Abstract

The herpesvirus maturational protease is essential for the production of infectious virus and is synthesized as a precursor that has multiple functions during capsid assembly. Since its discovery 12 years ago, it has received considerable attention as a possible target for antivirals, and in the past 7 years a wealth of information about this interesting, albeit challenging, enzyme has accumulated. The 28-kDa enzyme is derived from a 74-kDa precursor by autoproteolytic cleavage, first at the (M)aturational site near its carboxyl end, and then at the (R)elease site. R-site cleavage frees assemblin from the ---44-kDa carboxyl portion of the precursor. The proteolytic domain, called assemblin in cytomegaolvirus, has been cloned, purified, and studied in vitro. The enzyme is activated by dimerization but the dimer pair has two separate acitive sites, moreover, it differs remarkably from other serine proteases by its new fold (7- stranded [3 barrel) and catalytic triad (Ser-His-His). No comparable information is available about the precursor. Our objective is to learn more about this viral enzyme through biochemical and genetic studies, with particular attention to its precursor.
The specific aims are intended to help accomplish that objective by (i) applying mutant viruses to study the mechanism of this protease during virus infection, (ii) developing a protease mutant whose activity can be switched on in cells and in vitro by chemical rescue, (iii) investigating the ability of two catalytic-site mutants to form a complementation complex with selective specificity for the maturational-cleavage site, (iv) taking advantage of recent findings to investigate the structure of the precursor and compare its enzymatic properties with those of assemblin, and (v) investigating requirements and consequences of dimerization by both forms of the enzyme. Results of this work are anticipated to provide useful new information about this novel member of the serine proteinase family, and contribute to development of inhibitors that will block its function. It is also likely that useful new information will be generated in the areas of viral proteinase mechanisms and herpesvirus replication.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
5R01AI032957-15
Application #
7156940
Study Section
Virology Study Section (VR)
Program Officer
Dempsey, Walla L
Project Start
1992-07-01
Project End
2008-12-31
Budget Start
2007-01-01
Budget End
2008-12-31
Support Year
15
Fiscal Year
2007
Total Cost
$271,299
Indirect Cost

  Institution

Name
Johns Hopkins University
Department
Pharmacology
Type
Schools of Medicine
DUNS #
001910777
City
Baltimore
State
MD
Country
United States
Zip Code
21218

  Publications

Gibson, W (2008) Structure and formation of the cytomegalovirus virion. Curr Top Microbiol Immunol 325:187-204
Nguyen, Nang L; Loveland, Amy N; Gibson, Wade (2008) Nuclear localization sequences in cytomegalovirus capsid assembly proteins (UL80 proteins) are required for virus production: inactivating NLS1, NLS2, or both affects replication to strikingly different extents. J Virol 82:5381-9
Brignole, Edward J; Gibson, Wade (2007) Enzymatic activities of human cytomegalovirus maturational protease assemblin and its precursor (pPR, pUL80a) are comparable: [corrected] maximal activity of pPR requires self-interaction through its scaffolding domain. J Virol 81:4091-103
Loveland, Amy N; Nguyen, Nang L; Brignole, Edward J et al. (2007) The amino-conserved domain of human cytomegalovirus UL80a proteins is required for key interactions during early stages of capsid formation and virus production. J Virol 81:620-8
McCartney, Stephen A; Brignole, Edward J; Kolegraff, Keli N et al. (2005) Chemical rescue of I-site cleavage in living cells and in vitro discriminates between the cytomegalovirus protease, assemblin, and its precursor, pUL80a. J Biol Chem 280:33206-12
Loveland, Amy N; Chan, Chee-Kai; Brignole, Edward J et al. (2005) Cleavage of human cytomegalovirus protease pUL80a at internal and cryptic sites is not essential but enhances infectivity. J Virol 79:12961-8
Casaday, Rebecca J; Bailey, Justin R; Kalb, Suzanne R et al. (2004) Assembly protein precursor (pUL80.5 homolog) of simian cytomegalovirus is phosphorylated at a glycogen synthase kinase 3 site and its downstream ""priming"" site: phosphorylation affects interactions of protein with itself and with major capsid protein. J Virol 78:13501-11
Chan, Chee-Kai; Brignole, Edward J; Gibson, Wade (2002) Cytomegalovirus assemblin (pUL80a): cleavage at internal site not essential for virus growth; proteinase absent from virions. J Virol 76:8667-74
Plafker, S M; Gibson, W (1998) Cytomegalovirus assembly protein precursor and proteinase precursor contain two nuclear localization signals that mediate their own nuclear translocation and that of the major capsid protein. J Virol 72:7722-32
Gibson, W; Hall, M R (1997) Assemblin, an essential herpesvirus proteinase. Drug Des Discov 15:39-47

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