The long-term objective of this research is a detailed understanding of herpesvirus DNA polymerases and drugs that target them. These enzymes, which include a catalytic subunit (Pol) and an accessory subunit that stimulates long-chain DNA synthesis, are both prototype ?-like DNA polymerases and excellent targets for antiviral drugs. This latter property is especially health-related, as new drugs are needed for treatment of herpesvirus infections. In this application, unanswered questions regarding accessory subunits, catalytic subunits, and drugs that target these proteins and their interaction are addressed.
Specific aim 1 is to investigate the unusual and different manners by which the accessory subunits, such as herpes simplex virus (HSV) UL42 and human cytomegalovirus (HCMV) UL44, interact with DNA so that they bind tightly, yet diffuse linearly along the DNA to permit processive DNA synthesis. Single-molecule approaches will be used to analyze how these proteins move on DNA, particularly whether wild type UL42 or a tight-binding mutant necessarily moves helically or can, for example, move along one side of the helix. The force required to move these subunits will be compared with the force required to stop or slow the catalytic subunits. X-ray crystallography will be used to understand the molecular details of the protein-DNA interaction.
Specific aim 2 is to investigate the roles of structural domains of the catalytic subunits that are N-terminal to the thumb, palm, and fingers domains in terms of enzymatic functions, binding to the base excision repair (BER) enzyme uracil DNA glycosylase (UNG), viral replication, and mechanisms of antiviral drug resistance. Two structural domains, pre-NH2 and NH2, have been observed in the crystal structure of HSV Pol, but their roles in enzyme function and viral replication are unknown. To address these questions, mutant enzymes will be engineered and assayed for relevant biochemical activities. Mutant viruses will be engineered and assayed for viral replication both in cells and in a mouse model. The mechanisms by which mutant HCMV Pols with substitutions in their 3'-5'exonuclease domain resist ganciclovir (GCV) action will be investigated using enzymological analyses.
Specific aim 3 is to discover new compounds that inhibit the interaction of HCMV Pol and UL44, and HCMV replication, using a structure-based approach. The importance of the interaction between UL44 and another replication protein, UL84, for viral replication, and whether it can be exploited as a drug target, will be investigated using a combination of biochemical, molecular genetic, and cell biological approaches, including efforts to develop a new technique to map protein-protein interactions. Should the UL44-UL84 interaction look promising as a drug target, random screening for compounds that inhibit this interaction will be undertaken.

Public Health Relevance

Herpesviruses cause widespread disease in the population at large and severe disease in people with impaired immunity. There is considerable need for new drugs to combat these viruses. The research proposed should not only provide information that could aid in drug discovery and understanding how viruses become resistant to current drugs, but aims directly to discover new anti-herpesvirus drugs.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
5R01AI019838-27
Application #
8234957
Study Section
Virology - A Study Section (VIRA)
Program Officer
Challberg, Mark D
Project Start
1983-04-01
Project End
2016-04-30
Budget Start
2012-05-01
Budget End
2013-04-30
Support Year
27
Fiscal Year
2012
Total Cost
$506,797
Indirect Cost
$206,917
Name
Harvard University
Department
Biochemistry
Type
Schools of Medicine
DUNS #
047006379
City
Boston
State
MA
Country
United States
Zip Code
02115
Lawler, Jessica L; Mukherjee, Purba; Coen, Donald M (2018) Herpes Simplex Virus 1 DNA Polymerase RNase H Activity Acts in a 3'-to-5' Direction and Is Dependent on the 3'-to-5' Exonuclease Active Site. J Virol 92:
Chen, Han; Coseno, Molly; Ficarro, Scott B et al. (2017) A Small Covalent Allosteric Inhibitor of Human Cytomegalovirus DNA Polymerase Subunit Interactions. ACS Infect Dis 3:112-118
Khan, Amina S; Murray, Matthew J; Ho, Catherine M K et al. (2017) High-throughput screening of a GlaxoSmithKline protein kinase inhibitor set identifies an inhibitor of human cytomegalovirus replication that prevents CREB and histone H3 post-translational modification. J Gen Virol 98:754-768
Beelontally, Rooksarr; Wilkie, Gavin S; Lau, Betty et al. (2017) Identification of compounds with anti-human cytomegalovirus activity that inhibit production of IE2 proteins. Antiviral Res 138:61-67
Strang, Blair L (2017) RO0504985 is an inhibitor of CMGC kinase proteins and has anti-human cytomegalovirus activity. Antiviral Res 144:21-26
Wilkie, Adrian R; Lawler, Jessica L; Coen, Donald M (2016) A Role for Nuclear F-Actin Induction in Human Cytomegalovirus Nuclear Egress. MBio 7:
Chen, Han; Li, Chengwei; Zemlicka, Jiri et al. (2016) Potency and Stereoselectivity of Cyclopropavir Triphosphate Action on Human Cytomegalovirus DNA Polymerase. Antimicrob Agents Chemother 60:4176-82
Polachek, William S; Moshrif, Hanan F; Franti, Michael et al. (2016) High-Throughput Small Interfering RNA Screening Identifies Phosphatidylinositol 3-Kinase Class II Alpha as Important for Production of Human Cytomegalovirus Virions. J Virol 90:8360-71
Bender, Brian J; Coen, Donald M; Strang, Blair L (2014) Dynamic and nucleolin-dependent localization of human cytomegalovirus UL84 to the periphery of viral replication compartments and nucleoli. J Virol 88:11738-47
Chen, Han; Beardsley, G Peter; Coen, Donald M (2014) Mechanism of ganciclovir-induced chain termination revealed by resistant viral polymerase mutants with reduced exonuclease activity. Proc Natl Acad Sci U S A 111:17462-7

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