Studies on HIV-1 core assembly /

Abdurahman, Samir,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 4 uppsatser.

A study into the protein/protein interactions involved in HIV-1 capsid assembly

Douglas, Chanel Catherine.

January 2007

Thesis (Ph. D.)--University of Alabama at Birmingham, 2007. / Title from first page of PDF file (viewed Feb. 17, 2009). Includes bibliographical references.

Coupling selection of the HIV-1 tRNA primer used for reverse transcription with viral translation and encapsidation

Djekic, Uros V.

January 2007

Thesis (Ph. D.)--University of Alabama at Birmingham, 2007. / Title from first page of PDF file (viewed June 23, 2008). Includes bibliographical references.

The role of HSP70 chaperones in papovavirus disassembly and assembly /

Chromy, Laura R.

January 2007

Thesis (Ph.D. in Molecular Biology) -- University of Colorado Denver, 2007. / Typescript. Includes bibliographical references (leaves 142-165). Free to UCD affiliates. Online version available via ProQuest Digital Dissertations;

Role of the gM/gN glycoprotein complex in the final assembly and egress of the human cytomegalovirus (HCMV)

Krzyzaniak, Magdalena Anna.

January 2008

Thesis (Ph. D.)--University of Alabama at Birmingham, 2008. / Title from first page of PDF file (viewed Sept. 16, 2008). Includes bibliographical references.

Analysis of the pseudorabies virus tegument proteins Us3, VP22 and Us2 /

Lyman, Mathew G.

January 2005

Thesis (Ph.D. in Microbiology) -- University of Colorado at Denver and Health Sciences Center, 2005. / Typescript. Includes bibliographical references (leaves 142-168). Free to UCDHSC affiliates. Online version available via ProQuest Digital Dissertations;

The requirement of the DEAD-box protein DDX24 for the packaging of human immunodeficiency virus type 1 RNA /

Ma, Jing, 1978-

January 2008

No description available.

DEAD-box RNA Helicases -- metabolism.

RNA, Viral -- metabolism.

HIV-1 -- physiology.

Virus Assembly -- physiology.

Computational Analysis of Viruses in Metagenomic Data

Tithi, Saima Sultana

24 October 2019

Viruses have huge impact on controlling diseases and regulating many key ecosystem processes. As metagenomic data can contain many microbiomes including many viruses, by analyzing metagenomic data we can analyze many viruses at the same time. The first step towards analyzing metagenomic data is to identify and quantify viruses present in the data. In order to answer this question, we developed a computational pipeline, FastViromeExplorer. FastViromeExplorer leverages a pseudoalignment based approach, which is faster than the traditional alignment based approach to quickly align millions/billions of reads. Application of FastViromeExplorer on both human gut samples and environmental samples shows that our tool can successfully identify viruses and quantify the abundances of viruses quickly and accurately even for a large data set. As viruses are getting increased attention in recent times, most of the viruses are still unknown or uncategorized. To discover novel viruses from metagenomic data, we developed a computational pipeline named FVE-novel. FVE-novel leverages a hybrid of both reference based and de novo assembly approach to recover novel viruses from metagenomic data. By applying FVE-novel to an ocean metagenome sample, we successfully recovered two novel viruses and two different strains of known phages. Analysis of viral assemblies from metagenomic data reveals that viral assemblies often contain assembly errors like chimeric sequences which means more than one viral genomes are incorrectly assembled together. In order to identify and fix these types of assembly errors, we developed a computational tool called VirChecker. Our tool can identify and fix assembly errors due to chimeric assembly. VirChecker also extends the assembly as much as possible to complete it and then annotates the extended and improved assembly. Application of VirChecker to viral scaffolds collected from an ocean meatgenome sample shows that our tool successfully fixes the assembly errors and extends two novel virus genomes and two strains of known phage genomes. / Doctor of Philosophy / Virus, the most abundant micro-organism on earth has a profound impact on human health and environment. Analyzing metagenomic data for viruses has the beneFIt of analyzing many viruses at a time without the need of cultivating them in the lab environment. Here, in this dissertation, we addressed three research problems of analyzing viruses from metagenomic data. To analyze viruses in metagenomic data, the first question needs to answer is what viruses are there and at what quantity. To answer this question, we developed a computational pipeline, FastViromeExplorer. Our tool can identify viruses from metagenomic data and quantify the abundances of viruses present in the data quickly and accurately even for a large data set. To recover novel virus genomes from metagenomic data, we developed a computational pipeline named FVE-novel. By applying FVE-novel to an ocean metagenome sample, we successfully recovered two novel viruses and two strains of known phages. Examination of viral assemblies from metagenomic data reveals that due to the complex nature of metagenome data, viral assemblies often contain assembly errors and are incomplete. To solve this problem, we developed a computational pipeline, named VirChecker, to polish, extend and annotate viral assemblies. Application of VirChecker to virus genomes recovered from an ocean metagenome sample shows that our tool successfully extended and completed those virus genomes.

Metagenomics

Virus

Phage

Viral Read Classification

Viral Genome Assembly

Improvement of Virus Assembly

Development of Computational Pipeline

The mechanisms of Pol expression and assembly for human foamy virus /

Baldwin, David Norris.

January 1999

Thesis (Ph. D.)--University of Washington, 1999. / Vita. Includes bibliographical references (leaves 98-107).

EXPLORATION OF THE STRUCTURAL AND BIOCHEMICAL ASSEMBLY MECHANISMS OF FLAVIVIRUSES.docx

Conrrad Makea Rupe Nicholls (18127627)

08 March 2024

<p dir="ltr">It is with great pleasure that I present the culmination of my exploration into the process of flavivirus assembly, with particular emphasis on the envelope glycoproteins and C protein of ZIKV and DENV2, within the subsequent four chapters of this dissertation.</p><p dir="ltr">Beginning in Chapter 2, we describe findings from a structure-function study of the ZIKV prM and E transmembrane helices (TMHs) and their role in virus assembly. Using a mutagenesis approach in a ZIKV reporter virus particle (RVP) system to increase throughput and discovery, substantial information was obtained showcasing a novel function for specific residues located within a short (4 residue) connecting region between the two TMHs of prM protein – denoted as the prM TMH “turn” residues. During translation of the prM and E proteins, these TMH “turn” residues face towards the cytosolic side of the ER membrane. This orientation has been hypothesized to possibly play a role during viral assembly interactions between the envelope glycoproteins and the nucleocapsid core of flaviviruses. However, no information to date has supported or refuted this theory. Overall, a single amino acid change within the prM TMH “turn” residues was found to be highly detrimental to viral assembly, ultimately leading to the loss of capsid integration into released sub viral particles and the alteration of the lipid membrane architecture. We surmised that lipid interactions around the region of the mutation were perturbed, leading to a loss of assembly capabilities but interestingly maintaining the budding mechanisms. The work of Chapter 2 will be submitted for publication to a peer reviewed journal shortly after the submission of this dissertation.</p><p dir="ltr">Chapter 3 expands on the ZIKV RVP results described in Chapter 2 by detailing a series of mutagenesis experiments into the role of the prM and E TMHs in the fully infectious ZIKV and DENV2 systems. Mutations within the prM TMH “turn” residues of DENV2 were found to also perturb virus infectivity, with two mutations within prM completely eliminating infectivity. The two mutants were found to be capable of producing NS5 and intracellular E protein that had been glycosylated, indicating that translation was intact and that E protein trafficking into the trans-Golgi network still occurred. However, unlike the results discussed in Chapter 2, the DENV2 mutants did not release any detectable E protein into their supernatants. This suggested that while the mutants could generate viral proteins and somehow undergo protein trafficking into the Golgi (signifying potential particle maturation), no particles were released. The DENV2 results were supported by reciprocal mutations in the prM proteins of ZIKV using fully infectious cDNA clones. The ZIKV prM mutants also eliminated virus infectivity and prevented the release of the E protein into the supernatant, indicating no release of viral particles, infectious or otherwise. Overall, the mutations in the fully infectious DNEV2 and ZIKV systems add further support for a novel role of the prM TMHs in flavivirus assembly.</p><p dir="ltr">Chapter 4 describes our efforts to reconstitute the flavivirus envelope glycoproteins into natively derived lipid nanoparticles for in vitro assembly analysis. Styrene-maleic acid copolymers (SMAs) were utilized for this study due to their ability to self-polymerize into highly hydrophobic chains in aqueous solutions. These hydrophobic chains can imbed themselves into lipid membranes to escape the aqueous environment, and in doing so “cut out” ~10nm diameter “patches” of native lipid membranes, along with any integrated membrane proteins. This “lipid/protein patch” is referred to as a styrene-maleic acid lipid nanoparticle (SMALP). Initially, attempts were made to generate SMALPs using purified Kunjin virus (KUNV) particles as the source of membrane lipids and glycoproteins due to their rapid growth rate and homogenous particle population. Unfortunately, attempts to generate SMALPs using purified KUNV were unsuccessful. It is hypothesized that the membrane curvature of purified KUNV particles generated a sterically and energetically unfavorable environment for SMALP generation, leading to the complete destruction of the particles during SMA mixing. To circumvent this issue, cells transfected with either WT or mutant ZIKV RVP cDNA were fractionated and purified ER membrane samples were mixed with SMAs to generate SMALPs. Western blot analysis suggested that the SMALP generation was successful. However, further experimentation is warranted to confirm this outcome and the structural integrity of the envelope glycoproteins within the SMALP.</p><p dir="ltr">Chapter 5 describes collaborative work on the identification of a novel compound inhibitor against flavivirus assembly, specifically targeting C protein’s interactions with RNA. This work was done in conjunction with a visiting scholar from the Indian Institute of Technology Mandi – Dr. Prateek Kumar – during his time at Purdue University from August 2022-May 2023. Much of the foundational computation work was done by Prateek prior to his arrival at Purdue University. As such, while the full context and results for the entirety of the study will be discussed, this chapter will primarily focus on the in vitro experimental results that were gathered directly by me, or results that were produced by Prateek and myself equally. This chapter demonstrates that a novel small molecule inhibitor against ZIKV C protein can, in fact, diminish ZIKV assembly by impeding C protein’s binding to RNA, prevent efficient RNA replication through binding and disruption of NS2B/3 protease, and perturb virus binding and entry prior to infection by also binding to E protein. Moreover, the novel molecule was also found to disrupt DENV2 infection as well, albeit to a lesser degree than ZIKV. This multifaceted molecule was recommended for further study in animal systems to continue testing its safety and efficacy for treatment of ZIKV and DENV2 in humans. A co-authorship manuscript has been completed on the work from this chapter and is currently awaiting submission to a peer reviewed journal.</p><p dir="ltr">Finally, Chapter 6 will combine the conclusions from the above chapters and discuss, in detail, aspects pertaining to the future of studies aiming to better understand the assembly of flaviviruses. This chapter will focus on how the link between viral assembly and membrane lipid architecture fits with previously established literature and what future directions could be employed to answer the questions proposed within.</p>

Infectious agents

Virology

flaviviruses dengue virus

Zika genome

structural biology

Zika

Dengue

Flaviviruses

Flavivirus assembly

virus assembly