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PDBsum entry 1b1f
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References listed in PDB file
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Key reference
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Title
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The enzymological basis for resistance of herpesvirus DNA polymerase mutants to acyclovir: relationship to the structure of alpha-Like DNA polymerases.
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Authors
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L.Huang,
K.K.Ishii,
H.Zuccola,
A.M.Gehring,
C.B.Hwang,
J.Hogle,
D.M.Coen.
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Ref.
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Proc Natl Acad Sci U S A, 1999,
96,
447-452.
[DOI no: ]
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PubMed id
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Abstract
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Acyclovir (ACV), like many antiviral drugs, is a nucleoside analog. In vitro,
ACV triphosphate inhibits herpesvirus DNA polymerase by means of binding,
incorporation into primer/template, and dead-end complex formation in the
presence of the next deoxynucleoside triphosphate. However, it is not known
whether this mechanism operates in vivo. To address this and other questions, we
analyzed eight mutant polymerases encoded by drug-resistant viruses, each
altered in a region conserved among alpha-like DNA polymerases. We measured Km
and kcat values for dGTP and ACV triphosphate incorporation and Ki values of ACV
triphosphate for dGTP incorporation for each mutant. Certain mutants showed
increased Km values for ACV triphosphate incorporation, suggesting a defect in
inhibitor binding. Other mutants showed reduced kcat values for ACV triphosphate
incorporation, suggesting a defect in incorporation of inhibitor into DNA, while
the rest of the mutants exhibited both altered km and kcat values. In most
cases, the fold increase in Ki of ACV triphosphate for dGTP incorporation
relative to wild-type polymerase was similar to fold resistance conferred by the
mutation in vivo; however, one mutation conferred a much greater increase in
resistance than in Ki. The effects of mutations on enzyme kinetics could be
explained by using a model of an alpha-like DNA polymerase active site bound to
primer/template and inhibitor. The results have implications for mechanisms of
action and resistance of antiviral nucleoside analogs in vivo, in particular for
the importance of incorporation into DNA and for the functional roles of
conserved regions of polymerases.
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Figure 1.
Fig. 1. Cutaway diagram of an  -like DNA
polymerase active site containing primer/template and ACV-TP.
The -carbon
backbone of the protein chain derived from the structure of RB69
DNA polymerase (10) is presented as a gray ribbon diagram. The
location of the N terminus of conserved region II is indicated
with an arrow. The positions of amino acids altered by HSV drug
resistance mutations (e.g., R700G) as well as a conserved serine
(S720) relative to the RB69 sequence are indicated with black
dots and were aligned according to Wang et al. (10).
Primer/template is presented as two ribbons in the upper right
quadrant of the figure and ACV-TP is presented as gray dots
connected by gray lines.
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