EC:3.6.1.3 - FACTA Search

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Query: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Purified Bacillus subtilis DnaG primase (predicted molecular mass 68.8 kDa) behaves as a monomer in solution. We demonstrate that DnaG physically interacts with bacteriophage SPP1 hexameric helicase G40P (G40P6) in the absence of ATP. G40P6-ATP forms an unstable complex with ssDNA, and by itself carries out ATP-driven translocation along a ssDNA template with low processivity. The presence of DnaG in the reaction mixture increased the helicase activity of G40P6 about 3-fold, but not the ATPase activity. The results presented here suggest that the DnaG protein stabilises the G40P6-ssDNA complexes.
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PMID:Bacillus subtilis DnaG primase stabilises the bacteriophage SPP1 G40P helicase-ssDNA complex. 984 77

Initiation of Bacillus subtilis bacteriophage SPP1 replication requires the phage-encoded genes 38, 39 and 40 products (G38P, G39P and G40P). G39P, which does not bind DNA, interacts with the replisome organiser, G38P, in the absence of ATP and with the ATP-activated hexameric replication fork helicase, G40P. G38P, which specifically interacts with the phage replication origin (oriL) DNA, does not seem to form a stable complex with G40P in solution. G39P when complexed with G40P-ATP inactivates the single-stranded DNA binding, ATPase and unwinding activities of G40P, and such effects are reversed by increasing amounts of G38P. Unwinding of a forked substrate by G40P-ATP is increased about tenfold by the addition of G38P and G39P to the reaction mixture. The specific protein-protein interactions between oriL-bound G38P and the G39P-G40P-ATPgammaS complex are necessary for helicase delivery to the SPP1 replication origin. Formation of G38P-G39P heterodimers releases G40P-ATPgammaS from the unstable oriL-G38P-G39P-G40P-ATPgammaS intermediate. G40P-ATPgammaS binds to the origin region, the uncomplexed G38P fraction remains bound to oriL, and the G38P-G39P heterodimer is lost from the complex. We demonstrate that G39P is a component of an oligomeric nucleoprotein complex which plays an important role in the initiation of SPP1 replication.
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PMID:The Bacillus subtilis bacteriophage SPP1 G39P delivers and activates the G40P DNA helicase upon interacting with the G38P-bound replication origin. 1032 27

The terminase of bacteriophage SPP1, constituted by a large (G2P) and a small (G1P) subunit, is essential for the initiation of DNA packaging. A hexa-histidine G2P (H6-G2P), which is functional in vivo, possesses endonuclease, ATPase, and double-stranded DNA binding activities. H6-G2P introduces a cut with preference at the 5'-RCGG downward arrowCW-3' sequence. Distamycin A, which is a minor groove binder that mimics the architectural structure generated by G1P at pac, enhances the specific cut at both bona fide 5'-CTATTGCGG downward arrowC-3' sequences within pacC of SPP1 and SF6 phages. H6-G2P hydrolyzes rATP or dATP to the corresponding rADP or dADP and P(i). H6-G2P interacts with two discrete G1P domains (I and II). Full-length G1P and G1PDeltaN62 (lacking domain I) stimulate 3.5- and 1.9-fold, respectively, the ATPase activity of H6-G2P. The results presented suggest that a DNA structure, artificially promoted by distamycin A or facilitated by the assembly of G1P at pacL and/or pacR, stimulates H6-G2P cleavage at both target sites within pacC. In the presence of two G1P decamers per H6-G2P monomer, the H6-G2P endonuclease is repressed, and the ATPase activity stimulated. Based on these results, we propose a model that can account for the role of terminase in headful packaging.
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PMID:Functional analysis of the terminase large subunit, G2P, of Bacillus subtilis bacteriophage SPP1. 1093 Apr 7

In tailed bacteriophages and herpes viruses, the viral DNA is packaged through the portal protein channel. Channel closure is essential to prevent DNA release after packaging. Here we present the connector structure from bacteriophage SPP1 using cryo-electron microscopy and single particle analysis. The multiprotein complex comprises the portal protein gp6 and the head completion proteins gp15 and gp16. Although we show that gp6 in the connector has a fold similar to that of the isolated portal protein, we observe conformational changes in the region of gp6 exposed to the DNA-packaging ATPase and to gp15. This reorganization does not cause closure of the channel. The connector channel traverses the full height of gp6 and gp15, but it is closed by gp16 at the bottom of the complex. Gp16 acts as a valve whose closure prevents DNA leakage, while its opening is required for DNA release upon interaction of the virus with its host.
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PMID:Structure of a viral DNA gatekeeper at 10 A resolution by cryo-electron microscopy. 1262 18

Initiation of headful packaging of SPP1 DNA concatemers involves the interaction of the terminase, G1P and G2P, and the portal protein, G6P. G1P, which specifically recognizes the non-adjacent pacL and pacR subsites and directs loading of G2P to pacC, interacts with G6P. G2P, which has endonuclease, DNA binding, and ATPase activities, interacts with G1P and does it transiently with G6P. The stoichiometry of G1P on the G1P.G2P complex promotes the transition from a G2P endonuclease to an ATPase. G6P does not alter the endonuclease activity of G2P. Both G1P and G6P, which do not have endogenous ATPase activity, synergistically enhance and modulate the ATPase activity of G2P. Based on these results, we propose a model in which the modulation of the ATPase and endonuclease activities of G2P accounts for the role of the terminase in headful packaging.
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PMID:Bacillus subtilis bacteriophage SPP1 DNA packaging motor requires terminase and portal proteins. 1269 51

Bacteriophage terminases constitute a very interesting class of viral-coded multifunctional ATPase "motors" that apparently drive directional translocation of DNA into an empty viral capsid. A common Walker A motif and other conserved signatures of a critical ATPase catalytic center are identified in the N-terminal half of numerous large terminase proteins. However, several terminases, including the well-characterized lambda and SPP1 terminases, seem to lack the classic Walker A in the N-terminus. Using sequence alignment approaches, we discovered the presence of deviant Walker A motifs in these and many other phage terminases. One deviation, the presence of a lysine at the beginning of P-loop, may represent a 3D equivalent of the universally conserved lysine in the Walker A GKT/S signature. This and other novel putative Walker A motifs that first came to light through this study help define the ATPase centers of phage and viral terminases as well as elicit important insights into the molecular functioning of this fundamental motif in biological systems.
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PMID:Novel and deviant Walker A ATP-binding motifs in bacteriophage large terminase-DNA packaging proteins. 1505 82

A large number of viruses use a specialized portal for entry of DNA to the viral capsid and for its polarized exit at the beginning of infection. These families of viruses assemble an icosahedral procapsid containing a portal protein oligomer in one of its 12 vertices. The viral ATPase (terminase) interacts with the portal vertex to form a powerful molecular motor that translocates DNA to the procapsid interior against a steep concentration gradient. The portal protein is an essential component of this DNA packaging machine. Characterization of single amino acid substitutions in the portal protein gp6 of bacteriophage SPP1 that block DNA packaging identified sequential steps in the packaging mechanism that require its action. Gp6 is essential at early steps of DNA packaging and for DNA translocation to the capsid interior, it affects the efficiency of DNA packaging, it is a central component of the headful sensor that determines the size of the packaged DNA molecule, and is essential for closure of the portal pore by the head completion proteins to prevent exit of the DNA encapsidated. Functional regions of gp6 necessary at each step are identified within its primary structure. The similarity between the architecture of portal oligomers and between the DNA packaging strategies of viruses using portals strongly suggests that the portal protein plays the same roles in a large number of viruses.
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PMID:The portal protein plays essential roles at different steps of the SPP1 DNA packaging process. 1511 May 23

Tailed icosahedral bacteriophages and other viruses package their double-stranded DNA inside a preformed procapsid. In a large number of phages packaging is initiated by recognition and cleavage by a viral packaging ATPase (terminase) of the specific pac sequence (pac cleavage), which generates the first DNA end to be encapsidated. A sequence-independent cleavage (headful cleavage) terminates packaging, generating a new starting point for another round of packaging. The molecular mechanisms underlying headful packaging and its processivity remain poorly understood. A defined in vitro DNA packaging system for the headful double-stranded DNA bacteriophage SPP1 is reported. The in vitro system consists of DNA packaging reactions with highly purified terminase and SPP1 procapsids, coupled to a DNase protection assay. The high yield obtained enabled us to quantify directly the efficiency of DNA entry into the procapsids. We show that in vitro DNA packaging requires the presence of both terminase subunits. The SPP1 in vitro system is able to efficiently package mature SPP1 DNA as well as linear plasmid DNAs. In contrast, no DNA packaging could be detected with circular DNA, signifying that in vitro packaging requires free DNA extremities. Finally, we demonstrate that SPP1 in vitro DNA packaging is independent of the pac signal. These findings suggest that the formation of free DNA ends that are generated by pac cleavage in vivo is the rate-limiting step in processive headful DNA packaging.
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PMID:A defined in vitro system for DNA packaging by the bacteriophage SPP1: insights into the headful packaging mechanism. 1619 46

Bacillus subtilis bacteriophage SPP1 G40P hexameric replicative DNA helicase unidirectionally translocates with a 5'-->3' polarity while separating the DNA strands. A G40P mutant derivative lacking the N-terminal domain (containing amino acid residues 110-442 from G40P, G40PDeltaN109) was purified and characterized. G40PDeltaN109 showed an ATPase activity that was dependent on the presence of single-stranded (ss) DNA. Unlike G40P, G40PDeltaN109 was shown to bind with similar affinity both ssDNA arms of forked structures by nuclease protection assays. In a pH-dependent manner, G40PDeltaN109 unwound a branched double-arm substrate preferentially with a 3'-->5' polarity. Our results show that the linker region and the C-terminal domain of G40P are sufficient to render an enzyme capable of encircling the ssDNA tails of the forked DNA and to unwind DNA with both 5'-->3' and 3'-->5' polarity. The presence of the N-terminal domain, which does not play an essential role in helicase action, might be required indirectly for strand discrimination and polarity of translocation.
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PMID:Bacillus subtilis bacteriophage SPP1 G40P helicase lacking the n-terminal domain unwinds DNA bidirectionally. 1640 7

DNA packaging in tailed bacteriophages and herpesviruses requires assembly of a complex molecular machine at a specific vertex of a preformed procapsid. As in all these viruses, the DNA translocation motor of bacteriophage SPP1 is composed of the portal protein (gp6) that provides a tunnel for DNA entry into the procapsid and of the viral ATPase (gp1-gp2 complex) that fuels DNA translocation. Here we studied the cross-talk between the components of the motor to control its ATP consumption and DNA encapsidation. We showed that gp6 embedded in the procapsid structure stimulated more than 10-fold the gp2 ATPase activity. This stimulation, which was significantly higher than the one conferred by isolated gp6, depended on the presence of gp1. Mutations in different regions of gp6 abolished or decreased the gp6-induced stimulation of the ATPase. This effect on gp2 activity was observed both in the presence and in the absence of DNA and showed a strict correlation with the efficiency of DNA packaging into procapsids containing the mutant portals. Our results demonstrated that the portal protein has an active control over the viral ATPase activity that correlates with the performance of the DNA packaging motor.
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PMID:Modulation of the viral ATPase activity by the portal protein correlates with DNA packaging efficiency. 1673 2

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