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The Global ETD Search service is a free service for researchers
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Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
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Showing 131 to 140 of 140 (0.017 seconds)| 131 |
Understanding the Molecular Dynamics of YPEL3 and FHIT Gene ExpressionKelley, Kevin Daniel 27 October 2010 (has links)
No description available.
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The Histidine-rich Glycoprotein in ReproductionLindgren, Karin E January 2016 (has links)
Infertility affects 15% of reproductive-aged couples. The milieu surrounding the growing embryo is of outmost importance, and should be optimised during in vitro fertilisation (IVF). Many biological processes, such as angiogenesis, coagulation, and immune processes need to be well regulated for a pregnancy to occur and progress normally. Histidine-rich glycoprotein (HRG) is a plasma protein that regulates components of these systems by building complexes with various ligands. A single nucleotide polymorphism (SNP) in HRG, denoted HRG C633T, seem to be of importance for IVF treatment outcomes. The aim of this thesis was to further investigate the proposed human fertility effects of the HRG C633T SNP. According to the findings of this thesis, the HRG C633T genotype is associated with primary recurrent miscarriage. Male HRG C633T genotype is associated with semen characteristics in infertile men, and pregnancy rates following IVF. However, the distribution of the HRG C633T SNP does not differ between infertile and fertile couples. We further examined the role of the region surrounding the HRG C633T SNP for regulation of endometrial angiogenesis and human embryo development. The region affects primary endometrial endothelial cell migration, proliferation and tube-formation in vitro but does not appear to affect human embryo development. No effect of the HRG peptide was noted on the secretome of human embryos. However, early embryos secrete proteins into the surrounding culture media and the level of secretion of VEGF-A, IL-6, EMMPRIN and PlGF is greater in embryos of higher developmental stages. In conclusion, the HRG C633T genotype appears to play a role only if infertility is established. The region surrounding HRG C633T SNP is of relevance in vitro for regulation of human endometrial endothelial cell angiogenesis. To predict which embryos to transfer in IVF, we have highlighted a number of proteins of interest for further investigation.
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Mechanismus přenosu signálu hemovými senzorovými proteiny detekujícími kyslík / Molecular mechanisms of signal transduction in model heme-containing oxygen sensor proteinsStráňava, Martin January 2016 (has links)
EN Heme containing gas sensor proteins play important role in bacterial physiology in regulating many processes such as cell differentiation, virulence, biofilm formation or intercellular communication. For their structure, typical modular architecture is characteristic where various sensor domains (usually at the N-terminus) regulate the activity of the catalytic or functional domains (usually at the C-terminus). In this dissertation thesis, we focused on three representatives from the group of oxygen sensing proteins, namely histidine kinase AfGcHK, diguanylate cyclase YddV, phosphodiesterase EcDOS and also on protein RR, which is the interaction partner of AfGcHK. The main aim of the thesis was to study intra-protein/inter-domain signal transduction in two representatives of heme sensor proteins with a globin fold of the sensor domain (AfGcHK, YddV) and in one representative with PAS fold of the sensor domain (EcDOS). Another objective was to describe inter-protein signal transduction in the two component signaling system AfGcHK-RR and structurally characterize these two interacting partners. Emphasis was also placed on the study of the interaction between model sensor domains and different signaling molecules and also on function of individual amino acids involved in the binding of these...
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FTIR-spektroskopische Untersuchungen am Phytochrom Agp2Piwowarski, Patrick 18 May 2017 (has links)
In der vorliegenden Arbeit wurde der lichtinduzierte Reaktionszyklus des bakteriellen Phytochroms Agp2 aus Agrobacterium tumefaciens mit FTIR‑ und UV‑Vis‑Spektroskopie untersucht. Der Photorezeptor besteht aus einem photosensorischen Modul und einer signalgebenden Histidin-Kinase-Domäne. Das photosensorische Modul bindet das Tetrapyrrol Biliverdin als Chromophor. Der Grundzustand von Agp2 (Pfr, 750 nm) ist gegenüber dem lichtaktivierten Zustand (Pr, 700 nm) rotverschoben, weshalb Agp2 den Bathyphytochromen zugeordnet wird. Die Untersuchungen erfolgten unter Verwendung von Isotopenmarkierung, H/D-Austauschexperimenten und ortsspezifischer Mutagenese. Daraus ließen sich folgende molekulare Änderungen charakterisieren, welche im Reaktionszyklus von Agp2 erfolgen: Die lichtinduzierte Isomerisierung des Chromophors führt zu einem Übergang vom Pfr- in den Pr-Zustand, wobei zwei Intermediate, Lumi‑F und Meta‑F, durchlaufen werden. Neben der Konformationsänderung des Chromophor‑D‑Rings ist auch die C‑Ring-Propionsäureseitenkette an der Photoreaktion beteiligt. Die C-Ring-Propionsäureseitenkette ist im Pfr-Zustand protoniert und wird im Übergang von Meta-F zu Pr deprotoniert. Der Pr-Zustand weist eine pH-Abhängigkeit auf, welche auf die pH-abhängige Ladung des Histidins 278 der Chromophortasche zurückzuführen ist. Je nach Ladung des Histidins 278 wird die Keto‑ bzw. Enolform der C(19)=O‑Gruppe des D‑Rings stabilisiert. Die Keto/Enol-Tautomerie ist auf eine innerhalb des Chromophors erfolgende Protontranslokation zurückzuführen und moduliert die Relaxation in den Pfr-Zustand. Änderungen der Amid-I-Absorption im Pfr-Pr-Übergang werden der Umstrukturierung der Tongue-Region des photosensorischen Moduls von einer Alpha-helikalen zu einer Beta‑Faltblatt-Struktur zugeordnet. Diese Strukturänderung wird als möglicher Weg der proteininternen Signaltransduktion zwischen photosensorischem und signalgebendem Modul vorgeschlagen. / In this thesis the light-induced reaction cycle of the bacterial phytochrome Agp2 from Agrobacterium tumefaciens was investigated using FTIR and UV‑vis spectroscopy. The photoreceptor comprises a photosensitive module and a signalling histidine kinase domain. The photosensitive module binds the biliverdin tetrapyrrol as chromophore. The Agp2 ground state (Pfr, 750 nm) is red-shifted in comparison with its light-activated state (Pr, 700 nm). Therefore, Agp2 is assigned to the group of bathy phytochromes. The investigations were conducted using isotopically labelled protein, labelled chromophore as well as hydrogen‑deuterium (H‑D) exchange and site-directed mutagenesis. Based on these the following molecular changes could be characterized that occur in the reaction cycle of Agp2: The light-induced isomerization of the chromophore leads to a transition from the Pfr to the Pr state, involving two intermediates, Lumi-F and Meta-F. Besides conformational changes of the chromophore D-ring, the C-ring propionic side chain is involved in the photoreaction as well. The C-ring propionic side chain is protonated in the Pfr state and gets deprotonated in the Meta-F to Pr transition. The Pr state exhibits pH‑dependent alterations which can be explained by pH dependent polarity changes of histidine 278 in the chromophore pocket. Depending on the charge of histidine, the D‑ring C(19)=O group is stabilized either in keto or enol form. The keto/enol tautomerism involves a proton translocation within the chromophore and modulates the relaxation to the Pfr state. The changes in the amide I region in the Pfr-Pr transition are associated with an alpha‑helix to beta‑sheet secondary structure change of the PHY domain tongue‑region. This structural change is proposed as the potential path of signal transduction between the photosensitive and the signalling module.
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Kristallographische Analyse von pathologischen Kristallen, Periplasmischen dömane von ligandfreien CitA Sensor Kinasen und PDI-verwandten Chaperone / Crystallographic Analysis of Pathological Crystals, Periplasmic Domain of Ligand-free CitA Sensor Kinase and PDI-related ChaperonesSevvana, Madhumati 04 July 2006 (has links)
No description available.
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Islet Transplantation a Technical Challenge : Studies on Human Pancreas Preservation and Enzymatic DigestionCaballero-Corbalán, José January 2011 (has links)
Islet transplantation has found its niche in diabetes treatment. It has contributed to a better quality of life and better glycemic control of patients with diabetes suffering from severe hypoglycemia that are not eligible for vascularized pancreas transplantation. Islet isolation is a technically challenging procedure. The different studies within this doctoral thesis aim to improve and standardize different steps in the isolation procedure. They are in particular looking to improve human pancreas preservation during cold storage, to optimize islet release from the exocrine tissue and to assess whether the isolated islet yield can be predicted from a biopsy. We found that pancreas preservation with pre-oxygenated perfluorodecalin (two-layer method) did not improve the ischemic tolerance of the human pancreas as compared to cold storage with the University of Wisconsin (UW) solution. Furthermore, in pancreas with long cold ischemia time (CIT) (>10 hours), Histidine-Tryptophan-Ketoglutarate (HTK) had a limited preservation capacity as compared with the UW solution with respect to isolation outcome. We also found that during enzymatic pancreas digestion, Vitacyte HA was able to provide a similar islet yield and quality as Serva NB1 with less collagenase activity and shorter digestion time. We further describe the first experience with a new GMP manufactured enzyme called Liberase MTF-S for successful human islet isolation. Finally, we found that the isolated islet yield could not be predicted from a biopsy taken from the head of the pancreas concerning solely morphological parameters of the islets tissue. The improvement of pancreas preservation will allow for marginal organs with prolonged cold ischemia time to expand the donor pool. Better knowledge of how the pancreatic extracellular matrix is digested by collagenase will lead to a fast and predictable islet release from the exocrine tissue. By standardizing the isolation procedure and improving organ selection we will increase the success rate in human islet isolation, thereby making islet transplantation available for more patients.
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Systemic Profiling of Two Component Signaling Networks in Mycobacterium TuberculosisAgrawal, Ruchi January 2015 (has links) (PDF)
Mycobacterium tuberculosis, the causative organism of the disease tuberculosis (TB) in humans, leads to nearly two million deaths each year. This versatile pathogen can exist in highly distinct physiological states such as asymptomatic latent TB infection where bacilli lie dormant or as active TB disease in which the bacilli replicate in macrophages. The pathogenic lifestyle requires the tubercle bacillus to sense and respond to multiple environmental cues to ensure its survival. Such stimuli include hypoxia, nutrient limitation, presence of reactive oxygen and reactive nitrogen intermediates, pH alterations, and cell wall/ membrane stress. Two component systems (TCSs) form the primary apparatus for sensing and responding to environmental cues in bacteria. A prototypical TCS is composed of a sensory protein called sensor kinase (SK) and a response generating protein called response regulator (RR).
M. tuberculosis encodes 11 genetically paired TCSs, 2 orphan sensor kinases and six orphan response regulator proteins. Studies of the TB bacilli using transcriptional profiling and gene knockouts have revealed that TCSs play an important role in facilitating successful adaptation to diverse environmental conditions encountered within the host. The mtrAB and prrAB genes encoding corresponding TCSs have been shown to be essential for survival, mprAB for persistence and devRS for hypoxic adaptation. Further, inactivation of the TCSs regX3-senX3, tcrXY, trcRS, phoPR or kdpDE was shown to affect the growth and/or virulence of M. tuberculosis in animal infection models.
The SK and RR proteins of TCSs are modular and contain variable input and output domains coupled to conserved ‘transmitter’ and ‘receiver’ domains. Despite the modular nature and extensive homology of SK and RR proteins across TCSs, which may allow non-cognate interactions, it is believed that crosstalk across different TCSs is not favored and that individual pathways are generally well insulated. The existing profiling studies have been performed on the TCSs of bacterial species containing a relatively large number of TCSs. In those studies, specificity and insulation have been the norm and thus become the prevalent paradigm of TCS signaling. In vitro genome wide phosphotransfer profiling has revealed only a few cross- communication nodes in the TCSs of Escherichia coli (~3%), while none in Caulobacter crescentus (in 352 interactions tested, in short time duration) and Myxococcus xanthus (in 250 interactions tested).
Yet, many instances of cross talk have been reported in literature. For example, E. coli TCSs PmrAB and EnvZ-OmpR show cross-communication with QseBC and ArcBA, and many more. In M. tuberculosis, indirect evidence of the existence of such cross regulation has originated from studies where mutations in phoPR have been shown to affect the expression of the TCS devRS and its regulon. It is thus interesting to examine the extent of crosstalk in the TCSs of M. tuberculosis, which has an exceptionally small number of TCS proteins compared to E. coli.
As mentioned earlier, M. tuberculosis H37Rv has 11 cognate pairs of TCSs, 2 orphan sensor kinases and 6 orphan response regulators. To study the entire landscape, we aimed to study all 221 connections between SK and RR proteins including 12 cognate interactions. While 10 of the cognate TCS interactions were established in the literature, two putative systems KdpDE and NarSL and 5 orphan response regulators were still uncharacterized, therefore we initiated our work with the characterization of these TCSs. At the biochemical level, the KdpDE two component system of M. tuberculosis is not well studied, though one report showed interaction of the C-terminal domain of KdpD SK and KdpE RR using yeast two hybrid assay and another reported the interaction of the SK with LRP protein. Besides these associations, there is no evidence for the functionality of KdpDE system. Similarly, NarSL system also has not been characterized and it not known whether these putative two component proteins are functional. The initial part of the study includes the characterization of these two TCSs, NarS-NarL and KdpD-KdpE, at biochemical and physiological levels.
In our studies we demonstrated that KdpDE system is a bonafide two component system of M. tuberculosis, and KdpD SK undergoes autophosphorylation at His642 residue in presence of Mg+2 ions and then it transfers phosphoryl group to a conserved Asp52 residue on the KdpE RR protein. The acid-base stability analysis revealed the nature of chemical bonds present in the KdpD and KdpE proteins, and further confirmed that KdpD and KdpE are typical SK and RR respectively. SPR analysis demonstrated that KdpD and KdpE proteins interact under basal non-phosphorylated conditions and the interaction affinity reduced when SK was phosphorylated. The reduction in the interaction affinity indicated towards a possible dissociation of SK and RR protein during phosphotransfer, which allows RRs to exert their regulatory effect. On the similar line, the phosphorylation defective SK (KdpDH642Q) had least affinity with KdpE suggesting that perhaps this mutant SK, fails to interact with the RR. We have also shown that both the kdpD and kdpE genes are in the same operon and are up regulated in potassium ions limitation and osmotic stress conditions. Overall, using the biochemical approaches, we have established that Rv1027c–Rv1028c operon of M. tuberculosis encodes a functional and a typical KdpDE two component signal transduction system.
Using the similar biochemical and biophysical approaches, we have demonstrated that NarS-NarL proteins constitute a functional TCS and His241 and Asp61 are the phosphorylatable residues. In contrast to KdpDE which shows typical behaviour of TCS, NarSL TCS showed atypical behaviour. Malhotra and group’s work on NarSL suggested that there is cross-regulation between NarS/NarL and DevS/DosT/DevR systems. We addressed this possibility on three separate levels, by examining (i) the cross-phosphorylation of DevR and NarL RRs by non-cognate sensor kinases NarS and DevS/DosT respectively, (ii) the interaction between DevR and NarL RR proteins, and
(iii) examining the effect of DevR-NarL interactions on their DNA binding properties. Our studies ruled out the presence of any physiologically relevant phosphorylation mediated cross-talk between NarS/NarL and DevS/DosT/DevR. We identified that the cross talk between these TCSs could be explained on the basis of interaction between NarL and DevR RRs and their subsequent binding to the target gene promoter regions for concerted regulation of gene expression. We also identified that DevR activation is critical for cooperative action with NarL. This process comes out as a novel mechanism of gene regulation via heteromerization of RRs. We hypothesized that formation of NarL-DevR heteromers may arise because of high sequence similarities. Conclusively, our study provides insights into the functionality of M. tuberculosis NarL/NarS TCS and regulatory function of NarL protein which acts in concert with another RR, DevR. Overall, NarS-NarL system showed an atypical, novel mode of gene regulation involving RR heteromerization.
Subsequent to the basic biochemical characterization of NarSL and KdpDE system, the genome wide phosphotransfer profiling was done to identify the cross-connections between TCSs. Remarkably, we found that specificity was the exception rather than the rule. While only three of the TCS pairs were completely specific, all the other nine TCS pairs exhibited crosstalk, including a few that were highly promiscuous. We classified the interactions as specific, one-to-many, and many-to-one signaling circuits. We also profiled all the RRs including the orphans for their ability to accept phosphoryl group from a low molecular weight donor, acetyl phosphate, and interestingly found that only two RRs DevR and NarL were capable of accepting phosphoryl group from such a donor. Interestingly, none of the orphan RRs accepted phosphoryl group from any donor, neither SKs nor low molecular weight phospho donors, warranting further analysis of their roles and presence in the M. tuberculosis genome. Our exhaustive map of the crosstalk between the TCSs of M. tuberculosis sets the stage for a renewed view of TCS signaling and proposes a dispersive-integrative landscape for TCS signaling rather than one of insulation.
As an extension of our basic characterization work of NarSL TCS, we also attempted to understand the localization pattern of NarS sensor kinase in M. smegmatis cells using fluorescence approaches. It is known that many bacterial receptors including sensor kinases form clusters or show specific localization patterns inside the cell. We found that NarS shows distinct cellular localization pattern. However, the functional significance of this localization pattern is not obvious yet and warrants further investigations. We also developed a few non-radioactive methods to study interaction between two component systems to overcome the limitations associated with radioactive experiments in studying TCSs. We developed fluorescence resonance energy transfer (FRET) to study in vitro interaction between two component proteins which was sensitive to the phosphorylation status of the proteins. Using fluorescently tagged SKs and RRs, we determined a change in FRET for KdpDE and NarSL TCS pairs in vitro. Our study thus also provides an alternative approach to study TCS signaling, using an easier, non-radioactive and high throughput approach.
In summary, our study presents the evidence of an alternative paradigm of bacterial signaling, where significant crosstalk between the underlying TCSs prevails. The new paradigm is expected to have important implications in our understanding of the virulence and pathogenesis of bacterial infections. Overall, our studies (i) allowed the establishment of functionality of all paired TCSs encoded in the genome of M. tuberculosis including NarSL and KdpDE TCSs, (ii) identified the novel mechanism of gene regulation by NarL RR and DevR, (iii) demonstrated the existence of TCS signaling which is contrary to the existing notion of specificity (iv) showed the distinct localization pattern of NarS and (v) developed non-radioactive approaches to study two component interactions.
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Searching for novel protein-protein specificities using a combined approach of sequence co-evolution and local structural equilibrationNordesjö, Olle January 2016 (has links)
Greater understanding of how we can use protein simulations and statistical characteristics of biomolecular interfaces as proxies for biological function will make manifest major advances in protein engineering. Here we show how to use calculated change in binding affinity and coevolutionary scores to predict the functional effect of mutations in the interface between a Histidine Kinase and a Response Regulator. These proteins participate in the Two-Component Regulatory system, a system for intracellular signalling found in bacteria. We find that both scores work as proxies for functional mutants and demonstrate a ~30 fold improvement in initial positive predictive value compared with choosing randomly from a sequence space of 160 000 variants in the top 20 mutants. We also demonstrate qualitative differences in the predictions of the two scores, primarily a tendency for the coevolutionary score to miss out on one class of functional mutants with enriched frequency of the amino acid threonine in one position.
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Effect of Feed Additives on Amino Acid and Dipeptide Transport by Intestines of American Lobster and Atlantic White ShrimpPeterson, Maria Louise 01 January 2014 (has links)
Previous nutritional physiology research using L-histidine and zinc in American lobster intestine (Homarus americanus) has suggested that these solutes can be co-transported as complexes (Histidine-Zinc-Histidine) across the intestine using a peptide transporter. Furthermore, transport of L-leucine was shown to be inhibited by high calcium concentrations. Dipeptide and bis-complex transport and the role of calcium were investigated in the perfused intestines of lobster and Atlantic white shrimp (Litopenaeus setiferus). Following trans-intestinal transport, serosal medium was analyzed for amino acid composition by gas chromatography. In lobster, the transport of glycylsarcosine (Gly-Sar) from mucosa to serosa was stimulated two-fold with luminal pH 8.5, compared to the pH 5.5 control. Mucosa to serosa and serosa to mucosa fluxes of Gly-Sar were measured; the dipeptide was transported intact in both directions, but the net flux was from mucosa to serosa. The use of 0.5mM calcium chloride stimulated Gly-Sar transport two-fold, compared to 25 mM. In shrimp, the addition of 50 µM zinc chloride increased the rate of L-histidine transport, while Gly-Sar inhibited histidine transport in the presence of zinc. The rate of histidine transport was significantly higher with 1mM calcium chloride than with 25mM. These results suggest that shrimp transport bis-complexes in a manner similar to lobster. High calcium concentration had an inhibitory effect on both amino acid and dipeptide transport. Proposed mechanisms accounting for the effects of metals and calcium on trans-intestinal transports of both amino acids and dipeptides by lobster and shrimp digestive tracts are discussed.
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Stanovení vybraných komponent v lidské moči elektroforézou v krátké kapiláře. / Determination of selected components in human urine with electrophoresis in short capillary.Makrlíková, Anna January 2015 (has links)
Capillary zone electrophoresis is frequently used in various analyses. In this diploma thesis a hydrodynamic sample introduction method controlled by pressure pulse has been proposed for short-capillary electrophoresis. The base electrolyte flushes sample from the loop of a six-way sampling valve and is carried to the injection end of the capillary. At the time when the sample zone reached the capillary, a short pressure impulse is generated in the electrolyte stream, which provides injection of the sample into the capillary. Then the electrolyte flow is stopped and the separation voltage is turned on. The amount of sample introduced to the capillary is controlled by the duration of the pressure pulse. This new sample introduction method was tested in the determination of ammonia, histidine, creatinine, uric acid and hippuric acid in human urine and for rapid screening of the contents of the inorganic ions in cerebrospinal fluid and blood plasma. The determination was performed in a capillary with an overall length of 10,5 cm and two base electrolytes was tested - 50 mM MES + 5 mM NaOH (pH 5,10) and 1 M acetic acid + 1,5 mM crown ether 18-crown-6 (pH 2,40). Using dual detection techniques contactless conductivity and UV spectrometric detection, anorganic and organic substances in the sample could...
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