The ATPase domain of the large terminase protein, gp17, from bacteriophage T4 binds DNA: implications to the DNA packaging mechanism

Translocation of double-stranded DNA into a preformed capsid by tailed bacteriophages is driven by powerful motors assembled at the special portal vertex. The motor is thought to drive processive cycles of DNA binding, movement, and release to package the viral genome. In phage T4, there is evidence that the large terminase protein, gene product 17 (gp17), assembles into a multisubunit motor and translocates DNA by an inchworm mechanism. gp17 consists of two domains; an N-terminal ATPase domain (amino acids 1-360) that powers translocation of DNA, and a C-terminal nuclease domain (amino acids 361-610) that cuts concatemeric DNA to generate a headful-size viral genome. While the functional motifs of ATPase and nuclease have been well defined and the ATPase atomic structure has been solved, the DNA binding motif(s) responsible for viral DNA recognition, cutting, and translocation are unknown. Here we report the first evidence for the presence of a double-stranded DNA binding activity in the gp17 ATPase domain. Binding to DNA is sensitive to Mg²⁺ and salt, but not the type of DNA used. DNA fragments as short as 20 bp can bind to the ATPase but preferential binding was observed to DNA greater than 1 kb. A high molecular weight ATPase-DNA complex was isolated by gel filtration, suggesting oligomerization of ATPase following DNA interaction. DNA binding was not observed with the full-length gp17, or the C-terminal nuclease domain. The small terminase protein, gp16, inhibited DNA binding, which was further accentuated by ATP. The presence of a DNA binding site in the ATPase domain and its binding properties implicate a role in the DNA packaging mechanism.     

The DNA translocating ATPase of bacteriophage T4 packaging motor

In double-stranded DNA bacteriophages the viral DNA is translocated into an empty prohead shell by a powerful ATP-driven motor assembled at the unique portal vertex. Terminases consisting of two to three packaging-related ATPase sites are central to the packaging mechanism. But the nature of the key translocating ATPase, stoichiometry of packaging motor, and basic mechanism of DNA encapsidation are poorly understood. A defined phage T4 packaging system consisting of only two components, proheads and large terminase protein (gp17; 70 kDa), is constructed. Using the large expanded prohead, this system packages any linear double-stranded DNA, including the 171 kb T4 DNA. The small terminase protein, gp16 (18 kDa), is not only not required but also strongly inhibitory. An ATPase activity is stimulated when proheads, gp17, and DNA are actively engaged in the DNA packaging mode. No packaging ATPase was stimulated by the N-terminal gp17-ATPase mutants, K166G (Walker A), D255E (Walker B), E256Q (catalytic carboxylate), D255E-E256D and D255E-E256Q (Walker B and catalytic carboxylate), nor could these sponsor DNA encapsidation. Experiments with the two gp17 domains, N-terminal ATPase domain and C-terminal nuclease domain, suggest that terminase association with the prohead portal and communication between the domains are essential for ATPase stimulation. These data for the first time established an energetic linkage between packaging stimulation of N-terminal ATPase and DNA translocation. A core pathway for the assembly of functional DNA translocating motor is proposed. Since the catalytic motifs of the N-terminal ATPase are highly conserved among >200 large terminase sequences analyzed, these may represent common themes in phage and herpes viral DNA translocation.     

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.     

Structural basis for the nuclease activity of a bacteriophage large terminase

The DNA‐packaging motor in tailed bacteriophages requires nuclease activity to ensure that the genome is packaged correctly. This nuclease activity is tightly regulated as the enzyme is inactive for the duration of DNA translocation. Here, we report the X‐ray structure of the large terminase nuclease domain from bacteriophage SPP1. Similarity with the RNase H family endonucleases allowed interactions with the DNA to be predicted. A structure‐based alignment with the distantly related T4 gp17 terminase shows the conservation of an extended β‐sheet and an auxiliary β‐hairpin that are not found in other RNase H family proteins. The model with DNA suggests that the β‐hairpin partly blocks the active site, and in vivo activity assays show that the nuclease domain is not functional in the absence of the ATPase domain. Here, we propose that the nuclease activity is regulated by movement of the β‐hairpin, altering active site access and the orientation of catalytically essential residues.     

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.     

The functional domains of bacteriophage t4 terminase

The packaging of double-stranded genomic DNA into some viral and all bacteriophage capsids is driven by powerful molecular motors. In bacteriophage T4, the motor consists of the portal protein assembly composed of twelve copies of gene product 20 (gp20, 61 kDa) and an oligomeric terminase complex composed of gp16 (18 kDa) and gp17 (70 kDa). The packaging motor drives the 171-kbp T4 DNA into the capsid utilizing the free energy of ATP hydrolysis. Evidence suggests that gp17 is the key component of the motor; it exhibits ATPase, nuclease, and in vitro DNA-packaging activities. The N- and C-terminal halves of gp17 were expressed and purified to homogeneity and found to have ATPase and nuclease activities, respectively. The N-terminal domain exhibited 2-3-fold higher Kcat values for gp16-stimulated ATPase than the full-length gp17. Neither of the domains, individually or together, exhibited in vitro DNA-packaging activity, suggesting that communication between the domains is essential for DNA packaging. The domains, in particular the C-terminal domain or a mixture of both the N- and C-terminal domains, inhibited in vitro DNA packaging that is catalyzed by full-length gp17. In conjunction with genetic evidence, these data suggest that the domains compete with the full-length gp17 for binding sites on the portal protein. A model for the assembly of the T4 DNA-packaging machine is presented.     

Defining the ATPase center of bacteriophage T4 DNA packaging machine: requirement for a catalytic glutamate residue in the large terminase protein gp17

Double-stranded DNA packaging in icosahedral bacteriophages is driven by an ATPase-coupled packaging machine constituted by the portal protein and two non-structural packaging/terminase proteins assembled at the unique portal vertex of the empty viral capsid. Recent studies show that the N-terminal ATPase site of bacteriophage T4 large terminase protein gp17 is critically required for DNA packaging. It is likely that this is the DNA translocating ATPase that powers directional translocation of DNA into the viral capsid. Defining this ATPase center is therefore fundamentally important to understand the mechanism of ATP-driven DNA translocation in viruses. Using combinatorial mutagenesis and biochemical approaches, we have defined the catalytic carboxylate residue that is required for ATP hydrolysis. Although the original catalytic carboxylate hypothesis suggested the presence of a catalytic glutamate between the Walker A (SRQLGKT(161-167)) and Walker B (MIYID(251-255)) motifs, none of the four candidate glutamic acid residues, E198, E208, E220 and E227, is required for function. However, the E256 residue that is immediately adjacent to the putative Walker B aspartic acid residue (D255) exhibited a phenotypic pattern that is consistent with the catalytic carboxylate function. None of the amino acid substitutions, including the highly conservative D and Q, was tolerated. Biochemical analyses showed that the purified E256V, D, and Q mutant gp17s exhibited a complete loss of gp16-stimulated ATPase activity and in vitro DNA packaging activity, whereas their ATP binding and DNA cleavage functions remained intact. The data suggest that the E256 mutants are trapped in an ATP-bound conformation and are unable to catalyze the ATP hydrolysis-transduction cycle that powers DNA translocation. Thus, this study for the first time identified and characterized a catalytic glutamate residue that is involved in the energy transduction mechanism of a viral DNA packaging machine.     

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.     

Regulation by interdomain communication of a headful packaging nuclease from bacteriophage T4

In genome packaging by tailed bacteriophages and herpesviruses, a concatemeric DNA is cut and inserted into an empty procapsid. A series of cuts follow the encapsidation of each unit-length 'headful' genome, but the mechanisms by which cutting is coupled to packaging are not understood. Here we report the first biochemical characterization of a headful nuclease from bacteriophage T4. Our results show that the T4 nuclease, which resides in the C-terminal domain of large 'terminase' gp17, is a weak endonuclease and regulated by a variety of factors; Mg, NaCl, ATP, small terminase gp16 and N-terminal ATPase domain. The small terminase, which stimulates gp17-ATPase, also stimulates nuclease in the presence of ATP but inhibits in the absence of ATP suggesting interdomain crosstalk. Comparison of the 'relaxed' and 'tensed' states of the motor show that a number of basic residues lining the nuclease groove are positioned to interact with DNA in the tensed state but change their positions in the relaxed state. These results suggest that conformational changes in the ATPase center remodel the nuclease center via an interdomain 'communication track'. This might be a common regulatory mechanism for coupling DNA cutting to DNA packaging among the headful packaging nucleases from dsDNA viruses.     

Structure of p22 headful packaging nuclease

Packaging of viral genomes into preformed procapsids requires the controlled and synchronized activity of an ATPase and a genome-processing nuclease, both located in the large terminase (L-terminase) subunit. In this paper, we have characterized the structure and regulation of bacteriophage P22 L-terminase (gp2). Limited proteolysis reveals a bipartite organization consisting of an N-terminal ATPase core flexibly connected to a C-terminal nuclease domain. The 2.02 Å crystal structure of P22 headful nuclease obtained by in-drop proteolysis of full-length L-terminase (FL-L-terminase) reveals a central seven-stranded β-sheet core that harbors two magnesium ions. Modeling studies with DNA suggest that the two ions are poised for two-metal ion-dependent catalysis, but the nuclease DNA binding surface is sterically hindered by a loop-helix (L₁-α₂) motif, which is incompatible with catalysis. Accordingly, the isolated nuclease is completely inactive in vitro, whereas it exhibits endonucleolytic activity in the context of FL-L-terminase. Deleting the autoinhibitory L₁-α₂ motif (or just the loop L₁) restores nuclease activity to a level comparable with FL-L-terminase. Together, these results suggest that the activity of P22 headful nuclease is regulated by intramolecular cross-talk with the N-terminal ATPase domain. This cross-talk allows for precise and controlled cleavage of DNA that is essential for genome packaging.     

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.     

Portal-large terminase interactions of the bacteriophage T4 DNA packaging machine implicate a molecular lever mechanism for coupling ATPase to DNA translocation

DNA packaging by double-stranded DNA bacteriophages and herpesviruses is driven by a powerful molecular machine assembled at the portal vertex of the empty prohead. The phage T4 packaging machine consists of three components: dodecameric portal (gp20), pentameric large terminase motor (gp17), and 11- or 12-meric small terminase (gp16). These components dynamically interact and orchestrate a complex series of reactions to produce a DNA-filled head containing one viral genome per head. Here, we analyzed the interactions between the portal and motor proteins using a direct binding assay, mutagenesis, and structural analyses. Our results show that a portal binding site is located in the ATP hydrolysis-controlling subdomain II of gp17. Mutations at key residues of this site lead to temperature-sensitive or null phenotypes. A conserved helix-turn-helix (HLH) that is part of this site interacts with the portal. A recombinant HLH peptide competes with gp17 for portal binding and blocks DNA translocation. The helices apparently provide specificity to capture the cognate prohead, whereas the loop residues communicate the portal interaction to the ATPase center. These observations lead to a hypothesis in which a unique HLH-portal interaction in the symmetrically mismatched complex acts as a lever to position the arginine finger and trigger ATP hydrolysis. Transiently connecting the critical parts of the motor; subdomain I (ATP binding), subdomain II (controlling ATP hydrolysis), and C-domain (DNA movement), the portal-motor interactions might ensure tight coupling between ATP hydrolysis and DNA translocation.     

Analysis of capsid portal protein and terminase functional domains: interaction sites required for DNA packaging in bacteriophage T4.

Bacteriophage DNA packaging results from an ATP-driven translocation of concatemeric DNA into the prohead by the phage terminase complexed with the portal vertex dodecamer of the prohead. Functional domains of the bacteriophage T4 terminase and portal gene 20 product (gp20) were determined by mutant analysis and sequence localization within the structural genes. Interaction regions of the portal vertex and large terminase subunit (gp17) were determined by genetic (terminase-portal intergenic suppressor mutations), biochemical (column retention of gp17 and inhibition of in vitro DNA packaging by gp20 peptides), and immunological (co-immunoprecipitation of polymerized gp20 peptide and gp17) studies. The specificity of the interaction was tested by means of a phage T4 HOC (highly antigenicoutercapsid protein) display system in which wild-type, cs20, and scrambled portal peptide sequences were displayed on the HOC protein of phage T4. Binding affinities of these recombinant phages as determined by the retention of these phages by a His-tag immobilized gp17 column, and by co-immunoprecipitation with purified terminase supported the specific nature of the portal protein and terminase interaction sites. In further support of specificity, a gp20 peptide corresponding to a portion of the identified site inhibited packaging whereas the scrambled sequence peptide did not block DNA packaging in vitro.The portal interaction site is localized to 28 residues in the central portion of the linear sequence of gp20 (524 residues). As judged by two pairs of intergenic portal-terminase suppressor mutations, two separate regions of the terminase large subunit gp17 (central and COOH-terminal) interact through hydrophobic contacts at the portal site. Although the terminase apparently interacts with this gp20 portal peptide, polyclonal antibody against the portal peptide appears unable to access it in the native structure, suggesting intimate association of gp20 and gp17 possibly internalizes terminase regions within the portal in the packasome complex. Both similarities and differences are seen in comparison to analogous sites which have been identified in phages T3 and lambda.     

Defining the bacteriophage T4 DNA packaging machine: evidence for a C-terminal DNA cleavage domain in the large terminase/packaging protein gp17

Double-stranded DNA packaging in bacteriophage T4 and other viruses occurs by translocation of DNA into an empty prohead by a packaging machine assembled at the portal vertex. Coordinated with this complex process is the cutting of concatemeric DNA to initiate and terminate DNA packaging and encapsidate one genome-length viral DNA. The catalytic site responsible for cutting, and the mechanisms by which cutting is precisely coordinated with DNA translocation remained as interesting open questions. Phage T4, unlike the phages with defined ends (e.g. lambda, T3, T7), packages DNA in a strictly headful manner, and exhibits no strict sequence specificity to initiate or terminate DNA packaging. Previous evidence suggests that the large terminase protein gp17, a key component of the T4 packaging machine, possesses a non-specific DNA cutting activity. A histidine-rich metal-binding motif, H382-X(2)-H385-X(16)-C402-X(8)-H411-X(2)-H414-X(15)-H430-X(5)-H436, in the C-terminal half of gp17 is thought to be involved in the terminase cleavage. Here, exhaustive site-directed mutagenesis revealed that none of the cysteine and histidine residues other than the H436 residue is critical for function. On the other hand, a cluster of conserved residues within this region, D401, E404, G405, and D409, are found to be critical for function. Biochemical analyses showed that the D401 mutants exhibited a novel phenotype, showing a loss of in vivo DNA cutting activity but not the DNA packaging activity. The functional nature of the critical residues and their disposition in the conserved loop region between two predicted beta-strands suggest that these residues are part of a metal-coordinated catalytic site that cleaves the phosphodiester bond of DNA substrate. The data suggest that the T4 terminase consists of at least two functional domains, an N-terminal DNA-translocating ATPase domain and a C-terminal DNA-cutting domain. Although the DNA recognition mechanisms may be distinct, it appears that T4 and other phage terminases employ a common catalytic paradigm for phosphodiester bond cleavage that is used by numerous nucleases.     

Isolation and characterization of T4 bacteriophage gp17 terminase,a large subunit multimer with enhanced ATPase activity

Phage T4 terminase is a two-subunit enzyme that binds to the prohead portal protein and cuts and packages a headful of concatameric DNA. To characterize the T4 terminase large subunit, gp17 (70 kDa), gene 17 was cloned and expressed as a chitin-binding fusion protein. Following cleavage and release of gp17 from chitin, two additional column steps completed purification. The purification yielded (i) homogeneous soluble gp17 highly active in in vitro DNA packaging ( approximately 10% efficiency, >10(8) phage/ml of extract); (ii) gp17 lacking endonuclease and contaminating protease activities; and (iii) a DNA-independent ATPase activity stimulated >100-fold by the terminase small subunit, gp16 (18 kDa), and modestly by portal gp20 and single-stranded binding protein gp32 multimers. Analyses revealed a preparation of highly active and slightly active gp17 forms, and the latter could be removed by immunoprecipitation using antiserum raised against a denatured form of the gp17 protein, leaving a terminase with the increased specific activity (approximately 400 ATPs/gp17 monomer/min) required for DNA packaging. Analysis of gp17 complexes separated from gp16 on glycerol gradients showed that a prolonged enhanced ATPase activity persisted after exposure to gp16, suggesting that constant interaction of the two proteins may not be required during packaging.     

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.     

Functional analysis of the bacteriophage T4 DNA-packaging ATPase motor

Packaging of double-stranded DNA into bacteriophage capsids is driven by one of the most powerful force-generating motors reported to date. The phage T4 motor is constituted by gene product 16 (gp16) (18 kDa; small terminase), gp17 (70 kDa; large terminase), and gp20 (61 kDa; dodecameric portal). Extensive sequence alignments revealed that numerous phage and viral large terminases encode a common Walker-B motif in the N-terminal ATPase domain. The gp17 motif consists of a highly conserved aspartate (Asp255) preceded by four hydrophobic residues (251MIYI254), which are predicted to form a beta-strand. Combinatorial mutagenesis demonstrated that mutations that compromised hydrophobicity, or integrity of the beta-strand, resulted in a null phenotype, whereas certain changes in hydrophobicity resulted in cs/ts phenotypes. No substitutions, including a highly conservative glutamate, are tolerated at the conserved aspartate. Biochemical analyses revealed that the Asp255 mutants showed no detectable in vitro DNA packaging activity. The purified D255E, D255N, D255T, D255V, and D255E/E256D mutant proteins exhibited defective ATP binding and very low or no gp16-stimulated ATPase activity. The nuclease activity of gp17 is, however, retained, albeit at a greatly reduced level. These data define the N-terminal ATPase center in terminases and show for the first time that subtle defects in the ATP-Mg complex formation at this center lead to a profound loss of phage DNA packaging.     

Structural and Functional Studies of the Phage Sf6 Terminase Small Subunit Reveal a DNA-Spooling Device Facilitated by Structural Plasticity

In many DNA viruses, genome packaging is initiated by the small subunit of the packaging terminase, which specifically binds to the packaging signal on viral DNA and directs assembly of the terminase holoenzyme. We have experimentally mapped the DNA-interacting region on Shigella virus Sf6 terminase small subunit gp1, which occupies extended surface areas encircling the gp1 octamer, indicating that DNA wraps around gp1 through extensive contacts. High‐resolution structures reveal large-scale motions of the gp1 DNA-binding domain mediated by the curved helix formed by residues 54–81 and an intermolecular salt bridge formed by residues Arg67 and Glu73, indicating remarkable structural plasticity underlying multivalent, pleomorphic gp1:DNA interactions. These results provide spatial restraints for protein:DNA interactions, which enable construction of a three-dimensional pseudo-atomic model for a DNA-packaging initiation complex assembled from the terminase small subunit and the packaging region on viral DNA. Our results suggest that gp1 functions as a DNA-spooling device, which may transform DNA into a specific architecture appropriate for interaction with and cleavage by the terminase large subunit prior to DNA translocation into viral procapsid. This may represent a common mechanism for the initiation step of DNA packaging in tailed double‐stranded DNA bacterial viruses.     

A critical coiled coil motif in the small terminase, gp16, from bacteriophage T4: insights into DNA packaging initiation and assembly of packaging motor

Double-stranded DNA packaging in bacteriophages is driven by one of the most powerful force-generating molecular motors reported to date. The phage T4 motor is composed of the small terminase protein, gpl6 (18kDa), the large terminase protein, gp17 (70kDa), and the dodecameric portal protein gp20 (61kDa). gp16, which exists as an oligomer in solution, is involved in the recognition of the viral DNA substrate, the very first step in the DNA packaging pathway, and stimulates the ATPase and packaging activities associated with gp17. Sequence analyses using COILS2 revealed the presence of coiled coil motifs (CCMs) in gp16. Sixteen T4-family and numerous phage small terminases show CCMs in the corresponding region of the protein, suggesting a common structural and functional theme. Biochemical properties such as reversible thermal denaturation and analytical gel filtration data suggest that the central CCM-1 is critical for oligomerization of gp16. Mutations in CCM-1 that change the hydrophobicity of key residues, or pH 6.0, destabilized coiled coil interactions, resulting in a loss of gp16 oligomerization. The gp16 oligomers are in a dynamic equilibrium with lower M(r) intermediate species and monomer. Monomeric gp16 is unable to stimulate gp17-ATPase, an activity essential for DNA packaging, while conversion back into oligomeric form restored the activity. These data for the first time defined a CCM that is critical for structure and function of the small terminase. We postulate a packaging model in which the gp16 CCM is implicated in the regulation of packaging initiation and assembly of a supramolecular DNA packaging machine on the viral concatemer.