TY - JOUR
T1 - Replication termination mechanism as revealed by Tus-mediated polar arrest of a sliding helicase
AU - Bastia, Deepak
AU - Zzaman, Shamsu
AU - Krings, Gregor
AU - Saxena, Mukesh
AU - Peng, Xiaohua
AU - Greenberg, Marc M.
PY - 2008/9/2
Y1 - 2008/9/2
N2 - The replication terminator protein Tus of Escherichia coli promotes polar fork arrest at sequence-specific replication termini (Ter) by antagonizing DNA unwinding by the replicative helicase DnaB. Here, we report that Tus is also a polar antitranslocase. We have used this activity as a tool to uncouple helicase arrest at a Tus-Ter complex from DNA unwinding and have shown that helicase arrest occurred without the generation of a DNA fork or a bubble of unpaired bases at the Tus-Ter complex. A mutant form of Tus, which reduces DnaB-Tus interaction but not the binding affinity of Tus for Ter DNA, was also defective in arresting a sliding DnaB. A model of polar fork arrest that proposes melting of the Tus-Ter complex and flipping of a conserved C residue of Ter at the blocking but not the nonblocking face has been reported. The model suggests that enhanced stability of Tus-Ter interaction caused by DNA melting and capture of a flipped base by Tus generates polarity strictly by enhanced protein-DNA interaction. In contrast, the observations presented here show that polarity of helicase and fork arrest in vitro is generated by a mechanism that not only involves interaction between the terminator protein and the arrested enzyme but also of Tus with Ter DNA, without any melting and base flipping in the termination complex.
AB - The replication terminator protein Tus of Escherichia coli promotes polar fork arrest at sequence-specific replication termini (Ter) by antagonizing DNA unwinding by the replicative helicase DnaB. Here, we report that Tus is also a polar antitranslocase. We have used this activity as a tool to uncouple helicase arrest at a Tus-Ter complex from DNA unwinding and have shown that helicase arrest occurred without the generation of a DNA fork or a bubble of unpaired bases at the Tus-Ter complex. A mutant form of Tus, which reduces DnaB-Tus interaction but not the binding affinity of Tus for Ter DNA, was also defective in arresting a sliding DnaB. A model of polar fork arrest that proposes melting of the Tus-Ter complex and flipping of a conserved C residue of Ter at the blocking but not the nonblocking face has been reported. The model suggests that enhanced stability of Tus-Ter interaction caused by DNA melting and capture of a flipped base by Tus generates polarity strictly by enhanced protein-DNA interaction. In contrast, the observations presented here show that polarity of helicase and fork arrest in vitro is generated by a mechanism that not only involves interaction between the terminator protein and the arrested enzyme but also of Tus with Ter DNA, without any melting and base flipping in the termination complex.
KW - Protein-DNA interaction
KW - Protein-protein interaction
KW - Site-directed interstrand cross-linking
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U2 - 10.1073/pnas.0805898105
DO - 10.1073/pnas.0805898105
M3 - Article
C2 - 18708526
AN - SCOPUS:51349146628
SN - 0027-8424
VL - 105
SP - 12831
EP - 12836
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 35
ER -