DNA-Induced Switch from Independent to Sequential dTTP Hydrolysis in the Bacteriophage T7 DNA Helicase

Crampton, Donald J.; Mukherjee, Sourav; Richardson, Charles C.

doi:10.1016/j.molcel.2005.11.027

Cited by 101 publications

(128 citation statements)

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“…A sequential hydrolysis mechanism with coordination among the subunits has also been proposed for the f12 dsRNA packaging motor P4 [80,81,82 ]. In the case of T7gp4, DNAdependent ATPase activity has been shown to require active ATPase sites at all six subunit interfaces, inconsistent with a probabilistic hydrolysis model [66 ]. For T7gp4, it has been suggested that the reaction cycle may not proceed by one unique pathway and that multiple (perhaps similar) pathways could operate simultaneously [83 ].…”

Section: Hydrolysis Sequence and Timingmentioning

confidence: 99%

“…For example, with one defective cylinder, the machine may continue to operate with the remaining five. In the case of T7gp4, DNA-dependent ATPase activity has been shown to require an active catalytic base (E343) at all six subunit interfaces [66 ], but some inactive arginine fingers are permitted [87]. The most direct studies of a multisubunit machine's tolerance to individual ATP site disruption involve the bacterial unfoldase ClpX [79 ].…”

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confidence: 99%

“…It is not yet clear whether these two helicases operate by an identical mechanism or whether a single universal mechanism operates for hexameric helicases because the mode of DNA coordination by T7gp4 and the other hexameric helicases, such as MCM, are unknown. Bacteriophage T7gp4 requires intact lysine residues on the DNA-binding loop II region for all six subunits in order to achieve DNA-dependent ATP hydrolysis [66 ], demonstrating that all six subunits require the capacity to participate in DNA binding, but it is not known how many subunits bind DNA simultaneously. In the case of the homologous DnaB, single-stranded DNA coordination is dramatically tighter for 7-mer oligonucleotides than for 5-mer oligonucleotides [88].…”

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confidence: 99%

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On helicases and other motor proteins

Enemark

Joshua‐Tor

2008

Current Opinion in Structural Biology

192

238

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Helicases are molecular machines that utilize energy derived from ATP hydrolysis to move along nucleic acids and to separate base-paired nucleotides. The movement of the helicase can also be described as a stationary helicase that pumps nucleic acid. Recent structural data for the hexameric E1 helicase of papillomavirus in complex with single-stranded DNA and MgADP has provided a detailed atomic and mechanistic picture of its ATP-driven DNA translocation. The structural and mechanistic features of this helicase are compared with the hexameric helicase prototypes T7gp4 and SV40 T-antigen. The ATP-binding site architectures of these proteins are structurally similar to the sites of other prototypical ATP-driven motors such as F1-ATPase, suggesting related roles for the individual site residues in the ATPase activity. IntroductionHelicases are essential enzymes that unwind duplex DNA, RNA, or DNA-RNA hybrids. This unwinding is driven by consumption of input energy that is harnessed to separate base-paired oligonucleotides and also to maintain a unidirectional advancement of the helicase upon the nucleic acid substrate. This translocation can alternatively be described as an immobile helicase pumping nucleic acid. The energy for these transformations is derived from the hydrolysis of nucleotide triphosphate (NTP). Helicases can be depicted as an internal combustion engine with each individual NTPase site serving as one cylinder. Each individual cylinder follows a defined series of events: injection (ATP binding), compression (optimally positioning the site for hydrolysis), combustion (ATP hydrolysis/work generation), and exhaust (ADP and phosphate release). In a helicase, the individual combustion cylinders coordinate these actions to carry out the repetitive mechanical operation of prying open base pairs and/or actively translocating with respect to the nucleic acid substrate. Many other molecular motors utilize similar engines to carry out multiple diverse functions such as translocation of peptides in the case of ClpX, movement along cellular structures in the case of dyenin, and rotation about an axle as in F 1 -ATPase.Based upon conserved sequence motifs, helicases have been classified into six superfamilies [1,2 ]. An extensive review of these superfamilies has been provided recently [3 ]. Superfamily 1 (SF1) and superfamily 2 (SF2) helicases are very prevalent, generally monomeric, and participate in several diverse DNA and RNA manipulations. The other helicase superfamilies form hexameric rings (reviewed in [4]), as demonstrated by biochemistry [5][6][7][8] and electron microscopy studies [9][10][11][12][13][14][15][16][17], and often participate at the replication fork. All of these helicases bind and hydrolyze NTP at the interface between two recA-like domains. The binding site consists of a Walker A (P-loop) and a Walker B motif from the first domain and other elements such as an arginine finger from the other domain. The SF1 and SF2 helicases contain two recAlike domains coupled by a short linker, and t...

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Section: Hydrolysis Sequence and Timingmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

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On helicases and other motor proteins

Enemark

Joshua‐Tor

2008

Current Opinion in Structural Biology

192

238

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“…The sequence of these states around the hexamer led Singleton et al (6) to propose a sequential pathway in which all subunits participated in dTTP hydrolysis. Subsequent biochemical studies have largely validated this model (14,16). A structure of the bovine papillomavirus (BPV) E1 helicase, a member of the AAAϩ family, bound to an oligonucleotide and ADP, has provided insight into the actual coupling of nucleotide hydrolysis to translocation on ssDNA (17).…”

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confidence: 98%

“…Upon binding of the nucleotide, motif 4 assumes a helical conformation, suggesting a role for this motif in coupling NTP binding to DNA binding (6). In addition, loop II that protrudes inside the central hole of the hexamer also plays a role in DNA binding (14). Motif 4 from one subunit contacts loop II from an adjacent subunit at the interface of hexameric helicase.…”

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Communication between subunits critical to DNA binding by hexameric helicase of bacteriophage T7

Lee

Qimron

Richardson

2008

Proc. Natl. Acad. Sci. U.S.A.

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The DNA helicase encoded by bacteriophage T7 consists of six identical subunits that form a ring through which the DNA passes. Binding of ssDNA is a prior step to translocation and unwinding of DNA by the helicase. Arg-493 is located at a conserved structural motif within the interior cavity of the helicase and plays an important role in DNA binding. Replacement of Arg-493 with lysine or histidine reduces the ability of the helicase to bind DNA, hydrolyze dTTP, and unwind dsDNA. In contrast, replacement of Arg-493 with glutamine abolishes these activities, suggesting that positive charge at the position is essential. Based on the crystallographic structure of the helicase, Asp-468 is in the range to form a hydrogen bonding with Arg-493 on the adjacent subunit. In vivo complementation results indicate that an interaction between Asp-468 and Arg-493 is critical for a functional helicase and those residues can be swapped without losing the helicase activity. This study suggests that hydrogen bonding between Arg-493 and Asp-468 from adjacent subunits is critical for DNA binding ability of the T7 hexameric helicase.DNA replication ͉ hydrogen bonding ͉ subunit interaction ͉ residue swappping T he replication, recombination, and repair of DNA all require the unwinding of duplex DNA. Such an important transformation of dsDNA into ssDNA is carried out by a group of proteins designated as DNA helicases. Underlying the overall process of unwinding dsDNA is the ability of the protein to bind to ssDNA and use the hydrolysis of a nucleoside triphosphate to translocate unidirectionally on the DNA (1, 2). Not surprisingly, DNA helicases differ in the mechanism by which they bind to DNA, translocate on ssDNA, and unwind the duplex. On the basis of their amino acid sequences and 3D structures, DNA helicases can be divided into several families or superfamilies (2, 3).The helicase encoded by gene 4 of bacteriophage T7 is one of the most extensively characterized helicases. As a member of the DnaB-like family (family 4), the gene 4 protein forms a hexameric toroid. The oligomeric structure not only gives rise to the nucleotide bindings at the subunit interfaces but also provides a central cavity through which the ssDNA can pass. Binding sites for DNA and nucleotide span between subunits, thus allowing cooperative binding of DNA and efficient coupling of nucleotide hydrolysis to movement of the DNA strand.Electron microscopy and x-ray crystallography illustrated that the protein forms a closed ring-shaped oligomeric structure composed of six or seven subunits (4-7). Biochemical studies have identified regions critical to oligomerization of the protein, including a linker region that connects the C-terminal helicase domain of the protein to the N-terminal primase domain (8, 9). Four motifs were defined based on conserved amino acid sequences among family 4 helicases. Strictly conserved residues in motifs 1 and 2 contact the nucleotide at the nucleotide binding site located at the interface of subunits. These residues participate in h...

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Amyloid Remodeling by Hsp104

Shorter

2011

Protein Chaperones and Protection From Neurodegenerative Diseases

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Life demands that proteins fold into very precise functional structures. Functional native structure is enciphered by primary sequence (Anfinsen, 1973;Englander et al., 2007). However, native structures are dynamic systems composed of sophisticated networks of weak, mutually supportive contacts that are difficult to establish simultaneously during folding (Bartlett and Radford, 2009;Englander et al., 2007). Thus, folding energy landscapes are often rugged and create challenges for successful folding (Bartlett and Radford, 2009). Polypeptides can become trapped in non-native intermediate states or become diverted into off-pathway states. Even after the completion of folding, cooperative units of native structure, termed foldons, repeatedly unfold and refold (Englander et al., 2007). Moreover, mutation or errors in transcription or translation can yield polypeptides that are less able to form functional structures (Dobson, 2003;Lee et al., 2006). Environmental stress can also disrupt protein folding . Consequently, proteins can fail to fold or fail to remain correctly folded. These failures increase the risk of aggregation. The highly crowded macromolecular environment that cells are forced to maintain to function optimally further accentuates this risk (Dobson, 2003; Ellis and Minton, Protein Chaperones and Protection from Neurodegenerative Diseases, First Edition. Edited by Stephan N. Witt.

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DNA-Induced Switch from Independent to Sequential dTTP Hydrolysis in the Bacteriophage T7 DNA Helicase

Cited by 101 publications

References 41 publications

On helicases and other motor proteins

On helicases and other motor proteins

Communication between subunits critical to DNA binding by hexameric helicase of bacteriophage T7

Amyloid Remodeling by Hsp104

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