Developing a Recombinant Plant Virus Nanoparticle Vaccine for Rift Valley Fever Virus

Chun, Elizabeth M

01 January 2019

Rift Valley Fever (RVF) is an emerging infectious disease found in both livestock and humans. RVF is associated with high abortion and mortality rates in livestock and can be fatal in humans. As such, RVF is economically and socially significant to affected smallholder and subsistence farmers, those infected, and national livestock industries. However, Rift Valley Fever virus (RVFV) vaccines are not commercially available outside of endemic areas or for humans, and current vaccines are limited in their safety and efficacy. A plant-based, viral nanoparticle vaccine offers a more affordable alternative to conventional vaccines that is safe, rapidly producible, and easily scalable, better meeting the needs of impacted communities. This project focuses on assessing the potential of using a Nicotiana benthamiana plant expression system to generate recombinant tobacco mosaic virus (TMV) nanoparticles displaying RVFV glycoprotein epitopes. Eight TMV-RVFV glycoprotein constructs were designed. Five TMV-RVFV constructs were successfully cloned, and four recombinant TMV constructs were successfully expressed in planta. The antigenicity of these constructs was examined for their possible use in RVFV vaccine development.

viral zoonosis

virus-like particles VLPs

agrobacterium tumefaciens

plant-based vaccine development

Animal Sciences

Biology

Immunology and Infectious Disease

Molecular Biology

Plant Sciences

Virology

Vaccine development during a pandemic : A case study of an academic research group in Sweden and their vaccine(s) against SARS-CoV-2

Tarnovskaya, Anna

January 2023

This ethnographic study examines the multiple ways in which a vaccine against SARS-CoV-2 disease and infection is known in an academic research group in Sweden. This academic research group has been working to develop a vaccine since the start of the COVID-19 pandemic in early 2020. Theoretically, this study builds on a grounded theory methodological approach as re-worked by medical sociologist Adele Clarke in her 2005 work “Situational analysis”, as well as on studies of immunology and microbiology within anthropology, sociology, science and technology, and philosophy of science. The findings are generated mostly through interviews with scientists of the academic research group and through participant-observation of the group’s work during September 2020-April 2021. This thesis conceptualises the vaccine being developed by the research group as not one, but multiple objects of knowledge – the vaccine is namely known both as machinic and as a loved deity. These different knowledges of vaccine are constituted through different discursive practices in vaccine development work, and by differential relations between human and non-human actors including discourses that participate in these practices. These different knowledges of vaccine also entail different perspectives on whether the vaccine being developed by the research group is a solution for protecting people from COVID-19 disease.

vaccine development

COVID-19

discursive practices

situational analysis

grounded theory

DNA vaccine

Cultural Studies

Kulturstudier

Other Humanities not elsewhere specified

Övrig annan humaniora

Social Anthropology

Socialantropologi

The fish pathogen Francisella orientalis : characterisation and vaccine development

Ramirez Paredes, J. G.

January 2015

Piscine francisellosis in an infectious emerging bacterial disease that affects several marine and fresh water fish species worldwide, including farmed salmon, wild and farmed cod, farmed tilapia and several ornamental species, for which no commercial treatment or vaccine exists. During 2011 and the first semester of 2012, chronic episodes of moderate to high levels of mortality with nonspecific clinical signs, and widespread multifocal white nodules as the most consistent gross pathological lesion were experienced by farmed tilapia fingerlings at two different locations in Northern Europe. In this study such outbreaks of granulomatous disease were diagnosed as francisellosis with a genus-specific PCR, and 10 new isolates of the bacterium including the one named STIR-GUS-F2f7, were recovered on a new selective “cysteine blood-tilapia” agar and cysteine heart agar with bovine haemoglobin. Ultrastructural observations of the pathogen in Nile tilapia (O. niloticus) tissues suggested the secretion of outer membrane vesicles (OMVs) by the bacterial cells during infection in these fish. This represented the first documented report of isolation of pathogenic Francisella strains from tilapia in Europe. The phenotypic characterisation indicated that isolates recovered were able to metabolise dextrin, N-acetyl-D glucosamine, D-fructose, α-D-glucose, D-mannose, methyl pyruvate, acetic acid, α-keto butyric acid, L-alaninamide, L-alanine, L-alanylglycine, L-asparagine, L-glutamic acid, L-proline, L-serine, L-threonine, inosine, uridine, glycerol, D L-α-glycerol phosphate, glucose-1-phosphate and glucose-6-phosphate. The predominant structural fatty acids of the isolates were 24:1 (20.3%), 18:1n-9 (16.9%), 24:0 (13.1%) 14:0 (10.9%), 22:0 (7.8%), 16:0 (7.6%) and 18:0 (5.5%). Anti-microbial resistance analyses indicated that STIR-GUS-F2f7 was susceptible to neomycin, novobiocin, amikacin, ciprofloxacin, imipenem, gatifloxacin, meropenem, tobramycin, nitrofurantoin, and levofloxacin using the quantitative broth micro-dilution method, while the qualitative disc diffusion method indicated susceptibility to enrofloxacin, kanamycin, gentamicin, tetracycline, oxytetracycline, florfenicol, oxolinic acid and streptomycin. The use of the following housekeeping genes: mdh, dnaA, mutS, 16SrRNA-ITS-23SrRNA, prfB putA rpoA, rpoB and tpiA indicated 100% similarity with other isolates belonging to the subspecies F. noatunensis orientalis (Fno). Koch’s postulates were successfully fulfilled by establishing an intraperitoneal injection (IP) challenge model with STIR-GUS-F2f7 in Nile tilapia. Moreover, the challenge model was used to investigate the susceptibility of 3 genetic groups of tilapia to STIR-GUS-F2f7. The lowest amount of bacteria required to cause mortality was 12 CFU/ml and this was seen as early as only 24 hours post infection in the red Nile tilapia and in the wild type after 26 days, no mortalities were seen in the species O. mossambicus with this dose. The mortality in red O. niloticus was significantly higher than that of the other two tilapia groups when 12 and 120 CFU/fish were injected. It was also observed that when a dose of 1200 CFU/ml was used, the mortality in O. niloticus wild type was significantly lower than that of the other two tilapia groups and no differences were seen among the 3 groups when the highest dose (1.2 x105 CFU/fish) was used. The median lethal dose (LD50) of O. niloticus wild type was the most stable during the experiment (values around 104 CFU/ml) and the highest of the three groups after day 25 post infection. At the end of the experiment (day 45) the LD50 was 30 CFU/ml in the red Nile tilapia, 2.3x104 CFU/ml for the wild type and 3.3x102 CFU/ml for O. mossambicus. This pattern, where the LD50 of the red tilapia was lower than that of the other two groups, was observed during the whole experiment. The outcomes of these experiments suggested that the red Nile tilapia family appeared to be the most susceptible while the wild type Nile tilapia family the most resistant. The complete genome of STIR-GUS-F2f7 was sequenced using next generation sequencing (NGS) Illumina Hi-Seq platform™, and the annotation of the assembled genome predicted 1970 protein coding sequences and 63 non-coding rRNA sequences distributed in 328 sub-systems. The taxonomy of the species Francisella noatunensis was revised using genomic-derived parameters form STIR-GUS-F2f7 and other strains in combination with a polyphasic approach that included ecologic, chemotaxonomic and phenotypic analyses. The results indicated that STIR-GUS-F2f7 and all the other strains from warm water fish represent a new bacterial species for which the name Francisella orientalis was assigned. Moreover the description of F. noatunensis was emended and the creation of a new subspecies within this taxon i.e. Francisella noatunensis subsp. chilense was proposed. The results of this study led to the development of a highly efficacious vaccine to protect tilapia against francisellosis.

639.3

Mechanistic Insights into Translation and Replication of Hepatitis C Virus RNA : Exploring Direct-Acting Antivirals

Kumar, Anuj

January 2014

Hepatitis C virus (HCV), a blood-borne pathogen, is a small enveloped RNA virus belonging to the Hepacivirus genus of the Flaviviridae family. HCV infection represents one of the major health concerns affecting approximately 170 million people globally. Patients with chronic HCV infection are at risk of developing hepatic fibrosis, cirrhosis and hepatocellular carcinoma. No protective anti-HCV vaccine is available yet. Until recently, standard therapy based on pegylated interferon plus ribavirin, was inadequate in treating all the patients as it results in a sustained virological response in only 40 to 50 percent of patients infected with the most common genotype (gt 1). Advances in understanding host-HCV interactions have helped developing newer anti-HCV agents such as telaprevir and boceprevir. However, treatment success is still limited due to different factors including genotype specificity, high cost, potential drug-drug interactions, substantial side effects etc. The positive-sense single-stranded RNA genome of HCV is approximately 9.6kb long which is flanked by highly structured and conserved 5’ and 3’ untranslated regions (UTRs) at both ends. Unlike cap-dependent translation of host cell mRNAs, HCV translation is mediated by an internal ribosomal entry site (IRES) present majorly within the 5’UTR. Several reports have demonstrated the interaction of different cellular proteins with HCV-5’UTR and/or 3’UTR, which include human La protein, polypyrimidine tract binding protein (PTB), poly (rC)-binding protein 2 (PCBP2) etc. These interactions of trans-acting factors with the UTRs may be important for HCV translation and/or replication. Earlier study from our laboratory revealed the importance of interaction of human La protein, by its central RNA recognition motif (RRM), with the HCV IRES around a tetranucleotide sequence GCAC near initiator AUG in influencing HCV translation. However, the role of this interaction, if any, in HCV RNA replication was not known. In the first part of the thesis, we characterized the interaction between human La protein and the GCAC to understand its role in HCV replication. We incorporated mutation, which altered the binding of La, in the GCAC motif in HCV monocistronic replicon and checked HCV RNA replication by reverse transcriptase polymerase chain reaction (RT-PCR). The mutation drastically inhibited HCV replication. Interestingly, overexpression of La could reverse the effect of this mutation and significantly enhanced HCV RNA levels. Using a bicistronic replicon, we observed that decrease in replication was independent of translation inhibition. Furthermore, mutation at the GCAC motif reduced the association between La and viral polymerase, NS5B as seen in co-immunoprecipitation assays. Moreover, this mutation affected translation to replication switch regulated by the interplay between HCV-NS3 protease and human La protein. Our analyses of point mutations, based on RT-PCR and luciferase assays, revealed distinct roles of each nucleotide of the GCAC motif in HCV replication and translation. Finally, 5’-3’ crosslink assays revealed that specific interaction of the GCAC motif with human La protein is important for linking 5’ and 3’ends of HCV genome. Results clearly demonstrate the mechanism of regulation of HCV replication by interaction of cis-acting element GCAC within the HCV IRES with human La protein. HCV is highly species-specific. Under natural conditions, HCV infects only humans and chimpanzees. This restricted host-tropism has prevented the development of a small animal model to study HCV infection in vivo. Although several human-specific entry factors have been identified to be responsible for this species selectivity, full multiplication of the HCV in animals (other than humans and chimpanzees) is still not possible. In the second part of the thesis, we showed that a post-entry host factor –‘La protein’ may also contribute in determining HCV host tropism. We aligned La protein sequences from different species and interestingly we found that HCV RNA interacting beta-turn sequence (KYKETDL) in central RRM (residues 112-184) is conserved only in human and chimpanzee. Earlier, it was shown from our laboratory that a heptameric peptide comprising of this sequence (derived from human La) could inhibit HCV translation by competing with La interaction with the IRES element. However, in the current study, another peptide corresponding to the mouse La sequence (KYKDTNL) was unable to inhibit HCV RNA translation. Similarly, wild-type mouse La (mLa) failed to stimulate HCV IRES function, but addition of chimeric mouse La protein bearing human beta-turn sequence (mLahN7) significantly increased HCV IRES mediated translation in vitro. Also, exogenous supplementation of mLahN7 enhanced HCV translation in cell culture system. Moreover, quantitative as well as tagged RT-PCR analyses showed an enhanced HCV replication upon overexpression of mLahN7. The findings obtained in this part raise a possibility of creating HCV mouse model using human specific cellular entry factors and a humanized form of La protein. Hepatitis C has emerged as a major challenge to the medical community. Developing more potent and safe anti-HCV regimens is need of the hour. As described above, a linear hepatapeptide (KYKETDL) was synthesized and shown to reduce HCV translation. However, this linear peptide was stable only for a shorter time scale. Therefore, in the third part of the thesis, effect of a more stable cyclic form of this peptide has been described. NMR spectroscopy suggested that the beta turn conformation is preserved in cyclic peptide as well. Also, using in vitro bicistronic reporter assay, we demonstrated that cyclic peptide inhibits HCV translation in a dose dependent manner. In fact, due to its higher stability, cyclic peptide reduced HCV translation and replication more efficiently than the corresponding linear peptide at longer post-treatment time point. Additionally, we observed that cyclic peptide is non-toxic in cell culture system. Our results suggest that cyclic peptide might emerge as a promising lead compound against hepatitis C. Due to availability of only partially effective liver protective drugs in modem medicine, complementary and alternative medicine approach, based on plant derived compounds, is also being utilised against HCV. Plant derived compounds have advantages of having high chemical diversity, drug-likeliness properties and ability of being metabolized by the body with little or no toxicity than synthetic ones. Different studies have shown that phytochemicals may exert anti-HCV activities by acting as direct-acting antivirals and play a potential therapeutic role in treating HCV infection. Also, from our laboratory, it was shown that methanolic extract of Phyllanthus amarus (P. amarus) plant inhibited HCV replication. The fourth part of the thesis describes the study on the anti-HCV properties of several bioactive components from P. amarus extract. Using a fluorimetric assay, we demonstrated that two principal components of this extract, phyllanthin and corilagin reduced the HCV NS3 protease activity significantly in vitro. We also observed a sharp reduction in HCV negative sense RNA levels in cell culture system. Structural knowledge-based molecular docking studies showed interactions of phyllanthin and corilagin with the amino acid residues of the catalytic triad of NS3 protease. Further, these compounds were found to be non-toxic in cell culture. Also, phyllanthin and corilagin displayed antioxidant properties by blocking HCV induced oxidative stress generated by reactive oxygen species suggesting their hepatoprotective nature. More importantly, our in vivo toxicity analyses and pharmacokinetics studies proved their safety, tolerability, metabolic stability, and systemic oral bioavailability and support their potential as novel anti-HCV therapeutic candidates. Altogether, the study deciphers mechanistic details of translation and replication of HCV RNA and demonstrates novel antiviral agents targeting these important viral processes.

Hepatitis C Virus RNA

HCV Genotypes

HCV Vaccines

Hepatitis C Virus Infection

Antivirals

Human La Protein

Hepatitis C Virus Life Cycle

Viral Proteins

HCV Replication

HCV IRES

HCV Translation

HCV Infection

HCV Vaccine Development

Hepatitis C Virus (HCV)

Microbiology and Cell Biology