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Cross-striated muscles enable higher animals to perform directed movements and to create mechanical force. The cells of heart and skeletal muscles consist of myofibrils, serial arrays of the smallest contractile subunits, the sarcomeres. Main components of the sarcomeres are the thin and thick filaments, large protein assemblies consisting of mainly actin (thin filaments) and myosin (thick filaments), whose energy-dependent interaction is responsible for the contraction of sarcomeres and so of the whole muscle. The thin filaments are anchored in the sarcomere bordering Z-discs, while the thick filaments are anchored in the M-bands, traverse structures in the sarcomere center. Electron-microscopic studies revealed that the M-bands consist of regular, lattice-like structures that appear to cross-link the thick filaments. A number of proteins could be identified by immune-fluorescence and biochemical binding studies to be present and interact with each other in the M-bands. These data have been integrated into preliminary models of the M-bands. Detailed knowledge of how these proteins interact with each other in the center of the sarcomeres is, however, largely missing. The current study focuses on the structural characterization of the interactions between the titin, myomesin-1, obscurin and obscurin-like 1 (OBSL1), modular filamentous proteins interacting with each other in the M-bands. The high-resolution crystal structure of the titin M10 – OBSL1 Ig1 complex was solved. The structure and additional biophysical data show that titin and OBSL1 as well as titin and obscurin form stable binary complexes through the formation of a small intermolecular ß-sheet. In contrast to previously characterized intermolecular assemblies of sarcomeric proteins, this sheet is formed between parallel non- homologous ß-strands of the interaction partners. The investigation of disease-related variants of the M10 domain by biophysical methods did not allow to draw unambiguous conclusions on a direct connection between impaired OBSL1/obscurin binding and disease development. Two out of four known M10 variants have effects on the correct domain folding and so interfere with the ability to bind obscurin/OBSL1. The two other known variants displayed however only minor effects on fold and binding affinities. It should therefore be further elucidated whether a direct connection between impaired complex formation and disease development exists. -I- Abstract A direct interaction between titin and myomesin-1 could not be confirmed in vitro. Possible explanations for the different results are discussed. While the consequences of the inability of both proteins to interact are unclear, the further characterization of the putative interacting parts of titin and myomesin-1 led to the discovery of two new potential sites of self-assembly on M-band titin and myomesin-1. The crystal structure of titin M4 showed that this domain can form dimeric assemblies through the formation of a disulfide bridge and an intermolecular metal binding site between residues that are unique to this domain. On myomesin-1, in addition to the described C-terminal interaction site, a potential second site of self-assembly was found in its central Fn3-domain segment. The interacting site was mapped to the predicted Fn3 domain My5. The crystal structure of the domain in its dimeric form showed that the interaction is mediated by a mechanism that has previously not been observed in sarcomeric proteins. Two My5 interact with each other by the mutual exchange of an N-terminal ß-strand which complements the Fn3 fold on the binding partner. This type of interaction can be interpreted as misfolding. However, the position of the interacting domain and its mode of interaction allowed the postulation of a model of how myomesin-1 could be integrated in the M-bands. This model is in good agreement with the electron-microscopic appearance of the M-bands.
The scope of this work is to develop a novel single-molecule imaging technique by combining atomic force microscopy (AFM) and optical fluorescence microscopy. The technique is used for characterizing the structural properties of multi-protein complexes. The high-resolution fluorescence microscopy and AFM are combined (FIONA-AFM) to allow for the identification of individual proteins in such complexes. This is achieved by labeling single proteins with fluorescent dyes and determining the positions of these fluorophores with high precision in an optical image. The same area of the sample is subsequently scanned by AFM. Finally, the two images are aligned and the positions of the fluorophores are displayed on top of the topographical data. Using quantum dots as fiducial markers in addition to fluorescently labeled proteins, fluorescence and AFM information can be aligned with an accuracy better than 10 nm, which is sufficient to identify single fluorescently labeled proteins in most multi-protein complexes. The limitations of localization precision and accuracy in fluorescence and AFM images are investigated, including their effects on the overall registration accuracy of FIONA-AFM hybrid images. This combination of the two complementary techniques opens a wide spectrum of possible applications to the study of protein interactions, because AFM can yield high resolution (5–10 nm) information about the conformational properties of multi-protein complexes while the fluorescence can indicate spatial relationships of the proteins within the complexes. Additionally, computer simulations are performed in order to validate the accuracy of the registration algorithm.
Pneumolysin, a protein toxin, represents one of the major virulence factors of Streptococcus pneumoniae. This pathogen causes bacterial meningitis with especially high disease rates in young children, elderly people and immunosuppressed patients. The protein toxin belongs to the family of cholesterol-dependent cytolysins, which require membrane cholesterol in order to bind and to be activated. Upon activation, monomers assemble in a circle and undergo conformational change. This conformational change leads to the formation of a pore, which eventually leads to cell lysis. This knowledge was obtained by studies that used a higher concentration compared to the concentration of pneumolysin found in the cerebrospinal fluid of meningitis patients. Thus, a much lower concentration of pneumolysin was used in this work in order to investigate effects of this toxin on primary mouse astrocytes. Previously, a small GTPase activation, possibly leading to cytoskeletal changes, was found in a human neuroblastoma cell line. This led to the hypothesis that pneumolysin can lead to similar cytoskeletal changes in primary cells. The aim of this work was to investigate and characterise the effects of pneumolysin on primary mouse astrocytes in terms of a possible pore formation, cellular trafficking and immunological responses. Firstly, the importance of pore-formation on cytoskeletal changes was to be investigated. In order to tackle this question, wild-type pneumolysin and two mutant variants were used. One variant was generated by exchanging one amino acid in the cholesterol recognising region, the second variant was generated by deleting two amino acids in a protein domain that is essential for oligomerisation. These variants should be incapable of forming a pore and were compared to the wild-type in terms of lytic capacities, membrane binding, membrane depolarisation, pore-formation in artificial membranes (planar lipid bilayer) and effects on the cytoskeleton. These investigations resulted in the finding that the pore-formation is required for inducing cell lysis, membrane depolarisation and cytoskeletal changes in astrocytes. The variants were not able to form a pore in planar lipid bilayer and did not cause cell lysis and membrane depolarisation. However, they bound to the cell membrane to the same extent as the wild-type toxin. Thus, the pore-formation, but not the membrane binding was the cause for these changes. Secondly, the effect of pneumolysin on cellular trafficking was investigated. Here, the variants showed no effect, but the wild-type led to an increase in overall endocytotic events and was itself internalised into the cell. In order to characterise a possible mechanism for internalisation, a GFP-tagged version of pneumolysin was used. Several fluorescence-labelled markers for different endocytotic pathways were used in a co-staining approach with pneumolysin. Furthermore, inhibitors for two key-players in classical endocytotic pathways, dynamin and myosin II, were used in order to investigate classical endocytotic pathways and their possible involvement in toxin internalisation. The second finding of this work is that pneumolysin is taken up into the cell via dynamin- and caveolin-independent pinocytosis, which could transfer the toxin to caveosomes. From there, the fate of the toxin remains unknown. Additionally, pneumolysin leads to an overall increase in endocytotic events. This observation led to the third aim of this work. If the toxin increases the overall rate of endocytosis, the question arises whether toxin internalisation favours bacterial tissue penetration of the host or whether it serves as a defence mechanism of the cell in order to degrade the protein. Thus, several proinflammatory cytokines were investigated, as previous studies describe an effect of pneumolysin on cytokine production. Surprisingly, only interleukin 6-production was increased after toxin-treatment and no effect of endocytotic inhibitors on the interleukin 6-production was observed. The conclusion from this finding is that pneumolysin leads to an increase of interleukin 6, which would not depend on the endocytotic uptake of pneumolysin. The production of interleukin 6 would enhance the production of acute phase proteins, T-cell activation, growth and differentiation. On the one hand, this activation could serve pathogen clearance from infected tissue. On the other hand, the production of interleukin 6 could promote a further penetration of pathogen into host tissue. This question should be further investigated.
Streptococcus pneumoniae is one of the major causes of bacterial meningitis, which mainly affects young infants in the developing countries of Africa, Asia (esp. India) and South America, and which has case fatality rates up to 50% in those regions. Bacterial meningitis comprises an infection of the meninges and the sub-meningeal cortex tissue of the brain, whereat the presence of pneumolysin (PLY), a major virulence factor of the pneumococcus, is prerequisite for the development of a severe outcome of the infection and associated tissue damage (e. g. apoptosis, brain edema, and ischemia). Pneumolysin belongs to the family of pore forming, cholesterol-dependent cytolysins (CDCs), bacterial protein toxins, which basically use membrane-cholesterol as receptor and oligomerize to big aggregates, which induce cell lysis and cell death by disturbance of membrane integrity. Multiple recent studies, including this work, have revealed a new picture of pneumolysin, whose cell-related properties go far beyond membrane binding, pore formation and the induction of cell death and inflammatory responses. For a long time, it has been known that bacteria harm the tissues of their hosts in order to promote their own survival and proliferation. Many bacterial toxins aim to rather hijack cells than to kill them, by interacting with cellular components, such as the cytoskeleton or other endogenous proteins. This study was able to uncover a novel capacity of pneumolysin to interact with components of the actin machinery and to promote rapid, actin-dependent cell shape changes in primary astrocytes. The toxin was applied in disease-relevant concentrations, which were verified to be sub-lytic. These amounts of toxin induced a rapid actin cortex collapse in horizontal direction towards the cell core, whereat membrane integrity was preserved, indicating an actin severing function of pneumolysin, and being consistent with cell shrinkage, displacement, and blebbing observed in live cell imaging experiments. In contrast to neuroblastoma cells, in which pneumolysin led to cytoskeleton remodeling and simultaneously to activation of Rac1 and RhoA, in primary astrocytes the cell shape changes were seen to be primarily independent of small GTPases. The level of activated Rac1 and RhoA did not increase at the early time points after toxin application, when the initial shape changes have been observed, but at later time points when the actin-dependent displacement of cells was slower and less severe, probably presenting the cell’s attempt to re-establish proper cytoskeleton function. A GUV (giant unilamellar vesicle) approach provided insight into the effects of pneumolysin in a biomimetic system, an environment, which is strictly biochemical, but still comprises cellular components, limited to the factors of interest (actin, Arp2/3, ATP, and Mg2+ on one side, and PLY on the other side). This approach was able to show that the wildtype-toxin, but not the Δ6 mutant (mutated in the unfolding domain, and thus non-porous), had the capacity to exhibit its functions through a membrane bilayer, meaning it was able to aggregate actin, which was located on the other side of the membrane, either via direct interaction with actin or in an Arp2/3 activating manner. Taking a closer look at these two factors with the help of several different imaging and biochemical approaches, this work unveiled the capacity of pneumolysin to bind and interact both with actin and Arp2 of the Arp2/3 complex. Pneumolysin was capable to slightly stabilize actin in an actin-pyrene polymerization assay. The same experimental setup was applied to show that the toxin had the capacity to lead to actin polymerization through activation of the Arp2/3 complex. This effect was additionally confirmed with the help of fluorescent microscopy of rhodamine (TRITC)-tagged actin. Strongest Arp2/3 activation, and actin nucleation/polymerization is achieved by the VCA domain of the WASP family proteins. However, addition of PLY to the Arp2/3–VCA system led to an enhanced actin nucleation, suggesting a synergistic activation function of pneumolysin. Hence, two different effects of pneumolysin on the actin cytoskeleton were observed. On the one hand an actin severing property, and on the other hand an actin stabilization property, both of which do not necessarily exclude each other. Actin remodeling is a common feature of bacterial virulence strategies. This is the first time, however, that these properties were assigned to a toxin of the CDC family. Cytoskeletal dysfunction in astrocytes leads to dysfunction and unregulated movement of these cells, which, in context of bacterial meningitis, can favor bacterial penetration and spreading in the brain tissue, and thus comprises an additional role of pneumolysin as a virulence factor of Streptococcus pneumonia in the context of brain infection.
The Nucleotide Excision Repair (NER) pathway is able to remove a vast diversity of structurally unrelated DNA lesions and is the only repair mechanism in humans responsible for the excision of UV induced DNA damages. The NER mechanism raises two fundamental questions: 1) How is DNA damage recognition achieved discriminating damaged from non damaged DNA? 2) How is DNA incision regulated preventing endonucleases to cleave DNA non specifically but induce and ensure dual incision of damaged DNA? Thus, the aim of this work was to investigate the mechanisms leading from recognition to incision of damaged DNA. To decipher the underlying process of damage recognition in a prokaryotic model system, the intention of the first part of this work was to co crystallize the helicase UvrB form Bacillus caldotenax together with a DNA substrate comprising a fluorescein adducted thymine as an NER substrate. Incision assays were performed to address the question whether UvrB in complex with the endonuclease UvrC is able to specifically incise damaged DNA employing DNA substrates with unpaired regions at different positions with respect to the DNA lesion. The results presented here indicate that the formation of a specific pre incision complex is independent of the damage sensor UvrA. The preference for 5’ bubble substrate suggests that UvrB is able to slide along the DNA favorably in a 5’ → 3’ direction until it directly encounters a DNA damage on the translocating strand to then recruit the endonuclease UvrC. In the second part of this work, the novel endonuclease Bax1 from Thermoplasma acidophilum was characterized. Due to its close association to archaeal XPB, a potential involvement of Bax1 in archaeal NER has been postulated. Bax1 was shown to be a Mg2+ dependent, structure specific endonuclease incising 3’ overhang substrates in the single stranded region close to the ssDNA/dsDNA junction. Site directed mutagenesis of conserved amino acids was employed to identify putative active site residues of Bax1. In complex with the helicase XPB, however, incision activity of Bax1 is altered regarding substrate specificity. The presence of two distinct XPB/Bax1 complexes with different endonuclease activities indicates that XPB regulates Bax1 incision activity providing insights into the physical and functional interactions of XPB and Bax1.
Polarity and migration are essential for T cell activation, homeostasis, recirculation and effector function. To address how T cells coordinate polarization and migration when interacting with dendritic cells (DC) during homeostatic and activating conditions, a low density collagen model was used for confocal live-cell imaging and high-resolution 3D reconstruction of fixed samples. During short-lived (5 to 15 min) and migratory homeostatic interactions, recently activated T cells simultaneously maintained their amoeboid polarization and polarized towards the DC. The resulting fully dynamic and asymmetrical interaction plane comprised all compartments of the migrating T cell: the actin-rich leading edge drove migration but displayed only moderate signaling activity; the mid-zone mediated TCR/MHC induced signals associated with homeostatic proliferation; and the rear uropod mediated predominantly MHC independent signals possibly connected to contact-dependent T cell survival. This “dynamic immunological synapse” with distinct signaling sectors enables moving T cells to serially sample antigen-presenting cells and resident tissue cells and thus to collect information along the way. In contrast to homeostatic contacts, recognition of the cognate antigen led to long-lasting T cell/DC interaction with T cell rounding, disintegration of the uropod, T cell polarization towards the DC, and the formation of a symmetrical contact plane. However, the polarity of the continuously migrating DC remained intact and T cells aggregated within the DC uropod, an interesting cellular compartment potentially involved in T cell activation and regulation of the immune response. Taken together, 3D collagen facilitates high resolution morphological studies of T cell function under realistic, in vivo-like conditions.
Bacterial protein toxins belong to the most potent toxins which are known. They exist in many different forms and are part of our every day live. Some of them are spread by the bacteria during infections and therefore play a crucial role in pathogenicity of these strains. Others are secreted as a defense mechanism and could be uptaken with spoiled food. Concerning toxicity, some of the binary toxins of the AB7-type belong to the most potent and dangerous toxins in the world. Even very small amounts of these proteins are able to cause severe symptoms during an infection with pathogen species of the genus Clostridium or Bacillus. Apart from the thread the toxins constitute, they exhibit a unique way of intoxication. Members of the AB7-toxin family consist of a pore-forming subunit B, that acts as a molecular syringe to translocate the enzymatic moieties A into the cytosol of target cells. This complex mechanism does not only kill cells with high efficiency and therefore should be studied for treatment, but also displays a possibility to address certain cells with a specific protein cargo if used as a molecular delivery tool. Concerning both issues, binding and translocation of the channel are the crucial steps to either block or modify the system in the desired way. To gain deeper insight into the transport of binary toxins the structure of the B subunit is of great importance, but being a membrane protein, no crystal could be obtained up to now for either protective antigen (PA) of Anthrax toxin or any other AB7-type binding domain. Therefore, the method of choice in this work is an electro-physical approach using the so-called black-lipid-bilayer system for determination of biophysical constants. Additionally, diverse cell based assays serve as a proving method for the data gained during in vitro measurements. Further information was gathered with specially designed mutants of the protein channel. The first part of this thesis focuses on the translocation process and its possible use as a molecular tool to deliver protein cargo into special cell types. The task was addressed by measuring the binding of different effector proteins related and unrelated to the AB7 toxin family. These proteins were tested in titration experiments for the blockage of the ion current through a membrane saturated with toxin channels. Especially the influence of positively charged His-tags has been determined in detail for PA and C2II. As described in chapter 2, a His-tag transferred the ability of being transported by PA, but not by C2II, to different proteins like EDIN (from S. aureus) in vitro and in cell-based experiments. This process was found to change the well-known voltage-dependency of PA to a huge extend and therefore is related to membrane potentials which play a crucial role in many processes in living cells. Chapter 3 sums up findings, which depict that binding partners of PA share certain common motives. These could be detected in a broad range of substrates, ranging from simple ions in an electrolyte over small molecules to complex protein effectors. The gathered information could be further used to design blocker-substrates for treatment of Anthrax infections or tags, which render PA possible as a molecular syringe for cargo proteins. The deeper insight to homologies and differences of binary toxin components is the core of chapter 4, in which the cross-reactivity of Anthrax and C2-toxin was analyzed. The presented results lead to a better understanding of different motives involved in binding and translocation to and via the B components PA and C2II, as well as the enzymatically active A moieties edema factor (EF), lethal factor (LF) and C2I. In the second part of the thesis, the blockage of intoxication is the center of interest. Therefore, chapter 5 focuses on the analysis of specially designed blocker-substrate molecules for PA. These molecules form a plug in the pore, abolishing translocation of the enzymatic units. Especially, if multi-resistant strains of Anthrax (said to be already produced in Russia as a biological weapon) are taken into consideration, these substrates could stop intoxication and buy time, to deal with the infection. Chapter 6 describes the blockage of PA-channels by anti-His antibody from the trans-side of the porin, an effect which was not described for any other antibody before. Interestingly, even mutation of the estimated target amino acid Histidine 310 to Glycine could not interfere with this ionic strength dependent binding.
There is such vast amount of visual information in our surroundings at any time that filtering out the important information for further processing is a basic requirement for any visual system. This is accomplished by deploying attention to focus on one source of sensory inputs to the exclusion of others (Luck and Mangun 2009). Attention has been studied extensively in humans and non human primates (NHPs). In Drosophila, visual attention was first demonstrated in 1980 (Wolf and Heisenberg 1980) but this field remained largely unexplored until recently. Lately, however, studies have emerged that hypothesize the role of attention in several behaviors but do not specify the characteristic properties of attention. So, the aim of this research was to characterize the phenomenon of visual attention in wild-type Drosophila, including both externally cued and covert attention using tethered flight at a torque meter. Development of systematic quantifiable behavioral tests was a key aspect for this which was not only important for analyzing the behavior of a population of wild-type flies but also for comparing the wild-type flies with mutant flies. The latter would help understand the molecular, genetic, and neuronal bases of attention. Since Drosophila provides handy genetic tools, a model of attention in Drosophila will serve to the greater questions about the neuronal circuitry and mechanisms involved which might be analogous to those in primates. Such a model might later be used in research involving disorders of attention. Attention can be guided to a certain location in the visual field by the use of external cues. Here, using visual cues the attention of the fly was directed to one or the other of the two visual half-fields. A simple yet robust paradigm was designed with which the results were easily quantifiable. This paradigm helped discover several interesting properties of the cued attention, the most substantial one being that this kind of external guidance of attention is restricted to the lower part of the fly’s visual field. The guiding cue had an after-effect, i.e. it could occur at least up to 2 seconds before the test and still bias it. The cue could also be spatially separated from the test by at least 20° and yet attract the attention although the extent of the focus of attention (FoA) was smaller than one lower visual half-field. These observations excluded the possibility of any kind of interference between the test and the cue stimuli. Another interesting observation was the essentiality of continuous visibility of the test stimulus but not the cue for effective cuing. When the contrast of the visual scene was inverted, differences in response frequencies and cuing effects were observed. Syndirectional yaw torque responses became more frequent than the antidirectional responses and cuing was no longer effective in the lower visual field with inverted contrast. Interestingly, the test stimulus with simultaneous displacement of two stripes not only effectuated a phasic yaw torque response but also a landing response. A 50 landing response was produced in more than half of the cases whenever a yaw torque response was produced. Elucidation of the neuronal correlates of the cued attention was commenced. Pilot experiments with hydroxyurea (HU) treated flies showed that mushroom bodies were not required for the kind of guidance of attention tested in this study. Dopamine mutants were also tested for the guidance of attention in the lower visual field. Surprisingly, TH-Gal4/UAS-shits1 flies flew like wild-type flies and also showed normal optomotor response during the initial calibration phase of the experiment but did not show any phasic yaw torque or landing response at 18 °C, 25 °C or 30 °C. dumb2 flies that have almost no D1 dopamine receptor dDA1 expression in the mushroom bodies and the central complex (Kim et al. 2007) were also tested and like THGal4/ UAS-shits1 flies did not show any phasic yaw torque or landing response. Since the dopamine mutants did not show the basic yaw torque response for the test the role of dopamine in attention could not be deduced. A different paradigm would be needed to test these mutants. Not only can attention be guided through external cues, it can also be shifted endogenously (covert attention). Experiments with the windows having oscillating stripes nicely demonstrated the phenomenon of covert attention due to the production of a characteristic yaw torque pattern by the flies. However, the results were not easily quantifiable and reproducible thereby calling for a more systematic approach. Experiments with simultaneous opposing displacements of two stripes provide a promising avenue as the results from these experiments showed that the flies had a higher tendency to deliver one type of response than when the responses would be produced stochastically suggesting that attention increased this tendency. Further experiments and analysis of such experiments could shed more light on the mechanisms of covert attention in flies.
Die chronische Herzinsuffizienz stellt nach wie vor eine der häufigsten Todesursachen weltweit dar. Trotz intensiver Forschung ist es bisher nicht möglich die pathophysiologischen Prozesse aufzuhalten. Es wird nach neuen Strategien gesucht, hier therapeutisch eingreifen zu können. Kleine nicht-kodierende RNAs, sogenannte microRNAs (miRNAs), wurden als wichtige Faktoren bei verschiedenen Herzkrankheiten beschrieben. Die Mehrzahl der bisherigen Studien fokussierte sich dabei auf die am stärksten deregulierten miRNAs im erkrankten Herz. In einer automatisierten Analyse im 96 Well-Format untersuchten wir 230 miRNAs auf ihr Potential, in das Größenwachstum von primären Kardiomyozyten einzugreifen. Aus den miRNAs mit den größten Effekten selektierten wir diejenigen, die eine hohe endogene Expression aufwiesen, und unterzogen sie einem Validierungsprozess. Hier konnten wir die Effekte aller pro- (miR-22, miR-30c, miR-30d, miR-212, miR-365) und anti-hypertrophen (miR-27a, miR-27b, miR-133a) miRNAs bestätigen. Die Mehrzahl dieser miRNAs wurde hiermit erstmalig beschrieben, dass sie eine wichtige Rolle beim Größenwachstum von Kardiomyozyten spielen. Sie wären daher interessante Kandidaten für detaillierte funktionelle Studien mit dem Ziel ihr therapeutisches Potential zu evaluieren. In einem früheren genetischen Screen zur Identifizierung von kardialen, sezernierten Faktoren wurde der Protease Inhibitor 16 (PI16) entdeckt, der sich im insuffizienten Herz durch eine starke Akkumulation auszeichnet. Gegenstand des zweiten Teils dieser Arbeit war es, eine Mauslinie zu generieren, in der PI16 global oder konditionell mit Hilfe des Cre/LoxP-Systems ausgeschaltet werden kann. Nach Elektroporation des Pi16floxneo Targeting Vektors in embryonale Stammzellen und Blastozysteninjektion erhielten wir eine Mauslinie, die Träger der zielgerichteten Modifikation des Pi16 Allels war. Mit der globalen genetischen Deletion des LoxP-flankierten Abschnitts von Exon 3 bis 4 konnten wir die Expression des Pi16 Gens komplett unterbinden. Die PI16 Defizienz führte weder im Herz noch in anderen Organen per se zu pathologischen Veränderungen. Zudem war unbekannt, dass PI16 in der gesunden Maus in der kardialen Fibroblastenfraktion enthalten sowie in den Zilien der Epididymis und der Trachea und im Lumen der Schilddrüse lokalisiert ist. Im insuffizienten Herz bestätigten wir eine Akkumulation von PI16, die sich vor allem auf die fibrotischen Bereiche beschränkte. Das lässt Grund zur Annahme, dass die kardiale Funktion von PI16 erst dann offensichtlich wird, wenn man die defizienten Mäuse zukünftig entsprechenden Stressmodellen aussetzt. Das wird zu einem umfassenden Verständnis der kardialen Funktion von PI16 und dessen Potential als therapeutisches Zielmolekül führen.
Type 1 diabetes affects around 0.5% of the population in developed countries and the incidence rates have been rising over the years. The destruction of beta cells is irreversible and the current therapy available to patients only manages the symptoms and does not prevent the associated pathological manifestations. The patients need lifelong therapy and intensive research is being carried out to identify ways to eliminate autoimmune responses directed against pancreatic beta cells and to replace or regenerate beta cells. The work presented herein aimed at analyzing the role of the Th17 T cell subset, characterized by secretion of the pro- inflammatory cytokine IL-17A, in autoimmune diabetes and also at generating a beta cell reporter mouse line in the NOD background, the most widely- used mouse model for type 1 diabetes. We generated IL- 17A knockdown (KD) NOD mice, using RNAi in combination with lentiviral transgenesis. We analyzed diabetes frequency in IL-17A deficient mice and found that the loss of IL-17A did not protect the transgenic mice from diabetes. Based on these observations, we believe that Th17 cells do not play a critical role in type 1 diabetes through the IL-17A pathway, though they might still be involved in the disease process through alternate pathways. We also generated NOD and NOD-SCID mice with a transgene that drives the beta cell specific expression of a luciferase reporter gene. We used a lentiviral construct, which combined a luciferase sequence and a short- hairpin RNA (shRNA) expression cassette, allowing gene- knockdown under the beta cell specific rat insulin promoter (RIP). These mice will be of use in studying beta cell phenotypes resulting from the knockdown of target genes, using non- invasive bioimaging. We believe that the generation of these reporter mouse lines for diabetes studies will prove valuable in future investigations. Furthermore, the demonstration that the loss of IL-17A does not alter susceptibility to type 1 diabetes should help clarify the controversial involvement of Th17 cells in this disease.