient mice or deficient for Rap1a and Rap1b led to embryonic lethality suggesting that Rap1 is a key node protein during embryonic development. The development of conditionnal Rap1a/b endothelial/pericytes restricted deficient mice will help us to decipher more precisely the role of Rap1 during vascular development and angiogenesis.
The research presented in this thesis characterizes U2AF homology motifs (UHM) and their interactions with UHM ligand motifs (ULM) in the context of splicing regulation. UHM domains are a subgroup of RNA recognition motifs (RRM) originally discovered in the proteins U2AF65 and U2AF35. Whereas canonical RRMs are usually involved in binding of RNA, UHM domains bind tryptophan containing linear protein motifs (ULM) instead. In the first article, we analyze the complex network of interactions between splicing factors and RNA that initiate the assembly of the spliceosome at the 3´ splice site of an intron. The protein U2AF65 binds a pyrimidine-rich element in introns and recruits U2snRNP by binding its protein component SF3b155. My contribution was to define the binding site of the protein U2AF65 to the intrinsically unstructured N-terminus of the scaffolding protein SF3b155. I could show that the UHM domain of U2AF65 recognizes a ULM in SF3b155, and that this binding site is not overlapping with the binding sites of other splicing factors, like p14, to SF3b155. As the U2AF65-UHM:SF3b155-ULM interaction is mutually exclusive with an interaction between U2AF65-UHM and a ULM in the splicing factor SF1, which was reported to initially recognize the branch point sequence, my results provide the molecular details on how SF3b155 replaces SF1 during spliceosomal reorganizations. In the second article, we show that overexpression of the UHM domain of the splicing factor SPF45 induces exon 6 skipping in the pre-mRNA of Fas (CD95/APO-1). I provide evidence for in vitro binding of SPF45-UHM to ULM sequences in the splicing factors U2AF65, SF1, and SF3b155. I crystallized free and SF3b155-bound SPF45 UHM and solved both structures by X-ray crystallography. The analysis of the complex interface and sequence differences in the ULMs allowed me to design mutations of SPF45-UHM, which selectively inhibit binding to distinct ULMs. After assessing the ULM binding properties in vitro, we could show that the activity of SPF45-UHM in influencing the splicing pattern of Fas relies on interactions with SF3b155 and/or SF1, but that an interaction with U2AF65 is dispensable. A mechanism for the activity of SPF45-UHM could thus be engaging in ULM interactions and thus interfering with the network of interactions that initiate the assembly of the spliceosome at the 3´splice site, as described above. In the third article, we describe an unusual flexible homodimerization mode of the UHM in the splicing factor Puf60, which enables simultaneous interactions with ULM sequences on other splicing factors. I could show that the NMR relaxation properties of Puf60-UHM are inconsistent with a model of a rigid dimer, but rather indicate a dimerization via a flexible linker. I identified a flexible loop in the peptide backbone of Puf60-UHM, and showed that mutiation of acidic residues in this loop impairs the dimerization. To analyze the dimerization interface in further detail, I solved the structure of Puf60-UHM by X-ray crystallography. The acidic residues in the flexible loop of one UHM dimer subunit mediate the dimerization by contacting basic residues on the β-sheet surface of the other dimer subunit. Differences in the four dimer interfaces observed for the eight molecules in the asymmetric unit of the crystal support the model of an undescribed, flexible mode of dimerization, and thus complement the NMR relaxation data. Furthermore, I could show that the Puf60-UHM dimer and U2AF65-UHM contact different ULM sequences on the SF3b155 N-terminus in vitro, thus providing a possible explanation for the mutual cooperative activation of Puf60 and U2AF65 in splicing assays described in the literature. The fourth article is a review about recent research on the recognition of DNA double strand breaks (DSB) by covalent histone modifications. The p53 binding protein 1 (53BP1) is a DSB sensor and a checkpoint protein for mitosis. Recent crystallographic evidence indicates that 53BP1 recognizes DSB sites by binding histone H4 dimetylated at lysine 20 (H4-K20). We provide a comprehensive overview of the atomic resolution structures that revealed how proteins can specifically recognize histone tail modifications, especially methylated lysines, to read the information stored in what is called the histone code.
In this thesis I have investigated the regulation of eicosanoid synthesizing-enzymes by cannabinoid receptor agonists. Rat renal mesangial cells were used as a model system. I could show that all three (CB1, CB2, and GPR55) cannabinoid receptors are expressed on the mRNA level in rat renal mesangial cells – but with differing expression profiles. The CB1 and GPR55 receptors are expressed in comparable amounts, whereas the CB2 receptor is considerably less expressed than the CB1 and the GPR55 receptors. Furthermore I could show that stimulation of renal mesangial cells with CB1 receptor agonists, such as R(+)MA or ACEA, increased IL-1β-induced cPLA2, sPLA2-IIa, and COX2 protein and mRNA expression which subsequently led to an enhanced IL-1β-induced PGE2 formation. Additionally, the IL-1β- induced sPLA2-IIa promoter activity was also increased by CB1 receptor stimulation. Besides the modulated expression of the eicosanoid synthesizing enzymes, I could show that CB1 agonists also led to an increase of IL-1β-induced iNOS expression and subsequent NO formation. In contrast, stimulation with CB2 selective agonists led to a decrease in IL-1β- induced sPLA2-IIa protein expression and PGE2 formation. Accordingly, the IL-1β-induced sPLA2-IIa promoter activity was also reduced by CB2 receptor agonists. IL-1β-induced iNOS expression and subsequent NO formation were not influenced by CB2 recptor activation. Matching the results I obtained with CB1 receptor agonists on IL-1β-induced PGE2 formation, I could observe an increased cPLA2 protein and mRNA expression with a subsequent increase in IL-1β-induced PGE2 formation by GPR55 stimulation. Stimulation with THC, an unselective CB agonist, increased the IL-1β-induced sPLA2-IIa protein expression and subsequently led to an enhanced IL-1β-induced PGE2 formation. Subjecting the cells to higher THC concentrations surprisingly led to a reduction of the IL-1b-induced sPLA2-IIa protein expression and PGE2 formation. A possible explanation may be the differential expression of the three CB receptors. At low concentrations THC may predominantly activate CB1 and GPR55 and with increasing concentration CB2 receptors may also be activated, slightly reversing the enhancing effect. Moreover, I could show that the CB1 receptor stimulation mediated phosphorylation and hence the activation of ERK1/2 MAPK. Additionally to ERK1/2, there was also a phosphorylation and activation of NFkB observed by CB1 receptor stimulation. In my thesis I could show for the first time that PPARα was activated by IL-1β in rMC. The IL-1β-induced PPARα promoter activity was completely inhibited by addition of the CB2 receptor agonist, JWH015. These findings were confirmed by inhibition of the IL-1β-induced PGE2 formation by a PPARα antagonist (MK-886). In summary, I could show that activation of CB1 receptors in our system led to a worsening of an inflammatory condition, whereas activation of the CB2 receptors led to the complete opposite; namely a reduction of the inflammatory response by reducing the sPLA2-IIa expression and PGE2 formation. GPR55 activation did not display any alteration of inflammatory conditions, since the classical inflammatory pathway was not influenced.
Arthropods use fluid medium motion-sensing filiform hairs on their exoskeleton to detect aerodynamic or hydrodynamic stimuli in their surroundings that affect their behaviour. The hairs, often of different lengths and organized in groups or arrays, respond to particular fluid motion amplitudes and frequencies produced by prey, predators, or conspecifics, even in the presence of background noise peculiar to the environment. While long known to biologists and experimentally investigated by them, it is only relatively recently that comprehensive physical-mathematical models have emerged offering an alternative methodology for investigating the biomechanics of filiform hair motion. These models have been developed and applied to quantitatively predict the performance characteristics of filiform hairs in air and water as a function of the relevant parameters that affect their physical behaviour. They even allow the exploration of possible biological evolutionary paths for filiform hair changes resulting from physical selection pressures. In this chapter we review the state of knowledge of filiform hair biomechanics and discuss two physical-mathematical models to predict hair dynamical behaviour. One modelling approach is analytically exact, serving for quantitative purposes, while the other, derived from it, is approximate, serving for qualitative guidance concerning the parameter dependencies of hair motion. Using these models we look in turn at the influence of these parameters and the fluid media physical properties on hair motion, including the possibility of medium-facilitated viscous coupling between hairs. The models point to areas where data is currently lacking and future research could be focused. In addition, new results are presented pertaining to transient tlows. We qualitatively explore the possibility of an overlapping water-air niches adaptation potential that may explain how, over many generations, the filiform hairs of an arthropod living in water could have evolved to function in air. Because flow-sensing hairs have served to inspire corresponding artificial medium motion microsensors, we discuss recent advances in this area. Significant challenges remain to be overcome, especially with respect to the materials and fabrication techniques used. In spite of the impressive technological advances made, nature still remains unrivalled.
Ataxin-2 is a novel protein, within which the unstable expansion of a polyglutamine domain can cause Spinocerebellar Ataxia type 2 (SCA2), a neurodegenerative disease which belongs to the group of polyglutamine disorders. SCA2 is characterised by a progressive loss of neurons that first affects the cerebellum and brain stem and then may extend to other areas of the brain, like substantia nigra, motoneurons and thalamus. Several lines of research have attempted to determine therole of ataxin-2 in its normal and mutant version. Different animal models and cell culture approaches to study ataxin-2 function implicated ataxin-2 in RNA processing, embryonic development, apoptosis and cytoskeleton. However, the function of ataxin-2 still remains unclear. In this thesis, a protein interaction approach was chosen as an alternative to gain insights into the cellular function of ataxin-2. Full-length ataxin-2 was used as bait in a yeast two-hybrid screen of human adult brain cDNA. Among five candidate interactor proteins identified, two were the endophilins A1 and A3, proteins involved in vesicle endocytosis. Co-immunoprecipitation studies confirmed the association of these proteins in an endogenous complex of mouse brain. In vitro binding experiments narrowed the binding interfaces down to two proline-rich domains on ataxin-2, which interacted with the SH3 domain of endophilins A1/A3. Ataxin-2 and endophilins A1/A3 colocalised at the endoplasmic reticulum as determined by immunofluorescence microscopy of transfected cell lines, and by centrifugation fractionation studies of mouse brain. Importantly, the pattern observed in transfected cells was conserved in untransfected rat hippocampal neurons. In mouse brain, associations of ataxin-2 with endocytic proteins such as the adaptor CIN85, the ubiquitin ligase c-Cbl and also GRB2, in the last case by means of a SH3 domain array chip, were also demonstrated. GST pull-down assays showed ataxin-2 to interact directly with the SH3 domains A and C of CIN85, the C-terminal SH3 domain of GRB2, and the SH3 domain of Src, a kinase activated after receptor stimulation. Functional studies demonstrated that ataxin-2 affects endocytic trafficking of the epidermal growth factor receptor (EGFR) by reducing the EGFR internalisation after EGF stimulation. Taken together, these data implicate ataxin-2 to play a role in endocytic receptor cycling.
Plastids are complex plant organelles fulfilling essential physiological functions, such as photosynthesis and amino acid metabolism. The majority of proteins required for these functions are encoded in the nuclear genome and synthesized on cytosolic ribosomes as precursors, which are subsequently translocated across the outer and inner membrane of the organelle. Their targeting to the organelle is ensured by a so called transit peptide, which is specifically recognized by GTP-dependent receptors Toc159 and Toc34 at the cytosolic side of outer envelope. They cooperatively regulate the insertion of the precursor protein into the channel protein Toc75, thereby initiating the translocation process. Toc34 is regarded as the primary receptor, while Toc159 probably provides the driving force for the insertion. Precursor transfer is achieved by the physical interaction between both receptors in the GTP loaded state. One translocon unit, also called the Toc core complex, is formed by four molecules Toc34, four molecules Toc75 and one molecule Toc159. In the GDP-loaded state, Toc34 preferably forms homodimers, whose physiological function was investigated in the presented study. It could be shown that the dissociation of GDP and therefore the nucleotide exchange are inhibited by the homodimeric state of Toc34. Dissociation of the homodimer is induced by the recognition of a precursor protein, which renders the binding of GTP and subsequent interaction with Toc159 possible. Thus, the homodimeric conformation could reflect an inactive state of the translocon, preventing GTP consumption in the absence of a precursor protein. Both homodimerization as well as heterodimerization of the receptor are regulated by phosphorylation, which could be demonstrated by in vitro and in vivo approaches using atToc33 from Arabidopsis thaliana as a model system. Since the phosphorylated form of Toc34 cannot be assembled with the Toc core complex, it can be concluded that the interactions between GTPase domains not only regulate the transfer of precursor proteins, but also warrant the integrity of the translocon.
RNA interference (RNAi) is triggered by recognition of double-stranded RNA (dsRNA), and elicits the silencing of gene(s) complementary to the dsRNA sequence. RNAi is thought to have emerged as a way of safeguarding the genome against mobile genetic elements and viral infection, thus maintaining genomic integrity. dsRNA is first processed into small interfering RNAs (siRNA) by the enzyme Dicer. siRNAs are ~21 to 25 -nt long, and contain a signature 5’ phosphate group and a two nucleotide long 3’ overhang (Bernstein et al., 2001). The siRNA is then loaded into the RNA-induced si-lencing complex (RISC), of which Argonaute is the primary catalytic component (Liu et al., 2004). Energetic asymmetry of the siRNA ends allows for its directional loading into RISC (Khvorova et al., 2003; Schwarz et al., 2003). Argonaute cleaves the passen-ger strand of the siRNA, leaving the guide strand of the siRNA bound to RISC (Gregory et al., 2005; Matranga et al., 2005; Rand et al., 2005). This single-stranded guide strand siRNA bound to Argonaute is able to recognize target mRNA in a sequence-specific manner, and cleaves the mRNA. Argonaute 2 in complex with single-stranded siRNA is sufficient for mRNA recognition and cleavage, thus forming a minimal RISC (Rivas et al., 2005). miRNAs, endogenously expressed small RNA genes which typically contain mismatches and non-Watson-Crick base pairing, are processed by this general pathway, although typically modulate gene expression by translational repression as opposed to cleavage of their target mRNA. The number of Argonaute genes is highly variable between species, ranging from one in S. pombe to twenty-seven in C. elegans. Earlier crystal structures of Argonaute apoen-zymes show the architecture of Argonaute to be a multidomain protein composed of N terminal, PAZ, MID, and PIWI domains (Song et al., 2004; Yuan et al., 2005). These multi-domain proteins are present in both prokaryotic and eukaryotic organisms. The role of Argonaute proteins in prokaryotes is still unknown, but based similarity to eu-karyotic Argonautes, they may also be involved in nucleic acid-directed regulatory pathways. These proteins have served as excellent models for learning about the struc-ture and function of this family of proteins. RNAi has found a widespread application for the simple yet effective knockdown of genes of interest. The catalytic cycle of RISC requires the binding of a number of different nucleotide structures to Argonaute, and we expect Argonaute to undergo a number of conforma-tional changes during the cycle of mRNA recognition by RISC (Filipowicz, 2005; Tom-ari and Zamore, 2005). Nevertheless, it remains unclear how the multi-domain ar-rangement of Argonaute recognizes and distinguishes between single-stranded and dou-ble-stranded oligonucleotides, which correspond to the Dicer-processed siRNA product, guide strand siRNA, and the guide strand / mRNA duplex. The Argonaute protein from Aquifex aeolicus was cloned, expressed, crystallized and solved by molecular replacement. Relative to earlier Argonaute structures, a 24° reorientation of the PAZ domain in this structure opens a basic cleft between the N-terminal and PAZ domains, exposing the guide strand binding pocket of PAZ. A 5.5-ns molecular dynamics simulation of Argonaute showed a strong tendency of the PAZ and N-terminal domains to be mobile. Binding of single-stranded DNA to Argonaute was monitored by total internal reflection fluorescence spectroscopy (TIRFS). The experi-ments showed biphasic kinetics indicative of large conformational changes, and re-vealed a hotspot of binding energy corresponding to the first 9 nucleotides, the so-called “seed region” most crucial for sequence-specific target recognition. As RNAi may have evolved as a way of safeguarding the genome viral infection, it is not surprising that viruses have evolved different strategies to suppress the host RNAi response in the form of viral suppressor protein. (Hock and Meister, 2008; Lecellier and Voinnet, 2004; Rashid et al., 2007; Song et al., 2004; Vastenhouw and Plasterk, 2004). These viral suppressors are widespread, having been identified in a number of different viral families. Not surprisingly, they generally share little sequence homology with one another, although they appear to exist as oligomers built upon a ~ 100-200 amino acid protomer. Tomato aspermy virus, a member of the Cucumoviruses, encodes for protein 2B (TAV 2B, 95 a.a., ~11.3 kDa) that acts as an RNAi suppressor. Intriguingly, a similar genomic arrangement is seen in RNAi suppressors in the Nodaviruses, a family of viruses that can infect both plants and animals, such as Flock house virus b2 (FHV b2). The 2B and b2 proteins are both derived from a frameshifted ORF within the RNA polymerase gene (Chao et al., 2005). In spite of this genomic similarity, the 2B and b2 proteins share little sequence identity, and it is not well understood how the Cucumovirus 2B proteins suppress RNAi. To address how TAV 2B suppresses RNAi, the oligonucleotide-binding properties of TAV 2B were studied. TAV 2B shows a preference for double-stranded RNA oligonucleotides corresponding to siRNAs and miRNAs, and also binds to single-stranded RNA oligonucleotides. A stretch of positively charged residues between amino acids 20-30 are critical for RNA binding. Binding to RNA oligomerizes and induces a conformational change in TAV 2B into a primarily helical structure. These studies sug-gest that suppression of RNAi by TAV 2B may occur by targeting different stages of the RNAi pathway. TAV 2B falls under the category of more general RNAi suppres-sors, with potentially multiple targets for suppression.
The respiratory chain is composed of protein complexes residing in the inner mitochondrial membrane of eukaryotes or in the cytoplasmic membrane of prokaryotes. This cellular energy converter transforms a redox potential stored in low potential substrates into an electrochemical potential across the respective membrane. Typical respiratory chains contain the complexes I, II, III and IV named according to their sequence in the respiratory chain reaction. Electrons of low potential substrates enter at complex I or II and are passed via complex III to complex IV where they are transferred to oxygen. The transport of electrons between the complexes is mediated by small electron shuttles like quinol or cytochrome c. Two different models describe their exchange either by (1) random collision of freely diffusible electron shuttles and membrane protein complexes or (2) arrangement of the complexes in supercomplexes enabling direct channeling of electron shuttles. In the Gram positive bacterium Corynebacterium glutamicum, the complex III to complex IV electron shuttle cytochrome c is not diffusible but a covalently bound part of the diheme cytochrome subunit QcrC of complex III. Therefore, the complexes III and IV have to form a supercomplex for electron transduction. The aim of this thesis was to purify and characterise this obligatory supercomplex III/IV of C. glutamicum. To gain sufficient biomass of C. glutamicum as starting material for purification, a phosphate buffered minimal medium was developed that enabled yield of total 120 g wet cell mass (38 g dry mass) in 12 L (6×2 L) shaking cultures. The determined conversion factor of glucose into biomass was 0.46 g/g indicating an intact respiratory chain. The yield was increased by bioreactor cultivation to ~690 g wet cell mass (~220 g dry mass) in ~10 L culture volume. A previously described homologous expression system was applied that produces the complex IV subunit CtaD with a fused Strep-tag II to facilitate purification. Affinity purifications using the Strep-tag II affinity to Strep-Tactin resin yielded a mixture of complexes and supercomplexes. Two supercomplex III/IV versions named supercomplex A and B and free complex IV were identified in this mixture by size exclusion chromatography, redox difference spectroscopy and two dimensional polyacrylamide gel electrophoresis including blue native polyacrylamide electrophoresis. The here presented downscaled blue native polyacrylamide electrophoresis method with analysis times of ~1 h enabled efficient screening of factors influencing the stability of supercomplex III/IV. The screening resulted that the integrity of supercomplex III/IV is preserved by using neutral detergents at minimal detergent to protein ratios for solubilisation and low detergent concentrations for purification and storage slightly above the required critical micellar concentration. Furthermore, pH <=7.5 is required for stability of supercomplex III/IV. Large biomass yields enabled upscaling of supercomplex III/IV affinity purification. Application of the identified stability conditions resulted in affinity purified samples free of supercomplex B. The major component supercomplex A was efficiently separated from residual free complex IV by preparative size exclusion chromatography. Concentration of purified supercomplex A by ultracentrifugation resulted in integrity of the supercomplex for several days at 4 °C. Purified supercomplex A contains ten different previously described subunits. The heme content of supercomplex A relative to the protein mass is heme A: 6.0 μmol/g, heme B: 6.5 μmol/g, and heme C: 5.8 μmol/g determined by redox difference spectroscopy and biochemical protein quantification. This indicates an equimolar ratio of complex III and complex IV in supercomplex A. Supercomplex A has quinol oxidase activity that is inhibited by stigmatellin or sodium azide. The turnover number of transferred electrons per complex III monomer is 148 s−1 at 25° C. The homogeneity and stability of the prepared supercomplex A enabled the growth of threedimensional crystals of up to 0.1 mm in length. Their composition of supercomplex A was verified by redox difference spectroscopy of intact crystals and blue native polyacrylamide electrophoresis of dissolved crystals. The crystals diffracted X-rays corresponding to a resolution of ~10 Å. Electron microscopy of negative stained samples revealed the uniform shape of purified supercomplex A particles with dimensions of 22 × 9 nm in the view plane. Combined heme quantification, size determination, determined activity, symmetry considerations, and particle shape indicate that supercomplex A has a central dimer of complex III and two monomers of complex IV on opposite sides. This conformation is functionally reasonable because it provides each complex III monomer with one complex IV monomer as electron acceptor. Therefore, the stoichiometry of supercomplex A is most likely III2IV2. The sensitivity of supercomplex A to detergents indicated a role of phospholipids in its stability. Therefore, a method for phospholipid identification and quantification was developed that is suitable for detergent solubilised crude and purified membrane protein samples. The analysis combines separation of phospholipid classes according to their head group by normal phase high performance liquid chromatography with evaporative light scattering detection. Calibration with external standard allows quantification of phospholipid amount in the range of 0.25-12 μg. The method is verified by analysing the phospholipid content of the well characterised complex III of Saccharomyces cerevisiae. The reduction of its phospholipid content during its purification steps is monitored. The complex III sample purified to crystallisation quality contains the phospholipid content that was also observed in previously reported structures determined by X-ray crystallography. Purified stable supercomplex A from C. glutamicum revealed a large content of bound phospholipids. The main differences between intact supercomplex A and a mixture of potentially disintegrated smaller complexes is that intact supercomplex A has a doubled phosphatidic acid content and an increased phosphatidyl glycerol content. The importance of the small anionic phosphatidic acid for mediation of contacts between complexes in a supercomplex is discussed. The total phospholipid content of stable supercomplex A is sufficient for a complete belt surrounding the supercomplex in the membrane plane. This indicates that also all essential internal phospholipid binding positions are occupied and potentially stabilise supercomplex A.
Genetic analysis of salt adaptation in Methanosarcina mazei Gö1 : the role of abl, ota and otb genes
(2008)
1. M. mazei ist ein halotolerantes methanogenes Archäon und akkumuliert kompatible Solute als längerfristige Anpassung an erhöhte Osmolarität in der Umgebung. Bei intermediären Salzkonzentrationen (~ 400 mM NaCl) wird vorzugsweise α-Glutamat gebildet und bei höheren Salzkonzentrationen (~ 800 mM NaCl) wird Nε-Acetyl-ß-Lysin zusätzlich zu Alpha-Glutamat synthetisiert. 2. Eine Analyse der intrazellulären Solutezusammensetzung mittels NMR ergab, dass M. mazei Glycin-Betain als Osmolyt akkumulieren kann. Für die Aufnahme von Glycin-Betain konnten zwei putative Glycin-Betain-Transporter in M. mazei identifiziert werden, Ota und Otb. Ota steht für „osmoprotectant transporter A“ und Otb für „osmoprotectant transporter B“. Das Genom von M. mazei wurde, nachdem es vollstänidg sequenziert war, nach Genen durchsucht, die eine Rolle bei der Aufnhame von Glycin-Betain oder anderen kompabtiblen Solute spielen könnten. Dafür wurde die Sequenz eines Substratbindeproteins eines bekannten bakteriellen Glycin-Betain-Transporters, opuAC aus B. subtillis als Referenzsequenz verwendet. Hierbei konnte ein Homolog, otaC, in M. mazei identifiziert werden. otaC ist Teil eines Genclusters, welches für einen ABC-Transporter kodiert. otb wurde bei einer genomweiten Expressionsanalyse zur Salzadaptation von M. mazei identifiziert. Es wurden Gene eines putativen ABC-Transporters identifiziert, die unter Hochsalzbedingungen leicht induziert waren. Es stellte sich heraus, dass es sich hierbei um einen zweiten putativen Glycin-Betain-Transporter handelte. Otb gehört auch zur Familie der ABC-Transporter. Vergleichsanalysen zeigten, dass die beiden Transporter keine große Ähnlichkeit zueinander aufweisen. Die Funktion und Rolle der beiden ABC-Transporter, vor allem von Otb, war zu Beginn dieser Arbeit unklar. 3. Bei Analysen des intrazellulären Solutepools im Wildtyp von M. mazei stellte sich heraus, dass in Anwesenheit von Glycin-Betain die Konzentration von Glutamat und NE- Acetyl-ß-Lysin verringert war. Bei 400 mM NaCl reduzierte Glycin-Betain die Glutamat- Konzentration um 16% und bei 800 mM NaCl um 29%. Besonders deutlich zeigte sich der Einfluß von Glycin-Betain bei der Akkumulation von NE-Acetyl-ß-Lysin. Bei 400 mM NaCl reduzierte Glycin-Betain die Konzentration an NE-Acetyl-ß-Lysin um 60% und bei 800 mM NaCl um 50%. Der Einfluß von Glycin-Betain konnte auf verschiedenen Ebenen in M. mazei beobachten werden. Es konnte gezeigt werden, dass die relative Transkriptimenge von ota unter Hochsalzbedingungen zunimmt. Glycin-Betain reduzierte die Transkription von ota bei verschiedenen Salzkonzentrationen. Die relative Transkriptmenge an mRNA von ota wurde mittels quantitativer real-time PCR (qRT-PCR) quantifiziert und war bis zu 52% reduziert in Zellen, die in Gegenwart von Glycin-Betain gewachsen waren. Die Transkriptmenge von otb war unter den gleichen Bedingungen nicht beeinflusst und zeigte generell keine Zunahme mit der Salinität des Mediums. Des Weiteren konnte ein Effekt von Glycin-Betain auf Ebene der Transportaktivität von Ota gezeigt werden. Hier zeigte sich, dass Zellen, die bei 400 mM NaCl in Gegenwart von Glycin-Betain gezogen waren, eine geringere Transportaktivität aufweisen, als Zellen, die bei 400 mM NaCl ohne Glycin-Betain gewachsen waren. Die Transportaktivität war um 90% geringer. Es muss jedoch berücksichtigt werden, dass es sich bei den Zellen, die ohne Glycin-Betain gewachsen waren, um eine Nettoaufnahme von Glycin-Betain handelte. Im Gegensatz dazu, ist davon auszugehen, dass Zellen, die in Gegenwart von Glycin-Betain gewachsen waren, eine Austaschreaktion zwischen bereits vorhandenem intrazellulärem und extrazellulär angebotenem Glycin-Betain vornehmen. [Die dem letzten Punkt zugrundeliegenden Daten wurden von Silke Schmidt im Rahmen einer Diplomarbeit erhoben, die von mir mitbetreut wurde. Aus Gründen der vollständigen Darstellung des Projektverlaufes werden diese Daten mitaufgeführt.] 4. Zur weiteren Klärung der Rolle und Funktion der beiden putativen Glycin-Betain- Transporter Ota und Otb war es Ziel, Mutantenstudien durchzuführen. Eine Vorraussetzung für die Generierung von Mutanten ist, dass der Organismus auf Agarplatten wächst und Einzelkolonien von einer einzelnen Zelle ausgehend bildet. Dies ist ein wichtiger Punkt bei Methanosarcina spp., die Zellpakete, sogenannte Sarcinen bilden. Deshalb wurde zunächst nach den optimalsten Plattierungsbedingungen gesucht, unter denen M. mazei keine Sarcinen bildet und die Plattierungseffizienz am höchsten war. Die Plattierungseffizienz betrug im Durchschnitt 54%. Für das Einbringen von DNA in die Zellen wurde eine Liposomen-vermittelte Transformation getestet. Ein ähnliches Vorgehen war bereits für Methanosarcina acetivorans beschrieben, konnte bislang aber noch nicht erfolgreich für M. mazei Gö1 und andere Stämme von M. mazei angwendet werden. Erste Schritte zur Anpassung des Transformations-Protokolles beinhalteten das Testen von DOTAP verschiedener Hersteller, sowie die Konzentration an eingesetzter DNA. Das jeweilige Zielgen/Zieloperon, welches deletiert werden sollte, wurde durch eine pac-Kassette ersetzt. Diese kodiert für eine Puromycin-Transacetylase und verleiht dem Organismus Puromycin- Resistenz. Die pac-Kassette wurde von umgebenden Bereichen des Ziellocus flankiert und integrierte mit Hilfe dieser flankierenden Bereiche über doppelt-homologe Rekombination in das Genom. 5. Mit dem oben beschriebenen Verfahren wurden ota::pac- und otb::pac-Mutanten erzeugt und über Southern-Blot Analyse verifiziert. Eine erste Charakterisierung der Mutanten mittels qRT-PCR zeigte, dass auf mRNA-Ebene keine Transkripte von ota in M. mazei ota::pac oder otb in M. mazei otb::pac nachweisbar waren. Zusätzlich konnte auf Proteinebene das Substratbindeprotein OtaC in M. mazei ota::pac und OtbC in M. mazei otb::pac nicht über einen Antikörper gegen das jeweilige Substratbindeprotein nachgewiesen, was die erfolgreiche Deletion bestätigte. Erste phänotypische Charakterisierungen zeigten, dass das Wachstum von M. mazei ota::pac und M. mazei otb::pac unter Hochsalzbedingungen nicht beeinträchtigt und vergleichbar mit dem des Wildtyps war. Auch bei kälteren Wachstumstemperaturen von 22°C wuchsen die Mutanten ohne Phänotyp. 6. Radioaktive Transportstudien mit M. mazei otb::pac zeigten, dass diese Mutante, die noch ein funktionelles Ota besitzt, [14C]Glycin-Betain aufnehmen kann. Es stellte sich heraus, dass diese Mutante eine höhere Transportrate für Glycin-Betain aufwies, als der Wildtyp. Die Aufnahmerate war um einen Faktor 2 höher als beim Wildtyp. Zusätzlich konnten qRT-PCR Analysen zeigen, dass die relative Transkriptmenge an ota in der otb::pac-Mutante um einen Faktor 2 höher war, als im Wildtyp. Umgekehrt konnte dieser Effekt nicht beobachtet werden, d.h. eine erhöhte Transkriptmenge an otb in M. mazei ota::pac. Auf Proteinebene konnte beobachtet werden, dass die intrazelluläre Konzentration an OtaC in der Mutatne leicht höher war als im Wildtyp. Jedoch stellte sich heraus, dass die intrazelluläre Glycin-Betain-Konzentration bei 400 mM NaCl in der Mutante nicht erhöht war verglichen mit Wildtyp, sondern die Konzentrationen gleich waren. Bei höheren Salzkonzentrationen (800 mM NaCl) zeigte sich jedoch ein anderes Bild: die intrazelluläre Glycin-Betain-Konzentration war in der Mutante um 60% erhöht. Dies könnte auf die erhöhte Transportaktivität von M. mazei otb::pac zurückzuführen sein. Die Konzentration anderer kompatibler Solute wie Glutamat und NE-Acetyl-ß-Lysin waren in diesen Zellen bis zu 48% reduziert. In vorherigen Studien konnte gezeigt werden, dass heterolog überproduziertes Ota von M. mazei in E. coli MKH13, eine E. coli-Mutante, die keine Glycin-Betain-Transporter mehr besitzt, die Aufnahme von Glycin-Betain wieder herstellen konnte [die Daten von ota in E. coli MKH13 wurden in der bereits oben erwähnten Diplomarbeit von Silke Schmidt erhoben]. Zur Klärung der Funktion von Otb wurde der gleiche Versuch mit otb in E. coli MKH13 durchgeführt. Jedoch konnte eine heterologe Produktion von Otb aus M. mazei die Aufnahme von Glycin-Betain in E. coli MKH13 nicht wieder herstellen. Hierbei wurde über Western-Blot Analyse sichergestellt, dass Otb tatsächlich in der Membran vorhanden war. Auch Transportstudien mit der Mutante M. mazei ota::pac zeigten, dass diese Mutante kein [14C]Glycin-Betain mehr aufnehmen konnte. Es konnte auch keine Akkumulation von Glycin-Betain mittels NMR in dieser Mutante gemessen werden. Des Weiteren zeigte sich, dass die intrazellulären Konzentrationen an Glutamat und Nε-Acetyl-ß-Lysin bei 400 mM und 800 mM NaCl in der Mutante unbeeinflusst von der Glycin-Betain-Konzentration im Medium waren. Weitere Transportstudien mit M. mazei ota::pac zur Aufnahme von [14C]Cholin zeigten, dass dieses Molekül weder vom Wildtyp, noch von der Mutante aufgenommen wurde. Dieses Ergebnis wurde durch Messung des Solutepools mittels NMR bestätigt. Somit kann ausgeschlossen werden, dass Otb unter den gemessenen Bedingungen weder ein Glycin- Betain-Transporter noch ein Cholin-Transporter in M. mazei ist. Diese Beobachtungen belegen eindeutig, dass Ota der einzige funktionelle Glycin-Betain-Transporter in M. mazei ist, während die Rolle von Otb bislang noch ungeklärt ist. 7. Nε-Acetyl-ß-Lysin, das dominante kompatible Solut in M. mazei bei 800 mM NaCl, wird durch die Enzyme AblA, einer Lysin-2,3-Aminomutase und AblB, einer ß-Lysin- Acetyltransferase synthetisiert. In dieser Arbeit wurde eine Δabl::pac-Mutante generiert, um die Fragen zu klären, ob die beiden Enzyme vom postulierten abl-Operon kodiert werden und wenn ja, welchen Phänotyp eine Nε-Acetyl-ß-Lysin-freier-Mutante bei Salzstress zeigt. NMR-Analysen zeigten, dass in der abl::pac-Mutante kein Nε-Acetyl-ß-Lysin mehr nachweisbar war. Dies belegt, dass die Gene ablA und ablB und deren Genprodukte für die Synthese von NE-Acetyl-ß-Lysin in M. mazei essentiell sind. Unter Hochsalzbedingungen ist das Wachstum von M. mazei abl::pac im Vergleich zum Wildtyp deutlich verlangsamt. Dieses Ergebnis war unerwartet, da eine abl::pac-Mutante von Methanococcus maripaludis unter Hochsalzbedingungen nicht mehr wachsen konnte. Unter Niedrigsalz und bei intermediären Salzkonzentration war das Wachstum von M. mazei abl::pac nicht eingeschränkt und verhielt sich wie der Wildtyp. In Gegenwart von Glycin-Betain akkumulierte die abl::pac-Mutante von M. mazei unter Hochsalzbedingungen 2,4 mal mehr Glycin-Betain als der Wildtyp, um das Defizit im Solutepool auszugleichen und Wachstum bei Hochsalz zu ermöglichen. Dadurch war sie in der Lage, wieder wie der Wildtyp zu wachsen. 8. Der Verlust von NE-Acetyl-ß-Lysin wurde unter Hochsalzbedingungen durch erhöhte Konzentrationen an Glutamat und einem neuen kompatiblen Solut kompensiert. NMRAnalysen zeigten, dass es sich hierbei um Alanin handelte. Bis jetzt wurde die Verwendung von Alanin als kompatibles Solut noch nie beschrieben. Um sicherzustellen, dass Alanin als kompatibles Solut in M. mazei abl::pac dient, wurde die Konzentration bei verschiedenen Salzkonzentrationen gemessen. Die Konzentration an Alanin nahm mit steigender Salzkonzentration zu. Bei 800 mM NaCl war die Konzentration 12 fach erhöht verglichen mit der Konzentration bei 400 mM NaCl. Außerdem redzierte Glycin-Betain die Alanin- Konzentration bei 800 mM NaCl um 58%. Transportexperimente zeigten, dass M. mazei kein Alanin aus dem Medium aufnehmen kann. 9. Erste Analysen möglicher Synthesewege für Alanin zeigten, dass die Alanin- Dehydrogenase nicht auf Transkriptebene unter Hochsalzbedingungen induziert war und somit keine Rolle in der Synthese von Alanin als kompatibles Solut spielen dürfte. Es könnten jedoch Aminotransferasen eine Rolle bei der Biosynthese von Alanin spielen. Des Weiteren sind die Enzyme, die für die Synthese von Glutamat als kompatibles Solut verantwortlich sind, unbekannt. Dies gilt für alle bis jetzt untersuchten Organismen, die Glutamat als kompatibles Solut nutzen. In dieser Arbeit wurde versucht, mit Hilfe der abl::pac-Mutante, die erhöhte Glutamat-Mengen zum Osmoschutz produziert, der Frage nachzugehen, welche Gene/Enzyme eine Rolle spielen könnten bei der Synthese von Glutamat als kompatibles Solut. Dazu wurden unter Hochsalzbedingungen die Transkriptmengen verschiedener Genen, die an der Glutamat-Synthese beteiligt sein könnten, in der Mutante und im Wildtyp untersucht. Hierbei zeigte sich, dass mehrere Gene verschiedener Enzyme unter Hochsalzbedingungen in der Mutante leicht induziert waren. Eines dieser Enzyme ist die Glutaminsynthetase. Dieses Enzym ist für die Umsetzung von Glutamat zu Glutamin unter Verbrauch von ATP verantwortlich. M. mazei besitzt zwei Gene, die für eine putative Gluaminsynthetase kodieren. In M. mazei abl::pac ist unter Hochsalzbedingungen das Gen glnA2 im Vergleich zum Wildtyp (4,03 ± 1,14) leicht induziert (7,63 ± 2,2). Des weiteren konnte in der Mutante eine leichte Induktion von gltB1, gltB2 und gltB3 unter Hochsalz beobachtet werden. Diese Gene kodieren für die einzelnen Domänen einer Glutamatsynthase. Diese ersten Analysen geben einen Hinweis darauf, dass die Synthese von Glutamat als kompatibles Solut über eine gekoppelte Reaktion der Glutaminsynthetase und der Glutamatsynthase verlaufen könnte.
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.