Identification of putative functional motifs in viral proteins essential for human cytomegalovirus (HCMV) DNA replication

Woon, Heng Giap, Medical Sciences, Faculty of Medicine, UNSW

January 2008

Human cytomegalovirus (HCMV) is a ubiquitous virus that causes significant morbidity and mortality in immunocompromised individuals. Although there are prophylactic treatments available, all current antiviral drugs ultimately target the DNA polymerase, resulting in the increasing emergence of antiviral resistant strains in the clinical setting. There is a fundamental need for understanding the role of other essential genes in DNA replication as a foundation for developing new antiviral treatments that are safe and which utilize a mechanism of action different to existing therapies. In this study we looked at six HCMV replication genes encoding for the DNA polymerase accessory protein (UL44), single stranded DNA binding protein (UL57), primase (UL70), helicase (UL105), primase-helicase associated protein (UL102), and the putative initiator protein (UL84) in order to increase our understanding of their role in DNA replication. The aim of this project was to identify variation within these genes as well as to predict putative domains and motifs in order to ultimately express and study the functional properties of the HCMV primase (UL70) through the use of recombinant mutants. Sequencing of these genes revealed a high degree of conservation between the isolates with amino acid sequence identity of >97% for all genes. Using ScanProsite software from the Expert Protein Analysis System (ExPASy) proteomics server, we have mapped putative motifs throughout these HCMV replication genes. In particular, highly conserved putative Nlinked glycosylation sites were identified in UL105 that were also conserved across 33 homologues as well as several unique motifs including casein kinase II phosphorylation sites (CKII) in UL105 and UL84, a microbodies signal motif in UL57 and an integrin binding site in the UL102 helicase-primase associated protein. Our investigations have also elucidated motif-rich regions of the UL44 DNA polymerase accessory protein, mapped functionally important domains of the UL105 helicase and identified cysteine motifs that have implications for folding of the UL70 primase. Taken together, these findings provide insights to regions of these HCMV replication proteins that are important for post-translation modification, activation and overall function, and this information can be utilized to target further research into these proteins and advance the development of novel antiviral agents that target these processes.

Cytomegalovirus

DNA Replicaiton

Identification of putative functional motifs in viral proteins essential for human cytomegalovirus (HCMV) DNA replication

Woon, Heng Giap, Medical Sciences, Faculty of Medicine, UNSW

January 2008

Human cytomegalovirus (HCMV) is a ubiquitous virus that causes significant morbidity and mortality in immunocompromised individuals. Although there are prophylactic treatments available, all current antiviral drugs ultimately target the DNA polymerase, resulting in the increasing emergence of antiviral resistant strains in the clinical setting. There is a fundamental need for understanding the role of other essential genes in DNA replication as a foundation for developing new antiviral treatments that are safe and which utilize a mechanism of action different to existing therapies. In this study we looked at six HCMV replication genes encoding for the DNA polymerase accessory protein (UL44), single stranded DNA binding protein (UL57), primase (UL70), helicase (UL105), primase-helicase associated protein (UL102), and the putative initiator protein (UL84) in order to increase our understanding of their role in DNA replication. The aim of this project was to identify variation within these genes as well as to predict putative domains and motifs in order to ultimately express and study the functional properties of the HCMV primase (UL70) through the use of recombinant mutants. Sequencing of these genes revealed a high degree of conservation between the isolates with amino acid sequence identity of >97% for all genes. Using ScanProsite software from the Expert Protein Analysis System (ExPASy) proteomics server, we have mapped putative motifs throughout these HCMV replication genes. In particular, highly conserved putative Nlinked glycosylation sites were identified in UL105 that were also conserved across 33 homologues as well as several unique motifs including casein kinase II phosphorylation sites (CKII) in UL105 and UL84, a microbodies signal motif in UL57 and an integrin binding site in the UL102 helicase-primase associated protein. Our investigations have also elucidated motif-rich regions of the UL44 DNA polymerase accessory protein, mapped functionally important domains of the UL105 helicase and identified cysteine motifs that have implications for folding of the UL70 primase. Taken together, these findings provide insights to regions of these HCMV replication proteins that are important for post-translation modification, activation and overall function, and this information can be utilized to target further research into these proteins and advance the development of novel antiviral agents that target these processes.

Cytomegalovirus

DNA Replicaiton