Browsing by Subject "membrane protein"
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Item Characterization of the Bacteriophage Lambda Holin and Its Membrane Lesion(2011-10-21) Dewey, Jill SayesBacteriophage holins are a diverse group of proteins that are responsible for the spontaneous and specifically-timed triggering of host cell lysis. The best-studied holin, S105 of phage lambda, is known to form lesions, or ?holes?, in the inner membrane of E. coli which are large enough to allow the endolysin through to the periplasm. S105 has been studied extensively by both genetic and biochemical approaches; however, little is known about the mechanism of hole formation or the structure of the lambda holin and its inner membrane lesion. An in vitro system for reconstituting hole formation by S105 was developed in which liposomes containing a self-quenched fluorophore served as artificial cell membranes (1-2). Upon delivery of solubilized S105 to the liposomes, an increase in fluorescence was observed, indicating that the fluorophore within the liposomes had escaped into the surrounding media via an S105-mediated hole in the membrane. This in vitro system, which has been optimized in this work, has been a valuable biochemical tool for analysis and reconstitution of the pathway to S105 hole formation in the cell membrane. Due to the difficulty associated with over-expression and purification of toxic membrane proteins, there are no solved structures of bacteriophage holins. Sample preparation and experimental conditions for NMR spectroscopy were optimized and structural information about a lambda holin mutant protein was obtained. Specifically, micellar contacts of transmembrane domain regions versus water contacts of the C-terminal region, secondary structure, and backbone dynamics were determined. Cryo-electron microscopy was used to visualize the inner membrane lesions formed by phage holins [lambda] S105, P2 Y, and T4 T. Therefore, the large holes initially seen in cells expressing S105 are not specific to the lambda holin, nor to class I holins. The S105 holes average ~340 nm (3), and are the largest membrane lesions ever observed in biology. They are stable at their original size, and are not localized to a specific region of the membrane. In addition, missense mutants of S105 were used to correlate hole size, protein accumulation, and lysis timing in a current model for the S105 hole formation pathway.Item Mutational analysis of the West Nile Virus NS4B protein(2007-01-31) Jason Alan Wicker; Alan D.T. Barrett, Ph.D.; Stephen Higgs, Ph.D.; Richard M. Kinney, Ph.D.; Norbert J. Roberts, M.D.; James C. Lee, Ph.D.West Nile virus (WNV) is a member of the genus Flavivirus in the family Flaviviridae. The WNV genome is a positive-sense RNA molecule approximately 11kb in length encoding a single polyprotein that is cleaved by a combination of viral and host proteases to produce three structural and seven nonstructural proteins. The NS4B protein is a small hydrophobic protein approximately 27kD in size that is hypothesized to participate both in the viral replication complex and evasion of host innate immune defenses. The objective of this dissertation was to investigate the role of the NS4B protein in viral cell multiplication and mouse virulence phenotypes by studying recombinant mutant viruses encoding amino acid substitutions of selected residues within the NS4B protein. The first aim of this project used protein modeling and phylogenetic analysis of the NY99 WNV NS4B protein in comparison to NS4B proteins from other flavivirus and WNV strains to identify amino acid residues with a theoretical probability of contributing to the function of NS4B. The second aim utilized site-directed mutagenesis of a WNV NY99 infectious clone to introduce amino acid substitutions into the NS4B protein primarily targeting a highly conserved N-terminal domain, the variable central hydrophobic region, and the four cysteine residues. Out of fourteen recombinant viruses encoding engineered substitutions, two highly attenuated mutant viruses were identified (C102S and P38G/T116I viruses) that exhibited temperature-sensitive and mouse attenuation (greater than 10,000,000-fold compared to wild-type) phenotypes. The third aim investigated the putative underlying molecular mechanisms responsible for the attenuation of the C102S and P38G/T116I viruses. Both NS4B mutants exhibited reduced multiplication kinetics both in mice and in murine macrophage and dendritic cell types critical for mediating the antiviral immune response. In addition, preliminary data identified a series of genes by DNA microarray analysis that exhibited differential expression in wild-type WNV-infected cells compared to C102S mutant-infected cells that may be involved in viral manipulation of cellular processes. This study has for the first time demonstrated the role of the NS4B protein as mediator of WNV temperature-sensitive and mouse attenuation phenotypes and has led to the identification of putative molecular mechanisms that may be involved.Item On the structure and assembly of staphylococcal leukocidin: a study of the molecular architecture of beta-barrel pore-forming toxins(Texas A&M University, 2006-08-16) Miles, Jr., George EmmettStaphylococcal leukocidin pores are formed by the obligatory interaction of two distinct polypeptides, one of class F and one of class S, making them unique in the family of β-barrel pore-forming toxins (β-PFTs). By contrast, other β-PFTs form homooligomeric pores. For example, the staphylococcal α- hemolysin is a homoheptamer. Limited and controversial data exist on the assembly and molecular architecture of the leukocidin pore. In this work, biochemical and biophysical methods were used to characterize the leukocidin pore produced by the LukF (HlgB) and LukS (HlgC) components encoded by Staphylococcus aureus. I demonstrate that LukF and LukS assemble to form an SDS-stable pore on rabbit erythrocyte membranes. In addition, the pore-forming properties of recombinant leukocidin were investigated with planar lipid bilayers. Although leukocidins and staphylococcal α-hemolysin share partial sequence identity and related folds, LukF and LukS produce a pore with a unitary conductance of 2.5 nS (1 M KCl, 5 mM HEPES, pH 7.4), which is over three times greater than that of α-hemolysin measured under the same conditions. The subunit composition and stoichiometry of a leukocidin pore were determined by two independent methods, gel shift electrophoresis and sitespecific chemical modification during single channel recording. Four LukF and four LukS subunits were shown to co-assemble into an octameric transmembrane structure. The existence of an additional subunit in part explains properties of the leukocidin pore, such as its high conductance. Additionally, this is the first time that either technique has been applied successfully to assess the composition of a heteromeric membrane protein. It is also relevant to understanding the mechanism of assembly of β-PFT pores, and suggests new possibilities for engineering these proteins. In additional studies, the HlyII pore encoded by Bacillus cereus was found to form a homoheptameric transmembrane pore with properties conforming in general with those of other members of the class of β-PFTs. HlyII possesses additional properties which make it an attractive candidate for applications in biotechnology, such as an oligomer with a high thermal stability in the presence of SDS and the ability of the pore to remain open at high transmembrane potentials.Item Solubilization and functional analysis of the lambda holin(Texas A&M University, 2004-11-15) Deaton, John FranklinThe 105aa lambda S protein is the prototype holin, S accumulates in the cytoplasmic membrane during late gene expression until, at a time programmed into its primary structure, it disrupts the membrane and allows the lambda lysozyme, R, to attack the cell wall. In this study, a zwitterionic detergent Empigen BB, was used to extract and purify the lambda holin S. In Empigen BB, CD analysis on S gave 54% alpha helical content, consistent with 3 TM domains, which has been reported by other in vivo studies. Empigen BB-purified S can be exchanged into a chaotropic solution by dialysis and reconstituted into preformed lipid vesicles for activity assays. When diluted to fluorescein-loaded suspensions of liposomes, different chaotrope-solubilized S alleles caused dye release reflective of their in vivo phenotypes. The problem was the low efficiency of delivery of S to the liposomes. Unfortunately, dye loaded liposomes are highly sensitive to any detergent, making it necessary to find other ways to solubilize S. GroEL, a chaperonin from E. coli, is responsible for folding and refolding globular proteins in vitro. It has also been reported that GroEL improves the ability of a membrane protein synthesized in vitro to insert post-translationally into liposomes. This work will investigate the behavior of GroEL towards membrane proteins. The first of two membrane proteins studied in this respect is Bacteriorhodopsin (BR), a membrane proton pump, from H. halibium. The second is the105aa S protein, a prototype holin from bacteriophage lambda. Holin and BR subjected to detergent removal in the presence of GroEL remained in solution, while in the control sample (without GroEL) S and BR precipitated. "GroELsolubilized" holin still retained its lesion forming activity and solubilized BR maintained its proton pumping ability, detected by using a liposome dye activity assay unique to each protein. This approach may be applicable to other systems requiring detergent- or chaotrope-free preparation of membrane proteins. Finally, these results suggest that GroEL may be involved in the insertion of integral membrane proteins into the lipid bilayer, a role heretofore unsuspected.Item The phiX174 Lysis Protein E: a Protein Inhibitor of the Conserved Translocase MraY(2010-07-14) Zheng, YiMost bacteriophages release progeny virions at the end of the infection cycle by lysis of the host. Large phages with double-stranded DNA genomes use a multigene strategy based on holins, small membrane proteins, and bacteriolytic enzymes, or endolysins. Holins mediate the control of endolysin activity and thus the timing of lysis. Phages with small genomes only encode a single protein for cell lysis. There are three known unrelated single protein lysis systems: the ?X174 E protein, the MS2 L protein, and the Q? A2 protein. None of these phages encodes a cell wall degrading activity, and previous work has shown that the lytic activity of E stems from its ability to inhibit the host enzyme, MraY, which catalyzes the formation of lipid I, the first lipid intermediate in cell wall synthesis. The purpose of the work described in this dissertation was to characterize the ?X174 E-mediated inhibition of MraY using genetic and biochemical strategies. A fundamental question was why no large phages use the single gene system. This was addressed by constructing a recombinant phage, ?E, in which the holin-endolysin based lysis cassette of ? was replaced with E. ?E was compared with ? in genetic and physiological experiments, with the results indicating that the holin-endolysin system increases fitness in terms of adjusting lysis timing to environmental conditions. Using ?E, physiological experiments were conducted to characterize the interaction between E and MraY in vivo. Transmembrane domains (TMD) 5 and 9 have been identified as the potential E binding site by isolating MraY mutants resistant to E inhibition. The five Eresistant MraY mutants were found to fall into three classes, which reflect the apparent affinity of the mutant proteins for E. Finally, an assay for MraY activity employing the dansylated UDP-MurNAc-pentapeptide and phytol-P, was used to demonstrate the inhibition of MraY by purified E protein. It was determined that E is a non-competitive inhibitor for MraY in respect with both substrates. A model for E-mediated inhibition of MraY was proposed, in which E binds to TMDs 5 and 9 in MraY and thus inactivates the enzyme by inducing a conformational change.