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Role of Hypoxia-Inducible Factor (HIF) 1α in Dendritic Cells in Immune Regulation of Atherosclerosis
(2013)
Atherosclerosis is the underlying cause of cardiovascular diseases and a major threat to human health worldwide. It involves not only accumulation of lipids in the vessel wall but a chronic inflammatory response mediated by highly specific cellular and molecular responses. Macrophages and dendritic cells (DCs) play an essential role in taking up modified lipids and presenting them to T and B lymphocytes, which promote the immune response. Enhanced activation, migration and accumulation of inflammatory cells at the local site leads to formation of atherosclerotic plaques.
Atherosclerotic plaques become hypoxic due to reduced oxygen diffusion and high metabolic demand of accumulated cells. The various immune cells experience hypoxic conditions locally and inflammatory stimuli systemically, thus up-regulating Hypoxia-inducible factor 1α. Though the role of HIF1α in macrophages and lymphocytes has been elucidated, its role in DCs still remains controversial, especially with respect to atherosclerosis. In this project work, the role of HIF1α in DCs was investigated by using a cell specific knockout mouse model where HIF1α was deleted in CD11c+ cells.
Aortic root sections from atherosclerotic mice showed presence of hypoxia and up-regulation of HIF1α which co-localized with CD11c+ cells. Atherosclerotic splenic DCs also displayed enhanced expression of HIF1α, proving non-hypoxic stimulation of HIF1α due to systemic inflammation. Conditional knockout (CKO) mice lacking HIF1α in CD11c+ cells, under baseline conditions did not show changes in immune responses suggesting effects of HIF1α only under inflammatory conditions. When these mice were crossed to the Ldlr-/- line and placed on 8 weeks of high fat diet, they developed enhanced plaques with higher T-cell infiltration as compared to the wild-type (WT) controls. The plaques were of a complex phenotype, defined by increased percent of smooth muscle cells (SMCs) and necrotic core area and reduced percent of macrophages and DCs. The mice also displayed enhanced T-cell activation and a Th1 bias in the periphery.
The CKO DCs themselves exhibited increased expression of IL 12 and a higher capacity to proliferate and polarize naive T cells to the Th1 phenotype in vitro. The DCs also showed decreased expression of STAT3, in line with the inhibitory effects of STAT3 on DC activation seen in previous studies. When STAT3 was overexpressed in DCs in vitro, IL 12 was down-regulated, but its expression increased significantly on STAT3 inhibition using a mutant vector. In addition, when STAT3 was overexpressed in DCs in vivo using a Cre regulated lentiviral system, the mice showed decreased plaque formation compared to controls. Interestingly, the effects of STAT3 modulation were similar in WT and CKO mice, intending that STAT3 lies downstream of HIF1α. Finally, using a chromatin immunoprecipitation assay (ChIP), it was confirmed that HIF1α binds to hypoxia responsive elements (HREs) in the Stat3 gene promoter thus regulating its expression. When DCs lack HIF1α, STAT3 expression is not stimulated and hence IL 12 production by DCs is uninhibited. This excessive IL 12 can activate naive T cells and polarize them to the Th1 phenotype, thereby enhancing atherosclerotic plaque progression.
This project thus concludes that HIF1α restrains DC activation via STAT3 generation and prevents excessive production of IL 12 that helps to keep inflammation and atherosclerosis under check.
The present work illustrates the structural and biochemical characterization of two diverse proteins, BadI and MenD from Rhodopseudomonas palustris and Staphylococcus aureus, respectively.
BadI or 2-ketocyclohexanecarboxyl-CoA is one of the key enzymes involved in the anaerobic degradation of aromatic compounds. The degradation of aromatic compounds is a vital process for the maintenance of the biogeochemical carbon cycle and bioremediation of xenobiotic compounds, which if present at higher concentrations can cause potential hazards to humans. Due to the relatively inert nature of aromatic compounds, enzymes catalyzing their degradation are of special interest for industrial applications. BadI is one of the key enzymes involved in the anaerobic degradation of aromatic compounds into an aliphatic moiety.
The major focus of this study was to provide mechanistic insights into the reaction catalyzed by BadI. BadI belongs to the crotonase superfamily and shares high sequence homology with the family members of MenB or dihydroxynaphthoate synthase. BadI is known to catalyze the cleavage of the cyclic ring of 2-ketocyclohexane carboxyl-CoA by hydrolyzing the C-C bond leading to the formation of the aliphatic compound pimelyl CoA. On the other hand MenB catalyzes the condensation reaction of o-succinylbenzoyl-CoA to dihydroxylnaphthoyl-CoA. A comprehensive amino acid sequence analysis between BadI and MenB showed that the active site residues of MenB from Mycobacterium tuberculosis (mtMenB) are conserved in BadI from Rhodopseudomonas palustris. MenB is involved in the menaquinone biosynthesis pathway and is a potential drug target against Mycobacterium tuberculosis as it has no known human homologs. Due to the high homology between MenB and BadI and the inability to obtain MenB-inhibitor complex structures we extended our interest to BadI to explore a potential substitute model for mtMenB as a drug target.
In addition, BadI possesses some unique mechanistic characteristics. As mentioned before, it hydrolyzes the substrate via a retro Dieckmann’s reaction contrasting its closest homolog MenB that catalyzes a ring closing reaction through a Dieckmann’s reaction. Nevertheless the active site residues in both enzymes seem to be highly conserved. We therefore decided to pursue the structural characterization of BadI to shed light on the similarities and differences between BadI and MenB and thereby provide some insights how they accomplish the contrasting reactions described above.
We determined the first structures of BadI, in its apo and a substrate mimic bound form. The crystal structures revealed that the overall fold of BadI is similar to other crotonase superfamily members. However, there is no indication of domain swapping in BadI as observed for MenB. The absence of domain swapping is quite remarkable because the domain swapped C-terminal helical domain in MenB provides a tyrosine that is imperative for catalysis and is also conserved in the BadI sequence. Comparison of the active sites revealed that the C-terminus of BadI folds onto its core in such a way that the conserved tyrosine is located in the same position as in MenB and can form interactions with the ligand molecule. The structure of BadI also confirms the role of a serine and an aspartate in ligand interaction, thus validating that the conserved active site triad participates in the enzymatic reaction. The structures also reveal a noteworthy movement of the active site aspartate that adopts two major conformations. Structural studies further illuminated close proximity of the active site serine to a water and chlorine molecule and to the carbon atom at which the carbonyl group of the true substrate would reside. Biochemical characterization of BadI using enzyme kinetics validated that the suggested active site residues are involved in substrate interaction. However, the role of these residues is very distinct, with the serine assuming a major role. Thus, the present work ascertain the participation of putative active site residues and demonstrates that the active site residues of BadI adopt very distinctive roles compared to their closest homolog MenB.
The MenD protein also referred to as SEPHCHC (2-succinyl-5-enolpyruvyl-6- hydroxy-3-cyclohexene-1-carboxylic acid) synthase is one of the enzymes involved in menaquinone biosynthesis in Staphylococcous aureus. Though S. aureus is usually considered as a commensal it can act as a remarkable pathogen when it crosses the epithelium, causing a wide spectrum of disorders ranging from skin infection to life threatening diseases. Small colony variants (SCVs), a slow growing, small sized subpopulation of the bacteria has been associated with persistent, recurrent and antibiotic resistant infections. These variants show autotrophy for thiamine, menaquinone or hemin. Menaquinone is an essential component in the electron transport pathway in gram-positive organisms. Therefore, enzymes partaking in this pathway are attractive drug targets against pathogens such as Mycobacterium tuberculosis and Bacillus subtilis. MenD, an enzyme catalyzing the first irreversible step in the menaquinone biosynthetic pathway has been implicated in the SCV phenotype of S. aureus. In the present work we explored biochemical and structural properties of this important enzyme.
Our structural analysis revealed that despite its low sequence identity of 28%, the overall fold of staphylococcal MenD (saMenD) is similar to Escherichia coli MenD (ecMenD) albeit with some significant disparities. Major structural differences can be observed near the active site region of the protein and are profound in the C-terminal helix and a loop near the active site. The loop contains critical residues for cofactor binding and is well ordered only in the ecMenD-ThDP structure, while in the apo and substrate bound structures of ecMenD the loop is primarily disordered. In our saMenD structure the loop is for the first time completely ordered in the apo form and displays a novel conformation of the cofactor-binding loop. The loop adopts an unusual open conformation and the conserved residues, which are responsible for cofactor binding are located too far away to form a productive complex with the cofactor in this conformation. Additionally, biochemical studies in conjugation with the structural data aided in the identification of the substrate-binding pocket and delineated residues contributing to its binding and catalysis. Thus the present work successfully divulged the unique biochemical and structural characteristics of saMenD.
An essential step in eukaryotic gene expression is splicing, i.e. the excision of non-coding sequences from pre-mRNA and the ligation of coding-sequences. This reaction is carried out by the spliceosome, which is a macromolecular machine composed of small nuclear ribonucleoproteins (snRNPs) and a large number of proteins. Spliceosomal snRNPs are composed of one snRNA (or two in case of U4/6 snRNPs), seven common Sm proteins (SmD1, D2, D3, B, E, F, G) and several particle-specific proteins. The seven Sm proteins form a ring shaped structure on the snRNA, termed Sm core domain that forms a structural framework of all spliceosomal snRNPs. In the toroidal Sm core domain, the individual Sm proteins are arranged in the sequence SmE-SmG-SmD3-SmB- SmD1-SmD2-SmF from the first to the seventh nucleotide of the Sm site, respectively. The individual positions of Sm proteins in the Sm core domain are not interchangeable.
snRNPs are formed in vivo in a step-wise process, which starts with the export of newly transcribed snRNA to the cytoplasm. Within this compartment, Sm proteins are synthesized and subsequently transferred onto the snRNA. Upon formation of the Sm core and further modifications of snRNA, the snRNP is imported into the nucleus to join the spliceosome.
Prior to assembly into snRNPs, Sm proteins exist as specific hetero-oligomers in the cytoplasm. The association of these proteins with snRNA occurs spontaneously in vitro but requires the assistance of two major units, PRMT5- and SMN- complexes, in vivo. The early phase of assembly is critically influenced by the assembly chaperone pICln. This protein pre-organizes Sm proteins to functional building blocks and enables their recruitment onto the PRMT5 complex for methylation. Sm proteins are subsequently released from the PRMT5 complex as pICln bound entities and transferred onto the SMN-complex. The SMN complex then liberates the Sm proteins from the pICln-induced kinetic trap and allows their transfer onto the snRNA. Although the principal roles of SMN- and PRMT5 complexes in the assembly of snRNPs have been established, it is still not clear how newly translated Sm proteins are guided into the assembly line.
In this thesis, I have uncovered a new facet of pICln function in the assembly of snRNPs. I have shown that newly synthesized Sm proteins are retained at the ribosome upon termination of translation. Their release is facilitated by pICln, which interacts with the cognate Sm protein hetero-oligomers at their site of synthesis on the ribosome and recruits them into the assembly pathway. Additionally, I have been able to show that the early engagement of pICln with the Sm proteins ensures the flawless oligomerization of Sm proteins and prevents any non-chaperoned release and diffusion of Sm proteins in the cytoplasm.
In a second project, I have studied the mechanism of U7 snRNP assembly. This particle is a major component of the 3’ end processing machinery of replication dependent histone mRNAs. A biochemical hallmark of U7 is its unique Sm core in which the two canonical Sm proteins D1 and D2 are replaced by so-called “like Sm proteins”. The key question I addressed in my thesis was, how this “alternative” Sm core is assembled onto U7 snRNA. I have provided experimental evidence that the assembly route of U7 snRNPs and spliceosomal snRNPs are remarkably similar: The assembly of both particles depends on the same assembly factors and the mechanistic details are similar. It appears that formation of the U7- or spliceosomal- core specific 6S complex is the decisive step in assembly.
Whereas most currently used antibiotics act by interfering with essential bacterial processes, a smaller group of antibacterials disturbs the integrity of the cell membrane. Since fatty acids are a vital component of membrane phospholipids, the type-II fatty acid biosynthesis pathway (FAS-II) of bacteria constitutes a promising drug target. The front-line anti-tuberculosis prodrug isoniazid blocks the FAS-II pathway in M. tuberculosis thereby leading to morphological changes and finally to cell lysis. When it became evident that the enoyl-ACP reductase in the FAS-II pathway is the target of the activated isoniazid, several programs were initiated to develop novel inhibitors directed against this protein in different pathogens. The S. aureus enoyl-ACP reductase (saFabI) is of particular interest since three promising drug candidates inhibiting this homologue have reached clinical trials. However, despite these prospects, no crystal structures of saFabI were publicly available at the time the present work was initiated. Thus, one major goal of this thesis was the generation of high-resolution atomic models by means of X-ray crystallography. The development of a highly reproducible approach to co-crystallize saFabI in complex with NADP+ and diphenyl ether-based inhibitors led to crystal structures of 17 different ternary complexes. Additional crystallographic experiments permitted the view into two apo-structures and two atomic models of saFabI in complex with NADPH and 2-pyridone inhibitors. Based on the established saFabI structure, molecular dynamics (MD) simulations were performed to improve our understanding of the conformational mobility of this protein. Taken together, these investigations of the saFabI structure and its flexibility served as an ideal platform to address important questions surrounding substrate and inhibitor recognition by this enzyme. Intriguingly, our saFabI structures provide several vastly different snapshots along the reaction coordinate of ligand binding and hydride transfer, including the closure of the flexible substrate binding loop (SBL). The extraordinary mobility of saFabI was confirmed by MD simulations suggesting that conformational motions indeed play a pivotal role during substrate delivery and turnover. A water chain linking the active site with a water-basin inside the homo-tetrameric enzyme was found likely to be crucial for the closure and opening of the SBL and, thus, for the catalyzed reaction. Notably, the induced-fit ligand binding process involves a dimer-tetramer transition, which could be related to the observed positive cooperativity of cofactor and substrate binding. Overall, saFabI displays several unique characteristics compared to FabI proteins from other organisms that might be necessary for the synthesis of branched-chain fatty acids, which in turn are required for S. aureus fitness in vivo. This finding may explain why S. aureus is sensitive to FAS-II inhibitors even in the presence of exogenous fatty acids. Accordingly, saFabI remains a valid drug target and our structures can be used as a molecular basis for rational drug design efforts. In fact, binding affinity trends of diphenyl ether inhibitors and, more importantly, the correlated residence times could be rationalized at the molecular level. Furthermore, the structure of saFabI in complex with the 2-pyridone inhibitor CG400549 revealed unique interactions in the wider binding crevice of saFabI compared to other FabI homologues explaining the narrow activity spectrum of this clinical candidate with proven human efficacy. In summary, these studies provide an ideal platform for the development of new, effective saFabI inhibitors as exemplified by the promising 4-pyridone PT166. In the context of this dissertation, crystal structures of the condensing enzyme KasA in complex with several analogs of the naturally occurring inhibitor thiolactomycin have been solved.
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).
Atherosclerosis is accepted to be a chronic inflammatory disease of the arterial vessel wall. Several cellular subsets of the immune system are involved in its initiation and progression, such as monocytes, macrophages, T and B cells. Recent research has demonstrated that dendritic cells (DCs) contribute to atherosclerosis, too. DCs are defined by their ability to sense and phagocyte antigens, to migrate and to prime other immune cells, such as T cells. Although all DCs share these functional characteristics, they are heterogeneous with respect to phenotype and origin. Several markers have been used to describe DCs in different lymphoid and non-lymphoid organs; however, none of them has proven to be unambiguous. The expression of surface molecules is highly variable depending on the state of activation and the surrounding tissue. Furthermore, DCs in the aorta or the atherosclerotic plaque can be derived from designated precursor cells or from monocytes. In addition, DCs share both their marker expression and their functional characteristics with other myeloid cells like monocytes and macrophages. The repertoire of aortic DCs in healthy and atherosclerotic mice has just recently started to be explored, but yet there is no systemic study available, which describes the aortic DC compartment. Because it is conceivable that distinct aortic DC subsets exert dedicated functions, a detailed description of vascular DCs is required. The first part of this thesis characterizes DC subsets in healthy and atherosclerotic mice. It describes a previously unrecognized DC subset and also sheds light on the origin of vascular DCs. In recent years, microRNAs (miRNAs) have been demonstrated to regulate several cellular functions, such as apoptosis, differentiation, development or proliferation. Although several cell types have been characterized extensively with regard to the miRNAs involved in their regulation, only few studies are available that focus on the role of miRNAs in DCs. Because an improved understanding of the regulation of DC functions would allow for new therapeutic options, research on miRNAs in DCs is required. The second part of this thesis focuses on the role of the miRNA cluster miR- 17~92 in DCs by exploring its functions in healthy and atherosclerotic mice. This thesis clearly demonstrates for the first time an anti-inflammatory and atheroprotective role for the miR17-92 cluster. A model for its mechanism is suggested.
Background: Nicotine addiction is the most prevalent type of drug addiction that has been described as a cycle of spiraling dysregulation of the brain reward systems. Imaging studies have shown that nicotine addiction is associated with abnormal function in prefrontal brain regions that are important for cognitive emotion regulation. It was assumed that addicts may perform less well than healthy nonsmokers in cognitive emotion regulation tasks. The primary aims of this thesis were to investigate emotional responses to natural rewards among smokers and nonsmokers and to determine whether smokers differ from nonsmokers in cognitive regulation of positive and negative emotions. To address these aims, two forms of appraisal paradigms (i.e., appraisal frame and reappraisal) were applied to compare changes in emotional responses of smokers with that of nonsmokers as a function of appraisal strategies. Experiment 1: The aim of the first experiment was to evaluate whether and how appraisal frames preceding positive and negative picture stimuli affect emotional experience and facial expression of individuals. Twenty participants were exposed to 125 pairs of auditory appraisal frames (either neutral or emotional) followed by picture stimuli reflecting five conditions: unpleasant-negative, unpleasant-neutral, pleasant-positive, pleasant-neutral and neutral-neutral. Ratings of valence and arousal as well as facial EMG activity over the corrugator supercilii and the zygomaticus major were measured simultaneously. The results indicated that appraisal frames could alter both subjective emotional experience and facial expressions, irrespective of the valence of the pictorial stimuli. These results suggest and support that appraisal frame is an efficient paradigm in regulation of multi-level emotional responses. 8 Experiment 2: The second experiment applied the appraisal frame paradigm to investigate how smokers differ from nonsmokers on cognitive emotion regulation. Sixty participants (22 nonsmokers, 19 nondeprived smokers and 19 12-h deprived smokers) completed emotion regulation tasks as described in Experiment 1 while emotional responses were concurrently recorded as reflected by self-ratings and psychophysiological measures (i.e., facial EMG and EEG). The results indicated that there was no group difference on emotional responses to natural rewards. Moreover, nondeprived smokers and deprived smokers performed as well as nonsmokers on the emotion regulation task. The lack of group differences in multiple emotional responses (i.e., self-reports, facial EMG activity and brain EEG activity) suggests that nicotine addicts have no deficit in cognitive emotion regulation of natural rewards via appraisal frames. Experiment 3: The third experiment aimed to further evaluate smokers’ emotion regulation ability by comparing performances of smokers and nonsmokers in a more challenging cognitive task (i.e., reappraisal task). Sixty-five participants (23 nonsmokers, 22 nondeprived smokers and 20 12-h deprived smokers) were instructed to regulate emotions by imagining that the depicted negative or positive scenario would become less negative or less positive over time, respectively. The results showed that nondeprived smokers and deprived smokers responded similarly to emotional pictures and performed as well as nonsmokers in down-regulating positive and negative emotions via the reappraisal strategy. These results indicated that nicotine addicts do not have deficit in emotion regulation using cognitive appraisal strategies. In sum, the three studies consistently revealed that addicted smokers were capable to regulate emotions via appraisal strategies. This thesis establishes the groundwork for therapeutic use of appraisal instructions to cope with potential self-regulation failures in nicotine addicts.
In acute graft-versus-host disease (GVHD) alloreactive donor T cells selectively damage skin, liver, and the gastrointestinal tract while other organs are rarely affected. The mechanism of this selective target tissue infiltration is not well understood. We investigated the importance of alloantigen expression for the selective organ manifestation by examining spatiotemporal changes of cellular and molecular events after allogeneic hematopoietic cell transplantation (allo-HCT). To accomplish this we established a novel multicolor light sheet fluorescence microscopy (LSFM) approach for deciphering immune processes in large tissue specimens on a single-cell level in 3 dimensions. We combined and optimized protocols for antibody penetration, tissue clearing, and triple-color illumination to create a method for analyzing intact mouse and human tissues. This approach allowed us to successfully quantify changes in expression patterns of mucosal vascular addressin cell adhesion molecule–1 (MAdCAM-1) and T cell responses in Peyer’s patches following allo-HCT. In addition, we proofed that LSFM is suitable to map individual T cell subsets after HCT and detected rare cellular events. We employed this versatile technique to study the role of alloantigen expression for the selective organ manifestation after allo-HCT. Therefore, we used a T cell receptor (TCR) transgenic mouse model of GVHD that targets a single peptide antigen and thereby mimics a major histocompatibility complex (MHC)-matched single antigen mismatched (miHAg-mismatched) HCT. We transplanted TCR transgenic (OT-I) T cells into myeloablatively conditioned hosts that either express the peptide antigen ovalbumin ubiquitously (βa-Ova) or selectively in the pancreas (RIP-mOva), an organ that is normally not affected by acute GVHD. Of note, at day+6 after HCT we observed that OT-I T cell infiltration occurred in an alloantigen dependent manner. In βa-Ova recipients, where antigen was ubiquitously expressed, OT-I T cells infiltrated all organs and were not restricted to gastrointestinal tract, liver, and skin. In RIP-mOva recipients, where cognate antigen was only expressed in the pancreas, OT-I T cells selectively infiltrated this organ that is usually spared in acute GVHD. In conditioned RIP-mOva the transfer of 100 OT-I T cells sufficed to effectively infiltrate and destroy pancreatic islets resulting in 100% mortality. By employing intact tissue LSFM in RIP-mOva recipients, we identified very low numbers of initial islet infiltrating T cells on day+4 after HCT followed by a massive T cell migration to the pancreas within the following 24 hours. This suggested an effective mechanism of effector T cell recruitment to the tissue of alloantigen expression after initial antigen specific T cell encounter. In chimeras that either expressed the model antigen ovalbumin selectively in hematopoietic or in parenchymal cells only, transplanted OT-I T cells infiltrated target tissues irrespective of which compartment expressed the alloantigen. As IFN-γ could be detected in the serum of transplanted ovalbumin expressing recipients (βa-Ova, βa-Ova-chimeras and RIP-mOva) at day+6 after HCT, we hypothesized that this cytokine may be functionally involved in antigen specific OT-I T cell mediated pathology. In vitro activated OT-I T cells responded with the production of IFN-γ upon antigen re-encounter suggesting that IFN-γ might be relevant in the alloantigen dependent organ infiltration of antigen specific CD8+ T cell infiltration after HCT. Based on these data we propose that alloantigen expression plays an important role in organ specific T cell infiltration during acute GVHD and that initial alloreactive T cells recognizing the cognate antigen propagate a vicious cycle of enhanced T cell recruitment that subsequently culminates in the exacerbation of tissue restricted GVHD.
Myocardial infarction (MI) is a leading cause of death worldwide. Timely restoration of coronary blood flow to ischemic myocardium significantly reduces acute infarct mortality and attenuates ventricular remodeling. However, surviving MI patients frequently develop heart failure, which is associated with reduced quality of life, high mortality rate (10% annually), as well as high healthcare expenditures. The main processes involved in the evolution of heart failure post-MI are the great loss of contractile cardiomyocytes during ischemia-reperfusion and the subsequent complex structural and functional alterations, which are rooted in modifications at molecular and cellular levels in both the infarcted and non-infarcted myocardium. However, we still lack efficient treatments to prevent the development and progression of left ventricular remodeling. The improved survival rate of acute MI patients combined with the lack of effective therapy for post-MI remodeling contributes to the high prevalence of heart failure. Cardiac Magnetic Resonance Imaging (MRI) is an important tool for diagnosis and assessment of MI. With the advancement of this technology, the frontier of MRI has been extended to probing molecular and cellular events in vivo and non-invasively. In combination with assessment of morphology and function, the visualization of essential molecular and cellular markers in vivo could provide comprehensive, multifaceted views of the healing process in infarcted hearts, which might give new insight for the treatment of acute MI. In this thesis, molecular and cellular cardiac MRI methods were established to visualize and investigate inflammation and calcium flux in the healing process of acute MI in vivo, in a clinically relevant rat model.
Platelet activation and aggregation at sites of vascular injury are essential processes to limit blood loss but they also contribute to arterial thrombosis, which can lead to myocardial infarction and stroke. Stable thrombus formation requires a series of events involving platelet receptors which contribute to adhesion, activation and aggregation of platelets. Regulation of receptor expression by (metallo-)proteinases has been described for several platelet receptors, but the molecular mechanisms are ill-defined. The signaling lymphocyte activation molecule (SLAM) family member CD84 is expressed in immune cells and platelets, however its role in platelet physiology was unclear. In this thesis, CD84 deficient mice were generated and analyzed. In well established in vitro and in vivo assays testing platelet function and thrombus formation, CD84 deficient mice displayed phenotypes indistinguishable from wild-type controls. It was concluded that CD84 in platelets does not function as modulator of thrombus formation, but rather has other functions. In line with this, in the second part of this thesis, a novel regulation mechanism for platelet CD84 was discovered and elucidated. Upon platelet activation, the N-terminus of CD84 was found to be cleaved exclusively by the a disintegrin and metalloproteinase 10 (ADAM10), whereas the intracellular part was cleaved by calpain. In addition, regulation of the platelet activating collagen receptor glycoprotein VI (GPVI) was studied and it was shown that GPVI is in contrast to CD84 differentially regulated by ADAM10 and ADAM17. A novel role of CD84 under pathophysiological conditions was revealed as CD84 deficient mice were protected from ischemic stroke in the model of transient middle cerebral artery occlusion and this protection was based on the lack of CD84 in T cells. Ca2+ is an essential second messenger that facilitates activation of platelets and diverse functions in different eukaryotic cell types. Store-operated Ca2+ entry (SOCE) represents the major mechanism leading to rise in intracellular Ca2+ concentration in non-excitable cells. The Ca2+ sensor STIM1 (stromal interaction molecule 1) and the SOC channel subunit protein Orai1 are established mediators of SOCE in platelets. STIM2 is the major STIM isoform in neurons, but the role of the SOC channel subunit protein Orai2 in platelets and neurons has remained elusive. In the third part of this thesis, Orai2 deficient mice were generated and analyzed. Orai2 was dispensable for platelet function, however, Orai2 deficient mice were protected from ischemic neurodegeneration and this phenotype was attributed to defective SOCE in neurons.