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PDBsum entry 4zpb
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References listed in PDB file
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Key reference
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Title
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Design of a genetically stable high fidelity coxsackievirus b3 polymerase that attenuates virus growth in vivo.
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Authors
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S.Mcdonald,
A.Block,
S.Beaucourt,
G.Moratorio,
M.Vignuzzi,
O.B.Peersen.
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Ref.
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J Biol Chem, 2016,
291,
13999-14011.
[DOI no: ]
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PubMed id
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Abstract
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Positive strand RNA viruses replicate via a virally encoded RNA-dependent RNA
polymerase (RdRP) that uses a unique palm domain active site closure mechanism
to establish the canonical two-metal geometry needed for catalysis. This
mechanism allows these viruses to evolutionarily fine-tune their replication
fidelity to create an appropriate distribution of genetic variants known as a
quasispecies. Prior work has shown that mutations in conserved motif A
drastically alter RdRP fidelity, which can be either increased or decreased
depending on the viral polymerase background. In the work presented here, we
extend these studies to motif D, a region that forms the outer edge of the NTP
entry channel where it may act as a nucleotide sensor to trigger active site
closure. Crystallography, stopped-flow kinetics, quench-flow reactions, and
infectious virus studies were used to characterize 15 engineered mutations in
coxsackievirus B3 polymerase. Mutations that interfere with the transport of the
metal A Mg(2+) ion into the active site had only minor effects on RdRP function,
but the stacking interaction between Phe(364) and Pro(357), which is absolutely
conserved in enteroviral polymerases, was found to be critical for processive
elongation and virus growth. Mutating Phe(364) to tryptophan resulted in a
genetically stable high fidelity virus variant with significantly reduced
pathogenesis in mice. The data further illustrate the importance of the palm
domain movement for RdRP active site closure and demonstrate that protein
engineering can be used to alter viral polymerase function and attenuate virus
growth and pathogenesis.
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