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The transporter associated with antigen processing-like (TAPL) acts as a lysosomal ATP-dependent polypeptide transporter with broad length selectivity. To characterize in detail its substrate specificity, a procedure for solubilization, purification and functional reconstitution of human TAPL was developed. TAPL was expressed in Sf9 insect cells with the baculovirus expression system and solubilized from crude membranes. By intensive screening of detergents, the mild non-ionic detergents digitonin and dodecylmaltoside were found to be ideal for solubilization with respect to efficiency, long term stability, and functionality of TAPL. TAPL was isolated in a two-step procedure with a yield of 500 micro g/L cell culture and, subsequently, reconstituted into proteoliposomes. The KM(pep) for the peptide RRYCfKSTEL (f refers to fluorescence label) and KM(ATP) were determined to be 10.5 ± 2.3 micro M and 97.6 ± 27.5 micro M, respectively, which are in the same range as the Michaelis-Menten constants determined in the membranes. The peptide transport activity of the reconstituted TAPL strongly depends on the lipid composition. Interestingly, the E. coli lipids are prefered over other tested natural lipids extracts. Moreover, phosphatidylcholine, the most abundant phospholipid in eukaryotic cells influenced TAPL activity in a dose dependent manner. In addition, some negatively charged lipids like DOPA and DOPS increased peptide transport activity with preference for DOPS. However, DOPE or egg PG which are also negatively charged had no effect. It seems not only the charge but also the specific head group of phospholipids that has impact on the function of TAPL. With the help of combinatorial peptide libraries containing D-amino acid residues at defined positions as well as bulky fluorescein labeled peptides, the key positions of the peptides were localized to the N- and C-terminal residues with respect to peptide transport. The C-terminal position has the strongest selectivity since modification at this position shows strongest impact on peptide transport. Additionally, positions 2 and 3 of the peptide also have weak influence on peptide selectivity. Subsequently, the residue preferences at the key positions were systematically investigated by combinatorial peptide libraries with defined residues at certain positions. At both ends, TAPL favors positively charged, aromatic, or hydrophobic residues and disfavors negatively charged residues as well as asparagine and methionine. The residue preferences at the key positions are valid for peptide substrates with different length, indicating a general rule for TAPL selectivity. Besides specific interactions of both terminal residues, electrostatic interactions are important, since peptides with positive net charge are more efficiently transported than negatively charged ones. By size exclusion chromatography (SEC) and blue native PAGE, TAPL purified in the presence of digitonin or dodecylmaltoside had an apparent molecular weight of 200 kDa which is close to the theoretical molecular mass of the TAPL homodimer (172 kDa). The purified and reconstituted TAPL showed specific ATP hydrolysis activity which can be inhibited by orthovanadate. TAPL in proteoliposomes showed 6-fold higher ATP hydrolysis than digitonin solubilized protein, indicating the phospholipids impact on TAPL function. However, no peptide substrate stimulated ATPase activity was observed. For site-specific labeling of TAPL, eight cysteines in each half transporter were replaced by alanine or valine. The TAPL cys-less mutant showed the same peptide transport activity as TAPL wt. Based on the functional TAPL cys-less mutant, seven single cysteine mutants were introduced into strategic positions. All single cysteine mutants in the TMD did not influence peptide transport, whereas the mutant L701C, which is close to the conserved H-loop motif, displayed impaired transport. TAPL orthologs Haf-4 and Haf-9 from Caenorhabditis elegans possess around 40% sequence identities with TAPL and 50% with each other. Both proteins are putative half transporters and reported to be involved in the intestinal granule formation (Bauer, 2006; Kawai et al., 2009). To further understand the physiological functions of these two proteins, they were expressed in Sf9 insect cells. Haf-4 and Haf-9 showed weak but specific ATP- and peptide-dependent peptide transport activity for the given peptide RRYCfKSTEL. Therefore, it was proposed that the physiological roles for Haf-4 and Haf-9 might be related to their peptide transport activity. Besides forming functional homodimeric complex as estimated by the peptide transport activities, both half transporter could also form heteromers which was confirmed by coimmunoprecipitation. However, the heteromers showed decreased transport activity.
This work presents a biochemical, functional and structural characterization of Aquifex aeolicus F1FO ATP synthase obtained using both a native form (AAF1FO) and a heterologous form (EAF1FO) of this enzyme.
F1FO ATP synthases catalyze the synthesis of ATP from ADP and inorganic phosphate driven by ion motive forces across the membrane and therefore play a key cellular function. Because of their central role in supporting life, F1FO ATP synthases are ubiquitous and have been remarkably conserved throughout evolution. For their biological importance, F1FO ATP synthases have been extensively studied for many decades and many of them were characterized from both a functional and a structural standpoint. However, important properties of ATP synthases – specifically properties pertaining to their membrane embedded subunits – have yet to be determined and no structures are available to date for the intact enzyme complex. Therefore, F1FO ATP synthases are still a major focus of research worldwide. Our research group had previously reported an initial characterization of AAF1FO and had indicated that this enzyme presents unique features, i.e. a bent central stalk and a putatively heterodimeric peripheral stalk. Based on such a characterization, this enzyme revealed promising for structural and functional studies on ATP synthases and became the focus of this doctoral thesis. Two different lines of research were followed in this work.
First, the characterization of AAF1FO was extended by bioinformatic, biochemical and enzymatic analyses. The work on AAF1FO led to the identification of a new detergent that maintains a higher homogeneity and integrity of the complex, namely the detergent trans-4-(trans-4’-propylcyclohexyl)cyclohexyl-α-D-maltoside (α-PCC). The characterization of AAF1FO in this new detergent showed that AAF1FO is a proton-dependent, not a sodium ion-dependent ATP synthase and that its ATP hydrolysis mechanism needs to be triggered and activated by high temperatures, possibly inducing a conformational switch in subunit γ. Moreover, this approach suggested that AAF1FO may present unusual features in its membrane subunits, i.e. short N-terminal segments in subunits a and c with implications for the membrane insertion mechanism of these subunits.
Investigating on these unique features of A. aeolicus F1FO ATP synthase could not be done using A. aeolicus cells, because these require a harsh and dangerous environment for growth and they are inaccessible to genetic manipulations. Therefore, a second approach was pursued, in which an expression system was created to produce the enzyme in the heterologous host E. coli. This second approach was experimentally challenging, because A. aeolicus F1FO ATP synthase is a 500-kDa multimeric membrane enzyme with a complicated and still not entirely determined stoichiometry and because its encoding genes are scattered throughout A. aeolicus genome, rather than being organized in one single operon. However, an artificial operon suitable for expression was created in this work and led to the successful production of an active and fully assembled form of Aquifex aeolicus F1FO ATP synthase. Such artificial operon was created using a stepwise approach, in which we expressed and studied first individual subunits, then subcomplexes, and finally the entire F1FO ATP synthase complex. We confirmed experimentally that subunits b1 and b2 form a heterodimeric subcomplex in the E. coli membranes, which is a unique case among ATP synthases of non-photosynthetic organisms. Moreover, we determined that the b1b2 subcomplex is sufficient to recruit the soluble F1 subcomplex to the membranes, without requiring the presence of the other membrane subunits a and c. The latter subunits can be produced in our expression system only when the whole ATP synthase is expressed, but not in isolation nor in the context of smaller FO subcomplexes. These observations led us to propose a novel mechanism for the assembly of ATP synthases, in which first the F1 subcomplex attaches to the membrane via subunit b1b2, and then cring and subunits a assemble to complete the FO subcomplex. Furthermore, we could purify the heterologous ATP synthase (EAF1FO) to homogeneity by chromatography and electro-elution. Enzymatic assays showed that the purified form of EAF1FO is as active as AAF1FO. Peptide mass fingerprinting showed that EAF1FO is composed of the same subunits as AAF1FO and all soluble and membrane subunits could be identified. Finally, single-particle electron microscopy analysis revealed that the structure of EAF1FO is identical to that of AAF1FO. Therefore, the EAF1FO expression system serves as a reliable platform for investigating on properties of AAF1FO.
Specifically, in this work, EAF1FO was used to study the membrane insertion mechanism of rotary subunit c. Subunits c possess different lengths and levels of hydrophobicity across species and by analyzing their N-terminal variability, four phylogenetic groups of subunits c were distinguished (groups 1 to 4). As a member of group 2, the subunit c from A. aeolicus F1FO ATP synthase is characterized by an N-terminal segment that functions as a signal peptide with SRP recognition features, a unique case for bacterial F1FO ATP synthases. By accurately designing mutants of EAF1FO, we determined that such a signal peptide is strictly necessary for membrane insertion of subunit c and we concluded that A. aeolicus subunit c inserts into E. coli membranes using a different pathway than E. coli subunit c. Such a property may be common to other ATP synthases from extremophilic organisms, which all cluster in the same phylogenetic group.
In conclusion, the successful production of the fully assembled and active F1FO ATP synthase from A. aeolicus in E. coli reported in this work provides a novel genetic system to study A. aeolicus F1FO ATP synthase. To a broader extent, it will also serve in the future as a solid reference for designing strategies aimed at producing large multi-subunit complexes with complicated stoichiometry.
Metabotropic glutamate receptor subtype 7 (mGluR7) belongs to the family of G-protein coupled receptors. mGluR7 is widely distributed in the brain and primarily localized at presynaptic terminals, where it is thought to regulate neurotransmitter release and synaptic plasticity. Studies have shown that the intracellular C-terminal tail of mGluR7 binds a variety of proteins in addition to trimeric G-proteins. These newly identified protein interactions are believed to play a key role in the synaptic targeting and G-protein dependent signaling of mGluR7. Protein interacting with C kinase 1 (PICK1), a PDZ-domain protein, is a strong interaction partner of mGluR7a. In order to investigate the role of PICK1 in the synaptic trafficking and signaling of mGluR7a, a knock-in mouse line in which the interaction of mGluR7a and PICK1 is disrupted was generated. Analysis of the mutant mice by immunocytochemistry and immunoelectron microscopy showed that the synaptic targeting and clustering of mGluR7a was not altered, indicating that PICK1 is not required for mGluR7a receptor membrane trafficking and synaptic localization. However, when the spontaneous synaptic activity of cerebellar granule cell cultures prepared from both wild-type and knock-in mice was monitored, and L-AP4 (400μm) was found to decrease the frequency, but not the amplitude, of spontaneous excitatory currents in wild-type neurons, while no effect of L-AP4 on spontaneous synaptic activity was observed in knock-in neurons. This indicates that PICK1 binding to the C-terminal region of mGluR7a plays an essential role in mGluR7a mediated G-protein signaling. We examined the threshold sensitivity for the convulsant pentetrazole (PTZ) in knock-in mice. It was found that mGluR7a knock-in mice had a greater sensitivity to PTZ than wild-type mice. Moreover, the surface parietal cortex EEG recordings of the mutant mice revealed spontaneous synchronous oscillation, or "spike-and-wave discharges" (SWD), which displayed similar characteristics to absence-like seizures. It was also observed that the knock-in mice responded to pharmacology as human absence epilepsy. These data suggests that the knock-in mice displayed the phenotype of absencelike epilepsy. Furthermore, the behavioral analysis of the mGluR7a knock-in mice showed no deficits in motor coordination, pain sensation, anxiety as well as spatial learning and memory, thus the interaction of mGluR7a and PICK1 appears not to contribute to these physiological processes. Taken together, our data provides evidence for an important role of PICK1 in Gprotein dependent signaling of mGluR7a, whereas PICK1 is not required for synaptic targeting and clustering of mGluR7a. Our results also provide an animal model of absencelike epilepsy generated by disruption of a single mGluR7a-PDZ interaction, thus creating a novel therapeutic target against this neurological disease.
Heme-copper oxidases (HCOs) are the terminal enzymes of the aerobic respiratory chain in the inner mitochondrial membrane or the plasma membrane in many prokaryotes. These multi-subunit membrane protein complexes catalyze the reduction of oxygen to water, coupling this exothermic reaction to the establishment of an electrochemical proton gradient across the membrane in which they are embedded. The energy stored in the electrochemical proton gradient is used e.g. by the FOF1-ATP synthase to generate ATP from ADP and inorganic phosphate. The superfamily of HCOs is phylogenetically classified into three major families: A, B and C. The A-family HCOs, represented by the well-studied aa3-type cytochrome c oxidases (aa3-CcOs), are found in mitochondria and many bacteria. The B-family of HCOs contains a number of bacterial and archaeal oxidases. The C-family comprises only the cbb3-type cytochrome c oxidase (cbb3-CcO) and is most distantly related to the mitochondrial respiratory oxidases.
1. Fab co-complexes of proton pumping NADH:ubiquinone oxidoreductase (complex I) Fab fragments suitable for co-crystallization with complex I were generated using an immobilized papainbased protocol. The binding of the antibody fragments to complex I was verified using Surface Plasmon Resonance and size exclusion chromatography. The binding constants of the antibodies and their respective Fab fragments were found to be in the nanomolar range. This work presents the first report on successful crystallization of complex I (proton pumping NADH:ubiquinone oxidoreductase) from Yarrowia lipolytica with proteolytic Fab fragments. The quality of the crystals was significantly improved when compared to the initial experiments and the best crystals diffracted X-rays to a resolution of ~7 Å. The activity of complex I remained uninfluenced by antibody fragment binding. The initial diffraction data suggest that the complex I/Fab co-complex crystals represent a space group different to the one observed for the native protein. Ongoing experiments are aimed at further enhancements of the diffraction quality of the crystals. Providing a different space group the CI/Fab co-complexes may become a very useful approach for structure determination of the enzyme. Moreover, the bound Fab offers an additional possibility to generate phase information. The antibody-mediated crystallization represents a valuable tool in structural characterization of the NADH:oxidoreductase subcomplexes or even single subunits. 2. UDP-glucose pyrophosphorylase UDP-glucose pyrophosphorylase from Yarrowia lipolytica displays affinity towards Ni2+ NTA and was first detected in a contaminated sample of complex I. Following, separation from complex I, Ugp1p was purified using anion exchange chromatography. Sequence similarity studies revealed high identity to other known pyrophosphorylases. As indicated by laser-based mass spectrometry method (LILBID) Ugp1p from Y. lipolytica builds octamers similarly to the enzyme from Saccharomyces cerevisiae. The initial crystals grew as thin needles favorably in sitting drop setups. The size of the crystals was increased by employment of a micro batch technique. The improved crystals diffracted X-rays to a resolution of 3.2 Å at the synchrotron beamline. Structural characterization is under way using a molecular replacement approach based on the published structure of baker’s yeast UGPase.
The transcription factor p63 is part of the p53 protein family, which consists of three members, p53, p63 and p73. P63 shares structural similarity with all family members, but is associated to different biological functions than p53 or p73. While p53 is mainly linked to tumor suppression and p73 is connected with neuronal development, p63 has been connected to critical biological roles within ectodermal development and skin stem cell biology as well as supervision of the genetic stability of oocytes. Due to its gene structure p63 is expressed as at least six different isoforms, three of them containing a N-terminal transactivation domain. The isoforms that are of biological relevance both have a C-terminal inhibitory domain that negatively regulates the transcriptional activity. This inhibitory domain is supposed to contain two individual components of which one is internally binding and masking the transactivation domain while the other one can be sumoylated. To further investigate this domain a mutational analysis with the help of transactivation assays in SAOS2 cells was carried out to identify the critical amino acids within the inhibitory domain and the impact on transcriptional activity of TAp63alpha, the p63-isoform which is essential for the integrity of the female germline. The results of these experiments show that a stretch of approximately 13 amino acids seems to be important for the regulation of transcriptional activity in TAp63alpha, due to the increased transcriptional activity occurring in this region after mutation. Additional experiments showed that this mechanism is distinct from sumoylation, which seems to have only implications for the intracellular level of TAp63alpha. As a conclusion, the C-terminus of the Tap63alpha is essential for two different mechanisms, which control the transcriptional activity of the protein. Both regulatory elements are independent from each other and can now be restricted to certain amino acids. Activation of the wild type protein might take place in the identified region via post-translational modification. Furthermore an inhibition assay was carried out to test if the same region might have implications on the second biological relevant isoform deltaNp63alpha. The results show that the same amino acids which show an impact on transcriptional activity in Tap63alpha lead to a significant change in functional behaviour of deltaNp63alpha. There is a possibility that both proteins are regulated with opposite effects via the same mechanisms, based at the C-terminus of the p63alpha-isoforms. In both cases a modification of these residues could lead to a more opened conformation of the protein with consequences on promoter binding, which can be even important for deltaNp63alpha with respect to promoter squelching. Both alpha-isoforms seem to be regulated via the C-terminus and to elucidate if that is also the case for TAp63gamma a deletion analysis was carried out. The results show that there are also amino acids within the C-terminus of TAp63gamma, which have implications on the transcriptional activity of the protein. Therefore the C-terminus seems to play a major role for regulation of diverse p63 isoforms.
Ubiquitination now ranks with phosphorylation as one of the best-studied post-translational modifications of proteins with broad regulatory roles across all of biology. Ubiquitination usually involves the addition of ubiquitin chains to target protein molecules, and these may be of eight different types, seven of which involve the linkage of one of the seven internal lysine (K) residues in one ubiquitin molecule to the carboxy-terminal diglycine of the next. In the eighth, the so-called linear ubiquitin chains, the linkage is between the amino-terminal amino group of methionine on a ubiquitin that is conjugated with a target protein and the carboxy-terminal carboxy group of the incoming ubiquitin. Physiological roles are well established for K48-linked chains, which are essential for signaling proteasomal degradation of proteins, and for K63-linked chains, which play a part in recruitment of DNA repair enzymes, cell signaling and endocytosis. We focus here on linear ubiquitin chains, how they are assembled, and how three different avenues of research have indicated physiological roles for linear ubiquitination in innate and adaptive immunity and suppression of inflammation.
Three-dimensional structure of the glycine-betaine transporter BetP by cryo electron crystallography
(2008)
The soil bacterium Corynebacterium glutamicum has five secondary transporters for compatible solutes allowing it to cope with osmotic stress. The most abundant of them, the transporter BetP, performs a high affinity uptake of glycine-betain when encountering hyperosmotic stress. BetP belongs to the betaine/carnitine/choline/transporter (BCCT) family, and is predicted to have twelve transmembrane helices with both termini facing the cytoplasm. The goal of this thesis is to facilitate understanding of BetP function by determining a three dimensional (3D) model of its structure. Two-dimensional (2D) crystallization of wild-type (WT) BetP has been successfully performed by reconstitution into a mixture of E. coli lipids and bovine cardiolipin, which resulted in vesicular crystals diffracting to 7.5 Å resolution (Ziegler, Morbach et al. 2004). Diffraction patterns of these crystals however showed unfocused spots, generally due to high mosaicity. Better results were obtained by using the constitutively active mutant BetPdeltaC45 in which the first 45 amino acids of the positively charged C-terminus were removed. BetPdeltaC45 crystals obtained under the same conditions for BetP WT were concluded to be pseudo crystals, based on the inconsistence of symmetry. These crystals had BetPdeltaC45 molecules randomly up/downwards inserted into membrane crystals, and cannot be used for structure determination, even though they diffracted up to 7 Å. The problem of pseudo crystal formation could be solved by changing the lipids used for 2D crystallization to a native lipid extract from C. glutamicum cells. This change of lipids improved the crystals to well-ordered packing with exclusive p121_b symmetry. To understand the role of lipids in crystal packing and order, lipids were extracted at different stages during crystallization, and identified by using multiple precursor ion scanning mass spectrometry. The results show that phosphatidyl glycerol (PG) 16:0-18:1 is the most dominant lipid species in C. glutamicum membranes, and that BetP has a preference for the fatty acid moieties 16:0-18:1. Crystallization with synthetic PG 16:0-18:1 proved that an excess of this lipid prevents pseudo crystal formation, but these crystals did not reach the quality as previously achieved by using the C. glutamicum lipids. Apart from the effect of lipids in crystallinity, the concentration and type of salts influenced crystal growth and morphology. High salt conditions (>400 mM LiCl or KCl) yielded tubular crystals, whereas low salt conditions (<300 mM LiCl, NaCl or KCl) led to formation of up to 10 µm large sheet-like crystals. The intermediate concentration gave a mixture of sheet-like and tubular crystals. In terms of resolution, sheets diffracted better than tubes. The sheet-like crystals used for 3D map reconstruction were obtained from a dialysis buffer containing 200 mM NaCl combined with using C. glutamicum lipids. Electron microscopic images were taken from frozen-hydrated crystals using a helium-cooled JEOL 300 SFF microscope or a liquid nitrogen-cooled FEI Tecnai G2 microscope at 300 kV, which allowed optimal data collection and minimized radiation damage to the sample. More than 1000 images of tilt angles up to 50° were taken and evaluated using optical diffraction of a laser beam. The best 200 images were processed with the MRC image processing software package, and 79 images from different tilt angles were merged to the final data set used for calculation of a 3D map at a planar resolution of 8 Å. The structure shows BetPdeltaC45 as a trimer with each monomer consisting of 12 transmembrane alpha-helices. Protein termini and loop regions could not be determined due to the limited resolution of the map. Six of the twelve helices line a central cavity forming a potential substrate-binding chamber. Each monomer shows a central cavity in different sizes and shapes. Thus, the constitutively active BetPdeltaC45 thus forms an unusual asymmetric homotrimer. BetP most likely reflects three different conformational states of secondary transporters: the cytoplasmically open (C), the occluded (O), and the periplasmically open (P) states. The C and O states are similar to BetP WT projection structure, while the P state is discrepant and highly flexible due to the shape and size of the central cavity as well as the lowest intensity of the density. The observation of the P state corresponds well to the constitutively active property of BetPdeltaC45. For the high resolution structure of the C and O states are available, this work presents the first structural information of the P state of a secondary transporter.
Tumor development usually follows predictable paths where tumor cells acquire common characteristics and features known as the hallmarks of cancer. Recently, additional characteristics have been added to these hallmarks since solid tumors are composed of a very heterogeneous population of transformed, formerly normal tissue cells and stromal cells, e.g. immune cells and fibroblasts. Compelling evidence suggests that stromal cells and tumor cells maintain a symbiotic relationship to build up the tumor microenvironment and to fuel tumor growth. In cancer therapies, common features of tumors such as unrestricted cell growth, suppression of immunological responses, and the ability to form new blood vessels (angiogenesis) have emerged as the main targets of interest. The lipid mediator prostaglandin E2 (PGE2) is known to promote all these features and thus, is connected to cancer progression in general. Its synthesis is triggered in response to stress factors or during inflammation. Inducible PGE2 production relies on the enzymes cyclooxygenase 2 (COX-2) and microsomal prostanglandin E synthase 1 (mPGES-1), which are simultaneously expressed in response to a variety of different stimuli and are functionally coupled. Inhibition of COX-2 with non-steroidal antiinflammatory drugs (NSAIDs) for cancer treatment is, however, limited by cardiovascular risks, since selective COX-2 inhibition disrupts the prostacyclin/thromboxane balance. Therefore targeting mPGES-1 downstream of COX-2 for PGE2 inhibition was evaluated in this work in different steps of carcinogenesis. Knockdown of mPGES-1 in DU145 prostate cancer cells revealed that the mPGES-1 status did not affect growth of monolayer tumor cells, but significantly impaired 3D growth of multi-cellular tumor spheroids (MCTS). Spheroid formation induced COX-2 in DU145 and other prostate cancer spheroids. High levels of PGE2 were detected in supernatants of DU145 MCTS as opposed to monolayer DU145 cells. Pharmacological inhibition of COX-2 and mPGES-1 confirmed the pivotal role of PGE2 for DU145 MCTS growth. Besides promoting spheroid growth, MCTS-derived PGE2 also inhibited cytotoxic T lymphocyte (CTL) activation. When investigating the mechanisms of COX-2 induction during spheroid formation, the typical tumor microenvironmental factors such as glucose deprivation, hypoxia or tumor cell apoptosis failed to enhance COX-2. Interestingly, when interfering with apoptosis in DU145 spheroids, the pan-caspase inhibitor Z-VAD-FMK triggered a Summary 12 shift towards necrosis, thus enhancing COX-2 expression. Coculturing viable DU145 monolayer cells with isolated heat-shocked-treated necrotic DU145 cells, but not with necrotic cell supernatants, induced COX-2 and PGE2, confirming the impact of necrosis for MCTS growth and CTL inhibition. As mentioned, in vivo tumors are very heterogenous mixtures of tumor cells and stromal cells e.g. immune cells. Hence, the interaction of the immune system with tumors was investigated in further experiments. When coculturing MCF-7 breast cancer spheroids with human peripheral blood mononuclear cells (PBMCs), only low levels of PGE2 were detected, since MCF-7 cells did not upregulate COX-2 during spheroid formation and did not induce PGE2 production by PBMCs. Under inflammatory conditions, by adding the toll-like receptor 4 (TLR4) agonist lipopolysaccharide (LPS) to cocultures, PGE2 production was triggered, spheroid sizes were reduced, and numbers of high levels of granzyme B expressing (GrBhi) CTLs were increased, while CD80 expression by tumor-associated phagocytes was also elevated. Inhibition of CD80 but not CD86 diminished numbers of GrBhi CTLs and attenuated spheroid lysis. To determine the role of ctivation-induced PGE2 production, use of the COX-2 inhibitor celecoxib and the experimental mPGES-1 inhibitor C3 further increased CD80 expression. Addition of PGE2, the prostaglandin E2 (EP2) receptor agonist butaprost, and the phosphodiesterase 4 (PDE4) inhibitor rolipram reduced LPS/C3-triggered CD80 expression, confirming the impact of COX- 2/mPGES-1-derived PGE2 on shaping phagocyte phenotypes in an EP2/cAMP-dependent manner. In a spontaneous breast cancer model (MMTV-PyMT), mPGES-1-deficiency significantly delayed tumor growth in mice, confirming an overall protumorigenic role of mPGES-1 in breast cancer development in vivo. However in tumors of mPGES-1-/- mice, tumor-infiltrating phagocytes expressed low levels of CD80 similar to their wildtype counterparts. These data suggest that the immunosuppressive microenvironment does not allow for immunostimulatory effects by mPGES-1 inhibition without an activating stimulus. Evidences in this study recommend the application of mPGES-1 inhibitors for treating cancer diseases, since mPGES-1 promotes tumor growth in multiple steps of carcinogenesis, ranging from well-characterized effects of tumor cell growth to immune suppression of CTL activity and phagocyte polarization. Regarding the latter, blunting PGE2 during immune activation may limit the tumor-favoring features of inflammation and improve the efficiency of TLR4 based immune therapies.
To overcome poor treatment response of pediatric high-risk acute lymphoblastic leukemia (ALL), novel treatment strategies are required to reactivate programmed cell death in this malignancy. Therefore, we take advantage of using small-molecule antagonists of Inhibitor of apoptosis (IAP) proteins, so called Smac mimetics such as BV6, which are described to overcome apoptosis resistance and thereby sensitize tumor cells for several apoptotic stimuli. To address the question whether redox alterations can sensitize leukemic cells for Smac mimetic-mediated cell death, we interfered with the cellular redox status in different ALL cell lines. Here, we show for the first time that redox alterations, mediated by the glutathione depleting agent Buthioninesulfoximine (BSO), prime ALL cells for BV6-induced apoptosis. Besides ALL cell lines, BV6/BSO cotreatment similarly synergizes in cell death induction in patient-derived primary leukemic samples. In contrast, the combination treatment does not exert any cytotoxicity against peripheral blood lymphocytes (PBLs) or mesenchymal stroma cells (MSCs) from healthy donors, suggesting some tumor selectivity of this treatment. We also identify the underlying molecular mechanism of the novel synergistic drug interaction of BSO and BV6. We demonstrate that both agents act in concert to increase reactive oxygen species (ROS) production, lipid peroxidation and finally apoptotic cell death. Enhanced ROS levels in the combination treatment account for cell death induction, since several ROS scavengers, like NAC, MnTBAP and Trolox attenuate BSO/BV6-induced apoptosis. BSO/BV6-induced ROS can be mainly classified as lipid peroxides, since the vitamin E derivate α-Tocopherol as well as Glutathione peroxidase 4 (GPX4), which both specifically reduce lipid-membrane peroxides, prevent lipid peroxidation, caspase activation and cell death induction. Vice versa, GPX4 knockdown and pharmacological inhibition of GPX4 by RSL3 or Erastin enhance BV6-induced cell death. Importantly, cell death induction critically depends on the formation of a complex consisting of RIP1/FADD/Caspase-8, since all complex components are required for ROS production, lipid peroxidation and cell death induction. Taken together, we demonstrate that BSO and BV6 cooperate to induce ROS production and lipid peroxidation which are eventually required for caspase activation and cell death execution. Collectively, findings of this study indicate that BV6-induced apoptosis is mediated via redox alterations offering promising new treatment strategy to overcome apoptosis resistance in ALL.
The adaptive immune system of jawed vertebrates is based on recognition and elimination of cells that are either invaded by intracellular pathogens or malignantly transformed. One essential component of these processes is the cell surface presentation of antigenic peptides via major histocompatibility complex (MHC) class I molecules to cytotoxic T-cells (CTLs). Cells degrade defective ribosomal products and misfolded or unwanted proteins by the ubiquitin-proteasome pathway. The resulting degradation products are recognized and translocated by the transporter associated with antigen processing (TAP) into the endoplasmic reticulum (ER) lumen, where they are loaded onto MHC I molecules. Assembled peptide-MHC complexes are then shuttled by the secretory pathway to the cell surface for antigen presentation to CTLs, leading in the case of viral infection or malignant transformation to lysis and apoptosis of the target cell. Due to the fact that the TAP complex represents a key control point within the antigen presentation pathway, several viruses have evolved sophisticated strategies to evade immune surveillance by interfering with TAP function.
Detailed studies of the TAP mechanism or its viral inhibition have been severely impeded by difficulties in expressing sufficient amounts of functional heterodimeric TAP complex. Thus, the overexpression of TAP in the methylotrophic yeast Pichia pastoris was established for functional analysis of this important ABC complex. Biomass production was scaled up by fermentation using classical batch and feed methods. Extensive screening of optimal solubilization and purification conditions allowed the isolation of the heterodimeric transport complex. Notably, only the very mild detergent digitonin preserved TAP function. Hereby, the optimal solubilization and purification strategy yielded in 30 mg TAP transporter per liter culture. Remarkably, the protein amount was 50-fold increased compared to previously described expression/purification in cultured insect cells.
The high yield and quality of TAP produced in P. pastoris allowed an extensive analysis of substrate binding and transport kinetics of the transport complex in the membrane, its solubilized and purified state, as well as the reconstituted state. Thereby, a strong and direct effect of the lipid bilayer on ATP hydrolysis and peptide transport was discovered. These important results were extended further by successful functional reconstitution of the antigen translocation machinery in different lipid environments. For the first time, a stimulation of the transport activity by phosphatidylinositol (PI) and phosphatidylethanolamine (PE) was observed, whereas cholesterol was identified as an inhibitor of TAP activity.
Purification of TAP and subsequent thin-layer chromatography (TLC)/liquid chromatography Fourier transform-mass spectrometry (LC FT-MS) fingerprinting of residual lipids exhibited specifically associated glycerophospholipids; mainly PC, PE, and PI species. Strikingly, these lipids not only represent the primary class of phospholipids of the ER but were also shown to be essential for functional reactivation of delipidated, and thus inactive, TAP. The results demonstrate that transport of antigenic peptides by the ABC transporter TAP strictly requires specific glycerophospholipids.
In addition to the biochemical characterization of heterologous produced TAP, the soluble domain of the viral inhibitor US6 from human cytomegalovirus was expressed in E. coli. Optimization of the purification and refolding strategy yielded in functional protein, with a 35-fold increased protein amount compared to previous purification procedures. Protein activity was analyzed by specific inhibition of ATP binding to TAP. Furthermore, high protein yields allowed detailed investigation of TAP-dependent spatial and mechanistic separation of MHC I restricted cross-presentation in professional antigen presenting cells (pAPC).
Der L-Carnitin/gamma-Butyrobetain Antiporter CaiT ist ein Mitglied der Betain/Carnitin/Cholin Transporter (BCCT) Familie. Sekundärtransporter der BCCT Familie transportieren Substrate, die eine positiv-geladene quartäre Ammoniumgruppe besitzen. CaiT besteht aus 504 Amiosäuren und besitzt ein moleculares Gewicht von etwa 56 kDa. In Enterobakterien wie Escherichia coli, Proteus mirabilis und Salmonella typhimurium wird die Expression des caiTABCDE Operons unter anaeroben Bedingungen induziert. Unter diesen Bedinungen ist CaiT der Haupttransporter des Betain-Derivates L-Carnitin. In Enterobakterien wird L-Carnitin unter anaeroben Bedingungen aufgenommen und dehydratisiert wobei Crotonobetain ensteht. Crotonobetain wird anschließend zum Endprodukt gamma-Butyrobetain reduziert. Gamma-Butyrobetain ist das Gegensubstrat, das aus der Zelle hinaustransportiert wird, wenn L-Carnitin in die Zelle aufgenommen wird. Der Austauschmechanismus von LCarnitin gegen gamma-Butyrobetain geschieht ohne das Vorhandensein eines elektrochemischen Gradients, d.h. CaiT ist sowohl H+- als auch Na+-unabhängig. Ein Ziel dieser Arbeit war es die drei-dimensionale (3D) Struktur von CaiT mittels Röntgenstrukturanalyse zu lösen. Weiterhin sollten mit Hilfe der 3D-Struktur und funktionellen Studien detailiertere Erkenntnisse über den kationenunabhängigen Antiportmechanismus von CaiT ermittelt werden. Im Rahmen dieser Arbeit wurden die 3D-Röntgenkristallstrukturen von drei CaiT-Homologen der Enterobakterien P. mirabilis (PmCaiT), E. coli (EcCaiT) und S. typhimurium (StCaiT) mittels molekularem Ersatz (engl.: molecular replacement, MR) mit einem Alanin-Model des CaiT verwandten Na+/Glycinbetain Symporters BetP gelöst. PmCaiT konnte mit einer Auflösung von 2.3 Å gelöst werden. Das Protein kristallisierte in der Kristallraumgruppe H3, mit drei Molekülen in der asymmetrischen Einheit (engl.: asymmetric unit, AU). Die drei PmCaiT-Moleküle ordneten sich innerhalb der AU um eine kristallographische dreifach Symmetrieachse an. EcCaiT wurde mittels MR mit einem Alanin-Model von PmCaiT bei einer Auflösung von 3.5 Å gelöst. EcCaiT kristallisierte in der Kristallraumgruppe P32, ebenfalls mit drei Molekülen in der AU, jedoch ohne kristallographische Symmetry. Während der Verfeinerung des EcCaiT-Models wurde eine strenge dreifache nichtkristallographische Symmetry (engl.: non-crystallographic symmetry, NCS) angewandt. StCaiT, das ebenfalls mittels MR mit einem Alanin-Model von PmCaiT, aber bei einer Auflösung von 4.0 Å gelöst wurde, kristallisierte in der Kristallraumgruppe P65, ebenfalls mit drei StCaiT-Molekülen in der AU, ohne kristallographische Symmetry. Bei der Verfeinerung des StCaiT-Modells wurde wie bei EcCaiT eine strenge NCS angewandt. Da die Auflösung von 4.0 Å bei StCaiT zu niedrig ist um detailierte moleculare Erkenntnisse zu gewinnen, wurden Protein- sowie Substratinteraktionen nur an den Strukturen von PmCaiT und EcCaiT analysiert. Alle drei CaiT-Homologe weisen jedoch einen ähnlichen strukturellen Aufbau auf. In der Röntgenkristallstruktur bildet CaiT ein symmetrisches Trimer, das über ionische und polare Wechselwirkungen zwischen den Protomeren stabilisiert wird. Der trimere Oligomerisierungszustand von CaiT in Detergenzlösung sowie in zweidimensionalen Lipidmembrankristallen wurde bereits in früheren Arbeiten gezeigt. Jedes der drei CaiT-Protomere besteht aus zwölf Transmembranhelices (TMH), die N- und C-terminalen Domänen des Proteins befinden sich auf der cytoplasmatischen Seite. Zehn der TMH bilden zwei invertierte Wiederholungseinheiten aus jeweils fünf TMH. Die erste Einheit besteht aus den TMH 3 – 7, die invertierte zweite Einheit besteht aus den TMH 8 – 12. Beide Wiederholungseinheiten sind strukturell nahezu identisch und lassen sich fast vollständig übereinanderlegen, jedoch weisen die Aminosäuren der beiden Einheiten keine signifikante Sequenzidentität auf. Die ersten beiden Helices der Wiederholungseinheiten, die TMH 3 – 4 und die TMH 8 – 9, bilden ein antiparalleles vier-Helix-Bündel, in dem in CaiT zwei Substratbindestellen lokalisiert sind. Eine derartige Transporterarchitektur wurde erstmals in der Struktur des Na+/Alanin Symporters LeuTAa des thermophilen Bakteriums Aquifex aeolicus gezeigt. Bislang wurden, inklusive CaiT, sieben Sekundärtransporterstrukturen gelöst, die diese LeuT-Transporterarchitektur aufweisen. Ungewöhnlich dabei ist, dass diese sieben Sekundärtransporter fünf verschiedenen Transporterfamilien angehören und eine Verwandschaft auf Basis der Aminosäuren nicht zu finden ist. Da jedoch die tertiäre Struktur dieser Tansporter konserviert ist, kann davon ausgegangen werden, dass sie alle von einem Urprotein entstanden sind, welches zunächst aus fünf TMH bestanden haben muss. Im Laufe der Evolution hat sich das Urgen des Urproteins zunächst dupliziert und die weitere Evolution hat zwar die Aminosäuresequenz verändert und den Umweltbedingungen angepasst, jedoch ist die tertiäre Struktur erhalten geblieben. Da sich die tertiäre Struktur der sieben Sekundärtransporter so stark ähnelt, ist zu vermuten, dass auch der Transportmechanismus ähnlich, jedoch nicht identisch ist. Nach dem strukturellen Aufbau der Transporter, der Lage der Substratbindestellen in den jeweiligen Transportern und der Tatsache, dass es sich bei diesen Proteinen um Membranproteine handelt, wurde ein Transportmechanismus aufgestellt, in dem die Bindestelle des zu transportierende Substrats alternierend zu beiden Seiten der Membran zugänglich ist, ohne jedoch jemals den Substratweg innerhalb des Proteins vollständig zu öffnen. Dieser Mechanismus wurde als “alternating access mechanism” beschrieben. Anhand der unterschiedlichen Zustände, in denen einige der Transporter kristallisierten, kann abgeleitet werden, welche Konformationsänderungen erforderlich sind um das Substrat von einer Seiter der Membran auf die andere zu transportieren. Bisher kristallisierten einzelne der sechs Transporter in der nach außen gerichteten offenen Form, der nach außen gerichteten Form, in der die Substratbindestelle jedoch nicht mehr zugänglich ist, in einer Form, die keine Öffnungspräferenz der Substratbindestelle zu einer Seite der Membran hat und in der nach innen gerichteten Form, in der die Substratbindestelle jedoch nicht geöffnet ist. CaiT kristallisierte in der noch fehlenden Konformation, der nach innen gerichteten Form, in der die Substratbindestelle zugänglich ist. Mit dieser noch fehlenend Konformation kann der Transportzyklus des “alternating access mechanism” vollständig beschrieben werden. Alle drei CaiT-Homologe kristallisierten in der nach innen gerichteten, offenen Konformation. Im Gegensatz zur EcCaiT-Struktur kristallisierte PmCaiT in der substratungebundenen Form. In der StCaiT-Struktur konnte aufgrund der niedrigen Auflösung kein Substrat nachgewiesen werden. In der EcCaiT-Struktur sind zwei gamma-Butyrobetain-Moleküle gebunden. Das erste Molekül wurde in der zentralen Substratbindestelle, der sogenannten Tryptophan-Box bestehend aus vier Tryptophanen, im Zentrum des Protein lokalisiert. Das zweite gamma-Butyrobetain-Molekül wurde in einer Vertiefung an der extrazellulären Proteinoberfläche gefunden. Beide Substrate werden hauptsächlich über Kation-Pi-Interaktionen zwischen der positiv geladenen quatären Ammoniumgruppe des Substrats und des Pi-Elektronensystems der Tryptophane in den jeweiligen Bindestellen gebunden. Eine besondere Eigenschaft von CaiT ist der H+- bzw. Na+-unabhängige Substrattransport. Die CaiT-Struktur erklärt warum kein zusätzliches Kation benötigt wird um Substrat zu binden oder zu transportieren. In der EcCaiT-Struktur ist eine wichtige polare nicht-bindende Interaktion zwischen der Carboxylgruppe des gamma-Butyrobetains und dem Schwefelatom eines Methionins in der zentrale Bindestelle zu erkennen. Dieses Methionin ist konserviert in den prokaryotischen CaiTs und in den Na+-unabhängigen eukaryotischen L-Carnitin Transportern (OCTN), jedoch ist es nicht konserviert im Na+-abhängigen verwandten Glycinbetain Transporter BetP. In BetP ist diese Position des Methionins durch ein Valin ersetzt. Die Mutation des Methionins in CaiT zu Valin ermöglicht zwar immernoch die H+- bzw. Na+-unabhängige Bindung des Substrates durch die Tryptophan-Box, jedoch ist der Substrattransport nahezu vollständig zerstört. Eine derart wichtige Substratkoordinierende Funktion des Schwefelatoms eines Methionins wurde bisher nicht beschrieben. Eine weitere Stelle, die in H+- bzw. Na+-abhängigen Transporter mit H+ bzw. Na+ besetzt ist, ist in CaiT von einem positiv geladenen Arginin eingenommen. Eine positive Ladung an dieser Stelle stabilisiert den Bereich im Protein in der Nähe der zentralen Substratbindestelle. Die Mutation des Arginins zu Glutamat in CaiT erzielt eine vollständige Inaktivierung des Substrattansports. Durch Zugabe von Na+ im Transportansatz kann die Substrattransportaktivität der Glutamat-Mutante jedoch teilweise zurückerlangt werden. Diese eben beschriebenen Aminosäurereste in den beiden Stellen des Proteins erklären die Kationenunabhängigkeit von CaiT. Die Aktivierung des Antiportmechanismus in CaiT wurde mit Hilfe von Bindungsstudien an rekonstituiertem Protein ermittelt. Diese Messungen ergaben für das Wildtypprotein ein sigmoidales Substratbindungsverhalten, was auf ein positiv-kooperatives Bindungsverhalten hindeutet. Die beiden Substratbindestellen im Protein sowie die beiden unterschiedlichen Substrate, L-Carnitin und gamma-Butyrobetain, lassen auf einen heterotropen positiv-kooperativen Bindungs- und einen allosterisch regulierten Transportmechanismus schließen. Bei diesem Mechanismus erhöht die Bindung eines Substrats in der regulatorischen Bindestelle durch induzierte Konformationsänderungen die Affinität eines anderen Substrats in einer weiteren Substratbindestelle. Die regulatorische Bindestelle in CaiT befindet sich an der extrazellulären Proteinoberfläche. Eine Schwächung der Substrataffinität in dieser Bindestelle durch Einführung einer Mutation, verstärkt das sigmoidale Substratbindungsverhalten und hat einen negativen Einfluss auf den Substrattransport. Durch die in dieser Arbeit gelösten 3D-Röntgenkristallstrukturen der zwei CaiT-Homologen, PmCaiT und EcCaiT, sowie den durchgeführten funktionellen Studien sowohl an Wildtypprotein wie auch an Mutanten konnte ein L-Carnitin/gamma-Butyrobetain Antiport-Mechanismus für CaiT vorzuschlagen werden.
Rotary adenosine triphosphate (ATP)ases are ubiquitous, membrane-bound enzyme complexes involved in biological energy conversion. The first subtype, the so-called F1Fo ATP synthase, predominantly functions as an ATP synthesizing machinery in most bacteria, mitochondria and chloroplasts. The vacuolar subtype of enzyme, the V1Vo ATPase, operates as an ATP driven ion pump in eukaryotic membranes. The subtype found in archaea and some bacteria is called A1Ao ATP (synth)ase and is capable of working in both directions either to synthesize ATP or to generate an ion motive force by consuming the same.
All the three above-mentioned subtypes of rotary ATPases work as nanomolecular machines sharing a conserved mechanism to perform the energy conservation process. The simplest form of these enzymes is the bacterial F1Fo ATP synthase. Here, ions are channelled via the membrane stator subunit a to the rotor ring of the enzyme. After almost a complete rotation of the ring the ions are released again on the other side of the membrane. This rotation is further transmitted via the central stalk to the soluble part of the enzyme, the F1-complex, where conformational changes within the nucleotide binding sites result in the synthesis of ATP from ADP and Pi.
The rotor or c-ring of the enzyme is the key protein complex in mediating transmembrane ion translocation. Several structural and biochemical methods have been applied in the past years to study the rotor rings from many different organisms. The results revealed that the stoichiometry of a c-ring of a given species is constant while it can vary between different species within a range of 8 to 15 c subunits. The c-ring stoichiometry determines directly the number of ions transported through Fo per rotation whereby three molecules of ATP are concurrently synthesized in the water-soluble F1 headgroup. Hence the number of c subunits has an important influence on the bioenergetics of the corresponding enzyme and thus the entire organism.
The c-ring of a rotary ATPase is able to specifically bind either protons (H+) or sodium ions (Na+) as the coupling ion for the enzyme. Several structures are already available revealing the coordination network of both types of rotor rings. In each case ion binding includes a highly-conserved carboxylic acid residue (glutamate or aspartate), in addition to a more varying combination of amino acid residues, whereby Na+ coordination is structurally more demanding than H+ binding.
In the first part of my PhD thesis, I aimed to characterize the F1Fo ATP synthase rotor ring of the opportunistic pathogenic bacterium Fusobacterium nucleatum on a functional and structural level. F. nucleatum is an anaerobic bacterium which uses peptides and amino acids as a primary energy source. It is one of the most frequently occuring bacteria in human body infections and involved in human periodontal diseases.
The protein complex was heterologously expressed within a hybrid ATP synthase in Escherichia coli and purified without an affinity tag for further analysis. Two high resolution X-ray structures of the c-ring were solved at low (5.3) and high (8.7) pH to 2.2 and 2.64 Å, respectively. In both structures, the conserved glutamate is in an ion-locked conformation, revealing that the conformational state of the ion binding carboxylate is not depending on the pH of the crystallization condition, which is in good agreement with previous structural and biochemical studies of other c-rings.
A Na+ ion is present within the c-ring binding site and directly coordinated by four amino acid residues and a structural water molecule. Remarkably, the Na+ is bound by two glutamate residues instead of one as is the case in the I. tartaricus Na+ binding c-ring, of which the first high resolution X-ray structure of a c-ring has been solved in 2005. Thus, a new type of Na+ coordination in an ATP synthase rotor ring with a two-carboxylate ion binding motif is described here, which also occurs in other bacteria, including several pathogens. Na+ specificity of the investigated c-ring was further confirmed by a competitive biochemical labeling reaction performed with a fluorescent ATP synthase inhibitor molecule (N-cyclohexyl-N`-[4(dimethylamino)-α-naphtyl] carbodiimide, NCD-4).
We furthermore complemented our functional and structural data of the F. nucleatum c-ring by computational studies to explore the ion translocation mechanism of this enzyme in more details. We therefore analyzed the protonation state of the second, additional glutamate in the ion binding site. Molecular dynamics (MD) simulations and free-energy calculations indicated that this glutamate is constitutively protonated, in the ion-locked as well as in a simulated, more hydrated open-conformation of the ion binding glutamate as when it is travelling through the a/c-ring interface upon c-ring rotation.
In Nervensystemen werden zahlreiche Informationen wahrgenommen und verarbeitet um ein adäquates Verhalten hervorzurufen. Für die Untersuchung der funktionellen Zusammenhänge hierbei wurden verschiedene Methoden entwickelt, die eine gezielte Manipulation neuronaler Prozesse ermöglichen. Durch Analyse der resultierenden Effekte können dabei synaptische Proteine, einzelne Neuronen oder neuronale Netzwerke funktionell charakterisiert werden. Bisherige Ansätze verfügen jedoch nur über eine geringe zeitliche und räumliche Auflösung oder erlauben lediglich eine eingeschränkte Anwendung im frei beweglichen Tier.
Diese Nachteile können durch die heterologe Expression von lichtgesteuerten, mikrobiellen Rhodopsinen zur gezielten Manipulation des Membranpotentials umgangen werden. So induziert die Photoaktivierung des Kationenkanals Channelrhodopsin 2 (ChR2; (Nagel et al., Curr Biol 2005)) eine Depolarisation, während die Chloridpumpe Halorhodopsin (NpHR; (Zhang et al., Nature 2007)) für die Hyperpolarisation verwendet werden kann. Dabei ermöglichen die schnellen Kinetiken der Rhodopsine eine zeitlich präzise Steuerung des Membranpotentials. Durch Auswahl geeigneter Promotoren ist zudem oftmals eine zell spezifische Expression möglich. Dieser Ansatz wird daher allgemein als Optogenetik bezeichnet.
In der vorliegenden Arbeit wurden zunächst konventionelle Techniken genutzt, um die Funktion von zwei assoziierten Proteinen eines Acetylcholin Rezeptors in C. elegans zu untersuchen. Des Weiteren wurden verschiedene Methoden für den Fadenwurm entwickelt und angewendet, die die Vorteile optogenetischer Techniken für die funktionelle Charakterisierung synaptischer Proteine und neuronaler Netzwerke nutzbar machen. Hierbei erlaubt die Transparenz von C. elegans die optogenetische Stimulation im lebenden Organismus unter nicht invasiven Bedingungen. Weitere Vorteile von C. elegans als neurobiologischem Modellorganismus liegen in seiner einfachen Handhabung (Hope, 1999) und der stereotypen Entwicklung seines Nervensystems mit bekannten anatomischen Ausprägungen (Sulston and Horvitz, Dev Biol 1977; Varshney et al., PLoS Comput Biol 2011; White et al., Philos Trans R Soc Lond B Biol Sci 1986). Durch ihre Häufigkeit und die experimentelle Zugänglichkeit wird hierbei die neuromuskuläre Synapse oftmals zur Erforschung der synaptischen Reizweiterleitung genutzt (Von Stetina et al., Int Rev Neurobiol 2006). Durch pharmakologische (Lewis et al., Neuroscience 1980; McIntire et al., Nature 1993; Miller et al., Proc Natl Acad Sci U S A 1996; Richmond and Jorgensen, Nat Neurosci 1999) und elektrische Stimulation (Richmond and Jorgensen, Nat Neurosci 1999) können dabei Defekte der Transmission hervorgehoben werden, während Verhaltensexperimente oder elektrophysiologische Messungen der post synaptischen Ströme in Muskelzellen eine quantitative Analyse ermöglichen (Richmond and Jorgensen, Nat Neurosci 1999).
Diese Methoden wurden für die funktionelle Charakterisierung von NRA 2 und NRA 4 verwendet, die beide als akzessorische Proteine zusammen mit dem Levamisol sensitiven Acetylcholin Rezeptor der Körperwandmuskelzellen aufgereinigt wurden (Gottschalk et al., EMBO J 2005). Dabei konnte gezeigt werden, dass NRA 2 und NRA 4 im Endoplasmatischen Retikulum (ER) der Muskelzellen einen Komplex bilden, der die Sensitivität von beiden nikotinischen Acetylcholin Rezeptoren gegenüber verschiedenen cholinergen Agonisten verändert. In diesem Zusammenhang wurde auch nachgewiesen, dass die Oberflächenexpression einzelner Untereinheiten der beiden Rezeptoren durch NRA 2/4 beeinflusst wird. Diese Resultate legen die Vermutung nahe, dass beide Proteine die Zusammensetzung der Rezeptoren und somit ihre pharmakologischen Eigenschaften modulieren. Denkbar ist dabei eine regulatorische Funktion bei der Assemblierung verschiedener Untereinheiten zu einem funktionellen Rezeptor oder bei der Kontrolle des ER Austritts von Rezeptoren mit bestimmter Zusammensetzung. In dieser Hinsicht konnte jedoch keine Interaktion von NRA 2/4 mit der Notch Signalkaskade nachgewiesen werden, wie sie für die homologen Proteine nicalin und NOMO in Vertebraten gezeigt wurde (Haffner et al., J Biol Chem 2007; Haffner et al., EMBO J 2004).
Für die Untersuchung synaptischer Proteine durch optogenetische Techniken wurde ChR2(H134R) selektiv in cholinergen oder GABAergen Motorneuronen exprimiert, um die akute und lichtgesteuerte Freisetzung des jeweiligen Neurotransmitters zu ermöglichen. Die resultierende Stimulation bzw. Inhibition von Muskelzellen wurde hierbei durch elektrophysiologische Messungen der post synaptischen Ströme und durch Analyse von Kontraktionen respektive Relaxationen untersucht. Dabei wurde gezeigt, dass Störungen der synaptischen Reizweiterleitung die Ausprägung und Dynamik dieser lichtinduzierten Effekte beeinflussen und dadurch charakterisiert werden können. So zeigten beispielsweise Mutanten von Synaptojanin und Endophilin nachlassende Effekte bei anhaltender oder wiederholter Stimulation, was durch die gestörte Regeneration synaptischer Vesikel erklärt werden kann (Harris et al., J Cell Biol 2000; Schuske et al., Neuron 2003; Verstreken et al., Neuron 2003).
Die hohe Sensitivität dieser Methode wurde im Nachfolgenden dazu verwendet, die Inhibition cholinerger Motorneuronen durch den metabotropen GABAB Rezeptor zu untersuchen, der in C. elegans aus den beiden Untereinheiten GBB 1 und GBB 2 gebildet wird (Dittman and Kaplan, J Neurosci 2008; Vashlishan et al., Neuron 2008). Dabei konnte zunächst gezeigt werden, dass diese heterosynaptische Inhibition verschiedene lokomotorische Verhaltensweisen der Tiere beeinflusst. Für die mechanistische Untersuchung wurden anschließend cholinerge Motorneuronen durch ChR2(H134R) photoaktiviert, während resultierende Kontraktionseffekte in Abhängigkeit von GBB 1/2 analysiert wurden. Um hierbei die Funktion von GBB 1/2 durch erhöhte GABA Konzentrationen hervorzuheben, wurden zusätzlich GABAerge Motorneuronen optogenetisch stimuliert oder die Wiederaufnahme von GABA aus dem synaptischen Spalt durch Mutation des Membran ständigen GABA Transporters blockiert. So konnte gezeigt werden, dass GBB 1/2 eine akute Inhibition der cholinergen Motorneuronen bewirken, was vermutlich für die Regulation von Bewegungsabläufen eine wichtige Rolle spielt. Die geringe Dynamik der GBB 1/2 induzierten Effekte deutet allerdings darauf hin, dass die synaptische Aktivität durch den metabotropen Rezeptor kaum nachhaltig moduliert wird.
In nachfolgenden Versuchen wurde die optogenetische Stimulation von Motorneuronen außerdem mit der elektronenmikroskopischen Analyse der präsynaptischen Feinstruktur kombiniert. Dadurch konnte die Dynamik der Exozytose und Endozytose synaptischer Vesikel (SV) in Abhängigkeit von neuronaler Aktivität untersucht werden. So wurde gezeigt, dass synaptische Vesikel nahe der aktiven Zone während einer 30 sekündigen Hyperstimulation nahezu komplett aufgebraucht waren. Die vollständige Regeneration der SV Pools benötigte anschließend etwa 12 Sekunden und erfolgte zunächst in der Peripherie der aktiven Zone, was auf eine laterale Heranführung der Vesikel schließen lässt. Nach etwa 20 Sekunden erholte sich ebenfalls die Wirksamkeit der Stimulation von Muskelzellen durch die Motorneuronen, was durch elektrophysiologische Messungen der photo induzierten post synaptischen Ströme gezeigt wurde. Während der Hyperstimulation bildeten sich außerdem große vesikuläre Strukturen, die sich anschließend nach etwa acht Sekunden wieder aufgelöst hatten. In Analogie zu vergleichbaren Experimenten in anderen Organismen liegt die Vermutung nahe, dass es sich dabei um Zwischenprodukte der so genannten Bulk Phase Endozytose handelt, die das Clathrin abhängige Recycling von synaptischen Vesikeln bei starker neuronaler Aktivität ergänzt (Heuser and Reese, J Cell Biol 1973; Miller and Heuser, J Cell Biol 1984; Richards et al., Neuron 2000). Bemerkenswerterweise war der Abbau der vesikulären Strukturen in Synaptojanin und Endophilin defizienten Tieren stark verzögert. Denkbar ist, dass beide Proteine für die Synthese von synaptischen Vesikeln aus den vesikulären Zwischenprodukten der Bulk Phase Endozytose wichtig sind, analog zur ihrer Funktion bei der Clathrin abhängigen Endozytose an der Plasmamembran.
Durch die zielgerichtete Manipulation der Zellaktivität ermöglichen optogenetische Techniken außerdem die funktionelle Charakterisierung von Neuronen und neuronalen Netzwerken. Um die zelluläre Spezifität dieses Ansatzes zu erhöhen, wurde ein Tracking System entwickelt das die Position frei beweglicher Tiere in Echtzeit bestimmt und nachverfolgt. Dadurch konnte die Photoaktivierung optogenetischer Proteine auf definierte Bereiche der Fadenwürmer und somit auf ausgewählte Neuronen innerhalb der Expressionsmuster von verwendeten Promotoren eingeschränkt werden. Des Weiteren ermöglichte hierbei die Auswertung translatorischer Parameter die Analyse verschiedener lokomotorischer Merkmale wie Geschwindigkeit, Bewegungsbahn oder Ausprägung der Körperbiegungen. Dieses System wurde beispielhaft für die konzertierte Photoaktivierung durch ChR2(H134R) bzw. Photoinhibition durch MAC von zwei verschiedenen Gruppen von Neuronen angewendet, um die Integration mechanosensorischer Informationen durch Command Interneuronen zu untersuchen. In diesem Zusammenhang wurde zudem eine Rekombinase basierte Methode für optogenetische Proteine adaptiert, die die Transkription auf die zelluläre Schnittmenge von zwei verschiedenen Promotoren einschränkt und somit die Spezifität der Expression erhöht. Idealerweise kann dieser Ansatz außerdem mit der gezielten Photoaktivierung kombiniert werden, um die zelluläre Selektivität optogenetischer Anwendungen weiter zu verbessern.
Weiterhin ist die Anwendung optogenetischer Techniken bisher durch intrinsische Eigenschaften der verwendeten Rhodopsine auf die relativ kurzzeitige Manipulation des Membranpotentials von Zellen beschränkt. So benötigt ChR2 durch die schnelle Schließung seines offenen Kanals eine kontinuierliche Photoaktivierung, um eine andauernde Depolarisation hervorzurufen. Dies ist jedoch potentiell mit phototoxischen und – besonders bei C. elegans – phototaktischen Nebeneffekten verbunden. Deswegen wurden diverse Mutanten von ChR2 mit stark verlangsamter Inaktivierung (Berndt et al., Nat Neurosci 2009) für ihren Nutzen zur Langzeit Stimulation von erregbaren Zellen im Nematode getestet. Dabei wurde gezeigt, dass ChR2(C128S) durch einen kurzen Photostimulus mit vergleichsweise niedriger Intensität eine anhaltende Depolarisation über mehrere Minuten auslösen kann. Die wiederholte Stimulation in ASJ Neuronen ermöglichte zudem eine langzeitige Depolarisation über mehrere Tage, wodurch die genetisch veranlagte Entwicklung von Tieren manipuliert werden konnte. Durch gezielte Punktmutation konnten außerdem relevante Eigenschaften von ChR2(C128S) für die Langzeit Stimulation weiter verbessert werden.
Als weiteres optogenetisches Werkzeug wurde zudem die Photoaktivierbare Adenylatzyklase alpha (PACa) aus Euglena gracilis (Iseki et al., Nature 2002; Ntefidou et al., Plant Physiol 2003; Schroder-Lang et al., Nat Methods 2007) für die akute und lichtgetriebene Synthese des sekundären Botenstoffs cAMP in C. elegans etabliert. Die Photoaktivierung von PACa in cholinergen Motorneuronen verstärkte dabei die Neurotransmitterfreisetzung und induzierte hyperlokomotorische Phänotypen, vergleichbar zu Mutanten mit erhöhten cAMP Konzentrationen.
Zusammengefasst wurden diverse optogenetische Techniken für C. elegans entwickelt und optimiert, die die zellspezifische und nicht invasive Manipulation des Membranpotentials beziehungsweise die Synthese des sekundären Botenstoffs cAMP durch Licht im frei beweglichen Tier ermöglichen. Diese Methoden können zur gezielten Störung neuronaler Aktivität angewendet werden, um dadurch neurobiologische Fragestellungen im Fadenwurm zu untersuchen. Dies wurde beispielhaft für die Erforschung der synaptischen Reizweiterleitung und die funktionelle Analyse neuronaler Netzwerke demonstriert. Denkbar ist außerdem, diese für C. elegans etablierten Methoden vergleichbar in anderen Modellorganismen anzuwenden. So sind die Fruchtfliege ebenso wie der Zebrafisch Embryo bereits für optogenetische Techniken erprobt (Arrenberg et al., Proc Natl Acad Sci U S A 2009; Schroll et al., Curr Biol 2006). Für Säugetiere wie die Maus, die Ratte und den Makaken wurden zudem bereits Ansätze entwickelt, die die gezielte Photostimulation in lebenden und frei beweglichen Tieren ermöglichen (Han et al., Neuron 2009; Wentz et al., J Neural Eng 2011; Yizhar et al., Nature 2011; Zhang et al., Nat Rev Neurosci 2007).
Das Enzym 5-Lipoxygenase (5-LO) spielt eine entscheidende Rolle in der Generierung von Leukotrienen. Diese fungieren als wichtige proinflammatorische Mediatoren. Darüber hinaus ist die 5-LO anhand ihrer N-terminalen Domäne in der Lage mit verschiedenen Proteinen zu interagieren. Unter den Interaktionspartnern befindet sich Dicer, ein Enzym welches für den finalen Schritt der microRNA (miRNA)-Biosynthese verantwortlich ist. MiRNA sind kurze, nicht kodierende RNA Stränge mit einer typischen Länge von etwa 23 Nukleotiden, die an der posttranskriptionalen Regulierung der Proteinbiosynthese beteiligt sind.
Ziel dieser Arbeit war es den Einfluss der 5-LO auf die miRNA-Prozessierung im zellulären Kontext zu untersuchen. Als Modellsystem wurde die MonoMac6 (MM6) Zelllinie ausgewählt. MM6-Zellen exprimieren im undifferenzierten Grundzustand nur geringe Mengen an 5-LO. Erst nach Differenzierung mittels transformierenden Wachstumsfaktors ß (TGFß) und Calcitriol kommt es zur Induktion der 5-LO Proteinbiosynthese. Darüber hinaus war es Basavarajappa et al. möglich die 5-LO-Expression in diesen Zellen mittels RNA-Interferenz stark herunter zu regulieren (Δ5-LO).
Um die Frage der Auswirkungen des 5-LO knockdowns auf die miRNA-Expression analysieren zu können, wurde ein Microarray in differenzierten Kontroll-und Δ5-LO-Zellen durchgeführt.Es wurden 37 miRNAs identifiziert deren Expression 5-LO abhängig ist. Dabei war das Niveau von 30 Vertretern in Abwesenheit der 5-LO erhöht, wohingegen die Expression von sieben miRNAs reduziert war. Unter diesen sieben herunter regulierten miRNAs befanden sich miR-99b-5p und miR-125a-5p, die einem gemeinsamen Cluster entstammen. Als Cluster wird eine Gruppe von miRNAs bezeichnet, die aus einem gemeinsamen primären Transkript (pri-miRNA) hervorgeht. Diese Eigenschaft führte zur Vermutung, dass bereits die Expression dieser pri-miRNA durch die 5-LO reguliert wird. Allerdings zeigte sichim Verlauf dieser Arbeit, dass die Expression der pri-miRNA 5-LO unabhängig verläuft. Im Gegensatz dazu wies die Zwischenstufe zwischen pri-miRNA und reifer miRNA eine reduzierte Expression in Δ5-LO Zellen auf. Für die Prozessierung dieser sogenannten precursor miRNAs (pre-miRNA) ist die Ribonuklease III Drosha verantwortlich, welche die pre-miRNA aus der jeweiligen pri-miRNAs chneidet. Das verringerte pre-miR-99b-und pre-miR-125a-Niveau ist daher ein Hinweis darauf, dass überDicerhinausmöglicherweise ebenfalls die Drosha Aktivität mittels 5-LO reguliert wird.
Des Weiteren wurde untersucht iniefern Leukotriene beziehungsweise 5-LO-Inhibitoren die Expression von miR-99b-5p und miR-125a-5p beeinflussen. Dabei stellte sich heraus, dass das miRNA-Niveau unabhängig von der vorhandenen Leukotrien-Menge ist. Das 5-LO aktivierende Protein (FLAP) besitzt dahingegen einen mit der 5-LO vergleichbaren Einfluss auf die reife miRNA. FLAP ist ein weiterer Interaktionspartner der 5-LO und essentiell für die Leukotrien-Biosynthese in vivo. Anhand von Protein-Lokalisationsstudien mittels Immunofluoreszenz konnte gezeigt werden, dass FLAP außerdem in der Lage zu sein scheint die Relokalisation der 5-LO aus dem Zytoplasma in den Nukleus einzuschränken. Im Zytoplasma ist die 5-LO in der Lage mit Dicer zu interagieren. Daten bezüglich einer Interaktion zwischen Drosha und 5-LO im Zellkern liegen bisher nicht vor. Eine etwaige Interaktion könnte allerdings helfen die reduzierten pre-miRNA Spiegel in Abwesenheit der 5-LO zu erklären.
Im Laufe dieser Arbeit wurden weiterhin die Auswirkungen von proinflammatorischen Lipopolysacchariden (LPS) auf die Prozessierung von miR-99b-5p und miR-125a-5p analysiert. Ausschließlich in Anwesenheit von 5-LO zeigte sich eine differenzierungsunabhängig gesteigerte Biosynthese der pri-und der reifen miRNA. Allerdings konnte kein Einfluss von LPS auf die 5-LO-Lokalisation beziehungsweise Expression festgestellt werden. Aufgrund dessen sind weiterführende Studien, die den Zusammenhang zwischen LPS induzierter miR-99b-5p- beziehungsweise miR-125a-5p-Biosynthese und 5-LO herstellen, nötig.
Abschließend hat sich diese Arbeit mit den Zielgenen der durch 5-LO regulierten miRNAs auseinandergesetzt. Es konnte gezeigt werden, dass in Abwesenheit von miR-99b-5p und miR-125a-5p die Freisetzung der beiden durch LPS stimulierten Zytokine Interleukin 6 (IL-6) und Tumornekrosefaktor α (TNFα) gesteigert ist. Interessanterweise besitzt TNFα einen stimulierenden Effekt auf die Leukotrien-Biosynthese. Allerdings konnte kein direkter Zusammenhang zwischen miR-99b-5p/miR-125a-5p Expression, TNFα und der 5-LO Aktivität hergestellt werden. Der Einsatz von miR-99b-5p-und miR-125a-5p-Inhibitoren zeigte keine Auswirkungen auf die Leukotrien-Biosynthese nach LPS Stimulation. Im Gegensatz dazu konnte in unstimulierten Zellen eine signifikante Aktivitätssteigerung in Abwesenheit von miR-125a-5p festgestellt werden. Diese Beobachtungen legen nahe, dass miR-125a-5p einen TNFα unabhängigen Einfluss auf die 5-LO Aktivität besitzt. In LPS stimulierten Zellen kommt es möglicherweise zu Überlagerungen dieses Effektes.
Zusammenfassend konnte in dieser Arbeit gezeigt werden, dass 5-LO eine regulierende Funktion auf die Reifung der beiden miRNAs miR-99b-5p und miR-125a-5p aufweist. Dieser Effekt könnte einer direkten Interaktion zwischen 5-LO und Dicer zuzuschreiben sein. Des Weiteren konnte gezeigt werden, dass die Regulierung der Expression bestimmter miRNAs mittels 5-LO nicht auf deren kanonischer enzymatischer Aktivität beruht. Diese Ergebnisse schlagen eine neue Richtung der 5-LO-Forschung ein und können in Zukunft dazu beitragen 5-LO vermittelte Effekte besser charakterisieren zu können.
Analysis of coding principles in the olfactory system and their application in cheminformatics
(2007)
Unser Geruchssinn vermittelt uns die Wahrnehmung der chemischen Welt. Im Laufe der Evolution haben sich in unserem olfaktorischen System Mechanismen entwickelt, die wahrscheinlich optimal auf die Erfüllung dieser Aufgabe angepasst sind. Die Analyse dieser Verarbeitungsstrategien verspricht Einblicke in effiziente Algorithmen für die Kodierung und Verarbeitung chemischer Information, deren Entwicklung und Anwendung dem Kern der Chemieinformatik entspricht. In dieser Arbeit nähern wir uns der Entschlüsselung dieser Mechanismen durch die rechnerische Modellierung von funktionellen Einheiten des olfaktorischen Systems. Hierbei verfolgten wir einen interdisziplinären Ansatz, der die Gebiete der Chemie, der Neurobiologie und des maschinellen Lernens mit einbezieht.
The formation and maintenance of a defined three-dimensional structure is a prerequisite for most proteins in order to fulfill their function in the native context. However, there are proteins, which are intrinsically unstructured and thus natively unfolded. In addition, the misfolding and aggregation of many proteins can lead to severe diseases. The investigation of non-native states of proteins significantly contributes to the understanding of protein folding and misfolding. Nuclear magnetic resonance (NMR) spectroscopy is the only known technique that can provide information on structure and dynamics of non-native states of proteins at atomic resolution. Unfolded and non-native states of proteins have to be treated as ensembles of rapidly interconverting conformers and their observed properties are ensemble and time averaged. In this thesis, hen egg white lysozyme (HEWL) and mutants thereof have been investigated by NMR spectroscopy. The reduction of its four disulfide bridges and the successive methylation of the cysteine residues renders HEWL permanently non-native (‘HEWL-SMe’). Alternatively, the exchange of the eight cysteines for alanines results in very similar states (‘all-Ala-HEWL’). Under these conditions, HEWL-SMe and all-Ala-HEWL do not resemble random coil conformations, but exhibit residual secondary and tertiary structure. The presence of hydrophobic clusters and long-range interactions around the proteins six tryptophan residues and the modulation of these properties by single-point mutants has been observed. For the NMR spectroscopic investigation, HEWL has been isotopically labelled in E. coli by expression into inclusion bodies. After purification, the 1HN, 15NH, 13Calpha, 13Cbeta, 13C’, 1Halpha and 1Hbeta resonances of HEWL-SMe and all-Ala-HEWL have been assigned almost completely using three-dimensional NMR experiments. The analysis of secondary chemical shifts revealed regions in the proteins sequence — particularly around the six tryptophan residues—with significantly populated alpha-helix like conformations. In order to further elucidate the influence of the tryptophan side chains, a set of two new pulse sequences has been developed that allowed for the successful assignment of the 13Cg, 15Ne and 1HNe resonances in these side chains. This knowledge was eventually exploited in the interpretation of two-dimensional 15N-1H photo-CIDNP spectra, which revealed a differential solvent accessibility of the tryptophan residues in all-Ala-HEWL but not in the single point mutant W62G-all-Ala-HEWL. In addition, heteronuclear R2 relaxation rates have been determined for the indole 15Ne nuclei of all-Ala-HEWL and W62G. While in the wild-type like all-Ala-HEWL, the rates are different among the six tryptophan residues, in W62G they are more uniform. Together with relaxation data from the amide backbone, these results indicate the significant destabilization of the hydrophobic clusters in the absence of W62. In contrast, in the W108G mutant the profile of the R2 relaxation rates was not found to be significantly altered. No evidence was found by R1rho relaxation rates and relaxation dispersion measurements for conformational exchange on slower (micro- to millisecond) timescales. Residual dipolar couplings have been determined for non-native HEWL in order to retrieve structural information of these states. The differences of the W62G and the wild-type like non-native HEWL is also picked up in NH-RDCs of these proteins aligned in polyacrylamide gels. Significant positive RDCs are observed in the regions of the hydrophobic clusters in all-Ala-HEWL, but to a much lesser degree in W62G. So far, all attempts to simulate RDCs from generated non-native ensembles failed even when including long-range contacts or specific phi/psi backbone angle propensities. However, the measured RDCs can be used to cross-validate structural ensembles of non-native HEWL generated by molecular dynamics simulations that are based on restraints from the other experimental data, such as the differential solvent accessibilities from the photo-CIDNP experiments and the data on the hydrophobic clustering gained from the combined mutational and relaxation studies. Finally, non-native HEWL has been investigated for the first time using two-dimensional NMR in organic solvents, which are able to induce secondary structures and ultimately lead to amyloid formation. Under these conditions severe line broadening was observed, which was attributed to exchange between different — mostly a-helical— conformations. In summary, in this thesis methods have been developed, optimized and successfully applied for the structural and dynamical characterization of non-native states of proteins and the effect of single-point mutants on the properties of such ensembles has been investigated. Data has been gained that can considerably contribute to the further elucidation of the nature of non-native states of HEWL by molecular dynamics simulations.
The focus of this thesis has been to further advance and develop existing NMR techniques for the study of protein folding. In order to do so, experimental as well as theoretical approaches have been pursued. From the theoretical side, a successful attempt to the development of a general theory for the treatment of residual dipolar couplings in the case of unfolded proteins has been undertaken. Information contained in residual dipolar couplings is especially valuable due to its long-range nature. The dynamic character of unfolded states of proteins, which may be composed of distinct subsets of conformations, renders reliable interpretation of data a non-trivial task. Statistical-coil-based approaches have been shown to be powerful in data interpretation. A consistent theory based on fundamental polymer physics, however, had not been presented so far. The herein presented model addresses this problem building on the original work by Annila and co-workers. In this work, several shortcomings have been identified. These shortcomings have been corrected here leading to a general approach for the treatment of residual dipolar couplings of unfolded proteins. More specifically, it is shown that, in the case of fully unfolded proteins aligned by a steric mechanism, basic dependencies of dipolar couplings such as on chain length and location with in the chain can be analysed in simple analytical terms. The main predictions of the model are compared to experimental data showing reasonable agreement. The presented mathematical framework is principally suited for various improvements which could include the treatment of long-range interactions and of the actual geometry of the given aligment medium. From the experimental side, bovine alpha-lactalbumin has been chosen as a model system for the development of improved time-resolved 1D NMR methods aiming at the observation of conformational transitions by kinetic means. The presented results show that high-quality data can now be obtained at protein concentrations as low as 100uM. Rate constants characterising distinct conformational transitions of up to 8/s have been measured. These are the fastest rate constants which have been reported so far for protein folding events. The NMR data supplemented by complementary biophysical data furthermore demonstrate that the folding of bovine alpha-lactalbumin is more complex than has been anticipated. All data are consistent with a triangular folding mechanism involving parallel pathways of folding for formation of the native state of the protein. Interestingly, such a folding mechanism has also been found for the highly structurally homologous protein lysoyzme from hen egg white. Evidence is presented that the guiding role of long-range interactions in the unfolded state of lysoyzme for mediating intersubdomain interactions during folding is replaced in the case of bovine alpha-lactalbumin by the Ca2+ binding site.
Ubiquitin is a highly conserved protein involved in several cellular processes like protein degradation, endocytosis, signal transduction and DNA repair. The discovery of ubiquitin-like proteins (UBL) and ubiquitin-like domains (ULD) increases the number of regulation pathways where the property of the ubiquitin-fold is profitable.
Autophagy is the catabolic pathway used in cells to deliver cytosolic components and dysfunctional organelles to the lysosome for degradation. MAP1LC3 proteins are ubiquitin-like proteins involved in one hand for the expansion of the autophagosome, which sequesters cytosolic substrates. In the other hand, these proteins (LC3- and GABARAP- subfamilies) bind to autophagic receptors linked to polyubiquitinated proteins aggregates. For this project, the 3D structure of the GABARAPL-1/NBR1-LIR complex was determined and confirmed that GABARAPL-1 belongs to the MAP1LC3 proteins family, structurally characterized by an ubiquitin-fold, consisting of a central beta-sheet formed by four beta-strands and two alpha-helices on one side of the beta-sheet, preceded N terminally by two alpha-helices, resulting in the formation of two hydrophobic pockets, hp1 and hp2. The autophagic receptor NBR1 interacts with GABARAPL-1 through the hp1 and hp2 with its LIR motif taking an extended beta conformation upon binding, forming an intermolecular beta-sheet with the second beta-strand of GABARAPL 1. This LC3- interacting region (LIR) consists of an Theta XX Gamma sequence preceded by acidic amino acids, with Theta and Gamma represented by any aromatic and hydrophobic residues, respectively. Interaction studies of the LIR domains of p62, Nix and NBR1 with different members of the MAP1LC3 proteins family indicate that the presence of a tryptophan in the LIR motif increases the binding affinity. Substitution to other aromatic amino acids or increasing the number of negatively charged residues at the N-terminus of the LIR motif, however, has little effect on the binding affinity due to enthalpy-entropy compensation, suggesting that effector proteins can interact with a wide variety of different sequences with similar and moderate binding affinities.
Additionally to be present in proteins dealing with protein folding and degradation, ubiquitin-like domain were found protein involved in the regulation of signal transduction like TBK1, a serine/threonine kinase responsible for induction of immune response. In this second project, based on the NMR chemical shifts of the TBK1 domain contained between amino acids 302 and 383, secondary structure prediction programs (TALOS and CSI) confirmed the presence of an Ubiquitin-like domain in TBK1 by identifying one alpha-helix and four beta-strands sequentially aligned like following beta-beta-alpha-beta-beta. This alignment corresponds perfectly with the secondary structure elements of Ubiquitin and proved that TBK1_ULD belongs to the UBL protein superfamily. The similarity to ubiquitin was even bigger by the presence in addition of a small beta-strand and a short helix, which are observed as the beta 5-strand and a 310-helix in Ubiquitin, respectively. The first attempts on the 3D structure determination confirmed the Ub-fold but due to the lack of assignment in TBK1_ULD, only a structure based on ubiquitin as a model was determined. Interaction studies of TBK1_ULD with the IAD-SRR domain of IRF3 showed that both side of the molecule seems involved and that the TBK1/IRF3 interaction is more complex than a one to one binding process. Unfortunately, the instability of TBK1_ULD associated to the difficulty in the purification of IAD-SRR did not allow to further study this interaction more precisely.
Finally, to overcome the difficulty encountered in NMR experiments because of low expression and/or poor solubility, an expression vector using the intrinsic property of ubiquitin was designed. Fused to proteins or peptides targets, this construct produced proteins and peptides in a larger amount than with traditional expression vectors and also with a less cost than chemical synthesis for pure labeled peptides for NMR structural studies. The presence of a hexa histidine tag was useful for the isolation and the purification of the constructs. The existence of a TEV cleavage site was created to keep the possibility of releasing the ubiquitin moiety from the expressed protein or peptide. Moreover, the ubiquitin-tag could also still be attached to the protein/peptide of interest when biophysical methods like NMR, ITC or CD spectroscopy are applied, providing the same results than for the protein/peptide moiety alone.
Cellular metabolism can be envisaged by fluorescence lifetime imaging of fluorophores sensitive to specific intracellular factors such as [H+], [Ca2+], [O2], membrane potential, temperature, polarity of the probe environment, and alterations in the conformation and interactions of macromolecules. Lifetime measurements of the probes allow the quantitative determination of the intracellular factors. Fluorescence microscopy taking advantage of time-correlated single photon counting is a novel method that outperforms all other techniques with its single photon sensitivity and picoseconds time resolution. In this work, a time- and space-correlated single photon counting system was established to investigate the behavior of 2-(4-(dimethylamino)styryl)-1-methylpyridinium iodide (DASPMI) in living cells. DASPMI is known to selectively stain mitochondria in living cells. The uptake and fluorescence intensity of DASPMI in mitochondria is a dynamic measure of membrane potential. Hence, an endeavour was made to elucidate the mechanism of DASPMI fluorescence by obtaining spectrally-resolved fluorescence decays in different solvents. A bi-exponential decay model was sufficient to globally describe the wavelength dependent fluorescence in ethanol and chloroform. While in glycerol, a three-exponential decay model was necessary for global analysis. In the polar low-viscous solvent water, a mono-exponential decay model fitted the decay data. The sensitivity of DASPMI fluorescence to solvent viscosity was analysed using various proportions of glycerol/ethanol mixtures. The lifetimes were found to increase with increasing solvent viscosity. The negative amplitudes of the short lifetime component found in chloroform and glycerol at the longer wavelengths validated the formation of new excited state species from the initially excited state. Time-resolved emission spectra in chloroform and glycerol showed a biphasic increase of spectral width and emission maxima. The spectral width had an initial fast increase within 150 ps and a near constant thereafter. A two-state model based on solvation of the initially excited state and further formation of TICT state has been proposed to explain the excited state kinetics and has been substantiated by the de-composition of time-resolved spectra. The knowledge of DASPMI photophysics in a variety of solvents now provides the means of deducing complex physiological parameters of mitochondria from its behavior in living cells. Spatially-resolved fluorescence decays from single mitochondria or only very few organelles of XTH2 cells signified distinctive three-exponential decay kinetics of viscous environment. Based on DASPMI photophysics in a variety of solvents, these lifetimes have been attributed to the fluorescence from locally excited state (LE), intramolecular charge transfer state (ICT) and twisted intramolecular charge transfer (TICT) state. A considerable variation in lifetime among mitochondria of different morphology and within single cell was evident corresponding to the high physiological variations within single cells. Considerable shortening of the short lifetime component (τ1) under high membrane potential condition, such as in the presence of ATP and/or substrate, was similar to quenching and dramatic decrease of lifetime in polar solvents. Under these conditions τ2 and τ3 increased with decreasing contribution. Upon treatment with ionophore nigericin, hyperpolarization of mitochondria resulted in remarkable shortening of τ1 from 159 ps to 38 ps. Inhibiting respiration by cyanide resulted in notable increase of mean lifetime and decrease of mitochondrial fluorescence. Increase of DASPMI fluorescence on conditions elevating mitochondrial membrane potential has been attributed to uptake according Nernst distributions, to de-localisation of π electrons, quenching processes of the methyl pyridinium moiety and restricted torsional dynamics at the mitochondrial inner membrane. Accordingly, determination of anisotropy in DASPMI stained mitochondria in living XTH2 cells, revealed dependence of anisotropy on membrane potential. Such changes in anisotropy attributed to restriction of the torsional dynamics about the flexible single bonds neighboring the olefinic double bond revealed the previously known sub-mitochondrial zones with higher membrane potential along its length. Membrane-potential-dependent changes in anisotropy have further been demonstrated in senescent chick embryo fibroblasts. In conclusion, spectroscopic observations of excited-state kinetics of DASPMI in solvents and its behavior in living cells had revealed for the first time its localisation, mechanism of voltage sensitive fluorescence and its membrane-potential-dependent anisotropy in living cells. The simultaneous dependence of DASPMI photophysics on mitochondrial inner membrane viscosity and transmembrane potential has been highlighted.