Proteolytic activity of human cytomegalovirus UL80 protease cleavage site mutants

The human cytomegalovirus UL80 open reading frame encodes protease and assembly protein from its N- and C-terminal regions, respectively. We reported previously that a 30-kDa protease is derived by autoproteolytic processing of a polyprotein which is the translation product of the entire UL80 open reading frame (E. Z. Baum, G. A. Bebernitz, J. D. Hulmes, V. P. Muzithras, T. R. Jones, and Y. Gluzman, J. Virol. 67:497-506, 1993). Three autoproteolytic cleavage sites within the UL80 polyprotein were characterized; site 143 is within the protease domain and inactivates the protease. In this article, we report (i) expression analyses of UL80 in infected cells, including the processing kinetics of the UL80 polyprotein; (ii) the existence of an additional cleavage site (site 209) within the protease domain of the UL80 polyprotein; and (iii) the effect of mutagenesis at each of the cleavage sites upon proteolytic activity and steady-state levels of the UL80 processing products. During the course of infection, UL80 polyprotein processing begins at cleavage site 643 and follows at sites 256 and 143. Cleavage at site 643 and/or 256 within the polyprotein is not a prerequisite for efficient protease activity, since all three proteases (85-, 80-, and 30-kDa proteins) were equally active in cleaving the assembly protein precursor to its mature form. Inhibition of cleavage at site 143 resulted in a three- to sixfold increase in the steady-state level of the 30-kDa protease, supporting the hypothesis that cleavage at this site may represent a mechanism by which cytomegalovirus regulates the level of active protease.

[1]  I. Deckman,et al.  Investigation of the specificity of the herpes simplex virus type 1 protease by point mutagenesis of the autoproteolysis sites , 1994, Journal of virology.

[2]  W. Gibson,et al.  Herpesvirus proteinase: site-directed mutagenesis used to study maturational, release, and inactivation cleavage sites of precursor and to identify a possible catalytic site serine and histidine , 1993, Journal of virology.

[3]  B. Semler,et al.  Expression of virus-encoded proteinases: functional and structural similarities with cellular enzymes. , 1993, Microbiological reviews.

[4]  I. Deckman,et al.  Autoproteolysis of herpes simplex virus type 1 protease releases an active catalytic domain found in intermediate capsid particles , 1993, Journal of virology.

[5]  B. Roizman,et al.  Characterization of the protease and other products of amino-terminus-proximal cleavage of the herpes simplex virus 1 UL26 protein , 1993, Journal of virology.

[6]  R. Hay,et al.  The adenovirus protease is activated by a virus-coded disulphide-linked peptide , 1993, Cell.

[7]  Y. Gluzman,et al.  Expression and analysis of the human cytomegalovirus UL80-encoded protease: identification of autoproteolytic sites , 1993, Journal of virology.

[8]  C. Anderson,et al.  Viral DNA and a viral peptide can act as cofactors of adenovirus virion proteinase activity , 1993, Nature.

[9]  I. Deckman,et al.  Herpes simplex virus type 1 protease expressed in Escherichia coli exhibits autoprocessing and specific cleavage of the ICP35 assembly protein , 1992, Journal of virology.

[10]  A. Davison,et al.  Identification of genes encoding two capsid proteins (VP24 and VP26) of herpes simplex virus type 1. , 1992, The Journal of general virology.

[11]  F. Rixon,et al.  Processing of the herpes simplex virus assembly protein ICP35 near its carboxy terminal end requires the product of the whole of the UL26 reading frame. , 1992, Virology.

[12]  W. Gibson,et al.  A herpesvirus maturational proteinase, assemblin: identification of its gene, putative active site domain, and cleavage site. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[13]  B. Roizman,et al.  The herpes simplex virus 1 gene encoding a protease also contains within its coding domain the gene encoding the more abundant substrate , 1991, Journal of virology.

[14]  W. Gibson,et al.  Cytomegalovirus assembly protein nested gene family: four 3'-coterminal transcripts encode four in-frame, overlapping proteins , 1991, Journal of virology.

[15]  T. Jones,et al.  Fine mapping of transcripts expressed from the US6 gene family of human cytomegalovirus strain AD169 , 1991, Journal of virology.

[16]  The 45-kilodalton protein of cytomegalovirus (Colburn) B-capsids is an amino-terminal extension form of the assembly protein , 1991, Journal of virology.

[17]  W. Newcomb,et al.  Structure of the herpes simplex virus capsid: effects of extraction with guanidine hydrochloride and partial reconstitution of extracted capsids , 1991, Journal of virology.

[18]  B. Roizman,et al.  The promoter, transcriptional unit, and coding sequence of herpes simplex virus 1 family 35 proteins are contained within and in frame with the UL26 open reading frame , 1991, Journal of virology.

[19]  W. Gibson,et al.  Identification of precursor to cytomegalovirus capsid assembly protein and evidence that processing results in loss of its carboxy-terminal end , 1990, Journal of virology.

[20]  B. Barrell,et al.  Analysis of the protein-coding content of the sequence of human cytomegalovirus strain AD169. , 1990, Current topics in microbiology and immunology.

[21]  W. Gibson,et al.  Primate cytomegalovirus assembly protein: genome location and nucleotide sequence , 1989, Journal of virology.

[22]  F. Rixon,et al.  The products of herpes simplex virus type 1 gene UL26 which are involved in DNA packaging are strongly associated with empty but not with full capsids. , 1988, The Journal of general virology.

[23]  W. Gibson,et al.  Primate cytomegalovirus assembly: evidence that DNA packaging occurs subsequent to B capsid assembly. , 1988, Virology.

[24]  S. Bachenheimer,et al.  Characterization of intranuclear capsids made by ts morphogenic mutants of HSV-1. , 1988, Virology.

[25]  W. Gibson,et al.  Isolation of human cytomegalovirus intranuclear capsids, characterization of their protein constituents, and demonstration that the B-capsid assembly protein is also abundant in noninfectious enveloped particles , 1985, Journal of virology.

[26]  B. Roizman,et al.  Characterization of post-translational products of herpes simplex virus gene 35 proteins binding to the surfaces of full capsids but not empty capsids , 1984, Journal of virology.

[27]  J. Sambrook,et al.  Molecular Cloning: A Laboratory Manual , 2001 .

[28]  W. Gibson,et al.  Isolation and characterization of a noninfectious virion-like particle released from cells infected with human strains of cytomegalovirus. , 1983, Virology.

[29]  F. Rixon,et al.  Identification and Characterization of a Herpes Simplex Virus Gene Product Required for Encapsidation of Virus DNA , 1983, Journal of virology.

[30]  C. J. Duggleby,et al.  Use of recombinant plasmids to investigate the structure of the human cytomegalovirus genome. , 1982, The Journal of general virology.

[31]  T. Ben-Porat,et al.  Pathway of assembly of herpesvirus capsids: an analysis using DNA+ temperature-sensitive mutants of pseudorabies virus. , 1982, Virology.

[32]  W. Gibson Structural and nonstructural proteins of strain Colburn cytomegalovi , 1981 .

[33]  S. McKnight The nucleotide sequence and transcript map of the herpes simplex virus thymidine kinase gene. , 1980, Nucleic acids research.

[34]  C. Heilman,et al.  Shared antigenic determinants between two distinct classes of proteins in cells infected with herpes simplex virus , 1980, Journal of virology.

[35]  B. Roizman,et al.  Proteins Specified by Herpes Simplex Virus X. Staining and Radiolabeling Properties of B Capsid and Virion Proteins in Polyacrylamide Gels , 1974, Journal of virology.

[36]  B. Roizman,et al.  Proteins Specified by Herpes Simplex Virus VIII. Characterization and Composition of Multiple Capsid Forms of Subtypes 1 and 2 , 1972, Journal of virology.

[37]  A. Berger,et al.  On the size of the active site in proteases. I. Papain. , 1967, Biochemical and biophysical research communications.