Biophysical properties of the turnip yellow mosaic virus explored by coat protein mutagenesis

Powell, Joshua D.

05 April 2012

Plant viruses have been instrumental in our understanding of the biophysical properties pertaining to non-enveloped icosahedral virus particles. A substantial amount of research has been performed over five decades on Turnip yellow mosaic virus (TYMV), arguably one of the most extensively studied icosahedral plant viruses and the type-member of the Tymovirus plant virus genus. Even with a substantial body of published scientific literature, little is known about the role of specific coat protein (CP) residues in TYMV assembly, disassembly and disencapsidation. We have shown through our mutagenesis studies that the N-terminal region of the CP that is involved in the formation of an annulus structure and is disordered in A-subunit pentamers is not essential in vivo, but annulus-forming residues are critical in ensuring virion stability and low accessibility after virus is purified (Chapter 2). We have shown that a range of amino acid residue types is tolerated within the CP N-terminus in vivo, although they can greatly affect the stability of virions and empty particles, most notably at low pH (Chapter 3). Unlike full-length CP, N-terminal deletion and substitution mutants fail to reassemble into particles in vitro (Chapter 2, 3) suggesting a critical determinant for the N-terminus in reassembly (discussed Chapter 7). This is the first documented in vitro reassembly reported for a member of the Tymoviridae family and should provide a framework for further studies. We have identified a new way to create empty artificial top component (ATC)-particles through treatment with EDTA (Chapter 6) and we also show that tymoviruses can be engineered with altered pH-dependent enhanced stability (Chapter 4). In collaboration with the Qian Wang laboratory from the University of South Carolina we have shown that an RGD (Arg-Gly-Asp) motif can be genetically engineered within the CP of TYMV, resulting in infectious particles with attractive stem-cell adhesion properties (Chapter 5). With focus on basic viral mechanisms, we have crystallized the TYMV virion and ATC particle at pH 7.7 and collected data to less than 5 Å resolution (Chapter 4, supplementary). These structures represent the first tymovirus-based structures solved above pH 5.5 and will provide insight into the N-terminal conformations within the TYMV particle. Finally, we have characterized an N-terminal CP cleavage seen after ATC formation (Chapter 4) suggesting an additional and yet uncharacterized feature associated with decapsidation. / Graduation date: 2012

TYMV

plant virus

RGD arg-gly-asp

virus-like particle: VLP

Turnip yellow mosaic virus

Viruses -- Reproduction

Viral envelopes

Příprava polyomavirových nanostruktur pro diagnostiku BK virových infekcí / Preparation of polyomaviral nanostructures for diagnostics of BK virus infections

Sekavová, Alžběta

January 2017

No description available.

Development of Virus-like particles (VLPs) Based Vaccines Against Porcine Reproductive and  Respiratory Syndrome Virus (PRRSV) and Porcine Epidemic Diarrhea Virus (PEDV)

Lu, Yi

16 March 2020

Porcine reproductive and respiratory syndrome virus (PRRSV) and porcine epidemic diarrhea virus (PEDV) are two of the most prevalent swine pathogens that have impacted the global swine industry for decades. Both are RNA viruses with increasing heterogeneity over the years, making a vaccine solution ever so challenging. Modified live-attenuated vaccines (MLVs) have been the most common approach, but the long-term safety regarding their potential for pathogenic reversion still needs to be addressed. Subunit based vaccines have been the focus of numerous development studies around the world with renewed interest in their promising prospects in both safety and efficacy. Our lab has developed a unique approach to use hepatitis B virus core capsid protein (HBcAg) as a vaccine delivery vehicle for either PRRSV or PEDV viral epitope antigens. Recombinantly produced HBcAg forms an icosahedral capsid virus-like particle (VLP) that has 240 repeats in a single assembled particle. By inserting different epitope antigens from these porcine pathogens into the particle, we can achieve repetitive antigen presentation to the host's immune system by taking advantage of the polymeric nature of VLP. The first animal study evaluated the efficacy of 4 VLP based vaccine candidates against PRRSV in mice. These 4 vaccines incorporated 2 B-cell epitopes (61QAAIEVYEPGRS72 and 89ELGFVVPPGLSS100) and 2 T-cell epitopes (117LAALICFVIRLAKNC131 and 149KGRLYRWRSPVIIEK163) from PRRSV structural proteins GP3 and GP5 respectively. Candidate GP3-4 was able to stimulate a significant viral neutralizing response in mouse sera against two PRRSV strains, one being heterologous, demonstrating its potential of cross-protection against PRRSV. The second animal study took an optimized VLP vaccine candidate against PEDV from previous development studies in mice, and assessed its efficacy through a comprehensive pregnant gilt vaccination and neonatal piglet challenge model. The vaccine candidate incorporated B-cell epitope 748YSNIGVCK755 from the PEDV spike protein. It was able to elicit significant viral neutralization antibody titer in gilt milk at 3 days post-farrowing (DPF), and provided nursing piglets with clinical relief in terms of morbidity, viral shedding, small intestinal lesions, and 10 days post-challenge (DPC) survival rate. / Doctor of Philosophy / Porcine reproductive and respiratory syndrome virus (PRRSV) and porcine epidemic diarrhea virus (PEDV) are two pathogens that infect pigs, resulting in immense economic losses to the global pork production industry every year. Both viruses have large diversity with various strains due to mutations that have occurred over the years. This makes vaccine development that aims at combating the pathogens even more challenging. One common vaccine strategy has been immunizing animals with modified live viruses with decreased pathogenicity. Naturally, long term safety of this option has been a concern. A much safer vaccine approach that is purely protein based has attracted renewed interest around the world. Protein based vaccines lack genetic materials from the viruses and are not able to replicate inside the host. Our lab has developed a platform that uses protein-based particles (VLPs) originated from the hepatitis B virus (HBV), and incorporates short pieces of proteins from either PRRSV or PEDV to train host's immune system to recognize these pathogens, and hopefully to prevent future infection. For the first animal study, we tested 4 VLP vaccine candidates against PRRSV in mice and discovered that mouse serum from one candidate GP3-4 was able to prevent infection of 2 distinct PRRSV strains in petri dishes, paving the way for further development. For the second animal study, we took an optimized VLP vaccine candidate against PEDV from previous mouse studies, and evaluated its performance in pigs. We immunized pregnant mother pigs with the vaccine before they gave birth, then experimentally infected newborn piglets with the virus. Piglets from the vaccinated mothers showed improved clinical signs and faster recovery from the infection.

Virus-like particle (VLP)

Hepatitis B Virus Core Antigen (HBcAg)

Recombinant Vaccine

Porcine Epidemic Diarrhea Virus (PEDV).

HOW TO BE A BAD HOST FOR VIRUSES BY UNDERSTANDING THE COMPLEXITIES OF HOST LIPID-VIRAL PROTEIN INTERACTIONS

Emily A David (17583603)

10 December 2023

<p dir="ltr">The recent global pandemic, COVID-19, has revealed to all the importance of understanding the complex relationship between viruses and hosts. Before COVID-19, I started my study of viral protein-host lipid interactions in the hemorrhagic fevers Ebola and Marburg viruses. These viruses contain a matrix protein that interacts with the plasma membrane to facilitate the formation of both authentic viruses and virus-like particles. My goal was to understand the limitations of their specific host lipid interactions. However, when the COVID-19 pandemic began, so to be our swift response in the development of a biosafety level 2 compatible model. This model can be used for studying severe acute respiratory distress syndrome 2 (SARS-CoV-2) assembly, egress, and entry. This model enabled exponentially greater access to more facilities to study the intricacies of SARS-CoV-2 assembly. With more access to studying the virus in a safe model, our goal is to push the understanding of viral assembly faster. I then began to take apart the individual pieces of the model and started to look at understanding the roles that they play independently. The membrane protein is the most abundant structural protein and I studied the specific lipid interactions of the soluble fraction of the protein. Physicians observed nucleocapsid protein mutations in the clinic with the increasing number of SARS-CoV-2 variants that are on the rise. The microscopy data collected can give us more insight into perhaps how the nucleocapsid protein induces the formation of filopodia structures at the plasma membrane. The envelope protein proved to be a challenge, but I determined a specific envelope and ceramide interaction in cells. The envelope protein was also causing the formation of microvesicles for an undefined function. I was able to determine the subcellular localization of the protein to the mitochondria. The localization to the mitochondria appears to induce depolarization of the mitochondria membrane action potential and induces the increase in mitochondria dysfunction signal, cytochrome c. Although the mitochondria were dysfunctional, there was no increase in apoptosis signal in the presence of the protein alone.</p>

Enzymes

Protein trafficking

Virology

Medical biochemistry - lipids

Medical virology

Cell physiology

Basic pharmacology

BSL-2

Virus-like particle VLP

SARS-CoV-2

EBOV (Ebola virus)

mitochondrial membrane localization

lipid interaction studies

ceramide

scanning electron microscopy methodology

SARS-CoV-2-N

SARS-CoV-2-E

SARS-CoV-2-M

VP40