Identification of the ATP-binding site in the terminase subunit pUL56 of human cytomegalovirus

Human cytomegalovirus (HCMV) terminase is composed of subunits pUL56 (130 kDa) and pUL89 (~75 kDa), encoded by the UL56 and UL89 genes. In a recent investigation, we demonstrated that the main ATPase activity is associated with the large terminase subunit pUL56. The protein has two putative ATP-binding sites, which were suggested to be composed of the sequence (amino acids 463–470) for ATP-binding site 1 and YNETFGKQ (amino acids 709–716) for the second site. We now demonstrate using a 1.5 kb fragment encoding the C-terminal half of pUL56 that ATP-binding site 1 is not critical for the function, whereas ATP-binding site 2 is required for the enzymatic activity. Mutation G714A in this protein reduced the ATPase activity to ~65% and the double mutation G714A/K715N showed a reduction up to 75%. However, the substitution of E711A revoked the effect of the substitutions. The functional character of the ATP-binding site was demonstrated by transfer of YNETFGKQLSIACLR (709–723) to glutathione-S-transferase (GST). Interestingly, vanadate, an ATPase inhibitor, has the ability to block the ATPase activity of pUL56 as well as of Apyrase, while the antitumor ATP-mimetic agent geldanamycin, did not affect the ATP-binding of pUL56. Furthermore, in contrast to an inactive control compound, the specific HCMV terminase inhibitor BDCRB showed a partial inhibition of the pUL56-specific ATPase activity. Our results clearly demonstrated that (i) the enzymatic activity of the terminase subunit pUL56 could be inhibited by vanadate, (ii) only the ATP-binding site 2 is critical for the pUL56 function and (iii) glycine G714 is an invariant amino acid.     

Identification of the interaction domain of the small terminase subunit pUL89 with the large subunit pUL56 of human cytomegalovirus

The small terminase subunit pUL89 of human cytomegalovirus (HCMV) is thought to be required for cleavage of viral DNA into unit-length genomes in the cleavage/packaging process. Immunoprecipitations with a UL89-specific antibody demonstrated that pUL89 occurs predominantly as a monomer of approximate M(r) 75.000 together with a dimer of approximate 150.000. This was confirmed by gel permeation chromatography. In view of its putative function, pUL89 needs to be transported into the nucleus. By use of laser scanning confocal microscopy, pUL89 was found to be predominantly localized throughout the nucleus and in particular in viral replication centers of infected cells. By immunofluorescence, we demonstrated that both terminase subunits co-localized in viral replication centers. Furthermore, analysis with pUL89 GST-fusion protein mutants showed that amino acids 580-600 may represent the interaction domain with pUL56. To verify this result, a recombinant HCMV genome was constructed in which the UL89 open reading frame was disrupted. By transfection of the deletion BACmid alone, we showed that it has a lethal phenotype. Cotransfection assays demonstrated that, in contrast to pUL89 wild-type, a plasmid construct encoding a pUL89 variant without aa 580-590 as well as one encoding a variant without aa 590-600 could not complement the HCMV-pUL89 null genome, thus, suggesting that the 20 aa sequence GRDKALAVEQFISRFNSGYIK is sufficient for the interaction with pUL56 and in conclusion required for DNA packaging.     

Identification of acetylated, tetrahalogenated benzimidazole D-ribonucleosides with enhanced activity against human cytomegalovirus

DNA packaging is the key step in viral maturation and involves binding and cleavage of viral DNA containing specific DNA-packaging motifs. This process is mediated by a group of specific enzymes called terminases. We previously demonstrated that the human cytomegalovirus (HCMV) terminase is composed of the large subunit pUL56 and the small subunit pUL89. While the large subunit mediates sequence-specific DNA binding and ATP hydrolysis, pUL89 is required only for duplex nicking. An excellent inhibitor targeting HCMV terminase is 2-bromo-5,6-dichloro-1-(beta-d-ribofuranosyl)benzimidazole (BDCRB), but it was not developed as an antiviral drug due to its metabolic cleavage in experimental animals. We now have tested several new benzimidazole d-ribonucleosides in order to determine whether these compounds represent new, potent inhibitors. Analysis by bioluminometric ATPase activity assays identified two of the new compounds with a high inhibitory effect, 2-bromo-4,5,6-trichloro-1-(2,3,5-tri-O-acetyl-beta-D-ribofuranosyl) benzimidazole (BTCRB) and 2,4,5,6-tetrachloro-1-(2,3,5-tri-O-acetyl-beta-D-ribofuranosyl benzimidazole (Cl(4)RB). By using viral plaque formation, viral yield, and viral growth kinetics, we demonstrated that the two compounds BTCRB and Cl(4)RB had antiviral activities similar to that of BDCRB. Interestingly, BTCRB retained its inhibitory activity after preincubation with HFF cells. By use of electron microscopy, we observed an increase of B capsids and a lack of cytoplasmic capsids in the presence of the compounds that correlated with the virus yield. Furthermore, cleavage of concatenated DNA was inhibited by both compounds, and inhibition by BTCRB was shown to be dose dependent. These results demonstrate that the new compounds are highly active against HCMV and act by mechanisms similar but not identical to those of BDCRB.     

The terminase subunits pUL56 and pUL89 of human cytomegalovirus are DNA-metabolizing proteins with toroidal structure

Herpesvirus DNA packaging involves binding and cleavage of DNA containing the specific DNA-packaging motifs. Here we report a first characterization of the terminase subunits pUL56 and pUL89 of human cytomegalovirus (HCMV). Both gene products were shown to have comparable nuclease activities in vitro. Under limiting protein concentrations the nuclease activity is enhanced by interaction of pUL56 and pUL89. High amounts of 2-bromo-5,6-dichloro-1-beta-D-ribofuranosyl benzimidazole partially inhibited the pUL89-associated nuclease activity. It was demonstrated that pUL56 is able to bind to nucleocapsids in vivo. Electron microscopy (EM) and image analysis of purified pUL56 revealed that the molecules occurred as a distinct ring-shaped structure with a pronounced cleft. EM analysis of purified pUL89 demonstrated that this protein is also a toroidal DNA-metabolizing protein. Upon interaction of pUL56 with linearized DNA, the DNA remains uncut while the cutting event itself is mediated by pUL89. Using biochemical assays in conjunction with EM pUL56 was shown to (i) bind to DNA and (ii) associate with the capsid. In contrast to this, EM analysis implied that pUL89 is required to effect DNA cleavage. The data provide the first insights into the terminase-dependent viral DNA-packaging mechanism of HCMV.     

Biochemical characterization of an ATPase activity associated with the large packaging subunit gp17 from bacteriophage T4

Double-stranded DNA-packaging in icosahedral bacteriophages is believed to be driven by a packaging "machine" constituted by the portal protein and the two packaging/terminase proteins assembled at the unique portal vertex of the empty prohead shell. Although ATP hydrolysis is evidently the principal driving force, which component of the packaging machinery functions as the translocating ATPase has not been elucidated. Evidence suggests that the large packaging subunit is a strong candidate for the translocating ATPase. We have constructed new phage T4 terminase recombinants under the control of phage T7 promoter and overexpressed the packaging/terminase proteins gp16 and gp17 in various configurations. The hexahistidine-tagged-packaging proteins were purified to near homogeneity by Ni(2+)-agarose chromatography and were shown to be highly active for packaging DNA in vitro. The large packaging subunit gp17 but not the small subunit gp16 exhibited an ATPase activity. Although gp16 lacked ATPase activity, it enhanced the gp17-associated ATPase activity by >50-fold. The gp16 enhancement was specific and was due to an increased catalytic rate for ATP hydrolysis. A phosphorylated gp17 was demonstrated under conditions of low catalytic rates but not under high catalytic rates in the presence of gp16. The data are consistent with the hypothesis that a weak ATPase is transformed into a translocating ATPase of high catalytic capacity after assembly of the packaging machine.     

Interaction of the putative human cytomegalovirus portal protein pUL104 with the large terminase subunit pUL56 and its inhibition by benzimidazole-D-ribonucleosides

Herpesvirus DNA replication leads to unit length genomes that are translocated into preformed procapsids through a unique portal vertex. The translocation is performed by the terminase that cleaves the DNA and powers the insertion by its ATPase activity. Recently, we demonstrated that the putative human cytomegalovirus (HCMV) portal protein, pUL104, also forms high-molecular-weight complexes. Analyses now have been performed to determine the intracellular localization and identification of interaction partners of pUL104. In infected cells, HCMV pUL104 was found to be predominantly localized throughout the nucleus as well as in cytoplasmic clusters at late times of infection. The latter localization was abolished by phosphonoacetic acid, an inhibitor of viral DNA replication. Immunofluorescence revealed that pUL104 colocalized with pUL56, the large subunit of the HCMV terminase. Specific association of in vitro translated pUL104 with the carboxy-terminal half of GST-UL56C was detected. By using coimmunoprecipitations a direct interaction with pUL56 was confirmed. In addition, this interaction was no longer detected when the benzimidazole-D-nucleosides BDCRB or Cl4RB were added, thus indicating that these HCMV inhibitors block the insertion of the DNA into the capsid by preventing a necessary interaction of pUL56 with the portal. Electron microscopy revealed that in the presence of Cl4RB DNA is not packaged into capsids and these capsids failed to egress from the nucleus. Furthermore, pulsed-field gel electrophoresis showed that DNA concatemers synthesized in the presence of the compound failed to be processed.     

Insights into the structure of human cytomegalovirus large terminase subunit pUL56

Terminases are a class of proteins which catalyze the generation of unit-length genomes during DNA packaging. These essential proteins are conserved throughout the herpesviruses and many double-stranded DNA bacteriophages. We have determined the structure of the large terminase subunit pUL56 of human cytomegalovirus, a highly pathogenic virus, to 2.6 nm resolution. Image analysis of purified pUL56 suggests that the molecule exists as a dimer formed by the association of two ring-like structures positioned on top of each other and connected by a pronounced density on one side. The 3D reconstruction of pUL56 provides first structural insights into the active protein.     

Bacteriophage lambda terminase: alterations of the high-affinity ATPase affect viral DNA packaging

DNA packaging by large DNA viruses such as the tailed bacteriophages and the herpesviruses involves DNA translocation into a preformed protein shell, called the prohead. Translocation is driven by an ATP hydrolysis-powered DNA packaging motor. The bacteriophages encode a heterodimeric viral DNA packaging protein, called terminase. The terminases have an ATPase center located in the N terminus of the large subunit implicated in DNA translocation. In previous work with phage lambda, lethal mutations that changed ATP-reactive residues 46 and 84 of gpA, the large terminase subunit, were studied. These mutant enzymes retained the terminase endonuclease and helicase activities, but had severe defects in virion assembly, and lacked the terminase high-affinity ATPase activity. Surprisingly, in the work described here, we found that enzymes with the conservative gpA changes Y46F and Y46A had only mild packaging defects. These mild defects contrast with their profound virion assembly defects. Thus, these mutant enzymes have, in addition to the mild DNA packaging defects, a severe post-DNA packaging defect. In contrast, the gpA K84A enzyme had similar virion assembly and DNA packaging defects. The DNA packaging energy budget, i.e. DNA packaged/ATP hydrolyzed, was unchanged for the mutant enzymes, indicating that DNA translocation is tightly coupled to ATP hydrolysis. A model is proposed in which gpA residues 46 and 84 are important for terminase's high-affinity ATPase activity. Assembly of the translocation complex remodels this ATPase so that residues 46 and 84 are not crucial for the activated translocation ATPase. Changing gpA residues 46 and 84 primarily affects assembly, rather than the activity, of the translocation complex.     

Insight into the structure of the pUL89 C‐terminal domain of the human cytomegalovirus terminase complex

In a previous study, we identified 12 conserved domains within pUL89, the small terminase subunit of the human cytomegalovirus. A latter study showed that the fragment pUL89(580–600) plays an important role in the formation of the terminase complex by interacting with the large terminase subunit pUL56. In this study, analysis was performed to solve the structure of pUL89(568–635) in 50% H2O/50% acetonitrile (v/v). We showed that pUL89(568–635) consists of four alpha helices, but we did not identify any tertiary structure. The fragment 580–600 formed an amphipathic alpha helix, which had a hydrophobic side highly conserved among herpesviral homologs of pUL89; this was not observed for its hydrophilic side. The modeling of pUL89(457–612) using the recognition fold method allowed us to position pUL89(580–600) within this domain. The theoretical structure highlighted three important features. First, we identified a metal‐binding pocket containing residues Asp⁴⁶³, Glu⁵³⁴, and Glu⁵⁸⁸, which are highly conserved among pUL89 homologs. Second, the model predicted a positively charged surface able to interact with the DNA duplex during the nicking event. Third, a hydrophobic patch on the top of the catalytic site suggested that this may constitute part of the pUL89 site recognized by pUL56 potentially involved in DNA binding. Proteins 2010. © 2009 Wiley‐Liss, Inc.     

Kinetic characterization of the GTPase activity of phage lambda terminase: evidence for communication between the two "NTPase" catalytic sites of the enzyme.

The terminase enzyme from bacteriophage lambda is responsible for the insertion of viral DNA into the confined space within the capsid. The enzyme is composed of the virally encoded proteins gpA (73.3 kDa) and gpNu1 (20.4 kDa) isolated as a gpA(1).gpNu1(2) holoenzyme complex. Lambda terminase possesses a site-specific nuclease activity, an ATP-dependent DNA strand-separation activity, and an ATPase activity that must work in concert to effect genome packaging. We have previously characterized the ATPase activity of the holoenzyme and have identified catalytic active sites in each enzyme subunit [Tomka and Catalano (1993) Biochemistry 32, 11992-11997; Hwang et al. (1996) Biochemistry 35, 2796-2803]. We have noted that GTP stimulates the ATPase activity of the enzyme, and terminase-mediated GTP hydrolysis has been observed. The studies presented here describe a kinetic analysis of the GTPase activity of lambda terminase. GTP hydrolysis by the enzyme requires divalent metal, is optimal at alkaline pH, and is strongly inhibited by salt. Interestingly, while GTP can bind to the enzyme in the absence of DNA, GTP hydrolysis is strictly dependent on the presence of polynucleotide. Unlike ATP hydrolysis that occurs at both subunits of the holoenzyme, a single catalytic site is observed in the steady-state kinetic analysis of GTPase activity (k(cat) approximately 37 min(-)(1); K(m) approximately 500 microM). Moreover, while GTP stimulates ATP hydrolysis (apparent K(D) approximately 135 microM for GTP binding), all of the adenosine nucleotides examined strongly inhibit the GTPase activity of the enzyme. The data presented here suggest that the two "NTPase" catalytic sites in terminase holoenzyme communicate, and we propose a model describing allosteric interactions between the two sites. The biological significance of this interaction with respect to the assembly and disassembly of the multiple nucleoprotein packaging complexes required for virus assembly is discussed.     

The Structure of the Herpes Simplex Virus DNA-Packaging Terminase pUL15 Nuclease Domain Suggests an Evolutionary Lineage among Eukaryotic and Prokaryotic Viruses

Herpes simplex virus 1 (HSV-1), the prototypic member of herpesviruses, employs a virally encoded molecular machine called terminase to package the viral double-stranded DNA (dsDNA) genome into a preformed protein shell. The terminase contains a large subunit that is thought to cleave concatemeric viral DNA during the packaging initiation and completion of each packaging cycle and supply energy to the packaging process via ATP hydrolysis. We have determined the X-ray structure of the C-terminal domain of the terminase large-subunit pUL15 (pUL15C) from HSV-1. The structure shows a fold resembling those of bacteriophage terminases, RNase H, integrases, DNA polymerases, and topoisomerases, with an active site clustered with acidic residues. Docking analysis reveals a DNA-binding surface surrounded by flexible loops, indicating considerable conformational changes upon DNA binding. In vitro assay shows that pUL15C possesses non-sequence-specific, Mg²⁺-dependent nuclease activity. These results suggest that pUL15 uses an RNase H-like, metal ion-mediated catalysis mechanism for cleavage of viral concatemeric DNA. The structure reveals extra structural elements in addition to the RNase H-like fold core and variations in local architecture of the nuclease active site, which are conserved in herpesvirus terminases and bear great similarity to the phage T4 gp17 but are distinct from podovirus and siphovirus orthologs and cellular RNase H, delineating a new evolutionary lineage among a large family of eukaryotic viruses and simple and complex prokaryotic viruses.     

Direct Interaction of the Bacteriophage SPP1 Packaging ATPase with the Portal Protein

DNA packaging in tailed bacteriophages and other viruses requires assembly of a complex molecular machine at a specific vertex of the procapsid. This machine is composed of the portal protein that provides a tunnel for DNA entry, an ATPase that fuels DNA translocation (large terminase subunit), and most frequently, a small terminase subunit. Here we characterized the interaction between the terminase ATPase subunit of bacteriophage SPP1 (gp2) and the procapsid portal vertex. We found, by affinity pulldown assays with purified proteins, that gp2 interacts with the portal protein, gp6, independently of the terminase small subunit gp1, DNA, or ATP. The gp2-procapsid interaction via the portal protein depends on gp2 concentration and requires the presence of divalent cations. Competition experiments showed that isolated gp6 can only inhibit gp2-procapsid interactions and DNA packaging at gp6:procapsid molar ratios above 10-fold. Assays with gp6 carrying mutations in distinct regions of its structure that affect the portal-induced stimulation of ATPase and DNA packaging revealed that none of these mutations impedes gp2-gp6 binding. Our results demonstrate that the SPP1 packaging ATPase binds directly to the portal and that the interaction is stronger with the portal embedded in procapsids. Identification of mutations in gp6 that allow for assembly of the ATPase-portal complex but impair DNA packaging support an intricate cross-talk between the two proteins for activity of the DNA translocation motor.     

Role of a mutation in human cytomegalovirus gene UL104 in resistance to benzimidazole ribonucleosides

The benzimidazole D-ribonucleosides TCRB and BDCRB are potent and selective inhibitors of human cytomegalovirus (HCMV) replication. Two HCMV strains resistant to these compounds were selected and had resistance mutations in genes UL89 and UL56. Proteins encoded by these two genes are the two subunits of the HCMV "terminase" and are necessary for cleavage and packaging of viral genomic DNA, a process inhibited by TCRB and BDCRB. We now report that both strains also have a previously unidentified mutation in UL104, the HCMV portal protein. This mutation, which results in L21F substitution, was introduced into the genome of wild-type HCMV by utilizing a recently cloned genome of HCMV as a bacterial artificial chromosome. The virus with this mutation alone was not resistant to BDCRB, suggesting that this site is not involved in binding benzimidazole nucleosides. As in previous proposals for mutations in UL104 of murine cytomegalovirus and HCMV strains resistant to BAY 38-4766, we hypothesize that this mutation could compensate for conformational changes in mutant UL89 and UL56 proteins, since the HCMV terminase is likely to interact with the portal protein during cleavage and packaging of genomic DNA.     

Subunit conformations and assembly states of a DNA-translocating motor: the terminase of bacteriophage P22

Bacteriophage P22, a podovirus infecting strains of Salmonella typhimurium, packages a 42-kbp genome using a headful mechanism. DNA translocation is accomplished by the phage terminase, a powerful molecular motor consisting of large and small subunits. Although many of the structural proteins of the P22 virion have been well characterized, little is known about the terminase subunits and their molecular mechanism of DNA translocation. We report here structural and assembly properties of ectopically expressed and highly purified terminase large and small subunits. The large subunit (gp2), which contains the nuclease and ATPase activities of terminase, exists as a stable monomer with an α/β fold. The small subunit (gp3), which recognizes DNA for packaging and may regulate gp2 activity, exhibits a highly α-helical secondary structure and self-associates to form a stable oligomeric ring in solution. For wild-type gp3, the ring contains nine subunits, as demonstrated by hydrodynamic measurements, electron microscopy, and native mass spectrometry. We have also characterized a gp3 mutant (Ala 112 → Thr) that forms a 10-subunit ring, despite a subunit fold indistinguishable from wild type. Both the nonameric and decameric gp3 rings exhibit nonspecific DNA-binding activity, and gp2 is able to bind strongly to the DNA/gp3 complex but not to DNA alone. We propose a scheme for the roles of P22 terminase large and small subunits in the recruitment and packaging of viral DNA and discuss the model in relation to proposals for terminase-driven DNA translocation in other phages.     

An ATP hydrolysis sensor in the DNA packaging motor from bacteriophage T4 suggests an inchworm-type translocation mechanism

Tailed bacteriophages and large eukaryotic viruses employ powerful molecular motors to translocate dsDNA into a preassembled capsid shell. The phage T4 motor is composed of a dodecameric portal and small and large terminase subunits assembled at the special head-tail connector vertex of the prohead. The motor pumps DNA through the portal channel, utilizing ATP hydrolysis energy provided by an ATPase present in the large terminase subunit. We report that the ATPase motors of terminases, helicases, translocating restriction enzymes, and protein translocases possess a common coupling motif (C-motif). Mutations in the phage T4 terminase C-motif lead to loss of stimulated ATPase and DNA translocation activities. Surprisingly, the mutants can catalyze at least one ATP hydrolysis event but are unable to turn over and reset the motor. This is the first report of a catalytic block in translocating ATPase motor after ATP hydrolysis occurred. We suggest that the C-motif is an ATP hydrolysis sensor, linking product release to mechanical motion. A novel terminase-driven mechanism is proposed for translocation of dsDNA in viruses.     

Nucleotides regulate the conformational state of the small terminase subunit from bacteriophage lambda: implications for the assembly of a viral genome-packaging motor

Terminase enzymes are responsible for "packaging" of viral DNA into a preformed procapsid. Bacteriophage lambda terminase is composed of two subunits, gpA and gpNu1, in a gpA(1).gpNu1(2) holoenzyme complex. The larger gpA subunit is responsible for preparation of viral DNA for packaging, and is central to the packaging motor complex. The smaller gpNu1 subunit is required for site-specific assembly of the packaging motor on viral DNA. Terminase assembly at the packaging initiation site is regulated by ATP binding and hydrolysis at the gpNu1 subunit. Characterization of the catalytic and structural interactions between the DNA and nucleotide binding sites of gpNu1 is thus central to our understanding of the packaging motor at the molecular level. The high-resolution structure of the DNA binding domain of gpNu1 (gpNu1-DBD) was recently determined in our lab [de Beer, T., et al. (2002) Mol. Cell 9, 981-991]. The structure reveals the presence of a winged-helix-turn-helix DNA binding motif, but the location of the ATPase catalytic site in gpNu1 remains unknown. In this work, nucleotide binding to the gpNu1-DBD was probed using acrylamide fluorescence quenching and fluorescence-monitored ligand binding studies. The data indicate that the minimal DBD dimer binds both ATP and ADP at two equivalent but highly cooperative binding sites. The data further suggest that ATP and ADP induce distinct conformations of the dimer but do not affect DNA binding affinity. The implications of these results with respect to the assembly and function of a terminase DNA-packaging motor are discussed.     

The DNA maturation domain of gpA, the DNA packaging motor protein of bacteriophage lambda, contains an ATPase site associated with endonuclease activity

Terminase enzymes are common to double-stranded DNA (dsDNA) viruses and are responsible for packaging viral DNA into the confines of an empty capsid shell. In bacteriophage lambda the catalytic terminase subunit is gpA, which is responsible for maturation of the genome end prior to packaging and subsequent translocation of the matured DNA into the capsid. DNA packaging requires an ATPase catalytic site situated in the N terminus of the protein. A second ATPase catalytic site associated with the DNA maturation activities of the protein has been proposed; however, direct demonstration of this putative second site is lacking. Here we describe biochemical studies that define protease-resistant peptides of gpA and expression of these putative domains in Escherichia coli. Biochemical characterization of gpA-DeltaN179, a construct in which the N-terminal 179 residues of gpA have been deleted, indicates that this protein encompasses the DNA maturation domain of gpA. The construct is folded, soluble and possesses an ATP-dependent nuclease activity. Moreover, the construct binds and hydrolyzes ATP despite the fact that the DNA packaging ATPase site in the N terminus of gpA has been deleted. Mutation of lysine 497, which alters the conserved lysine in a predicted Walker A "P-loop" sequence, does not affect ATP binding but severely impairs ATP hydrolysis. Further, this mutation abrogates the ATP-dependent nuclease activity of the protein. These studies provide direct evidence for the elusive nucleotide-binding site in gpA that is directly associated with the DNA maturation activity of the protein. The implications of these results with respect to the two roles of the terminase holoenzyme, DNA maturation and DNA packaging, are discussed.     

The nuclease domain of the SPP1 packaging motor coordinates DNA cleavage and encapsidation

The large terminase subunit is a central component of the genome packaging motor from tailed bacteriophages and herpes viruses. This two-domain enzyme has an N-terminal ATPase activity that fuels DNA translocation during packaging and a C-terminal nuclease activity required for initiation and termination of the packaging cycle. Here, we report that bacteriophage SPP1 large terminase (gp2) is a metal-dependent nuclease whose stability and activity are strongly and preferentially enhanced by Mn²⁺ ions. Mutation of conserved residues that coordinate Mn²⁺ ions in the nuclease catalytic site affect the metal-induced gp2 stabilization and impair both gp2-specific cleavage at the packaging initiation site pac and unspecific nuclease activity. Several of these mutations block also DNA encapsidation without affecting ATP hydrolysis or gp2 C-terminus binding to the procapsid portal vertex. The data are consistent with a mechanism in which the nuclease domain bound to the portal switches between nuclease activity and a coordinated action with the ATPase domain for DNA translocation. This switch of activities of the nuclease domain is critical to achieve the viral chromosome packaging cycle.     

Sequence analysis of bacteriophage T4 DNA packaging/terminase genes 16 and 17 reveals a common ATPase center in the large subunit of viral terminases

Phage DNA packaging is believed to be driven by a rotary device coupled to an ATPase ‘motor’. Recent evidence suggests that the phage DNA packaging motor is one of the strongest force-generating molecular motors reported to date. However, the ATPase center that is responsible for generating this force is unknown. In order to identify the DNA translocating ATPase, the sequences of the packaging/terminase genes of coliphages T4 and RB49 and vibriophages KVP40 and KVP20 have been analyzed. Alignment of the terminase polypeptide sequences revealed a number of functional signatures in the terminase genes 16 and 17. Most importantly, the data provide compelling evidence for an ATPase catalytic center in the N-terminal half of the large terminase subunit gp17. An analogous ATPase domain consisting of conserved functional signatures is also identified in the large terminase subunit of other bacteriophages and herpesviruses. Interestingly, the putative terminase ATPase domain exhibits some of the common features found in the ATPase domain of DEAD box helicases. Residues that would be critical for ATPase catalysis and its coupling to DNA packaging are identified. Com binatorial mutagenesis shows that the predicted threonine residues in the putative ATPase coupling motif are indeed critical for function.     

Analysis of the ATPase subassembly which initiates processive DNA synthesis by DNA polymerase III holoenzyme.

The gamma complex (gamma delta delta' chi psi) subassembly of DNA polymerase III holoenzyme transfers the beta subunit onto primed DNA in a reaction which requires ATP hydrolysis. Once on DNA, beta is a "sliding clamp" which tethers the polymerase to DNA for highly processive synthesis. We have examined beta and the gamma complex to identify which subunit(s) hydrolyzes ATP. We find the gamma complex is a DNA dependent ATPase. The beta subunit, which lacks ATPase activity, enhances the gamma complex ATPase when primed DNA is used as an effector. Hence, the gamma complex recognizes DNA and couples ATP hydrolysis to clamp beta onto primed DNA. Study of gamma complex subunits showed no single subunit contained significant ATPase activity. However, the heterodimers, gamma delta and gamma delta', were both DNA-dependent ATPases. Only the gamma delta ATPase was stimulated by beta and was functional in transferring the beta from solution to primed DNA. Similarity in ATPase activity of DNA polymerase III holoenzyme accessory proteins to accessory proteins of phage T4 DNA polymerase and mammalian DNA polymerase delta suggests the basic strategy of chromosome duplication has been conserved throughout evolution.