Auxiliary ATP binding sites support DNA unwinding by RecBCD

Rani Zananiri; Sivasubramanyan Mangapuram Venkata; Vera Gaydar; Dan Yahalom; Omri Malik; Sergei Rudnizky; Oded Kleifeld; Ariel Kaplan; Arnon Henn

doi:10.1038/s41467-022-29387-1

Technion - Israel Institute of Technology

Research output: Contribution to journal › Article › peer-review

Abstract

The RecBCD helicase initiates double-stranded break repair in bacteria by processively unwinding DNA with a rate approaching ∼1,600 bp·s⁻¹, but the mechanism enabling such a fast rate is unknown. Employing a wide range of methodologies — including equilibrium and time-resolved binding experiments, ensemble and single-molecule unwinding assays, and crosslinking followed by mass spectrometry — we reveal the existence of auxiliary binding sites in the RecC subunit, where ATP binds with lower affinity and distinct chemical interactions as compared to the known catalytic sites. The essentiality and functionality of these sites are demonstrated by their impact on the survival of E.coli after exposure to damage-inducing radiation. We propose a model by which RecBCD achieves its optimized unwinding rate, even when ATP is scarce, by using the auxiliary binding sites to increase the flux of ATP to its catalytic sites.

Original language	English
Article number	1806
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-29387-1
State	Published - 4 Apr 2022

ASJC Scopus subject areas

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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10.1038/s41467-022-29387-1

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title = "Auxiliary ATP binding sites support DNA unwinding by RecBCD",

abstract = "The RecBCD helicase initiates double-stranded break repair in bacteria by processively unwinding DNA with a rate approaching ∼1,600 bp·s−1, but the mechanism enabling such a fast rate is unknown. Employing a wide range of methodologies — including equilibrium and time-resolved binding experiments, ensemble and single-molecule unwinding assays, and crosslinking followed by mass spectrometry — we reveal the existence of auxiliary binding sites in the RecC subunit, where ATP binds with lower affinity and distinct chemical interactions as compared to the known catalytic sites. The essentiality and functionality of these sites are demonstrated by their impact on the survival of E.coli after exposure to damage-inducing radiation. We propose a model by which RecBCD achieves its optimized unwinding rate, even when ATP is scarce, by using the auxiliary binding sites to increase the flux of ATP to its catalytic sites.",

author = "Rani Zananiri and \{Mangapuram Venkata\}, Sivasubramanyan and Vera Gaydar and Dan Yahalom and Omri Malik and Sergei Rudnizky and Oded Kleifeld and Ariel Kaplan and Arnon Henn",

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doi = "10.1038/s41467-022-29387-1",

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T1 - Auxiliary ATP binding sites support DNA unwinding by RecBCD

AU - Zananiri, Rani

AU - Mangapuram Venkata, Sivasubramanyan

AU - Gaydar, Vera

AU - Yahalom, Dan

AU - Malik, Omri

AU - Rudnizky, Sergei

AU - Kleifeld, Oded

AU - Kaplan, Ariel

AU - Henn, Arnon

PY - 2022/4/4

Y1 - 2022/4/4

N2 - The RecBCD helicase initiates double-stranded break repair in bacteria by processively unwinding DNA with a rate approaching ∼1,600 bp·s−1, but the mechanism enabling such a fast rate is unknown. Employing a wide range of methodologies — including equilibrium and time-resolved binding experiments, ensemble and single-molecule unwinding assays, and crosslinking followed by mass spectrometry — we reveal the existence of auxiliary binding sites in the RecC subunit, where ATP binds with lower affinity and distinct chemical interactions as compared to the known catalytic sites. The essentiality and functionality of these sites are demonstrated by their impact on the survival of E.coli after exposure to damage-inducing radiation. We propose a model by which RecBCD achieves its optimized unwinding rate, even when ATP is scarce, by using the auxiliary binding sites to increase the flux of ATP to its catalytic sites.

AB - The RecBCD helicase initiates double-stranded break repair in bacteria by processively unwinding DNA with a rate approaching ∼1,600 bp·s−1, but the mechanism enabling such a fast rate is unknown. Employing a wide range of methodologies — including equilibrium and time-resolved binding experiments, ensemble and single-molecule unwinding assays, and crosslinking followed by mass spectrometry — we reveal the existence of auxiliary binding sites in the RecC subunit, where ATP binds with lower affinity and distinct chemical interactions as compared to the known catalytic sites. The essentiality and functionality of these sites are demonstrated by their impact on the survival of E.coli after exposure to damage-inducing radiation. We propose a model by which RecBCD achieves its optimized unwinding rate, even when ATP is scarce, by using the auxiliary binding sites to increase the flux of ATP to its catalytic sites.

UR - https://www.scopus.com/pages/publications/85127530000

U2 - 10.1038/s41467-022-29387-1

DO - 10.1038/s41467-022-29387-1

M3 - مقالة

C2 - 35379800

SN - 2041-1723

VL - 13

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 1806

ER -

Auxiliary ATP binding sites support DNA unwinding by RecBCD

Abstract

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