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The WHO-designated neglected-disease pathogen Chlamydia trachomatis (CT) is a gram-negative bacterium responsible for the most frequently diagnosed sexually transmitted infection worldwide. CT infections can lead to infertility, blindness and reactive arthritis, among others. CT acts as an infectious agent by its ability to evade the immune response of its host, which includes the impairment of the NF-κB mediated inflammatory response and the Mcl1 pro-apoptotic pathway through its deubiquitylating, deneddylating and transacetylating enzyme ChlaDUB1 (Cdu1). Expression of Cdu1 is also connected to host cell Golgi apparatus fragmentation, a key process in CT infections.
Cdu1 may this be an attractive drug target for the treatment of CT infections. However, a lead molecule for the development of novel potent inhibitors has been unknown so far. Sequence alignments and phylogenetic searches allocate Cdu1 in the CE clan of cysteine proteases. The adenovirus protease (adenain) also belongs to this clan and shares a high degree of structural similarity with Cdu1. Taking advantage of topological similarities between the active sites of Cdu1 and adenain, a target-hopping approach on a focused set of adenain inhibitors, developed at Novartis, has been pursued. The thereby identified cyano-pyrimidines represent the first active-site directed covalent reversible inhibitors for Cdu1. High-resolution crystal structures of Cdu1 in complex with the covalently bound cyano-pyrimidines as well as with its substrate ubiquitin have been elucidated. The structural data of this thesis, combined with enzymatic assays and covalent docking studies, provide valuable insights into Cdu1s activity, substrate recognition, active site pocket flexibility and potential hotspots for ligand interaction. Structure-informed drug design permitted the optimization of this cyano-pyrimidine based scaffold towards HJR108, the first molecule of its kind specifically designed to disrupt the function of Cdu1. The structures of potentially more potent and selective Cdu1 inhibitors are herein proposed.
This thesis provides important insights towards our understanding of the structural basis of ubiquitin recognition by Cdu1, and the basis to design highly specific Cdu1 covalent inhibitors.
Chlamydia trachomatis, an obligate intracellular human pathogen, is the world’s leading cause of infection related blindness and the most common, bacterial sexually transmitted disease. In order to establish an optimal replicative niche, the pathogen extensively interferes with the physiology of the host cell. Chlamydia switches in its complex developmental cycle between the infectious non-replicative elementary bodies (EBs) and the non-infectious replicative reticulate bodies (RBs). The transformation to RBs, shortly after entering a host cell, is a crucial process in infection to start chlamydial replication. Currently it is unknown how the transition from EBs to RBs is initiated. In this thesis, we could show that, in an axenic media approach, L glutamine uptake by the pathogen is crucial to initiate the EB to RB transition. L-glutamine is converted to amino acids which are used by the bacteria to synthesize peptidoglycan. Peptidoglycan inturn is believed to function in separating dividing Chlamydia. The glutamine metabolism is reprogrammed in infected cells in a c-Myc-dependent manner, in order to accomplish the increased requirement for L-glutamine. Upon a chlamydial infection, the proto-oncogene c-Myc gets upregulated to promote host cell glutaminolysis via glutaminase GLS1 and the L-glutamine transporter SLC1A5/ASCT2. Interference with this metabolic reprogramming leads to limited growth of C. trachomatis. Besides the active infection, Chlamydia can persist over a long period of time within the host cell whereby chronic and recurrent infections establish. C. trachomatis acquire a persistent state during an immune attack in response to elevated interferon-γ (IFN-γ) levels. It has been shown that IFN-γ activates the catabolic depletion of L-tryptophan via indoleamine 2,3-dioxygenase (IDO), resulting in the formation of non-infectious atypical chlamydial forms. In this thesis, we could show that IFN-γ depletes the key metabolic regulator c-Myc, which has been demonstrated to be a prerequisite for chlamydial development and growth, in a STAT1-dependent manner. Moreover, metabolic analyses revealed that the pathogen de routs the host cell TCA cycle to enrich pyrimidine biosynthesis. Supplementing pyrimidines or a-ketoglutarate helps the bacteria to partially overcome the persistent state. Together, the results indicate a central role of c-Myc induced host glutamine metabolism reprogramming and L-glutamine for the development of C. trachomatis, which may provide a basis for anti-infectious strategies. Furthermore, they challenge the longstanding hypothesis of L-tryptophan shortage as the sole reason for IFN-γ induced persistence and suggest a pivotal role of c-Myc in the control of the C. trachomatis dormancy.
The resolution of fluorescence light microscopy was long believed to be limited by the diffraction limit of light of around 200-250 nm described in 1873 by Ernst Abbe. Within the last decade, several approaches, such as structured illumination microscopy (SIM), stimulated emission depletion STED and (direct) stochastic optical reconstruction microscopy (d)STORM have been established to bypass the diffraction limit. However, such super-resolution techniques enabling a resolution <100 nm require specialized and expensive setups as well as expert knowledge in order to avoid artifacts. They are therefore limited to specialized laboratories. Recently, Boyden and colleagues introduced an alternate approach, termed expansion microscopy (ExM). The latter offers the possibility to perform superresolution microscopy on conventional confocal microscopes by embedding the sample into a swellable hydrogel that is isotropically expanded. Since its introduction in 2015, expansion microscopy has developed rapidly offering protocols for 4x, 10x and 20x expansion of proteins and RNA in cells, tissues and human clinical specimens.
Mitochondria are double membrane-bound organelles and crucial to the cell by performing numerous tasks, from ATP production through oxidative phosphorylation, production of many important metabolites, cell signaling to the regulation of apoptosis. The inner mitochondrial membrane is strongly folded forming so-called cristae. Besides being the location of the oxidative phosphorylation and therefore energy conversion and ATP production, cristae have been of great interest because changes in morphology have been linked to a plethora of diseases from cancer, diabetes, neurodegenerative diseases, to aging and infection. However, cristae imaging remains challenging as the distance between two individual cristae is often below 100 nm. Within this work, we demonstrate that the mitochondrial creatine kinase MtCK linked to fluorescent protein GFP (MtCK-GFP) can be used as a cristae marker. Upon fourfold expansion, we illustrate that our novel marker enables visualization of cristae morphology and localization of mitochondrial proteins relative to cristae without the need for specialized setups. Furthermore, we show the applicability of expansion microscopy for several bacterial pathogens, such as Chlamydia trachomatis, Simkania negevensis, Neisseria gonorrhoeae and Staphylococcus aureus. Due to differences in bacterial cell walls, we reveal important aspects for the digestion of pathogens for isotropic expansion. We further show that expansion of the intracellular pathogens C. trachomatis and S. negevensis, enables the differentiation between the two distinct developmental forms, catabolic active reticulate bodies (RB) and infectious elementary bodies (EB), on a conventional confocal microscope. We demonstrate the possibility to precisely locate chlamydial effector proteins, such as CPAF or Cdu1, within and outside the chlamydial inclusion. Moreover, we show that expansion microscopy enables the investigation of bacteria, herein S. aureus, within LAMP1 and LC3-II vesicles. With the introduction of the unnatural α-NH2-ω-N3-C6-ceramide, we further present the first approach for the expansion of lipids that may also be suitable for far inaccessible molecule classes like carbohydrates. The efficient accumulation and high labeling density of our functionalized α-NH2-ω-N3-C6-ceramide in both cells and bacteria enables in combination with tenfold expansion nanoscale resolution (10-20 nm) of the interaction of proteins with the plasma membrane, membrane of organelles and bacteria. Ceramide is the central molecule of the sphingolipid metabolism, an important constituent of cellular membranes and regulates many important cellular processes such as differentiation, proliferation and apoptosis. Many studies report about the importance of sphingolipids during infection of various pathogens. While the transport of ceramide to Chlamydia has been reported earlier, one of the unanswered questions remaining was if ceramide forms parts of the outer or inner bacterial membrane. Expansion of α-NH2-ω-N3-C6-ceramide enabled the visualization of ceramide in the inner and outer membrane of C. trachomatis and their distance was determined to be 27.6 ± 7.7 nm.
Ovarian cancer is one of the most common gynecological malignancies in the world. The prevalence of a microbial signature in ovarian cancer has been reported by several studies till date. In these microorganisms, Human herpesvirus 6 (HHV-6) and Chlamydia trachomatis (C.tr) are especially important as they have significantly high prevalence rate. Moreover, these pathogens are directly involved in causing DNA damage and thereby disrupting the integrity of host genome which is the underlying cause of any cancer. This study focuses on how the two pathogens, HHV-6 and C. trachomatis can affect the genome integrity in their individual capacities and thereby may drive ovarian epithelial cells towards transformation. HHV-6 has unique tendency to integrate its genome into the host genome at subtelomeric regions and achieve a state of latency. This latent virus may get reactivated during the course of life by stress, drugs such as steroids, during transplantation, pregnancy etc. The study presented here began with an interesting observation wherein the direct repeat (DR) sequences flanking the ends of double stranded viral genome were found in unusually high numbers in human blood samples as opposed to normal ratio of two DR copies per viral genome. This study was corroborated with in vitro data where cell lines were generated to mimic the HHV-6 status in human samples. The same observation of unusually high DR copies was found in these cell lines as well. Interestingly, fluorescence in situ hybridization (FISH) and inverse polymerase chain reaction followed by southern blotting showed that DR sequences were found to be integrated in nontelomeric regions as opposed to the usual sub-telomeric integration sites in both human samples and in cell lines. Sanger sequencing confirmed the non-telomeric integration of viral DR sequences in the host genome. Several studies have shown that C. trachomatis causes DNA damage and inhibits the signaling cascade of DNA damage response. However, the effect of C. trachomatis infection on process of DNA repair itself was not addressed. In this study, the effect of C. trachomatis infection on host base excision repair (BER) has been addressed. Base excision repair is a pathway which is responsible for replacing the oxidized bases with new undamaged ones. Interestingly, it was found that C. trachomatis infection downregulated polymerase β expression and attenuated polymerase β- mediated BER in vitro. The mechanism of the polymerase β downregulation was found to be associated with the changes in the host microRNAs and downregulation of tumor suppressor, p53. MicroRNA-499 which has a binding site in the polymerase β 3’UTR was shown to be upregulated during C. trachomatis infection. Inhibition of miR-499 using synthetic miR-499 inhibitor indeed improved the repair efficiency during C. trachomatis infection in the in vitro repair assay. Moreover, p53 transcriptionally regulates polymerase β and stabilizing p53 during C. trachomatis infection enhanced the repair efficiency. Previous studies have shown that C. trachomatis can reactivate latent HHV-6. Therefore, genomic instability due to insertions of unstable ‘transposon-like’ HHV-6 DR followed by compromised BER during C. trachomatis infection cumulatively support the hypothesis of pathogenic infections as a probable cause of ovarian cancer
The role of human Ephrin receptor tyrosine kinase A2 (EphA2) in Chlamydia trachomatis infection
(2015)
Chlamydia trachomatis (Ctr), an obligate intracellular gram negative human pathogen, causes sexually transmitted diseases and acquired blindness in developing countries. The infectious elementary bodies (EB) of Ctr involved in adherence and invasion processes are critical for chlamydial infectivity and subsequent pathogenesis which requires cooperative interaction of several host cell factors. Few receptors have been known for this early event, yet the molecular mechanism of these receptors involvement throughout Ctr infection is not known. Chlamydial inclusion membrane serves as a signaling platform that coordinates Chlamydia-host cell interaction which encouraged me to look for host cell factors that associates with the inclusion membrane, using proteome analysis. The role of these factors in chlamydial replication was analyzed by RNA interference (RNAi) (in collaboration with AG Thomas Meyer). Interestingly, EphrinA2 receptor (EphA2), a cell surface tyrosine kinase receptor, implicated in many cancers, was identified as one of the potential candidates. Due to the presence of EphA2 in the Ctr inclusion proteome data, I investigated the role of EphA2 in Ctr infection. EphA2 was identified as a direct interacting receptor for adherence and entry of C. trachomatis. Pre-incubation of Ctr-EB with recombinant human EphA2, knockdown of EphA2 by siRNA, pretreatment of cells with anti-EphA2 antibodies or the tyrosine kinase inhibitor dasatinib significantly reduced Ctr infection. This marked reduction of Ctr infection was seen with both epithelial and endothelial cells used in this study. Ctr activates EphA2 upon infection and invades the cell together with the activated EphA2 receptor that interacts and activates PI3K survival signal, promoting chlamydial replication. EphA2 upregulation during infection is associated with Ctr inclusion membrane inside the cell and are prevented being translocated to the cell surface. Ephrins are natural ligands for Ephrin receptors that repress the activation of the PI3K/Akt pathway in a process called reverse signaling. Purified Ephrin-A1, a ligand of EphA2, strongly interferes with chlamydial infection and normal development, supporting the central role of these receptors in Chlamydia infection. Overexpression of full length EphA2, but not the mutant form lacking the intracellular cytoplasmic domain, enhanced PI3K activation and Ctr infection. Ctr infection induces EphA2 upregulation and is mediated by activation of ERK signaling pathway. Interfering with EphA2 upregulation sensitizes Ctr-infected cells to apoptosis induced by tumor necrosis factor-alpha (TNF-α) suggesting the importance of intracellular EphA2 signaling.
Collectively, these results revealed the first Ephrin receptor “EphA2” that functions in promoting chlamydial infection. In addition, the engagement of a cell surface receptor at the inclusion membrane is a new mechanism how Chlamydia subverts the host cell and induces apoptosis resistance. By applying the natural ligand Ephrin-A1 and targeting EphA2 offers a promising new approach to interfere with Chlamydia infection. Thus, the work provides the evidence for a host cell surface tyrosine kinase receptor that is exploited for invasion as well as for receptor-mediated intracellular signaling to facilitate the chlamydial replication.