Expression, purification and structural characterization of the DNA-binding domain of BZLF1

Brooksbank, Robert Alan

January 1994

No description available.

572.8

Epstein-Barr virus; Proteins

The characterization of inner core protein VP6 of African horsesickness virus

De Waal Pamela Jean.

January 2005

Thesis (Ph. D.)(Genetics)--University of Pretoria, 2005. / Includes summary. Includes bibliographical references. Available on the Internet via the World Wide Web.

African horse sickness virus Proteins.

Structural Studies On Physalis Mottle Virus Capsid Proteins & Stress Response Proteins Of Oryza Sativa And Salmonella Typhimurium

Sagurthi, Someswar Rao

06 1900

X-ray crystallography is one of the most powerful tools for the elucidation of the structure of biological macromolecules such as proteins and viruses. Crystallographic techniques are extensively used for investigations on protein structure, ligand-binding, mechanisms of enzyme catalyzed reactions, protein-protein interactions, role of metal ions in protein structure and function, structure of multi-enzyme complexes and viruses, protein dynamics and for a myriad other problems in structural biology. Crystallographic studies are essential for understanding the intricate details of the mechanism of action of enzymes at molecular level. Understanding the subtle differences between the pathogenic enzymes and host enzymes is necessary for the design of inhibitor molecules that specifically inhibit parasite enzymes. The current thesis deals with the application of biochemical and crystallographic techniques for understanding the structure and function of proteins from two pathogenic organisms – a plant virus Physalis Mottle Virus (PhMV), and a pathogenic bacterium, Salmonella typhimurium and also stress induced proteins from Oryza sativa. The thesis has been divided into seven chapters, with the first four chapters describing the work carried out on PhMV, while the rest of the chapters deal with the studies on stress response proteins from Oryza sativa and Salmonella typhimurium. The first part of the thesis deals with studies on viral capsids. Viruses are obligate parasites that have proteinaceous capsids enclosing the genetic material, which, in the case of small plant viruses, is invariably ss-RNA. X-ray diffraction studies on single crystals of viruses enable visualization of the structures of intact virus particles at near-atomic resolution. These studies provide detailed information regarding the coat protein folding, molecular interactions between protein subunits, flexibility of the N-and C-terminal segments and their probable importance in viral assembly, role of RNA in capsid assembly, nucleic acid (RNA)-protein interactions, the capsid structure and mechanism of assembly and disassembly. The present thesis deals with the capsid structure and analysis of the coat protein (CP) recombinant mutants of PhMV. Virus assembly, one of the important steps in the life cycle of a virus, involves specific interactions between the structural protein and cognate viral genome. This is a complex process that requires precise protein-protein and protein nucleic acid interactions. In fact, most of the biological functional units such as ribosomes and proteosomes also require highly co-ordinated macromolecular interactions for their functional expression. Viruses being simple in their architecture, serve as excellent model systems to understand mechanism of macromolecular assembly and provide necessary information for the development of antiviral therapeutics, especially in animal viruses. PhMV is a plant virus infecting several members of Solanaceae family. It belongs to the tymoviridae group of single stranded RNA viruses. Its genome is encapsidated in a shell comprising of 180 (architecture based on T = 3 icosahedral lattice) chemically identical coat protein (CP) subunits (~ 20,000Da) arranged with icosahedral symmetry. In an earlier phase of work, PhMV purified from infected plant leaves was crystallized in the space group R3 (a = 294.56 Å,  = 59.86). X-ray diffraction data to 3.8 Å resolution were recorded on films by screenless oscillation photography. Using this data of severely limited quality and poor completion (40%), the structure PhMV was determined by molecular replacement using the related turnip yellow mosaic virus (TYMV) structure as the phasing model. There was therefore a need to re-determine and improve the structure, which could be useful for understanding the earlier detailed studies on its biophysical properties. As a continuation of these studies, the present investigations were conceived with the goal of determining the natural top and bottom component capsid structures of PhMV. Investigations were also carried out to examine the possibility of enhancing the diffraction quality of PhMV crystals. The thesis begins with a review of the current literature on the available crystal structures of viruses and their implications for capsid assembly (chapter I). All experimental and computational methods used during the course of investigations are described in chapter II, as most of these are applicable to all the structure determinations and analyses. The experimental procedures described include cloning, overexpression, purification, crystallization and intensity data collection. Computational methods covered include details of various programs used during data processing, structure solution, refinement, model building, validation and analysis. Chapter III describes structural studies on top and bottom components of PhMV. Purified tymoviruses including PhMV are found to contain two classes of particles that sediment at different velocities through sucrose gradients and are called the top (sedimentation coefficient 54 Svedberg units(S)) and the bottom (115S) components. The top component particles are either devoid of RNA or contain only a small subgenomic RNA (5%) while the bottom component particles contain the full length genomic RNA. Only the bottom component is infectious. The top and bottom components were separately crystallized in P1 and R3 space groups, respectively. It is of interest to note that crystals of the bottom component obtained earlier belonged to R3 space group while recombinant capsids that lack of full length RNA as in natural top component crystallized in the P1 space group. A polyalanine model of the homologous TYMV was used as the phasing model to determine the structures of these particles by molecular replacement using the program AMoRe. The refinement of top and bottom component capsid structures were carried out using CNS version 1.1 and the polypeptide models were built into the final electron-density map using the interactive graphics program O. The quality of the map was sufficient for building the model and unambiguous positioning of the side chains. There is a significant difference in the radius of the top and bottom component capsids, the top component being 5 Å larger in radius. Thus, RNA makes the capsid more compact, even though RNA is not a pre-requisite for capsid assembly. Partially ordered RNA was observed in the bottom component. The refined models could form the basis for understanding the architecture, protein-protein interactions, protein-nucleic acid interactions, stability and assembly of PhMV. Chapter IV provides a detailed description of the mutations carried out on PhMV coat protein towards enhancing the diffraction quality of crystals. The gene coding for PhMV coat protein (PhMVCP) and several of its deletion and substitution mutants were originally cloned in pRSETC and pET-21 vectors by Mira Sastri and Uma Shankar in Prof. Savithri’s laboratory at the Department of Biochemistry. It was observed that the recombinant intact coat protein and several mutants lacking up to 30 amino acids from the N-terminal end could assemble into empty shells resembling the natural top component. None of these deletion mutants crystallized in forms that diffracted to high resolution. Based on the intersubunit contacts observed, three more site-specific mutants were designed. These three mutants were expressed in BL21 (DE3), purified and crystallized. Even these mutant crystals did not diffract to high resolution. The polypeptide fold of PhMV coat protein therefore was carefully examined for probable reasons. It was found that PhMV subunit has three major cavities. Three cavities are likely to increase the flexibility of protein subunits, which in turn may result in crystals of poor quality. Mutations V52W, S158Q and A160L were shown to fill up these cavities and with the view of obtaining better crystals. These site specific mutations were carried out the mutant proteins were purified. It was shown that the recombinant capsids are stable and possess T=3 architecture. Two mutants were crystallized and a data set for V52W extending to 6.0 Å resolution could be collected. Due to the limited resolution, further work was not pursued. It is plausible that the triple mutant will diffract to higher resolution. The second part of the thesis deals with stress response proteins from Oryza sativa and Salmonella typhimurium. It is known that viral infection and abiotic and biotic stresses induce a network of proteins in plants. Chapter V presents a review of the current literature on stress proteins, focusing mainly on Oryza sativa and S. typhimurium stress response proteins. Chapter VI describes the over expression of stress proteins SAP1 and SAP2 from rice. These stress related proteins confer tolerance to cold, dehydration and salt stress in rice. These proteins have been cloned in the expression vector pEt-28(a) and expressed in E. coli strain BL21 CodonPlus(DE3)RIL. The proteins were purified and crystallization trials were made. However, there were no hits. In an attempt to get crystals, nine deletion constructs of SAP1 were designed eliminating potentially disordered and unfolded regions based on a bioinformatics analysis. Crystallization trails are being carried out on three of the constructs. Structural studies on a universal stress protein from Salmonella typhimurium, which shares homology with the rice universal stress proteins, was initiated. Apart from this, several other stress related proteins of Salmonella typhimurium have also been selected for structural and functional studies. These include YdaA, YbdQ, Yic, Ynaf, Yec, Spy and Usb. All these were cloned and expressed in E. coli. Out of seven proteins, Ynaf, YdaA and YbdQ were found in the soluble fraction and were expressed in quantities suitable for structural studies. I could crystallize YdaA and Ynaf. X-ray diffraction data to resolutions of 3.6 Å and 2.3 Å were collected on crystals of YdaA and YnaF, respectively. A tentative structure of YnaF has been obtained. Further attempts to determine these structures are in progress. Biophysical, Biochemical functional characterization of YdaA and YnaF proteins are described. Structural studies on mannose-6-phosphate isomerase, an enzyme related to stress regulatory proteins from S. typhimurium are dealt with in Chapter VII. Mannose 6-phosphate isomerase (MPI) catalyzes the interconversion of mannose 6-phosphate and fructose 6-phosphate. The structure could be solved in its apo and holo forms (with two different metal atoms, Y3+ and Zn2+), and complexed with the cyclic form of the substrate fructose 6-phosphate (F6P) and Zn2+. Isomerization involves acid/base catalysis with proton transfer between C1 and C2 atoms of the substrate. Lys 132, His 131, His 99 and Asp 270 are close to the substrate and are likely to be the residues involved in proton transfer. Interactions observed at the active site suggest that the ring opening step is catalyzed by His 99 and Asp 270. An active site loop consisting of residues 130-133 undergoes conformational changes upon substrate binding. The metal ion is not close to the substrate atoms involved in proton transfer. Binding of the metal induces structural order in the loop consisting of residues 50-54. Hence, the metal atom does not appear to play a direct role in catalysis, but is probably important for maintaining the architecture of the active site. Based on these structures and earlier biochemical work, a probable isomerization mechanism has been proposed. The thesis concludes with a brief discussion on the future prospects of the work. The following manuscripts have been published or will be communicated for publication based on the results presented in the thesis:

Typhoiopoidea - Proteins

Typhoid Virus - Proteins

Physalis Mottle Virus Proteins

Oryza Sativa Virus - Proteins

Viral Capsids

Stress Response Proteins

Capsid Proteins

Salmonella typhimurium

Physalis Mottle Virus (PhMV)

Virology

Investigation of protein-protein and protein-DNA interactions involved in the function of herpes simplex virus transactivator VMW65.

Shaw, Peter Xiao. Capone, John P.

Unknown Date

Thesis (Ph.D.)--McMaster University (Canada), 1996. / Source: Dissertation Abstracts International, Volume: 57-10, Section: B, page: 6096. Adviser: J. P. Capone.

ISGylation and phosphorylation two protein posttranslational modifications that play important roles in influenza A virus replication /

Hsiang, Tien-ying,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2008. / Vita. Includes bibliographical references.

Development of a generic, structural bioinformatics information management system and its application to variation in foot-and-mouth disease virus proteins

De Beer, T.A.P. (Tjaart Andries Petrus)

30 May 2009

Structural biology forms the basis of all functions in an organism from how enzymes work to how a cell is assembled. In silico structural biology has been a rather isolated domain due to the perceived difficulty of working with the tools. This work focused on constructing a web-based Functional Genomics Information Management System (FunGIMS) that will provide biologists access to the most commonly used structural biology tools without the need to learn program or operating specific syntax. The system was designed using a Model-View-Controller architecture which is easy to maintain and expand. It is Python-based with various other technologies incorporated. The specific focus of this work was the Structural module which allows a user to work with protein structures. The database behind the system is based on a modified version of the Macromolecular Structure Database from the EBI. The Structural module provides functionality to explore protein structures at each level of complexity through an easy-to-use interface. The module also provides some analysis tools which allows the user to identify features on a protein sequence as well as to identify unknown protein sequences. Another vital functionality allows the users to build protein models. The user can choose between building models online on downloading a generated script. Similar script generation utilities are provided for mutation modeling and molecular dynamics. A search functionality was also provided which allows the user to search for a keyword in the database. The system was used on three examples in Foot-and-Mouth Disease Virus (FMDV). In the first case, several FMDV proteomes were reannotated and compared to elucidate any functional differences between them. The second case involved the modeling of two FMDV proteins involved in replication, 3C and 3D. Variation between the several different strains were mapped to the structures to understand how variation affects enzymes structure. The last example involved capsid protein stability differences between two subtypes. Models were built and molecular dynamics simulations were run to determine at which protein structure level stability was influenced by the differences between the subtypes. This work provides an important introductory tool for biologists to structural biology. / Thesis (PhD)--University of Pretoria, 2009. / Biochemistry / unrestricted

Bioinformatics information management

Foot-and-mouth disease virus proteins

UCTD

Identification and Characterization of SNAPIN as a Novel Antagonist of HIV-1 Egress: A Dissertation

Younan, Patrick

05 April 2010

Vpu has been shown to possess two distinct roles in the pathogenesis of HIV. First, Vpu has been shown to down-regulate the expression of CD4 molecules at the plasma membrane of infected cells by targeting CD4 molecules for degradation in the endoplasmic reticulum. Second, Vpu promotes viral egress in specific cell lines termed non-permissive cells by mechanism that remain relatively unclear. Therefore, experiments were conducted in order to identify cellular factors involved in the Vpu-dependent phenotype. Using full-length Vpu as bait in yeast two-hybrid experiments, several candidate cellular factors were identified. One protein, SNAPIN, was identified as a cellular factor putatively involved in the Vpu-dependent phenotype. Further experiments determined that not only do SNAPIN and Vpu interact, but that Vpu also leads to the degradation of SNAPIN by both proteasomal and lysosomal degradation pathways. Over-expression of SNAPIN in cell lines that do not normally require Vpu expression for viral production resulted in a Vpu-dependent phenotype. While over-expression of SNAPIN in otherwise permissive cell lines significantly reduced Vpu-deficient virus production, wild type levels remained relatively constant. Importantly, no defective viral structural protein production was observed; however, intracellular p24/p55 did not accumulate suggesting that in SNAPIN expressing cells, Gag is also targeted for degradation. In addition, the reduction of SNAPIN expression in non-permissive cell lines significantly increased viral titers in supernatants. Of particular interest, even in cells expressing Bst-2 (a previously identified cellular factor involved in the Vpu-phenotype), siRNA mediated knockdown of SNAPIN led to increased viral titers. In addition, the co-transfection of siRNAs targeting both SNAPIN and Bst-2 resulted in an additive effect, in which Vpu-deficient viral titers were nearly equivalent to wild-type titers. Surprisingly, siRNA-mediated knockdown of SNAPIN in Jurkat cells was sufficient to overcome any restriction in viral egress imposed by the deletion of Vpu. Conversely, siRNA targeting Bst-2 had little or no effect on viral titers in Jurkat cells regardless of whether it was transfected alone or in combination with siRNAs targeting SNAPIN. These experiments provide evidence of an alternate cellular restriction mechanism involved in viral egress that is countered by the HIV-1 accessory protein, Vpu. In addition, this research may provide further insight into the complex cellular networks involved in the trafficking of Gag through cellular endosomal pathways.

Human Immunodeficiency Virus Proteins

Viral Regulatory and Accessory Proteins

Vesicular Transport Proteins

Genes

vpu

HIV-1

Virus Release

Gene Products

gag

Amino Acids, Peptides, and Proteins

Cells

Genetic Phenomena

Pathology

Viruses

Mutations in the <em>vpu</em> and <em>env</em> Genes of HIV-1 Can Adversely Impact Infectivity: A Dissertation

Richards, Kathryn H.

12 May 2008

The Human Immunodeficiency Virus (HIV) is able to infect CD4+ T cells as well as macrophages. Macrophage-tropism has been linked to determinants in the envelope of HIV. These determinants allow envelopes to exploit low levels of CD4 for infection. Macrophages are an important reservoir of virus, especially during chronic infection, and are likely responsible for the bulk of virus produced after CD4+T cells have declined. Viral factors that may impact the ability to infect macrophages are worth studying because this cell type is so important in infection. It was previously reported that the macrophage-tropic primary isolate AD8 was vpu-independent. The molecular clone YU-2, derived from brain tissue without culture, was also reported to be macrophage-tropic despite having a mutation in the vpu start codon. It was therefore possible that vpu-independent envelopes could evolve in vivo. To examine this possibility, I constructed chimeras containing wild type or defective vpu start codons, and gp160 sequences from AD8, YU-2 or SF162 (a vpu-dependent control). I also used full length AD8 and YU-2 with wild type or defective vpu start codons. I infected macrophages with equal amounts of virus, and measured viral output over two weeks. Viruses with defective vpu start codons were released to lower levels compared to their wild type vpucounterparts. In contrast to previous reports, the AD8 envelope is not vpu-independent for replication in macrophages. The YU-2 envelope is also not vpu-independent. Macrophage-tropic envelopes from late stages of infection can be sensitive to antibodies that bind the CD4 binding site on gp120, implying that macrophage-tropic envelopes have more exposed CD4 binding sites. Neutralizing antibodies may act as modulators of macrophage-tropism over the course of infection. Using chimeras containing gp120 sequences derived from the PBMC of four HIV+patients, I examined the capacity for envelopes to infect macrophages. Three patients (MM1, 4, and 8) had macrophage-tropic envelopes before and after developing autologous neutralizing antibodies. Three patients (MM1, 4, and 23) developed heterologous antibodies against IIIB, an easily neutralized T-cell line adapted strain of HIV-1. This data indicates that macrophage-tropism in these patients is not modulated by the presence of neutralizing antibodies. The macrophage-tropism of envelopes tends to segregate depending on the tissue origin of the virus. Envelopes from two separate tissues from the same patient exhibit very different infectivity characteristics. The B33 envelope, from brain tissue, is very infectious and is macrophage-tropic, while the LN40 envelope, from lymph node tissue, is weakly infectious and is not macrophage-tropic. Replacing the entire gp41 of LN40 with that of B33 restores some infectivity to LN40. The cytoplasmic domain of gp41 contains many motifs important for assembly and infectivity. To examine which motifs are responsible for the weak infectivity of LN40, I made chimeras of gp41, as well as point mutations in gp41. The LN40 chimera containing the entire gp41 of B33 restored the most infectivity. Point mutations in the palmitoylation site, Pr55gagbinding region, and dileucine motif at the C-terminus also restored infectivity when combined. Determinants in the gp41 cytoplasmic domain are responsible for the weak infectivity of LN40; however, it is possible that there are contributing determinants in gp120, such as the ability to use low levels of CD4. Here, I examined how changes in the vpu and env genes of HIV-1 can impact infectivity, especially infectivity of macrophages. Changes that adversely impact the virus’ ability to infect macrophages may also impact the overall course of disease. However, the data here show that retaining the ability to infect, and replicate in, macrophages give HIV an advantage. I speculate that retaining the ability to infect macrophages gives the virus a reservoir for later in disease, when CD4+ T cells have been depleted, as well as way of avoiding neutralizing antibodies. This work further defines the importance of macrophages in HIV-1 infectivity and disease.

HIV-1

HIV Infections

Tropism

Viral Envelope Proteins

Macrophages

Human Immunodeficiency Virus Proteins

Viral Regulatory and Accessory Proteins

Virus Replication

Amino Acids, Peptides, and Proteins

Cells

Genetic Phenomena

Hemic and Immune Systems

Viruses