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This doctoral thesis is concerned with the development of a method that allows to measure in vivo and non-invasively the mid-infrared absorption spectra of human epidermis, using photoacoustic spectroscopy. The main focus is the monitoring of the glucose level in epidermal interstitial fluid and its correlation with the blood glucose level; which is the most important parameter for the diagnosis and treatment of diabetes mellitus. Most publications in this field have only reported measurements in vitro for the absorption spectra of epidermis in the mid-infrared range. Using the approach presented in this work, it was possible to record in vivo and in situ the absorption spectra of skin of volunteers; and with these spectra, the changing glucose concentration could be monitored. The novelty of the photoacoustic method introduced here is that it operates in acoustic resonance in the ultrasound range. This considerably reduces the signal noise due to the external acoustic background. Although the photoacoustic method reported in this work was used to measure glucose in human epidermis, it can also be applied to other solid samples with relevant absorption bands in the mid-infrared. Furthermore, it can be used in other spectral regions if the laser source covers relevant absorption bands of the sample.
Retroviral vectors are powerful tools in clinical gene therapy as they integrate permanently into the target cell genome and thus guarantee long-term expression of transgenes. Therefore, they belong to the most frequently used application platforms in clinical gene therapy involving a broad range of different target cells and tissues. However, stable genomic integration of retroviral vectors can be oncogenic, as reported in several animal models and in clinical trials. In particular, γ-retroviral vectors, which derive from naturally mutagenic γ-retroviruses, integrate semirandomly into the host genome with regard to the target sequence, but have a preference for regions of active transcription and regulatory elements of transcriptionally active genes. The integration can result in overexpression of adjacent genes or disruption of ‘target’ gene expression. Moreover, γ-retroviral integration can cause modified transcripts and proteins through alternative or aberrant splicing or through premature termination of transcription.
Initially, the event of insertional mutagenesis and subsequent induction of leukemia by the genotoxicity of a γ-retroviral vector was described in a mouse model after genetic modification of hematopoietic stem cells (HSCs). Vector-related activation and overexpression of the oncogene ecotropic viral integration site-1 (Evi1) fostered clonal outgrowth and leukemogenesis. Additional genotoxic events of γ-retroviral vectors were observed in clinical HSC gene therapy trials for X-linked severe combined immune deficiency (SCID-X1), chronic granulomatous disease (X-CGD), and Wiskott-Aldrich Syndrome (WAS). But, genotoxicity induced by γ-retroviral vectors has never been described in clinical gene therapy trials involving adoptive transfer of genetically modified mature T lymphocytes. This fact is surprising, since T cells are long-lived and have a high capacity of self-renewal.
In a previous study, the susceptibility towards oncogenic transformation of mature T cells and HSCs after genetic modification was compared. It could be demonstrated that T-cell receptor (TCR)-polyclonal mature T cells are far less prone to transformation after γ-retroviral transfer of (proto-)oncogenes in vivo than HSCs. Additional experiments revealed that TCR-oligoclonal (OT-I and P14) mature T cells are transformable in the same setting and give rise to mature T-cell lymphomas (MTCLs).
In the present thesis, the susceptibility of mature T cells towards insertional mutagenesis was investigated. Within the first part of the thesis, retroviral integration sites (RISs) from 33 murine MTCLs were retrieved and subsequently analyzed in terms of integration pattern, detection of common integration sites (CIS) and gene ontology (GO). As these bioinformatic results demonstrated that insertional mutagenesis most likely contributed to mature T-cell lymphomagenesis, the susceptibility of mature T cells was directly assessed in a mouse model. Therefore, murine TCR-oligoclonal OT-I T cells were transduced with an enhanced green fluorescent protein (EGFP) encoding γ-retroviral vector and gene-modified T cells were transplanted into RAG1-/- mice. After 16 months, including one round of serial transplantation, a case of MTCL emerged. Tumor cells were characterized by CD3, CD8, TCR and ICOS expression. Integration site analysis via ligation-mediated polymerase chain reaction (LM-PCR) revealed a proviral insertion in the Janus kinase 1 (Jak1) gene. Subsequent overexpression of Jak1 could be demonstrated on transcriptional and protein level. Furthermore, T-cell lymphoma cells were characterized by an activated Jak/STAT-pathway as signal transducer and activator of transcription 3 (STAT3) was highly phosphorylated. The overexpression of Jak1 was causally implicated in tumor growth promotion as specific pharmacological inhibition of Jak1 using Ruxolitinib significantly prolonged survival of mice transplanted with these Jak1-activated tumor cells. A concluding systematic metaanalysis of available gene expression data on human mature T-cell lymphomas/leukemias confirmed the relevance of Jak/STAT overexpression in sporadic human T-cell tumorigenesis.
This was the first reported case of an insertional mutagenesis event in mature T cells in vivo. Thus, the results obtained in this thesis underline the importance of long-term monitoring of genetically modified T cells in vivo and the evaluation of vector toxicology and safety in T-cell based gene therapies. In particular, the transduction of T cells with a recombinant TCR or CAR (chimeric antigen receptor) bears a risk enhancement, as normal T-cell homeostasis is perturbed besides the general risk of insertional mutagenesis.
In this work the main emphasis is put on the investigation of relativistic shock waves and Mach cones in hot and dense matter using the microscopic transport model BAMPS, based on the relativistic Boltzmann equation. Using this kinetic approach we study the complete transition from ideal-fluid behavior to free streaming. This includes shock-wave formation in a simplified (1+1)-dimensional setup as well as the investigation of Mach-cone formation induced by supersonic projectiles and/or jets in (2+1)- and (3+1)-dimensional static and expanding systems. We further address the question whether jet-medium interactions inducing Mach cones can contribute to a double-peak structure observed in two-particle correlations in heavy-ion collision experiments. Furthermore, BAMPS is used as a benchmark to compare kinetic theory to several relativistic hydrodynamic theories in order to verify their accuracy and to find their limitations.
The prevalence of food allergies has increased in the westernized countries during the past decades. Clinical manifestations of food allergies involve the skin (e.g. atopic dermatitis), the respiratory tract (e.g. rhinitis, and asthma), the ocular area (e.g. conjunctivitis), the gastrointestinal tract (e.g. food-protein-induced enterocolitis syndrome, food-induced proctocolitis, and eosinophilic gastroenteropathies), and the cardiovascular system (e.g. anaphylaxis). A curative treatment of these diseases has not been established yet. Oral immunotherapy (OIT) has gained attention as a potential therapy for food allergies. Continuous feeding of allergenic diet applied in the model described here mirrors to a certain extent an OIT treatment. It might be therefore useful to investigate efficacy and safety of OIT pre-clinically.
Mouse models have been widely used to analyse novel treatment approaches. Unfortunately, most of them have focussed on IgE-mediated hyperreactivity. Only a limited number of mouse models presenting mixed IgE- and non-IgE-mediated gastrointestinal symptoms and inflammation upon allergen-challenge are available. To study the mechanisms underlying the induction of food-induced gastrointestinal inflammation and subsequent oral tolerance induction, a mouse model of food-induced gastrointestinal allergy was established. BALB/c mice were sensitised with Ovalbumin (OVA) plus ALUM and subsequently challenged by feeding a diet containing egg white (EW diet). During the first seven days on EW diet, OVA-sensitised mice (OVA/ALUM EW mice) developed gastrointestinal symptoms (e.g. weight loss, ruffed fur, soft stool and less mobility) and inflammation in the small intestines accompanied by a strong induction of OVA-specific IgE antibodies and mouse mast cell protease-1 (mMCP-1). Proliferation of CD4+ T cells from spleen of OVA/ALUM EW mice was reduced compared controls. The result indicated that feeding EW diet induced T cell tolerance systemically. In contrast, CD4+ T cells isolated from MLN of OVA/ALUM EW mice showed stronger proliferation upon OVA stimulation in vitro than mice OVA-sensitised but fed a conventional diet, indicating that tolerance was not induced by short-term EW diet. Histological analysis of the small intestinal tissue of OVA/ALUM EW mice revealed strong inflammation present in the duodenum, jejunum and ileum at this time point.
Interestingly, the observed symptoms in OVA/ALUM EW mice resolved spontaneously after 7 days on EW diet, if the feeding was continued. In the next steps the CD4+ T cell-mediated immune response after 28 days continuous EW diet was assessed and revealed that tolerance was induced systemically as well as locally. This was shown by reduced proliferation and cytokine secretion of CD4+ T cells from MLN of OVA/ALUM EW mice after long-term EW diet. However, the inflammation in the jejunum was aggravated instead of resolved at this time point of allergenic diet. Our results suggest that application of OIT in food-allergic patients with gastrointestinal inflammation may need to be reconsidered, since continuous administration of allergenic food may aggravate inflammation in the local tissue. Interestingly, only the jejunum was affected by a worsened condition, whereas duodenum and ileum resolved inflammation. In accordance to the observed jejunal inflammation mMCP-1 levels in the sera were not changed. Allergen-specific IgE levels did not reach baseline level after long-term EW diet, although they were reduced compared to levels in mice after 7 days on EW diet. This result suggests that residual OVA-specific IgE antibodies would promote the jejunal inflammation by sustained activation of mast cells. Furthermore, our results suggest that IL-4 produced by activated Th2 cells could be an effector molecule to induce intestinal inflammation.
The second part of this thesis was aimed at verifying the hypothesis that IgE-mediated mast cell activation is a major effector mechanism in induction of chronic inflammation induced by long-term EW diet. For that mice deficient for FcεRI, a high affinity IgE receptor, were used. These mice were sensitised with OVA and fed EW diet as described for WT mice. Although FcεRI-deficient mice showed an intact Th2 immunity with IgE production, weight loss in the receptor-deficient mice was moderately induced by EW diet compared to WT mice, suggesting that this clinical symptom during the acute phase of allergic response is associated with IgE-mediated mechanisms. Surprisingly, the deficient mice presented comparable intestinal inflammation on day seven of EW diet as WT mice did. However, if EW diet was continued, recovery of intestinal inflammation was observed in FcεRI-deficient mice in contrast to WT mice. These results suggest that the induction of intestinal inflammation is not IgE-dependent. Nevertheless, this does not rule out a potential role of mast cells in the inflammation, because of their IgE-independent activation pathways. It also suggests the involvement of T cell-mediated mechanisms during induction of jejunal inflammation. Interestingly, the aggravated inflammation seen after long-term EW diet in WT mice seems to be IgE-dependent, considering that it was not observed in FcεRI-deficient mice. The elevated number of mast cells in the intestine of WT mice further led to a hypothesis that their continuous activation might be responsible for the chronification of allergic inflammation observed after long-term EW diet. In the context of OIT it further implies that IgE might be a poor prognostic factor for recovery of intestinal inflammation during and after an OIT treatment. In the third part of this thesis regulatory mechanisms employed by the immune system were analysed. Initial results from CD4+ T cells isolated from MLN from OVA/ALUM EW mice showed elevated IL-10 levels in their supernatants after short-term EW diet. IL-10-deficient mice were used to analyse the effect of this immunosuppressive cytokine in the mouse model presented here. However, IL-10-deficient mice tend to develop a strong Th1-dominated immune response. Nevertheless, an accelerated weight loss and slight inflammation of the jejunum was observed after short-term EW diet. Analysis of OVA-specific proliferation and cytokine production CD4+ T cells from Spleen and MLN of IL-10-deficient mice on EW diet suggested that systemic as well as local tolerance was induced after short-term and long-term EW diet feeding, respectively. The result suggests that IL-10 is dispensable for induction of T cell tolerance in our mouse model.
However, the presence of functionally active Tregs was observed during this study in WT mice fed short-term EW diet, suggesting that Tregs might have an important role in regulating the systemic or local immune response. T cell deletion as an alternative immune regulatory mechanism was also observed. Additionally, the efficacy of continuous EW diet (mirroring to a certain extent an OIT treatment) in induction of permanent tolerance was assessed. In OVA-sensitised WT mice continuous allergenic diet was stopped after resolution of clinical symptoms and reintroduced after a defined period on conventional diet. Evaluating the weight development showed that reintroduction of EW diet induced weight loss again, but not as pronounced as seen after short-term EW diet. Also the CD4+ T cell-mediated response was elevated again upon allergen stimulation in vitro. The results suggested that permanent tolerance was not induced in the chosen feeding regime.
The mouse model established and analysed here was used to investigate inflammatory and regulatory mechanisms underlying food-induced gastrointestinal allergy. It presents clinical symptoms and intestinal inflammation (Burggraf et al., 2011). This model is easy to be reproduced in different laboratories, and is useful for testing novel therapy approaches (Schülke et al., 2011; Bohnen et al., 2013). It further provides an opportunity to investigate basic mechanisms underlying OIT. This therapy approach is currently extensively investigated and our mouse model would help to understand the therapeutic mechanism of OIT.
Channelrhodopsin-2 (ChR2) is a light-gated cation selective channel from the unicellular alga Chlamydomonas reinhardtii, which is involved in phototaxis and photophobic responses. As other rhodopsins, ChR2 comprises a seven-transmembrane helix (TMH) motif and a retinal as the light-sensitive chromophore. The chromophore is covalently attached via a protonated Schiff base to the conserved lysine residue Lys257 located in TMH7. Based on its primary sequence and the all-trans configuration of the retinal in the ground state, ChR2 is assigned to the type I rhodopsins, also referred to as microbial-type rhodopsins. Upon light activation, the retinal isomerizes from the all-trans to the 13-cis form. This photoisomerization, which is accompanied by conformational changes of the protein, eventually leads to the opening of the channel and cation translocation. Cation flux during the conductive state leads to depolarization of the cell membrane and subsequent triggering of action potentials when expressed in neurons. Therefore, ChR2 has become the most versatile optogenetic tool, enabling a non-invasive investigation of neural circuits at high spatial and temporal resolution. With the rapidly increasing importance of ChR2 as a tool in neurobiology and cell biology, structural information is the prerequisite to an unambiguous understanding of the molecular mechanisms of this unique light-activated ion channel. The coupling between isomerization and structural alterations is well understood for other microbial-type rhodopsins, like bacteriorhodopsin (bR), halorhodopsin (HR) and sensory rhodopsin II (SRII). In case of ChR2, the first data on light-induced conformational changes came from spectroscopic studies and structural information is still missing. However, in order to fully understand the mechanism of light transduction by ChR2, it is necessary to determine the changes in the protein structure at specific steps in the photocycle.
By the time I started my PhD thesis, there was no structural information of ChR2 available. Therefore, the objective of this thesis was to obtain structural information of the transmembrane domain containing the first 315 amino acids of ChR2 by cryo electron crystallography. Besides revealing the structure of membrane proteins, cryo-EM of two-dimensional (2D) crystals is ideal for investigating conformational changes in membrane proteins induced by different stimuli. Therefore, the second objective of my thesis was the investigation of light-induced conformational changes in the slow C128T ChR2 mutant. The ~1,000 times longer lifetime of the open state of the C128T mutant compared to the wild-type allowed to trap different intermediates that accumulate during the photocycle.
In 2012, the X-ray structure of a channelrhodopsin-1/channelrhodopsin-2 chimaera (C1C2) at 2.3 Å resolution in the closed dark-adapted state was published (Kato et al., 2012). The structure revealed the essential molecular architecture of C1C2, including the retinal-binding pocket and the putative cation conduction pathway. Together with biochemical, spectroscopic, mutagenesis experiments, and the high-resolution model, some functionally important residues of ChR2 have been identified. However, unambiguous explanation of the molecular determinants that contribute to activation (gating) and transport were still mostly unknown.
RESULTS AND CONCLUSIONS
The first half of my theses dealt with 2D crystallization of ChR2. I succeeded in obtaining 2D crystals of ChR2 of four different types, which differed in size, crystal packing, crystal contacts and resolution, yielding structure factors up to 6 Å resolution. The crystals were grown by reconstituting the protein with different lipids at various lipid-to-protein ratios. The best crystals formed with the synthetic lipid DMPC and EPL upon detergent removal by dialysis. The projection maps calculated from these crystals revealed the overall structure of C128T ChR2 at 6 Å resolution and were published in 2011 (Müller et al., 2011). Surprisingly, ChR2 was found to be a dimer in all crystal types. The ChR2 dimer was stable both in detergent solution and in the presence of lipids for 2D crystallization. The monomers clearly showed the expected densities for the seven TMHs.
The arrangement of the ChR2 dimers on the four 2D lattices was different. However, comparison of the individual rojection maps revealed no significant differences within the ChR2 interface in the four crystal forms. The observation that the structure of the dimer was the same in all four crystal forms and in different lipids suggested strong specific contacts between the two protomers and implied that the protein was also dimeric in the native membrane. These findings were in agreement with Western blot analysis of plasma membranes from oocytes expressing ChR2 and laser-induced liquid bead ion desorption mass spectrometry, which both showed ChR2 as a dimer. The unusual stability of the ChR2 dimer contrasts with other microbial rhodopsins, which exist in different oligomeric states, i.e. monomers, trimers or dimers. These observations raised the question whether the functional unit is the monomer or the dimer.
The comparison of the projection map of the light-driven proton pump bR at the same resolution showed similar overall dimensions. Based on this comparison, the densities which became evident in the ChR2 projection maps could be assigned to the corresponding seven densities in bR. The shape of the densities near the dimer interface suggested that TMHs 2, 3, and 4 are oriented more or less perpendicular to the membrane plane, while the other four helices appear to be more tilted, as in bR.
Based on the high-resolution bR structure and the projection structures obtained, I have built a homology model. On the basis of this homology model, several residues found in the dimer interface were selected for mutational studies in order to disrupt the dimer interface.
The investigation of light-induced conformational changes in C128T ChR2 was the second part of my thesis. I designed an experimental setup for trapping light-induced conformational changes in C128T ChR2. In addition, I optimized the sample preparation in a way that the different illumination conditions did not alter the quality of the crystals. I have trapped two different functional states, namely the conductive open state and the non-conductive closed dark-adapted state.
In order to visualize the location and the extent of conformational changes, projection difference maps were calculated between the open and the closed state. Visual inspection of the difference maps between the open and the two closed states revealed three difference peaks that map to the TMHs 2, 6, and 7, indicating significant and specific rearrangements of these helices. The strong pair of positive/negative peaks at TMH6 suggests an outward tilt movement of approximately 2 Å. Close comparison of similar work on bR revealed that this movement is likely to occur at the cytoplasmic end of TMH6. A second highly significant negative peak is observed at TMH7, indicating a less pronounced tilt compared to TMH6. The third negative peak at TMH2 indicates a loss of density in this region. No significant differences were recorded at the TMH1, 5 and at the dimer interface formed by TMH3 and 4.
I succeeded in trapping and characterizing the open and closed state in the photocycle of ChR2 and could demonstrate that the transition from the closed to the open state is linked to significant light-induced tilt movements of TMH6 and 7, plus a loss of order in TMH2. These conformational changes are likely to create a large water-filled conducting pore, which seems to be required for the conductance of up to 2,000 ions per photocycle. The previously mentioned spectroscopic studies support the difference structures I obtained. This approach sets the stage for studying structural changes accompanying the formation and decay of other photocycle intermediates in ChR2. Future studies will aim at three-dimensional maps of the open and closed state at higher resolution.
To reconstruct ocean circulation changes during specific periods of Earth history, benthic and planktic foraminifera were used as proxies in the different parts of this thesis. Both studied time periods, the Late Cretaceous and the early Pleistocene, are characterized by long-term climate cooling and major changes in ocean circulation. The first part of this thesis concentrated in the Late Cretaceous. During the Late Cretaceous long-term cooling phase, benthic foraminiferal δ18O values show a positive shift lasting about 1.5 Myr (71.5–70 Ma). This shift can be observed on a global scale and has become known as the Campanian-Maastrichtian Boundary Event (CMBE). It is proposed that this δ18O excursion is influenced either by changing intermediate- to deep-water circulation or by temporal build-up of Antarctic ice sheets. Benthic foraminiferal assemblage counts from a southern high-latitudinal site near Antarctica (ODP Site 690) are analyzed to test if the influence of the CMBE on the benthic species composition. One of the two discussed hypotheses for the causation of the δ18O transition is a change in intermediate- to deep-water circulation from low-latitude to high-latitude water masses. This change would result in cooler temperatures, higher oxygen concentration, and possibly lower organic-matter flux at the seafloor, causing a major benthic foraminiferal assemblage change. Another possible explanation of the δ18O transition of the CMBE is significant ice formation on Antarctica. However no major benthic foraminiferal assemblage change would be expected in this case. The benthic foraminiferal assemblage of Site 690 shows a separation of the studied succession into two parts with significantly different species composition. The older part (73.0–70.5 Ma) is dominated by species, which are typical for lower bottom water oxygen concentration and more common in low-latitude assemblages. Species dominating the younger part (70.0–68.0 Ma) are indicators for well-oxygenated bottom waters and more common in high-latitude assemblages. This change in the benthic foraminiferal assemblages is interpreted to represent a shift of low-latitude toward high-latitude dominated intermediateto deep-water sources. A change in oceanic circulation was therefore at least a major component of the CMBE. The Pacific Ocean contributed significantly to the climatic development during the Late Cretaceous cooling period. The contribution of ocean circulation changes in the Pacific Ocean to the Late Cretaceous climatic development in general and the CMBE and Mid-Maastrichtian Event (MME) in particular, however, is poorly understood. Previously measured high resolution planktic and benthic stable isotope data and a neodymium (Nd) isotope record from the Pacific ODP Site 1210 (Shatsky Rise, tropical Pacific Ocean) for the Campanian to Maastrichtian (69.5 to 72.5 Ma) are used to reconstruct changes in surface- and bottom water temperatures as well as changes in the source region of deep- to intermediate waters [see Appendix 4; Jung et al. 2013]. The results of the benthic foraminiferal δ18O and Nd isotope records in combination with Nd isotope records from other studies indicate changes in the intensity of intermediate- to deep ocean circulation in the tropical Pacific across the Campanian-Maastrichtian interval [see Appendix 4; Jung et al. 2013]. During the early Maastrichtian (72.5 to 69.5 Ma), a three-million-year-long period of cooler conditions and a simultaneous change towards less radiogenic Nd isotope signatures is interpreted to represent a period of increased admixture and northward flow of deep waters from the Southern Ocean (Southern Component Water, SCW). This change was probably caused by an intensified formation of deep waters in the Southern Ocean. This was reduced again during the MME (69.5 to 68.5 Ma). This early Maastrichtian cold interval is similar to the CMBEδ13C fall and succeeding δ13C rise towards the MME and is therefore also interpreted to represent tectonically forced, long-term changes in the global carbon cycle and thus a tectonic forcing of the early Maastrichtian climate cooling. Overall, the Campanian-Maastrichtian Nd and stable isotope records of Shatsky Rise indicate changes in ocean circulation that are paralleled by global warming and cooling periods. The fluctuating strength of SCW contribution in the tropical Pacific points towards an increased respectively weakened ocean circulation, which is probably related to the strength of deep-water formation in the Southern Ocean [see Appendix 4; Jung et al. 2013]. For this study, the analysis of benthic foraminiferal assemblages of Site 1210 is carried out for the same time interval (69.5 to 72.5 Ma) as Nd and stable isotopes to evaluate the influence of intermediate- to deep ocean circulation changes on the benthic foraminiferal community. The possible reaction of benthic foraminiferal assemblages is compared to the results of stable isotope and neodymium isotopes. The observed changes in species abundances only partly reflect the circulation changes reconstructed with Nd and stable oxygen istopes. For example, Stensioina spp., Aragonia spp. and Lenticulina spp., cold-water preferring species, start to be increasingly abundant at the beginning of enhanced influence of SCW. However, their abundance pattern does not follow the varying strength of the cold SCW influence at Shatsky Rise. Other species prefer lesser oxygen concentrations and warmer bottom water, e.g. Paralabamina spp. and Globorotalites spp. Paralabamina spp. has its highest relativ abundance at the beginning of the studied succession, where the influence of SCW is small. However, this taxa occurs throughout the record, even though the influence of SCW increases. Globorotalites spp. is even most abundance after the CMBE, where bottom waters are till cold and influenced by SCW. This leads to the conclusion that the varying strength of SCW in the tropical Pacific at Shatsky Rise through the studied interval is not facilitating a significant faunal turnover as has been observed at the South Atlantic Site 690 (Chapter 3). These results of the benthic foraminiferal assemblage analysis suggest a rather minor influence of the SCW on the major environmental factors that are generally influencing benthic foraminiferal communities (e.g., oxygen concentration, organic matter flux to the sea floor, bottom-water temperature). The second major part of this thesis focused on the late Pliocene-earliest Pleistocene. The late Pliocene is characterized by a long-term global cooling trend resulting in a major increase of Arctic ice sheets from around 3 Ma onwards, culminating in the Plio-Pleistocene intensification of the Northern Hemisphere glaciation. At around 2.7 Ma, large amplitude glacial-interglacial excursions (~1‰ δ18O in benthic foraminiferal calcite) in benthic oxygen isotopes can be observed. Marine isotope stage (MIS) 100 at around 2.55 Ma is the first glacial, when widespread ice rafted debris has been found in sediments in the North Atlantic Ocean. To gain a deeper understanding of the climatic evolution of the latest Pliocene-early Pleistocene, it is necessary to improve the reconstructions of North Atlantic paleohydrography, as the North Atlantic provides a key region for global climate. The consequences of the intensification of Northern Hemisphere on the early Pleistocene North Atlantic thermocline stratification and intermediate waters are still poorly understood. However, surface hydrography, the history of the thermocline and development of North Atlantic intermediate waters are well-studied for the Last Glacial Maximum (LGM). These well-known mechanisms responsible for the LGM in comparison with the present-day interglacial North Atlantic are used as an analogue for te early Pleistocene glacialinterglacials cycles. In this study, suborbitally resolved stable oxygen and carbon isotope and Mg/Ca records are measured from a deep-dwelling planktic foraminifera (Globorotaliacrassaformis) from Integrated Ocean Drilling Program Site U1313 (North Atlantic, 41°N) covering marine oxygen isotope stages MIS 103 to 95 (early Pleistocene, 2.6 to 2.4 Ma). The results are interpreted to represent a change in intermediate-water masses on glacialinterglacial timescales. During glacials geochemical records in G. crassaformis (~500–1000 m) bear the imprint of Glacial North Atlantic Intermediate Water (GNAIW), while during interglacials this species reflects the signature of the influence of Mediterranean Outflow Water (MOW) in combination with the subtropical gyre. The comparison of this data with the published records from G. ruber from the same samples facilitates the reconstruction of glacial-interglacial stratification changes of the upper water column at Site U1313. The results show that larger gradients of temperature, salinity and δ13C prevailed during glacials, suggesting a stronger stratification of the upper water column. This can be seen to indicate glacial-interglacial changes in ntermediate water masses in the North Atlantic similar to those reconstructed for the latest Pleistocene. As an additional proxy, the clumped isotope paleothermometer is applied for the Late Cretaceous study as well as for the early Pleistocene. This proxy is commonly assumed to be independent of other factors than temperature. Clumped isotopes are measured for the Late Cretaceous Site 690 on the planktic foraminiferal species Archaeoglobigerina australis and compared to already existing stable oxygen isotopes of this species. This is assumed to enable the reconstruction of paleotemperature independent of ice volume and therefore contribute to the long-lasting discussion whether there was a temporal ice build-up on Antarctic during the Campanian-Maastrichtian cooling period. For the early Pleistocene, the planktic foraminiferal species G. crassaformis is used from Site U1313 from MIS 99 (interglacial) and MIS 98 (glacial). This provides the opportunity to separate ice volume, salinity and temperature effects on the measured δ18O record of G. crassaformis. The results of the clumped isotope measurements reveal comparatively large standard errors. For the Late Cretaceous the standard error of the clumped isotope measurements proved too large to allow any conclusions on the temperature component on the δ18O record of A. australis. For the early Pleistocene, the temperature difference is also too small to be reconstructed with the standard error of the clumped isotope measurements in this study. Measuring many replicates of one sample would minimize the standard error considerably. However, the amount necessary to measure replicates cannot be gained for either time period, as almost all foraminifera were picked from the respective samples. It is concluded that the respective questions may be solved with a different method of clumped isotope analysis requiring less sample material. This method is, for example, available at the ETH Zurich.
The biogenesis and function of photosynthetically active chloroplasts relies on the import of thousands of nuclear encoded proteins via the coordinated actions of two multiprotein translocon machineries in the outer and inner envelope membrane. Trafficking of preproteins across the soluble compartment of InterMembrane Space (IMS) is currently envisioned to be facilitated by an IMS complex composed of outer envelope proteins Toc64 and Toc12, a soluble IMS component, Tic22 and an IMS-localized Hsp70. Among them, currently Tic22 is the only component that stands undisputed in terms of its existence. Having two closely related homologs in A. thaliana, their biochemical and functional characterization was still lacking. A critical analysis of Tic22 knockout mutants displayed growth phenotype reminiscent of ppi1, the mutant of Toc33. However, both the genes have similar expression patterns with no clear preference for photosynthetic or nonphotosynthetic tissues, which explained the absence of a detectable phenotype in single mutants. In addition, transgenic complementation study with either of the homolog affirmed the identical localization of both proteins in the IMS which characterizes the two homologs as functionally redundant. Based on the pale-yellow phenotype exhibited by the double mutant plants, an attempt to analyze the import capacity of a stromal substrate in the double mutant revealed threefold reduction when compared to wild-type acknowledging the essential role of Tic22 in the import mechanism. Initially, Tic22 was identified together with another protein, Tic20, which has been heavily discussed as a protein conducting channel in the inner membrane. Despite being characterized, in A. thaliana, two out of four homologs of Tic20 are differentially localized with one being additionally localized in mitochondria and the other, exclusively residing in the thylakoids.
According to in silico analysis, for all the Tic20 proteins, a four-helix transmembrane topology was predicted. Accordingly, its topology was mapped by employing the recently established selfassembling GFP-based in vivo experiments. Astonishingly, the expression of one of the inner envelope localized Tic20 homolog enforces inner membrane proliferation affecting the shape and organization of the membrane. Therefore this study focuses on analyzing the effects of high envelope protein concentrations on membrane structures, which together with the existing results, an imbalance in the lipid to protein ratio and a possible role of signaling pathway regulating membrane biogenesis is discussed.
ATP synthases are multi-subunit membrane enzymes, which utilize the energy stored in a transmembrane electrochemical ion gradient to produce adenosine-5´-triphosphate (ATP), the universal energy carrier in biological systems. Research on these important enzymes goes back more than 50 years and has produced innumerable studies. The F-type ATP synthase consists of two functionally distinct, but tightly coupled subcomplexes, the water-soluble F1 and the membrane-embedded Fo complex. In its simplest form, F1 consists of five different subunits with a stoichiometry of α 3β3γδε, and harbors three catalytic centers in the α 3β3-headpiece, while Fo consists of three different subunits in a stoichiometry of ab2cn, where n varies between 8 to 15 depending on the species. From a mechanistic standpoint, the complex can also be divided into two different units, namely a stator, α3β3δ-ab2, and a rotor, γε-cn. The enzyme utilizes the energy stored in a transmembrane electrochemical gradient of protons, or in some cases Na+, to drive ATP synthesis. In particular, the downhill translocation of these ions across the Fo complex drives rotation of the γε-cn unit, which is then transduced to the active centers, catalyzing the phosphorylation of adenosine-5`-diphosphate (ADP) with inorganic phosphate (Pi), and the release of ATP....
ß1-integrins are essential for angiogenesis but the mechanisms regulating integrin function in endothelial cells (EC) and their contribution to angiogenesis remain elusive. BRAG2 is a guanine nucleotide exchange factor for the small Arf-GTPases Arf5 and Arf6. The role of BRAG2 in EC and angiogenesis and the underlying molecular mechanisms remains unclear. siRNA-mediated BRAG2-silencing reduced EC angiogenic sprouting and migration. BRAG2-siRNA-transfection differentially affected a5ß1- and aVß3-integrin function: specifically, BRAG2-silencing increased focal/fibrillar adhesions and EC adhesion on ß1-integrin-ligands (fibronectin and collagen), while reducing the adhesion on the aVß3-integrin-ligand, vitronectin. Consistent with these results, BRAG2-silencing enhanced surface expression of a5ß1-integrin, while reducing surface expression of aVß3-integrin. Mechanistically, BRAG2 mediated recycling of aVß3-integrins and endocytosis of ß1-integrins and specifically of the active/matrix bound a5ß1-integrin present in fibrillar/focal adhesions (FA), suggesting that BRAG2 contributes to the disassembly of FA via ß1-integrin-endocytosis. Arf5 and Arf6 are promoting downstream of BRAG2 angiogenic sprouting, ß1-integrin-endocytosis and the regulation of FA. In vivo silencing of the BRAG2-orthologues in zebrafish embryos using morpholinos perturbed vascular development. Furthermore, in vivo intravitral injection of plasmids containing BRAG2-shRNA reduced pathological ischemia-induced retinal and choroidal neovascularization. These data reveals that BRAG2 is essential for developmental and pathological angiogenesis by promoting EC sprouting through regulation of adhesion by mediating ß1-integrin internalization and associates for the first time the process of ß1-integrin endocytosis with angiogenesis.
So far clinical human immunodeficiency virus (HIV) therapy is limited to non-curative treatments. However, as recently shown, alternative approaches such as HIV gene therapy have the potential to functionally cure the disease (e.g. the hematopoietic stem cell (HSC)-transplantation with a CCR5Δ32 homozygous transplant) (1). In contrast to the highly personalized medical treatment applied in the ‘Berlin case’, more broadly applicable approaches are currently under intensive investigation.
One example is the adeno-associated-virus (AAV)-mediated delivery of in vivo secreted antiviral entry inhibitors (iSAVE), the concept of which is based on the direct in vivo administration of a broadly applicable highly potent antiviral gene (here: a C46-derived entry inhibitory peptide interfering with HIV-1 membrane fusion). The AAV-based gene delivery is believed to overcome several limitations of gene therapeutic treatments based on ex vivo lentiviral trials in the past. It is (i) targeting differentiated HIV target cells (i.e. liver and differentiated lymphatic cells) reducing the risk of genotoxicity compared to stem cell-based trials, (ii) overcoming the limitation of a low number of genetically modifiable cells as in lentivirally based ex vivo transduction strategies (i.e. limited modifiable cell number due to culture conditions and lower vector titers) and (iii) using the safe AAV vector system, which has not been associated with major genotoxicity in men. (iv) Most importantly, the concept of secretable entry inhibitors does not require transduction of large amounts of cells due to the protective bystander effect. Thus, iSAVE might be a treatment principle for HIV infection that might be able to cure patients irrespective of their viral isolates or adherence.
Accordingly, the iSAVE concept could aim at two different sites in the patient for the production of antiviral transgenes, either the systemic production via suitable producer cells (e.g. hepatocytes) or the local production in the lymphatic system.
In a first approach, we are able to efficiently target hepatocytes using the natural AAV serotype 8 to express high plasma levels of secretable antiviral entry inhibitors in order to systemically suppress viral replication. In this setting we could show that iSAVE peptides are highly expressed in hepatocytes. However, plasma levels of iSAVE were insufficient when using a secretable peptide as sole antiviral transgene.
As a second treatment strategy, the iSAVE project aimed to deliver antiviral genes directly to the site of viral replication, the lymphatic system. Here, (i) a panel of naturally occurring AAV serotypes as well as (ii) AAV retargeting approaches were employed to design a highly efficient and selective AAV vector variant for gene delivery into the lymphatic system after intravenous vector administration.
In detail, (i) screening of the natural occurring serotypes revealed that the AAV serotype 1 (AAV-1) was best in targeting splenic tissue in two humanized mouse models, however at a very low level. After systemic AAV-1 vector administration neither transduction of human lymphocytes did occur nor was iSAVE expressed in the lymphatic system in a humanized mouse model.
(ii) In a second approach, we modified the well-characterized AAV-2 serotype in a tropism-defining region of its capsid gene by insertion of human peripheral blood lymphocytes (hPBL)-tropic peptide ligands. These in turn were selected by M13 in vivo phage display and by in vivo AAV peptide display. Selected variants were cloned and tested for hPBL transduction in vitro. Although the selected variants did not show increased expression efficacies compared to AAV-2 WT, it still might be possible that the selected variant are more specific for hPBLs as these conditions have not been tested.
As these selection processes required a humanized mouse model that comprises a functional lymphatic system, we established the previously described Trimera mouse model in our lab (2). We found that this mouse model could be further improved to allow engraftment of a lower number of gene-modified (gm) human T cells as in the classical Trimera model. These modified Trimera mice (mT3 mice) were conditioned by inclusion of cyclophosphamide (CTX) to the irradiation-conditioning scheme of the classical Trimera model.
Comparison of mT3 mice with established NSG and DKO mice in an adoptive gm T cell transplantation setting revealed that NSG mice were the most robust model providing high reproducibility in human T cell engraftment. MT3 mice allowed a substantial, yet more variable engraftment of gm T cells. Besides comparing engraftment kinetics, the graft quality (i.e. clonality and cytokine milieu) was analyzed. Again, NSG mice showed the most balanced homeostatic repopulation three weeks after transplantation, while mT3 mice were prone to Th1-type, oligloclonal repopulation, indicating an early onset of xenograft-versus-host disease. Finally, the lymphatic infiltration was analyzed. As expected, mT3 mice provided the most intact lymphatic structures, although the normal lymphatic morphology was not restored.
In conclusion, it was demonstrated in this work that AAV-mediated iSAVE gene therapy faces specific limitations depending on the respective targeting approach
In the systemic approach, iSAVE peptides have to be further optimized in terms of transgene design itself, as high-level accumulation in murine plasma was not feasible for the short iSAVE precursor. In the local, lymphatic targeting approach, AAV-mediated expression faces its limits in targeting specificity but foremost expression efficacy. Thus, the AAV vector itself needs further optimization for sufficient local iSAVE expression levels. Independently from the AAV-related approaches, a novel humanized mouse model was established in this work. Despite drawbacks regarding repopulation variability and set-up complexity, the novel mT3 mouse model comprised improved secondary lymphatic structures for adoptive T cell transfer, which might be an interesting platform for studies in lymphoma or leukemia therapy.