• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 150
  • 24
  • 24
  • 17
  • 16
  • 4
  • 2
  • 1
  • 1
  • Tagged with
  • 298
  • 298
  • 52
  • 40
  • 36
  • 32
  • 31
  • 29
  • 29
  • 27
  • 27
  • 26
  • 26
  • 26
  • 23
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    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.
61

SOLID-STATE NMR SPECTROSCOPIC STUDIES OF PROTEINS AND SMALL MOLECULES IN PHOSPHOLIPID MEMBRANES

Chu, Shidong 06 August 2010 (has links)
No description available.
62

Lipid Accessibility Prediction and Identification of Functional Hotspots in Transmembrane Proteins

Phatak, Mukta 13 April 2010 (has links)
No description available.
63

DEVELOPMENT AND APPLICATION OF A NOVEL PULSED EPR APPROACH FOR MEMBRANE PROTEIN LOCAL SECONDARY STRUCTURE CHARACTERIZATION

liu, lishan 16 September 2015 (has links)
No description available.
64

Membrane protein insertion in bacteria by the YidC and Sec pathway

Yuan, Jijun 19 March 2008 (has links)
No description available.
65

Macrophage SR-BI and Atherosclerosis

Tedesco, Vivienne C. 04 1900 (has links)
<p> The Scavenger Receptor, Class B, Type I (SR-BI) is an integral membrane protein whose expression in the liver is critical to reverse cholesterol transport by mediating the selective uptake of HDL-derived cholesterol. SR-BI is expressed in a variety of tissues including bone marrow derived macrophages and foam cells in atherosclerotic lesions. We have explored the effect of eliminating SR-BI in leukocytes on advanced stages of atherosclerotic plaque development in apoE KO mice. We observed statistically significant cardiomegaly as a result of the elimination of SR-BI in bone marrow derived cells compared to controls (P=0.02). We report that the elimination of SR-BI in bone marrow derived cells in apoE KO mice induced to undergo atherosclerosis by feeding a high fat diet for four weeks leads to no significant difference in cross-sectional atherosclerotic plaque area at the aortic root (4.9±0.9x10^4 μm^2 when SR-BI-/- apoE-/- --> apoE-/- [n=9] and 5.5±0.9x10^4 μm^2 when SR-BI +/+ apoE-/- --> apoE -/- [n=12], P=0.68) or plaque volume through the aortic sinus (1.8±0.3x 10^7 μm^3 when SR-BI-/- apoE-/- --> apoE-/- [n=9] and 1.9±0.3x10^7 μm^3 when SR-BI +/+ apoE-/- --> apoE -/- [n=12], P=0.69). We demonstrate that macrophage SR-BI protein expression can be decreased by cholesterol associated with lipoproteins. Furthermore, we report that in Raw 264.7 macrophage-like cells the expression of SR-BI can also decrease in response to glucosamine treatment. The expression of SR-BI is decreased significantly in cells overexpressing SR-BI (1d1A[mSR-BI] cells [P=0.003]) due to treatment with glucosamine with increased protein mobility. We support this finding by demonstrating that this difference may be the result of altered glycosylation.</p> / Thesis / Master of Science (MSc)
66

Investigations of the function of the Pit-accessory protein (Pap) in Sinorhizobium meliloti

Tiller, Lauren January 2019 (has links)
Phosphate (PO4-3 or Pi) is an essential molecule necessary for sustaining life and it plays important roles in nucleic acid and cell membrane integrity. However, phosphate is found in growth-limiting concentrations in most environments. Bacteria have developed a diverse set of transport systems to uptake and scavenge phosphate from their environment for use in cellular processes. In the soil bacterium, Sinorhizobium meliloti, one such Pi transport system is the Pap-Pit system. Pit is a membrane transporter for Pi and is associated with a cytosolic protein of unknown function known as Pap (Pit-accessory protein). Interestingly, the stop codon of pap overlaps with the start codon of pit by a single nucleotide. In previous work, the pap gene appeared to be required immediately upstream of pit in an operon for functional Pi transport. Thus, in a pap deletion mutant, when pap is present in trans, there is no Pi transport. This suggests a possible translational coupling mechanism between Pap and Pit, in which the translation of Pap is required for the translation of Pit. Here, an alkaline phosphatase (phoA/lacZ) and a β-glucuronidase (gusA) translational reporter were fused to Pit as a measure of its translation and to understand the role of translational coupling in the Pap-Pit system. Growth complementation experiments with a conditionally Pi transport deficient S. meliloti mutant carrying various mutations in both pap and pit have also been performed in an attempt to determine the function of Pap in Pi uptake. The results presented here provide evidence that pap and pit are translationally coupled, and this is necessary for functional Pi transport via Pap-Pit. / Thesis / Master of Science (MSc) / Microbes require phosphorus in the form of inorganic phosphate (Pi) as an essential nutrient, but it is often found in growth-limiting concentrations in the environment. Bacteria have developed a diverse set of Pi transport systems to scavenge and take up phosphate from the environment. In the soil bacterium, Sinorhizobium meliloti, one such Pi transport system is the Pap-Pit system. Pit is a membrane transporter for Pi and is associated with a cytosolic protein of unknown function known as Pap. Various mutations in both pap and pit have been constructed in an attempt to determine the function of Pap in Pi uptake via Pit. The pap gene appears to be required immediately upstream of pit in an operon for functional Pi transport. The pap and pit genes overlap by a single nucleotide and this may suggest a translational coupling mechanism that is required for functional Pi transport via Pap-Pit.
67

Sequence And Structural Determinants of Helices in Membrane Proteins

Shelar, Ashish January 2016 (has links) (PDF)
Membrane proteins roughly constitute 30% of open reading frames in a genome and form 70% of current drug targets. They are classified as integral, peripheral membrane proteins and polypeptide toxins. α-helices and β -strands are the principal secondary structures observed in integral membrane proteins. This thesis presents the results of studies on analysis and correlation of sequence and structure of helices constituting integral helical membrane proteins. The aim of this work is to understand the helix stabilization, distortion as well as packing in terms of amino acid sequences and the correlated structures they adopt. To this end, analyses of datasets of X-ray crystal structures of integral helical membrane proteins and their comparison with a dataset of representative folds of globular proteins was carried out. Initial analysis was carried out using a non-redundant dataset of 75 membrane proteins to understand sequence and structural preferences for stabilization of helix termini. The subsequent analysis of helix distortions in membrane proteins was carried out using an updated dataset of 90 membrane proteins. Chapter 1 of the thesis reviews experimental as well as theoretical studies that have provided insights into understanding the structure of helical membrane proteins. Chapter 2 details the methods used during the course of the present investigations. These include the protocol used for creation of the non-redundant database of membrane and globular proteins. Various statistical methods used to test significance of the position-wise representation of amino acids in helical regions and the differences in globular and membrane protein datasets have been listed. Based on the tests of significance, a methodology to identify differences in propensity values that are statistically significant among two datasets has been devised. Programs used for secondary structure identification of membrane proteins namely Structure Identification (STRIDE) and Assignment of Secondary Structure in Proteins (ASSP) as well as those used for characterization of helical geometry (Helanal-Plus) have also been enlisted. In Chapter 3, datasets of 865 α-helices in 75 membrane proteins and 2680 α- helices from 626 representative folds in globular proteins defined by the STRIDE program have been analyzed to study the sequence determinants at fifteen positions within and around the α-helix. The amino acid propensities have been studied for positions that are important for the process of helix initiation, propagation, stabilization and termination. Each of the 15 positions has unique sequence characteristics reflecting their role and contribution towards the stability of the α-helix. A comparison of the sequence preferences in membrane and globular proteins revealed common residue preferences in both these datasets confirming the importance of these positions and the strict residue preferences therein. However, short/medium length α-helices that initiated/terminated within the membrane showed distinct amino acid preferences at the N-terminus (Ncap, N1, N2) as well as the C-terminus ( Ccap, Ct) when compared to α-helices belonging to membrane and globular proteins. The sequence preferences in membrane proteins were governed by the helix initiating and terminating property of the amino acids as well as the external environment of the helix. Results from our analysis also conformed well with experimentally tested amino acid preferences in a position-specific amino acid preference library of the rat neurotensin receptor (Schlinkmann et al (2012) Proc Natl Acad Sci USA 109(25):1890-5) as well as crystal structures of GPCR proteins. In the light of the environment dependent amino acid preferences found at α- helix termini, a survey was carried out to find various helix capping motifs adopted at both termini of α-helices in globular and membrane proteins to stabilize these helix termini. The results from these findings have been reported in Chapter 4. A sequence dependent structural preference is found for capping motifs at helix termini embedded inside and protruding outside the membrane. The N-terminus of α-helices was capped by hydrogen bonds involving free main chain amide groups of the first helical turn as donors and amino acid side chains as acceptors, as against the C-terminus which showed position-dependent characteristic backbone conformations to cap the helix. Overall helix termini inside the membrane did not show a very high number of capping motifs; instead these termini were stabilized by helix- helix interactions contributed by the neighboring helices of the helical bundle. In Chapter 5, we examine transmembrane helical (TMH) regions to identify as well as characterize the various types of helix perturbations in membrane proteins using ASSP and Helanal-Plus. A survey of literature shows that the term ‘helix kink’ has been used rather loosely when in fact helical regions show significant amounts of variation and transitions in helical parameters. Hence a systematic analysis of TMH regions was undertaken to quantify different types of helix perturbations, based on geometric parameters such as helical twist, rise per residue and local bending angle. Results from this analysis indicated that helices are not only kinked but undergo transitions to form interspersed stretches of 310 helices and π-bulges within the bilayer. These interspersed 310 and π-helices showed unique sequence preferences within and around their helical body, and also assisted in main- taining the helical structure within the bilayer. We found that Proline not only kinked the helical regions in a characteristic manner but also caused a tightening or unwinding in a helical region to form 310 and π-helix fragments respectively. The helix distortions also resulted in backbone hydrogen bonds to be missed which were stabilized by hydrogen bonds from neighboring residues mediated by their side chain atoms. Furthermore, a packing analysis showed that helical regions with distortions were able to establish inter-helical interactions with more number of transmembrane segments in the helical bundle. The study on helix perturbations presented in the previous chapter, brought to light a previously unreported 19 amino acid π-helix fragment interspersed between α-helices in the functionally important transmembrane helix 2 (TM2) belonging to Mitochondrial cytochrome-c-oxidase (1v55). Chapter 6 describes a case study of the structurally similar but functionally different members within the Heme-Copper- Superoxidases (HCO) superfamily that were considered for a comparative analysis of TM2. An analysis of 7 family members revealed that the π-helix shortens, fragments in two shorter π-helices or was even absent in some family members. The long π-helix significantly decreased the total twist and rise of the entire helical fragment thus accommodating more hydrophobic amino acids within the bilayer to avoid hydrophobic mismatch with the bilayer. The increased radius of the TM2 helical fragment also assisted in helix packing interactions by increasing the number of residues involved in helix-helix interactions and hydrogen bonds. Chapter 7 documents the conclusions from the different analyses presented in each of the above chapters. Overall, it is found that membrane proteins optimize the biophysical and chemical constraints of the external environment to strategically place select amino acids at helix termini to ‘start’ and ‘stop’ α-helices. The stabilization of these helix termini is a consequence of sequence dependent structural preferences to form helix capping motifs. The studies on helix transitions and distortions highlight that membrane proteins are not only packed as α-helices but also accomodate 310- and π-helical fragments. These transitions and distortions help in harboring more hydrophobic amino acids and aiding inter-helical interactions important for maintaining the fold of the membrane protein. Appendix A describes a comparison of α-helix assignments in globular and membrane proteins by two algorithms, one based on Cα trace (ASSP) and the other using a combination of hydrogen bond pattern along with backbone torsion angles φ and ψ (STRIDE).
68

Deciphering the Role of YidC in Bacterial Membrane Protein Insertion

Chen, Minyong 20 December 2002 (has links)
No description available.
69

Structural Studies of Phospho-MurNAc-pentapeptide Translocase and Ternary Complex of a NaV C-Terminal Domain, a Fibroblast Growth Factor Homologous Factor, and Calmodulin

Chung, Chih-Pin January 2013 (has links)
<p>Phospho-MurNAc-pentapeptide translocase (MraY) is a conserved membrane-spanning enzyme involved in the biosynthesis of bacterial cell walls. MraY generates lipid I by transferring the phospho-MurNAc-pentapeptide to the lipid carrier undecaprenyl-phosphate. MraY is a primary target for antibiotic development because it is essential in peptidoglycan synthesis and targeted by 5 classes of natural product antibiotics. The structure of this enzyme will provide insight into the catalytic mechanism and a platform for future antibiotic development. MraY genes from 19 bacteria were cloned, expressed, purified and assayed for biochemical stability. After initial crystallization screening, I found that MraY from Aquifex aeolicus (MraYAA) produced diffracting crystals. Recombinant MraYAA is functional and shows inhibition by the natural inhibitor capuramycin. After extensive optimization of crystallization conditions, we extended the resolution limit of the crystal to 3.3 Å. The crystal structure, the first structure of the polyprenyl-phosphate N-acetyl hexosamine 1-phosphate transferase (PNPT) superfamily, reveals the architecture of MraYAA and together with functional studies, allow us to identify the location of Mg2+ at the active site and the putative binding sites of both substrates. My crystallographic studies provide insights into the mechanism of how MraY attaches a building block of peptidoglycan to the carrier lipid.</p><p>Voltage-gated Na+ (NaV) channels initiate action potentials in neurons and cardiac myocytes. NaV channels are composed of a transmembrane domain responsible for voltage-dependent Na+ conduction and a cytosolic C-terminal domain (CTD) that regulates channel function through interactions with many auxiliary proteins including members of the fibroblast growth factor homologous factor (FHF) family and calmodulin (CaM). Through the collaboration between our lab and Geoffrey Pitt's lab, we report the first crystal structure of the ternary complex of the human NaV1.5 CTD, FGF13, and Ca2+-free CaM at 2.2 Å. Combined with functional experiments based on structural insights, we present a platform to understand roles of these auxiliary proteins in NaV channel regulation and the molecular basis of mutations that lead to neuronal and cardiac diseases. Furthermore, we identify a critical interaction that contributes to the specificity between individual NaV CTD isoforms and distinctive FHFs.</p> / Dissertation
70

The biosynthesis and membrane integration of P2X₂ at the endoplasmic reticulum

Cross, Benedict C. S. January 2008 (has links)
A crucial step in the biosynthesis of membrane proteins is their incorporation into the hydrophobic environment of the lipid bilayer. In eukaryotic cells this event occurs largely in concert with translation on ribosomes bound to the membrane of the endoplasmic reticulum (ER) at a site termed the ER translocon. This dynamic proteinaceous complex forms an aqueous conduit across the ER membrane and is laterally gated to allow transmembrane (TM) segments to partition into the lipid phase. In the case of polytopic membrane proteins, the coordinated release of multiple TM segments by the ER translocon is a poorly defined process and appears to be highly substratespecific. In this study, the ion channel subunit P2X2 was used as a novel model to examine themolecular details of membrane protein integration at the ER translocon. A primarily in vitro approach was taken using stable biosynthetic intermediates to simulate each stage of the membrane translocation and integration of P2X2. Chemical and photoreactive site-specific cross-linking analyses were then conducted to determine the molecular environment of the P2X2 TM segments throughout biosynthesis. Remarkably, both TM1 and TM2 of P2X2 were found to remain directly adjacent to the ER translocon throughout P2X2 biosynthesis and were only dislocated into the lipid phase by artificial termination of translation and disruption of the ribosome-translocon interaction. Retention of P2X2 TM1 at the ER translocon is maintained despite the synthesis of over 300 amino acid residues separating it from the ribosome peptidyl transferase centre. Premature dislocation of TM1 from the ER translocon site resulted in a pronounced aggregation of TM1 fragments both in vitro and in vivo. This is in stark contrast to previous passive-partitioning models of membrane integration and suggests that the ER translocon regulates the integration of polytopic membrane proteins in order to accommodate the specific requirementsof the substrate protein itself. The detailed characterisation of P2X2 biosynthesis was then exploited in order to examine the effect of a novel small inhibitor of ER translocon function. Eeyarestatin 1 (ESI) was found to cause a substantial inhibition of protein secretion in vivo and dramatically reduced the ER translocation of three distinct classes of substrate, including P2X2, in vitro. Using both a cross-linking analysis and a protease-protection assay for a specialised translocation reaction, ESI was shown to prevent the transfer of the nascent polypeptide chain from the membrane delivery machinery to the ER translocon complex. Further evidence that ESI targets the Sec61 complex is presented and a model for ESI-mediated inhibition of ER translocation is suggested. Taken together these data establish ESI as a novel small molecule inhibitor that selectively inhibits protein translocation both in vitroand in vivo.

Page generated in 0.0517 seconds