Emmanuelle Delagoutte scite author profile

Helicases are proteins that harness the chemical free energy of ATP hydrolysis to catalyze the unwinding of double-stranded nucleic acids. These enzymes have been much studied in isolation, and here we review what is known about the mechanisms of the unwinding process. We begin by considering the thermally driven 'breathing' of double-stranded nucleic acids by themselves, in order to ask whether helicases might take advantage of some of these breathing modes. We next provide a brief summary of helicase mechanisms that have been elucidated by biochemical, thermodynamic, and kinetic studies, and then review in detail recent structural studies of helicases in isolation, in order to correlate structural findings with biophysical and biochemical results. We conclude that there are certainly common mechanistic themes for helicase function, but that different helicases have devised solutions to the nucleic acid unwinding problem that differ in structural detail. In Part II of this review (to be published in the next issue of this journal) we consider how these mechanisms are further modified to reflect the functional coupling of these proteins into macromolecular machines, and discuss the role of helicases in several central biological processes to illustrate how this coupling actually works in the various processes of gene expression.

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Helicase mechanisms and the coupling of helicases within macromolecular machines Part II: Integration of helicases into cellular processes

Delagoutte

Hippel

2003

Quart. Rev. Biophys.

139

110

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In Part I of this review [Delagoutte & von Hippel, Quarterly Reviews of Biophysics (2002) 35, 431-478] we summarized what is known about the properties, mechanisms, and structures of the various helicases that catalyze the unwinding of double-stranded nucleic acids. Here, in Part II, we consider these helicases as tightly integrated (or coupled) components of the various macromolecular machines within which they operate. The biological processes that are considered explicitly include DNA replication, recombination, and nucleotide excision repair, as well as RNA transcription and splicing. We discuss the activities of the constituent helicases (and their protein partners) in the assembly (or loading) of the relevant complex onto (and into) the specific nucleic acid sites at which the actions of the helicase-containing complexes are to be initiated, the mechanisms by which the helicases (and the complexes) translocate along the nucleic acids in discharging their functions, and the reactions that are used to terminate the translocation of the helicase-containing complexes at specific sites within the nucleic acid 'substrate'. We emerge with several specific descriptions of how helicases function within the above processes of genetic expression which, we hope, can serve as paradigms for considering how helicases may also be coupled and function within other macromolecular machines.

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RPA prevents G‐rich structure formation at lagging‐strand telomeres to allow maintenance of chromosome ends

et al. 2015

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Replication protein A (RPA) is a highly conserved heterotrimeric single-stranded DNA-binding protein involved in DNA replication, recombination, and repair. In fission yeast, the Rpa1-D223Y mutation provokes telomere shortening. Here, we show that this mutation impairs lagging-strand telomere replication and leads to the accumulation of secondary structures and recruitment of the homologous recombination factor Rad52. The presence of these secondary DNA structures correlates with reduced association of shelterin subunits Pot1 and Ccq1 at telomeres. Strikingly, heterologous expression of the budding yeast Pif1 known to efficiently unwind G-quadruplex rescues all the telomeric defects of the D223Y cells. Furthermore, in vitro data show that the identical D to Y mutation in human RPA specifically affects its ability to bind G-quadruplex. We propose that RPA prevents the formation of G-quadruplex structures at lagging-strand telomeres to promote shelterin association and facilitate telomerase action at telomeres.

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