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This thesis aimed the development of a correlated device which combines FluidFM® with Fluorescence Microscopy (FL) (FL-FluidFM®) and enables the simultaneous quantification of adhesion forces and fluorescent visualization of mature cells. The implementation of a PIFOC was crucial to achieve a high-resolution as well as a stable but dynamic focus level. The functionality of SCFS after hardware modification was verified by comparing two force-curves, both showing the typical force progression and measured with the optimized and conventional hardware, respectively. Then, the integration of FL was examined by detaching fluorescently labeled REF52 cells. The fluorescence illumination of the cytoskeleton showed the expected characteristic force profile and no evidence of interference effects. Afterwards a corresponding correlative data analysis was addressed including manual force step fitting, the identification of visualized cellular unbinding, and a time-dependent correlation. This procedure revealed a link between the area of cytoskeletal unbinding and force-jumps. This was followed by a comparison of the detachment characteristics of intercellular connected HUVECs and individual REF52 cells. HUVECs showed maximum detachment forces in the same order of magnitude as the ones of single REF52 cells. This contrasted with the expected strong cohesiveness of endothelial cells and indicated a lack of cell-cell contact formation. The latter was confirmed by a comparison of HUVECs, primary HBMVECs, and immortalized EA.hy926 cells fluorescently labeled for two marker proteins of intercellular junctions. This unveiled that both the previous cultivation duration and the cell type have a major impact on the development of intercellular junctions. In summary, the correlative FL FluidFM® represents a powerful novel approach, which enables a truly contemporaneous performance and, thus, has the potential to reveal new insights into the mechanobiological properties of cell adhesion.
We examined 143 patients suffering from FMS, a syndrome characterized by chronic widespread pain, sleep disturbances, and fatigue. Etiology and pathophysiology of FMS are scarcely understood. In recent years abnormalities of small Aδ- and C-nerve fibers have been found in subgroups of FMS patients. It is yet unclear how such SFP is caused in FMS patients and how it contributes to FMS symptoms.
We used CCM to analyze corneal small nerve fibers and associated LC, comparing FMS patients’ results to those from 65 healthy controls and 41 disease controls suffering from SFN. We, further, assessed expression levels of mRNA and miRNA in keratinocytes taken from skin punch biopsies of FMS patients and healthy controls kept as monocellular cell cultures. A screening was performed using NGS in a small cohort of 12 FMS patients and 5 healthy controls. Results were validated in larger cohorts by qRT-PCR.
As in previous studies IENFD and CNFD were reduced in a subgroup of FMS patients. We found identical LC densities in FMS patients, healthy controls, and SFN patients. The subpopulation of dLCfiber contact in FMS and SFN patients was lower than in healthy controls. Our RNA expression analysis revealed one mRNA that was expressed higher in FMS patients than in controls: PRSS21.
We conclude that reduced neurotrophic signaling of LC may contribute to SFP in the cornea. Epidermal PRSS21 expression and dLCfiber contact density are promising biomarker candidates for FMS diagnosis.
The yeast Candida albicans is a member of the normal microflora on the mucosal surfaces of the gastrointestinal and urogenital tract in healthy persons. However, it is an opportunistic pathogen that can cause a range of infections from superficial to disseminated, in response to perturbation of the normal microflora or alterations in the host immunity. C. albicans exhibits a variety of characteristics such as adhesion, morphogenetic switching and secreted aspartic protease production that contribute to its virulence. Expression of many of these virulence factors is controlled by the availability of essential element, nitrogen. C. albicans undergoes morphogenetic transition to form filaments under nitrogen starvation conditions and this switch is controlled by the ammonium permease Mep2p. However, little is known about how this signaling function of Mep2p is regulated. Mutational analysis of Mep2p was carried out to identify the residues that confer signaling activity to this permease. The C-terminal cytoplasmic tail of Mep2p contains a signaling domain that is dispensable for ammonium transport but essential for the signaling activity of Mep2p. In this work, progressive C-terminal truncations analysis demonstrated that a MEP2DC433 allele was still able to induce filamentation while nitrogen starvation-induced filamentous growth was abolished in cells expressing a MEP2DC432 allele. Therefore, tyrosine at position 433 (Y433) is the last amino acid in Mep2p that is essential for signaling. To gain insights into how the signaling activity of Mep2p is regulated by ammonium availability and transport, conserved residues that have been implicated in ammonium binding or uptake were mutated. Mutation of D180, which has been proposed to mediate initial contact with extracellular ammonium, or the pore-lining residues H188 and H342 abolished Mep2p expression, indicating that these residues are important for protein stability. Mutation of F239, which together with F126 is predicted to form an extracytosolic gate to the conductance channel, abolished both ammonium uptake and Mep2p-dependent filamentation, despite proper localization of the protein. On the other hand, mutation of W167, which is assumed to participate along with Y122, F126, and S243 in the recruitment and coordination of the ammonium ion at the extracytosolic side of the cell membrane, also abolished filamentation without having a strong impact on ammonium transport, demonstrating that extracellular alterations in Mep2p can affect intracellular signaling. Mutation of Y122 reduced ammonium uptake much more strongly than mutation of W167 but still allowed efficient filamentation, indicating that the signaling activity of Mep2p is not directly correlated with its transport activity. An important aspect in the ability of Mep2p to stimulate filamentation in response to nitrogen limitation is its high expression levels. The cis-acting sequences and trans-acting regulators that mediate MEP2 induction in response to nitrogen limitation were identified. Promoter analysis revealed that two putative binding sites for GATA transcription factors have a central role in MEP2 expression, as deletion of the region containing these sites or mutation of the GATAA sequences in the full-length MEP2 promoter strongly reduced MEP2 expression. To elucidate the roles of the GATA transcription factors GLN3 and GAT1 in regulating MEP2 expression, mutants lacking one or both of these transcription factors were constructed. Mep2p expression was strongly reduced in gln3D and gat1D single mutants and virtually abolished in gln3D gat1D double mutants. Deletion of GLN3 strongly inhibited filamentous growth under limiting nitrogen conditions, which could be rescued by constitutive expression of MEP2 from the ADH1 promoter. In contrast, inactivation of GAT1 had no effect on filamentation. Surprisingly, filamentation became partially independent of the presence of a functional MEP2 gene in the gat1D mutants, indicating that the loss of GAT1 function results in the activation of other pathways that induce filamentous growth. These findings demonstrated that the GATA transcription factors Gln3p and Gat1p control expression of the MEP2 ammonium permease and that GLN3 is also an important regulator of nitrogen starvation-induced filamentous growth in C. albicans. C. albicans mutants lacking both the GATA transcription factors Gln3p and Gat1p were unable to grow in a medium containing an alternative nitrogen source, bovine serum albumin (BSA) as the sole nitrogen source. The ability to utilize proteins as sole source of nitrogen for growth of C. albicans is conferred by the secreted aspartic protease Sap2p, which degrades the proteins, and oligopeptide transporters that mediate uptake of the proteolytic products into cell. The growth defect of gln3D gat1D mutants was mainly caused by their inability to express the SAP2 gene, as SAP2 expression from the constitutive ADH1 promoter restored the ability of the mutants to grow on BSA. Expression of STP1, which encodes a transcription factor that is required for SAP2 induction in the presence of proteins, was regulated by Gln3p and Gat1p. Forced expression of STP1 from a tetracycline-inducible promoter bypassed the requirement of the GATA transcription factors for growth of C. albicans on proteins. When preferred nitrogen sources are available, SAP2 is repressed and this nitrogen catabolite repression of SAP2 was correlated with downregulation of STP1 under these conditions. Tetracycline-induced STP1 expression abolished nitrogen catabolite repression of SAP2, demonstrating that regulation of STP1 expression levels by the GATA transcription factors is a key aspect of both positive and negative regulation of SAP2 expression. Therefore, by using a regulatory cascade in which expression of the specific transcription factor Stp1p is controlled by the general regulators Gln3p and Gat1p, C. albicans places SAP2 expression under nitrogen control and ensures proper expression of this virulence determinant. In summary, the present study illustrated how GATA factors, Gln3p and Gat1p, play partially overlapping, but distinct roles, in mediating the appropriate responses of C. albicans to the availability of different nitrogen sources. These responses are also determinants of pathogenicity of the fungus. The relative contributions of Gln3p and Gat1p vary with their target genes and the availability of nitrogen source. Overall, these findings provide us with a better understanding of the molecular basis of some of the important processes that help in adaptation of C. albicans to various environmental conditions. The yeast Candida albicans is a member of the normal microflora on the mucosal surfaces of the gastrointestinal and urogenital tract in healthy persons. However, it is an opportunistic pathogen that can cause a range of infections from superficial to disseminated, in response to perturbation of the normal microflora or alterations in the host immunity. C. albicans exhibits a variety of characteristics such as adhesion, morphogenetic switching and secreted aspartic protease production that contribute to its virulence. Expression of many of these virulence factors is controlled by the availability of essential element, nitrogen. C. albicans undergoes morphogenetic transition to form filaments under nitrogen starvation conditions and this switch is controlled by the ammonium permease Mep2p. However, little is known about how this signaling function of Mep2p is regulated. Mutational analysis of Mep2p was carried out to identify the residues that confer signaling activity to this permease. The C-terminal cytoplasmic tail of Mep2p contains a signaling domain that is dispensable for ammonium transport but essential for the signaling activity of Mep2p. In this work, progressive C-terminal truncations analysis demonstrated that a MEP2DC433 allele was still able to induce filamentation while nitrogen starvation-induced filamentous growth was abolished in cells expressing a MEP2DC432 allele. Therefore, tyrosine at position 433 (Y433) is the last amino acid in Mep2p that is essential for signaling. To gain insights into how the signaling activity of Mep2p is regulated by ammonium availability and transport, conserved residues that have been implicated in ammonium binding or uptake were mutated. Mutation of D180, which has been proposed to mediate initial contact with extracellular ammonium, or the pore-lining residues H188 and H342 abolished Mep2p expression, indicating that these residues are important for protein stability. Mutation of F239, which together with F126 is predicted to form an extracytosolic gate to the conductance channel, abolished both ammonium uptake and Mep2p-dependent filamentation, despite proper localization of the protein. On the other hand, mutation of W167, which is assumed to participate along with Y122, F126, and S243 in the recruitment and coordination of the ammonium ion at the extracytosolic side of the cell membrane, also abolished filamentation without having a strong impact on ammonium transport, demonstrating that extracellular alterations in Mep2p can affect intracellular signaling. Mutation of Y122 reduced ammonium uptake much more strongly than mutation of W167 but still allowed efficient filamentation, indicating that the signaling activity of Mep2p is not directly correlated with its transport activity. An important aspect in the ability of Mep2p to stimulate filamentation in response to nitrogen limitation is its high expression levels. The cis-acting sequences and trans-acting regulators that mediate MEP2 induction in response to nitrogen limitation were identified. Promoter analysis revealed that two putative binding sites for GATA transcription factors have a central role in MEP2 expression, as deletion of the region containing these sites or mutation of the GATAA sequences in the full-length MEP2 promoter strongly reduced MEP2 expression. To elucidate the roles of the GATA transcription factors GLN3 and GAT1 in regulating MEP2 expression, mutants lacking one or both of these transcription factors were constructed. Mep2p expression was strongly reduced in gln3D and gat1D single mutants and virtually abolished in gln3D gat1D double mutants. Deletion of GLN3 strongly inhibited filamentous growth under limiting nitrogen conditions, which could be rescued by constitutive expression of MEP2 from the ADH1 promoter. In contrast, inactivation of GAT1 had no effect on filamentation. Surprisingly, filamentation became partially independent of the presence of a functional MEP2 gene in the gat1D mutants, indicating that the loss of GAT1 function results in the activation of other pathways that induce filamentous growth. These findings demonstrated that the GATA transcription factors Gln3p and Gat1p control expression of the MEP2 ammonium permease and that GLN3 is also an important regulator of nitrogen starvation-induced filamentous growth in C. albicans. C. albicans mutants lacking both the GATA transcription factors Gln3p and Gat1p were unable to grow in a medium containing an alternative nitrogen source, bovine serum albumin (BSA) as the sole nitrogen source. The ability to utilize proteins as sole source of nitrogen for growth of C. albicans is conferred by the secreted aspartic protease Sap2p, which degrades the proteins, and oligopeptide transporters that mediate uptake of the proteolytic products into cell. The growth defect of gln3D gat1D mutants was mainly caused by their inability to express the SAP2 gene, as SAP2 expression from the constitutive ADH1 promoter restored the ability of the mutants to grow on BSA. Expression of STP1, which encodes a transcription factor that is required for SAP2 induction in the presence of proteins, was regulated by Gln3p and Gat1p. Forced expression of STP1 from a tetracycline-inducible promoter bypassed the requirement of the GATA transcription factors for growth of C. albicans on proteins. When preferred nitrogen sources are available, SAP2 is repressed and this nitrogen catabolite repression of SAP2 was correlated with downregulation of STP1 under these conditions. Tetracycline-induced STP1 expression abolished nitrogen catabolite repression of SAP2, demonstrating that regulation of STP1 expression levels by the GATA transcription factors is a key aspect of both positive and negative regulation of SAP2 expression. Therefore, by using a regulatory cascade in which expression of the specific transcription factor Stp1p is controlled by the general regulators Gln3p and Gat1p, C. albicans places SAP2 expression under nitrogen control and ensures proper expression of this virulence determinant. In summary, the present study illustrated how GATA factors, Gln3p and Gat1p, play partially overlapping, but distinct roles, in mediating the appropriate responses of C. albicans to the availability of different nitrogen sources. These responses are also determinants of pathogenicity of the fungus. The relative contributions of Gln3p and Gat1p vary with their target genes and the availability of nitrogen source. Overall, these findings provide us with a better understanding of the molecular basis of some of the important processes that help in adaptation of C. albicans to various environmental conditions.
Ongoing research to fight cancer, one of the dominant diseases of the 21st century has led to big progress especially when it comes to understanding the tumor growth and metastasis. This includes the discovery of the molecular mechanisms of tumor vascularization, which is critically required for establishment of tumor metastasis.
Formation of new blood vessels is the first step in tumor vascularization. Therefore, understanding the molecular and cellular basis of tumor vascularization attracted a significant effort studying in biomedical research. The blood vessels for supplying tumor can be formed by sprouting from pre-existing vessels, a process called angiogenesis, or by vasculogenesis, that is de novo formation of blood vessels from not fully differentiated progenitor cell populations. Vasculogenic endothelial progenitor cells (EPCs) can either be activated from populations in the bone marrow reaching the pathological region via the circulation or they can be recruited from local reservoirs. Neovessel formation influences tumor progression, hence therapeutic response model systems of angiogenesis/vasculogenesis are necessary to study the underlying mechanisms. Although, initially the research in this area focused more on angiogenesis, it is now well understood that both angiogenesis and postnatal vasculogenesis contribute to neovessel formation in adult under both most pathological as well as physiological conditions. Studies in the last two decades demonstrate that in addition to the intimal layer of fully differentiated mature endothelial cells (ECs) and various smaller supplying vessels (vasa vasorum) that can serve as a source for new vessels by angiogenesis, especially the adventitia of large and medium size blood vessels harbors various vascular wall-resident stem and progenitor cells (VW-SPCs) populations that serve as a source for new vessels by postnatal vasculogenesis. However, little is known about the potential role of VW-SPCs in tumor vascularization.
To this end, the present work started first to establish a modified aortic ring assay (ARA) using mouse aorta in order to study the contribution of vascular adventitia-resident VW-SPCs to neovascularization in general and in presence of tumor cells. ARA is already established an ex vivo model for neovascularization allows to study the morphogenetic events of complex new vessel formation that includes all layers of mature blood vessels, a significant advantage over the assays that employ monolayer endothelial cell cultures. Moreover, in contrast to assays employing endothelial cells monocultures, both angiogenic and vasculogenic events take place during new vessel formation in ARA although the exact contribution of these two processes to new vessel formation cannot be easily distinguished in conventional ARA. Thus, in this study, a modified protocol for the ARA (mdARA) was established by either removing or keeping the aortic adventitia in place. The mdARA allows to distinguish the role of VW-SPCs from those of other aortic layers. The present data show that angiogenic sprouting from mature aortic endothelium was markedly delayed when the adventitial layer was removed. Furthermore, the network between the capillary-like sprouts was significantly reduced in absence of aortic adventitia. Moreover, the stabilization of new sprouts by assembling the NG2+ pericyte-like cells that enwrapped the endothelial sprouts from the outside was improved when the adventitial layer remained in place.
Next, mimicking the tumor-vessel adventitia-interaction, multicellular tumor spheroids (MCTS) and aortic rings (ARs) with or without adventitia of C57BL/6-Tg (UBC-GFP) mice were confronted within the collagen gel and cultured ex vivo. This 3D model enabled analysis of the mobilization, migration and capillary-like sprouts formation by VW-SPCs within tumor-vessel wall-interface in comparison to tumor-free side of the ARs. Interestingly, while MCTS preferred the uptake of single vascular adventitia-derived cells, neural spheroids were directly penetrated by capillary-like structures that were sprouted from the aortic adventitia. In summary, the model established in this work allows to study new vessel formation by both postnatal vasculogenesis and angiogenesis under same conditions. It can be applied in various mouse models including reporter mouse models, e.g. Cxcr1 CreER+/mTmG+/- mice, in which GFP-marked macrophages of the vessel wall were directly observed as they mobilized from their niche and migrated into collagen gel. Another benefit of the model is that it can be used for testing different factors such as small molecules, growth factors, cytokines, and drugs with both pro- and anti-angiogenic/vasculogenic effects.
Sustained anxiety is considered as a chronic and future-oriented state of apprehension that does not belong to a specific object. It is discussed as an important characteristic of anxiety disorders including panic disorder, generalized anxiety disorder (GAD) and posttraumatic stress disorder (PTSD). Experimentally, sustained anxiety can be induced by contextual fear conditioning in which aversive events are unpredictably presented and therefore the whole context becomes associated with the threat. This thesis aimed at investigating important mechanisms in the development and maintenance of sustained anxiety: (1) facilitated acquisition and resistant extinction of contextual anxiety due to genetic risk factors (Study 1), and (2) the return of contextual anxiety after successful extinction using a new reinstatement paradigm (Study 2). To this end, two contextual fear conditioning studies were conducted in virtual reality (VR). During acquisition one virtual office was paired with unpredictable mildly painful electric stimuli (unconditioned stimulus, US), thus becoming the anxiety context (CXT+). Another virtual office was never paired with any US, thus becoming the safety context (CXT-). Extinction was conducted 24 h later, i.e. no US was presented, and extinction recall was tested another 24 h later on Day 3. In both studies context-evoked anxiety was measured on three different response levels: behavioral (anxiety-potentiated startle reflex), physiological (skin conductance level), and verbal (explicit ratings). In Study 1, participants were stratified for 5-HTTLPR (S+ risk allele vs. LL no risk allele) and NPSR1 rs324981 (T+ risk allele vs. AA no risk allele) polymorphisms, resulting in four combined genotype groups with 20 participants each: S+/T+, S+/LL, LL/T+, and LL/AA. Results showed that acquisition of anxiety-potentiated startle was influenced by a gene × gene interaction: only carriers of both risk alleles (S+ carriers of the 5-HTTLPR and T+ carriers of the NPSR1 polymorphism) exhibited significantly higher startle magnitudes in CXT+ compared to CXT-. However, extinction recall as measured with anxiety-potentiated startle was not affected by any genotype. Interestingly, the explicit anxiety level, i.e. valence and anxiety ratings, was only influenced by the NPSR1 genotype, in a way that no risk allele carriers (AA) reported higher anxiety and more negative valence in response to CXT+ compared to CXT-, whereas risk allele carriers (T+) did not. Study 2 adopted nearly the same paradigm with the modification that one group (reinstatement group) received one unsignaled US at the beginning of the experimental session on Day 3 before seeing CXT+ and CXT-. The second group served as a control group and received no US, but was immediately exposed to CXT+ and CXT-. Results showed a return of anxiety on the implicit and explicit level (higher startle responses and anxiety ratings in response to CXT+ compared to CXT-) in the reinstatement group only. Most important, the return of contextual anxiety in the reinstatement group was associated with a change of state anxiety and mood from extinction to test, that is the more anxiety and negative mood participants experienced before the reinstatement procedure, the higher their return of anxiety was. In sum, results of Study 1 showed that facilitated contextual fear conditioning on an implicit behavioral level (startle response) could be regarded as an endophenotype for anxiety disorders, which can contribute to our understanding of the etiology of anxiety disorders. Results of Study 2 imply that anxiety and negative mood after extinction could be an important facilitator for the return of anxiety. Furthermore, the present VR-based contextual fear conditioning paradigm seems to be an ideal tool to experimentally study mechanisms underlying the acquisition and the return of anxiety. Future studies could investigate clinical samples and extend the VR paradigm to evolutionary-relevant contexts (e.g., heights, darkness, open spaces).
The probiotic Escherichia coli strain Nissle 1917 (EcN) is one of the few probiotics licensed as a medication in several countries. Best documented is its effectiveness in keeping patients suffering from ulcerative colitis (UC) in remission. This might be due to its ability to induce the production of human beta defensin 2 (HBD2) in a flagellin-dependent way in intestinal epithelial cells. In contrast to ulcerative colitis, for Crohn´s disease (CD) convincing evidence is lacking that EcN might be clinically effective, most likely due to the genetically based inability of sufficient defensin production in CD patients. As a first step in the development of an alternative approach for the treatment of CD patients, EcN strains were constructed which were able to produce human alpha-defensin 5 (HD5) or beta-defensin 2 (HBD2). For that purpose codon-optimized defensin genes encoding either the proform with the signal sequence or the mature form of human alpha defensin 5 (HD5) or the gene encoding HBD2 with or without the signal sequence were cloned in an expression vector plasmid under the control of the T7 promoter. Synthesis of the encoded defensins was shown by Western blots after induction of expression and lysis of the recombinant EcN strains. Recombinant mature HBD2 with an N-terminal His-tag could be purified by Ni-column chromatography and showed antimicrobial activity against E. coli, Salmonella enterica serovar Typhimurium and Listeria monocytogenes. In a second approach, that part of the HBD2-gene which encodes mature HBD2 was fused with yebF gene. The resulting fusion protein YebFMHBD2 was secreted from the encoding EcN mutant strain after induction of expression. Presence of YebFMHBD2 in the medium was not the result of leakage from the bacterial cells, as demonstrated in the spent culture supernatant by Western blots specific for ß-galactosidase and maltose-binding protein. The dialyzed and concentrated culture supernatant inhibited the growth of E. coli, Salmonella enterica serovar Typhimurium and Listeria monocytogenes in radial diffusion assays as well as in liquid coculture. This demonstrates EcN to be a suitable probiotic E. coli strain for the production of certain defensins.
Adrenal Cushing’s Syndrome (CS) is a rare but life-threatening disease and therefore it is of great importance to understand the pathogenesis leading to adrenal CS. It is well accepted that Protein Kinase A (PKA) signalling mediates steroid secretion in adrenocortical cells. PKA is an inactive heterotetramer, consisting of two catalytic and two regulatory subunits. Upon cAMP binding to the regulatory subunits, the catalytic subunits are released and are able to phosphorylate their target proteins. Recently, activating somatic mutations affecting the catalytic subunit a of PKA have been identified in a sub-population of cortisol-producing adenomas (CPAs) associated with overt CS. Interestingly, the PKA regulatory subunit IIb has long been known to have significantly lower protein levels in a sub-group of CPAs compared to other adrenocortical tumours. Yet, it is unknown, why these CPAs lack the regulatory subunit IIb, neither are any functional consequences nor are the underlying regulation mechanisms leading to reduced RIIb levels known. The results obtained in this thesis show a clear connection between Ca mutations and reduced RIIb protein levels in CPAs but not in other adrenocortical tumours. Furthermore, a specific pattern of PKA subunit expression in the different zones of the normal adrenal gland is demonstrated. In addition, a Ca L206R mutation-mediated degradation of RIIb was observed in adrenocortical cells in vitro. RIIb degradation was found to be mediated by caspases and by performing mutagenesis experiments of the regulatory subunits IIb and Ia, S114 phosphorylation of RIIb was identified to make RIIb susceptible for degradation. LC-MS/MS revealed RIIb interaction partners to differ in the presence of either Ca WT and Ca L206R. These newly identified interaction partners are possibly involved in targeting RIIb to subcellular compartments or bringing it into spatial proximity of degrading enzymes. Furthermore, reducing RIIb protein levels in an in vitro system were shown to correlate with increased cortisol secretion also in the absence of PRKACA mutations. The inhibiting role of RIIb in cortisol secretion demonstrates a new function of this regulatory PKA subunit, improving the understanding of the complex regulation of PKA as key regulator in many cells.
Complementation of a bimolecular Antibody-Derivative within the context of the Immunological Synapse
(2021)
Cancer is a disease of uncontrolled cell proliferation and migration. Downregulation of antigen-presenting major histocompatibility complex (MHC) and co-stimulatory molecules are two of the most commonly used pathways by cancer cells to escape from immune surveillance. Therefore, many approaches have been developed for restoring the immune surveillance in cancer patients. One approach is to redirect the patient’s own T cells for tumor cell destruction. For T cell function it is important to induce a durable and robust cytotoxic response against target cells and to generate memory T cells, after MHC-mediated recognition of foreign intracellular antigens presented on the surface of antigen presenting cells (APC). Because of these cytotoxic properties, T cell mediated immunotherapy has been established as an effective and durable anti-neoplastic treatment. Different T cell mediated therapies for cancer treatment exist. One of them is using bispecific antibody fragments, so called bi-sepcific T cell engagers (BiTEs), for retargeting of T cells against single antigen positive tumor cells. The BiTE antibodies have two antigen binding domains, one against a target on the target cell, the second against CD3 on the T cells, facilitating cell-to-cell interactions. However, suitable single tumor antigens are limited, which restricts this approach to very few tumor types. To overcome this limitation, we have developed T cell-engaging antibody derivatives, termed hemibodies. Hemibodies exist as two complementary polypeptide chains. Each consists of two specific domains. On one end there is a single-chain variable fragment (scFv) against a target protein and on the other end there is either the heavy chain variable domain (VH) or light chain variable domain (VL) of an anti-CD3 binding antibody. Only when both hemibodies bind their respective antigens on the same tumor cell, the complementary anti CD3 VH and VL domains become aligned and reconstitute the functional CD3 binding-domain to engage T cells.
For targeting malignant cells of hematopoietic origin, we used hemibodies against CD45 and HLA-A2. They were expressed in CHO cells, then purified via Strep-tag. To get more insight into the hemibody mechanism of T cell mediated target cell killing, we analyzed the biochemical and functional properties of hemibodies in more detail.
Our main finding indicates that VLαCD3-scFvαHLA-A2 and VHαCD3-scFvαCD45 hemibodies induce an atypical immunological synapse characterized by a co-localization of HLA-A2 and CD45 out of the target cell -T cell interface. Nevertheless, hemibodies induce a high caspase activity in target cells in a concentration-dependent manner at nanomolar concentrations in vitro. Looking at ZAP70, which is usually recruited from the cytoplasm to the CD3 receptor in the middle of the cell-cell interface, we were able to detect activated ZAP70 outside of the cell-cell interface in the presence of hemibodies. In contrast cells treated with BiTEs show a central recruitment in the cell-cell interface as expected.
We looked also at the interaction of hemibodies with soluble recombinant CD3 epsilon/gamma protein in the absence of target cells. The binding could be measured only at very high concentration out of the therapeutic window.
This work contributes to the mechanistic understanding, which underlies the hemibody technology as a new dual antigen restricted T cell-mediated immunotherapy of cancer.
Comparative transcriptomics and post-transcriptional regulation in \(Campylobacter\) \(jejuni\)
(2016)
The transcriptome is defined as the set of all RNA molecules transcribed in a cell. These include protein-coding messenger RNAs (mRNAs) as well as non-coding RNAs, such as ribosomal RNAs (rRNAs), transfer RNAs (tRNAs), and small non-coding RNAs (sRNAs). sRNAs are known to play an important role in regulating gene expression and virulence in pathogens. In this thesis, the transcriptome of the food-borne pathogen Campylobacter jejuni was characterized at single nucleotide resolution by use of next-generation sequencing approaches. The first genome of a C. jejuni strain was published in the year 2000. However, its transcriptome remained uncharacterized at large.
C. jejuni can survive in a variety of ecological niches and hosts. However, how strain-specific transcriptional changes contribute to such adaptation is not known. In this study, the global transcriptome maps of four closely related C. jejuni strains were defined using a differential RNA-seq (dRNA-seq) approach. This analysis also included a novel automated method to annotate the transcriptional start sites (TSS) at a genome-wide scale. Next, the transcriptomes of four strains were simultaneously mapped and compared by the use of a common coordinate system derived from whole-genome alignment, termed as SuperGenome. This approach helped to refine the promoter maps by comparison of TSS within strains. Most of the TSS were found to be conserved among all four strains, but some single-nucleotide-polymorphisms (SNPs) around promoter regions led to strain-specific transcriptional output. Most of these SNPs altered transcription only slightly, but some others led to a complete abrogation of transcription leading to differential molecular phenotypes. These in turn might help the strains to adapt to their specific host or microniche. The transcriptome also unveiled a plethora of sRNAs, some of which were conserved among the four strains while others were strain specific. Furthermore, a Cas9-dependent minimal type-II CRISPR-Cas system with only three Cas genes and multiple promoters to drive the transcription of the CRISPR locus was also characterized in C. jejuni using the dRNA-seq dataset.
Apart from sRNAs, the role of global RNA binding proteins (RBPs) is also unclear in C. jejuni. Aided by the global transcriptome data, the role of RBPs in post-transcriptional regulation of C. jejuni was studied at a global scale. Two of the most widely studied RNA binding proteins in bacteria are Hfq and CsrA. The RNA interactome of the translational regulator CsrA was defined using another global deep-sequencing technique that combines co-immunoprecipitation (coIP) with RNA sequencing (RIP-seq). Using this interactome dataset, the direct targets of this widespread global post-transcriptional regulator were defined, revealing a significant enrichment for mRNAs encoding genes involved in flagella biosynthesis. Unlike Gammaproteobacteria, where sRNAs such as CsrB/C, antagonize CsrA activity, no sRNAs were enriched in the CsrA-coIP in C. jejuni, indicating absence of any sRNA antagonists and novel modes of CsrA activity regulation. Instead, the CsrA regulatory pathway revealed flaA mRNA, encoding the major flagellin, as a dual-function mRNA. flaA mRNA was the main target of CsrA but it also served to antagonize CsrA activity along with the protein antagonist FliW previously identified in the Gram-positive bacterium Bacillus subtilis. Furthermore, this regulatory mRNA was also shown in this thesis to localize to the poles of elongating C. jejuni cells in a translation-dependent manner. It was also shown that this localization is dependent on the CsrA-FliW regulon, which controls the translation of flaA mRNA. The role and mechanism of flaA mRNA localization or mRNA localization in general is not yet clear in bacteria when compared to their eukaryotic counterparts.
Overall, this study provides first insights into riboregulation of the bacterial pathogen C. jejuni. The work presented in this thesis unveils several novel modes of riboregulation in C. jejuni, which could be applicable more generally. Moreover, this study also lays out several unsolved intriguing questions, which may pave the way for interesting studies to come.
The plant cuticle is a continuous extracellular protective layer covering the outermost surfaces of higher plants that are in contact with the surrounding atmosphere. The primary function of the cuticular lipid membrane, which is mainly composed of biopolymer cutin and cuticular waxes, is to protect the plant organs against uncontrolled water loss. The chemical composition and the biophysical properties of cuticular waxes affect the rate of water diffusion across the cuticle. Fruit transpiration plays an important role in the development and the maintenance of fruit quality. The fruit has been suggested to present better dehydration stress tolerance than the leaf. However, the differences in transpiration and the chemical composition of cuticular waxes between fruit and leaf have yet to be comprehensively investigated.
The present study aims to investigate the water permeability and cuticular wax composition of fruit and leaf cuticles of a wide range of plant species and to elucidate the different roles of the cuticular wax components in the transpiration barrier. To address these objectives, fruit and leaf samples from 17 species were investigated. The cuticular transpiration of intact fruits and astomatous adaxial leaf surfaces and the minimum leaf conductance obtained by leaf drying curves for intact leaves were gravimetrically determined for a variety of plant species. The chemical composition of cuticular waxes of fruits and leaves was thoroughly analysed by gas chromatography with flame ionization and mass spectrometry.
The water permeability of fruits ranged from 3.7 x 10-5 m s-1 (Prunus domestica subsp. syriaca) to 37.4 x 10-5 m s-1 (Coffea arabica), whereas permeability for leaves varied between 1.6 x 10-5 m s-1 (Cornus officinalis) and 4.5 x 10-5 m s-1 (Prunus domestica subsp. syriaca (L.)). The interspecies range of water permeability of fruits was significantly higher than that of leaves. Chemical analyses of the cuticular waxes demonstrated that fatty acids, primary alcohols, n-alkanes, aldehydes and alkyl esters were the predominant very-long-chain aliphatic compound classes of fruit and leaf surfaces. Sterols, such as β-sitosterol and campesterol, and triterpenoids, such as oleanolic acid, ursolic acid, α-amyrin and ß-amyrin, were the major cyclic compound classes in the cuticular wax membrane.
The amount and composition of cuticular waxes of both fruits and leaves varied at an intraspecific level. There were no significant correlations between the total cuticular wax load or the individual cuticular wax composition and the water permeability of fruits or leaves independently or together. After combining the fruit and leaf data set, a significant correlation between the average chain length of very-long-chain aliphatic compounds and permeabilities was detected, i.e. the longer the average chain length, the lower the water permeability.
Interestingly, n-Nonacosane (C29) was abundantly detected in fruit waxes of Rosaceae species. These fruits exhibited a relatively low transpiration level, which was very close to their leaf cuticular permeability. The present study suggests that the lower cuticular permeability of leaves, in comparison to that of fruits, may be attributed to the longer average chain length of aliphatic compounds. The accumulation of total wax, triterpenoids and aliphatic compounds may not contribute to the transpiration barrier directly. The present results are highly consistent with the previous model assumptions for the cuticular structure and transport barrier. Furthermore, this comparative study on leaf and fruit cuticles provides further insights linking the cuticular wax chemistry to the physiological properties of the plant cuticle.