Mark C. Young scite author profile

T7 DNA polymerase catalyses DNA replication in vitro at rates of more than 100 bases per second and has a 3'-->5' exonuclease (nucleotide removing) activity at a separate active site. This enzyme possesses a 'right hand' shape which is common to most polymerases with fingers, palm and thumb domains. The rate-limiting step for replication is thought to involve a conformational change between an 'open fingers' state in which the active site samples nucleotides, and a 'closed' state in which nucleotide incorporation occurs. DNA polymerase must function as a molecular motor converting chemical energy into mechanical force as it moves over the template. Here we show, using a single-molecule assay based on the differential elasticity of single-stranded and double-stranded DNA, that mechanical force is generated during the rate-limiting step and that the motor can work against a maximum template tension of approximately 34 pN. Estimates of the mechanical and entropic work done by the enzyme show that T7 DNA polymerase organizes two template bases in the polymerization site during each catalytic cycle. We also find a force-induced 100-fold increase in exonucleolysis above 40 pN.

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Multiple RNA Polymerase Conformations and GreA: Control of the Fidelity of Transcription

Erie

Hajiseyedjavadi

Young

et al. 1993

Science

289

260

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Pre-steady state kinetics of misincorporation were used to investigate the addition of single nucleotides to nascent RNA by Escherichia coli RNA polymerase during transcription elongation. The results were fit with a branched kinetic mechanism that permits conformational switching, at each template position, between an activated and an unactivated enzyme complex, both of which can bind nucleotide triphosphates (NTPs) from solution. The complex exists most often in the long-lived activated state, and only becomes unactivated when transcription is slowed. This model permits multiple levels of nucleotide discrimination in transcription, since the complex can be "kinetically trapped" in the unactivated state in the absence of the correct NTP or if the 3' terminal residue is incorrectly matched. The transcription cleavage factor GreA (or an activity enhanced by GreA) increased the fidelity of transcription by preferential cleavage of transcripts containing misincorporated residues in the unactivated state of the elongation complex. This cleavage mechanism by GreA may prevent the formation of "dead-end" transcription complexes in vivo.

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Kinetic Theory of ATP-driven Translocases on One-dimensional Polymer Lattices

Young

Kuhl

Hippel

1994

Journal of Molecular Biology

109

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Kinetic Parameters of the Translocation of Bacteriophage T4 Gene 41 Protein Helicase on Single-stranded DNA

Young

Schultz

Ring

et al. 1994

Journal of Molecular Biology

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Structure and function of the bacteriophage T4 DNA polymerase holoenzyme

Young¹,

Reddy²,

Hippel³

1992

Biochemistry

108

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Mark C. Young

Single-molecule studies of the effect of template tension on T7 DNA polymerase activity

Multiple RNA Polymerase Conformations and GreA: Control of the Fidelity of Transcription

Kinetic Theory of ATP-driven Translocases on One-dimensional Polymer Lattices

Kinetic Parameters of the Translocation of Bacteriophage T4 Gene 41 Protein Helicase on Single-stranded DNA

Structure and function of the bacteriophage T4 DNA polymerase holoenzyme

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