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Functional characterization of the US3 serine/threonine kinase during BHV-1 infection

Bovine herpesvirus 1 (BHV-1) is a member of the Alphaherpesvirinae subfamily and is the prototype ruminant herpesvirus. BHV-1 causes a number of complications in cattle including upper respiratory tract disorders, conjunctivitis, genital disorders, abortions, and immune suppression. Like all herpesviruses, reactivation from latency can occur throughout the animal’s life. Of particular economic importance is the bovine respiratory disease complex (BRDC) or ‘shipping fever’, in which BHV-1 plays a major role. BRDC is an enormous economic concern as it costs the US cattle industry approximately one billion dollars annually.

In order to generate improved gene-deleted vaccines against BHV-1, there is a need to understand the contributions of viral gene products during infection. US3 is a serine/threonine kinase present in BHV-1 and is thought to play major roles during viral infection. As in other herpesviruses, US3 in BHV-1 is expected to phosphorylate several cellular and/or viral proteins. We recently presented evidence that BHV-1 US3 phosphorylates both VP8 and VP22; however, further functional characteristics of BHV-1 US3 during viral infection have not been elucidated.

The hypothesis of this project is that the deletion of the US3 gene leads to reduced BHV-1 fitness. To explore this hypothesis, we generated a US3-deleted (ΔUS3) and subsequent US3-rescued (US3R) BHV-1 virus. Using these viral mutants, we characterized the growth properties of the viruses, evaluated the effect of the US3 deletion on major structural BHV-1 proteins, characterized the protein composition of the mature virions, and, identified viral processes that were impaired in the deletion mutant.

Initially, the ∆US3 virus was generated through a 3-step PCR strategy which replaced the gene of interest with an antibiotic resistance cassette. Following this, the US3 gene was rescued via a two-step en passant mutagenesis strategy which has been previously used to generate insertions, deletions, and substitutions in herpesvirus-containing bacterial artificial chromosome (BAC) DNA.

In vitro characterization of ∆US3 BHV-1 has demonstrated that US3 deletion affects BHV-1 growth characteristics, expression kinetics of major structural proteins, mature virion composition, cell to cell spread, and the subcellular localization of key viral proteins during infection. Growth kinetics of ∆US3 BHV-1 were impaired compared to wild-type (WT) BHV-1, especially at late times post-infection. Plaque sizes formed by ∆US3 BHV-1 were significantly smaller than those formed by either WT or US3R BHV-1, demonstrating that US3 is important for cell to cell spread. The expression kinetics of major structural and regulatory BHV-1 proteins were different between cells infected with ∆US3 or WT BHV-1, and incorporation of these proteins into the mature viruses differed, demonstrating that US3 is instrumental in ensuring proper protein expression and mature virus composition in vitro.

Of particular importance, glycoprotein B (gB), was shown to be expressed in higher quantities earlier during infection in the absence of US3, and that this protein was incorporated in significantly higher amounts in mature virions which lacked US3. Qualitative analysis of ∆US3 BHV-1 infected monolayers suggested the abolishment of cell to cell projections characteristic of WT BHV-1 infection. Finally, the disruption of gB in ∆US3 BHV-1 infected cells was confirmed by confocal microscopy and fluorescence-activated cell sorting (FACS) analysis. Through confocal microscopy, evidence was provided that infection with ∆US3 BHV-1 possibly results in earlier expression of gB on the surface of cells and less intracellular accumulation of this protein during late stages of infection. The observed effect on the localization of intracellular gB in ∆US3 BHV-1 infected cells was quantified by flow cytometry. ∆US3 BHV-1 infected cells had approximately 25% higher gB expression on the surface of cells and a corresponding 25% decrease in intracellular gB. Although these differences have not yet been demonstrated to be statistically significant and not confirmed through infection with US3R BHV-1, this suggests that US3 may influence the synthesis and cellular trafficking of gB in vitro.

Identiferoai:union.ndltd.org:USASK/oai:ecommons.usask.ca:10388/ETD-2013-08-1201
Date2013 August 1900
Contributorsvan Drunen Littel-van den Hurk, Sylvia
Source SetsUniversity of Saskatchewan Library
LanguageEnglish
Detected LanguageEnglish
Typetext, thesis

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