DNA packaging and cutting by phage terminases: Control in phage T4 by a synaptic mechanism

Phage DNA packaging occurs by DNA translocation into a prohead. Terminases are enzymes which initiate DNA packaging by cutting the DNA concatemer, and they are closely fitted structurally to the portal vertex of the prohead to form a ‘packasome’. Analysis among a number of phages supports an active role of the terminases in coupling ATP hydrolysis to DNA translocation through the portal. In phage T4 the small terminase subunit promotes a sequence-specific terminase gene amplification within the chromosome. This link between recombination and packaging suggests a DNA synapsis mechanism by the terminase to control packaging initiation, formally homologous to eukaryotic chromosome segregation.     

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.     

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.     

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.     

Single-Molecule and FRET Fluorescence Correlation Spectroscopy Analyses of Phage DNA Packaging: Colocalization of Packaged Phage T4 DNA Ends within the Capsid

Linear DNAs of any sequence can be packaged into empty viral procapsids by the phage T4 terminase with high efficiency in vitro. Packaging substrates of 5 kbp and 50 kbp, terminated by energy transfer dye pairs, were constructed from plasmid and λ phage DNAs. Nuclease and fluorescence correlation spectroscopy (FCS) assays showed that ∼ 20% of the substrate DNA was packaged and that the DNA dye ends of the packaged DNA were protected from nuclease digestion. Upon packaging, both 5-kbp and  50-kbp DNAs produced comparable fluorescence resonance energy transfer (FRET) between Cy5 and Cy5.5 double-dye terminated DNAs. Single-molecule FRET (sm-FRET) and photobleaching analysis shows that FRET is intramolecular rather than intermolecular upon packaging of most procapsids and demonstrates that single-molecule detection allows mechanistic analysis of packaging in vitro. FRET-FCS and sm-FRET measurements are comparable and show that both the 5-kbp and the  50-kbp packaged DNA ends are held within 8-9 nm of each other, within the dimensions of the long axis of the procapsid portal. The calculated distribution of FRET distances is relatively narrow for both FRET-FCS and sm-FRET, suggesting that the two packaged DNA ends are held at the same fixed distance relative to each other in most capsids. Because one DNA end is known to be positioned for ejection through the portal, it can be inferred that both DNAs ends are held in proximity to the portal entrance and ejection channel. The analysis suggests that a DNA loop, rather than a DNA end, is translocated by the packaging motor to fill the procapsid.     

A functional domain of bacteriophage lambda terminase for prohead binding

Terminase is a multifunctional protein complex involved in DNA packaging during bacteriophage lambda assembly. Terminase is made of gpNul and gpA, the products of the phage lambda Nu1 and A genes. Early during DNA packaging terminase binds to lambda DNA to form a complex called complex I. Terminase is required for the binding of proheads by complex I to form a DNA: terminase: prohead complex known as complex II. Terminase remains associated with the DNA during encapsidation. The other known role for terminase in packaging is the production of staggered nicks in the DNA thereby generating the cohesive ends. Lambdoid phage 21 has cohesive ends identical to those of lambda. The head genes of lambda and 21 show partial sequence homology and are analogous in structure, function and position. The terminases of lambda and 21 are not interchangeable. At least two actions of terminase are involved in this specificity: (1) DNA binding; (2) prohead binding. The 1 and 2 genes at the left end of the 21 chromosome were identified as coding for the 21 terminase. gp1 and gp2 are analogous to gpNu1 and gpA, respectively. We have isolated a phage, lambda-21 hybrid 33, which is the product of a crossover between lambda and 21 within the terminase genes. Lambda-21 hybrid 33 DNA and terminase have phage 21 packaging specificity, as determined by complementation and helper packaging studies. The terminase of lambda-21 hybrid 33 requires lambda proheads for packaging. We have determined the position at which the crossover between lambda DNA and 21 DNA occurred to produce the hybrid phage. Lambda-21 hybrid 33 carries the phage 21 1 gene and a hybrid phage 2/A gene. Sequencing of lambda-21 hybrid 33 DNA shows that it encodes a protein that is homologous at the carboxy terminus with the 38 amino acids of the carboxy terminus of lambda gpA; the remainder of the protein is homologous to gp2. The results of these studies define a specificity domain for prohead binding at the carboxy terminus of gpA.     

Mutations in Nu1, the gene encoding the small subunit of bacteriophage lambda terminase, suppress the postcleavage DNA packaging defect of cosB mutations.

The linear double-stranded DNA molecules in lambda virions are generated by nicking of concatemeric intracellular DNA by terminase, the lambda DNA packaging enzyme. Staggered nicks are introduced at cosN to generate the cohesive ends of virion DNA. After nicking, the cohesive ends are separated by terminase; terminase bound to the left end of the DNA to be packaged then binds the empty protein shell, i.e., the prohead, and translocation of DNA into the prohead occurs. cosB, a site adjacent to cosN, is a terminase binding site. cosB facilitates the rate and fidelity of the cosN cleavage reaction by serving as an anchoring point for gpNu1, the small subunit of terminase. cosB is also crucial for the formation of a stable terminase-DNA complex, called complex I, formed after cosN cleavage. The role of complex I is to bind the prohead. Mutations in cosB affect both cosB functions, causing mild defects in cosN cleavage and severe packaging defects. The lethal cosB R3- R2- R1- mutation contains a transition mutation in each of the three gpNu1 binding sites of cosB. Pseudorevertants of lambda cosB R3- R2- R1- DNA contain suppressor mutations affecting gpNu1. Results of experiments that show that two such suppressors, Nu1ms1 and Nu1ms3, do not suppress the mild cosN cleavage defect caused by the cosB R3- R2- R1- mutation but strongly suppress the DNA packaging defect are presented. It is proposed that the suppressing terminases, unlike the wild-type enzyme, are able to assemble a stable complex I with cosB R3- R2- R1- DNA. Observations on the adenosine triphosphatase activities and protease susceptibilities of gpNu1 of the Nu1ms1 and Nu1ms3 terminases indicate that the conformation of gpNu1 is altered in the suppressing terminases.     

The terminase of bacteriophage lambda. Functional domains for cosB binding and multimer assembly

Terminase is a protein complex involved in lambda DNA packaging. The subunits of terminase, gpNul and gpA, are the products of genes Nul and A. The actions of terminase include DNA binding, prohead binding and DNA nicking. Phage 21 is a lambdoid phage that also makes a terminase, encoded by genes 1 and 2. The terminases of 21 and lambda are not interchangeable. This specificity involves two actions of terminase; DNA binding and prohead binding. In addition, the subunits of lambda terminase will not form functional multimers with the subunits of 21 terminase. lambda-21 hybrid phages can be produced as a result of recombination. We describe here lambda-21 hybrid phages that have hybrid terminase genes. The packaging specificities of the hybrids and the structure of their genes were compared in order to identify functional domains of terminase. The packaging specificities were determined in vivo by complementation tests and helper packaging experiments. Restriction enzyme site mapping and sequencing located the sites at which recombination occurred to produce the hybrid phages. lambda-21 hybrid 51 carries the lambda A gene, and a hybrid 1/Nul gene. The crossover that produced this phage occurred near the middle of the 1 and Nul genes. The amino-terminal portion of the hybrid protein is homologous to gp1 and the carboxy-terminal portion is homologous to gpNul. It binds to 21 DNA and forms functional multimers with gpA, providing evidence that the amino-terminal portion of gpNul is involved in DNA binding and the carboxy-terminal portion of gpNul is involved in the interaction with gpA. lambda-21 hybrid 54 has a hybrid 2/A gene. The amino terminus of the hybrid protein of lambda-21 hybrid 54 is homologous with gp2. This protein forms functional multimers only with gp1, providing evidence that the amino terminus of gpA is involved in the interaction with gpNul. These studies identify three functional domains of terminase.     

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.     

Domains for Protein-Protein Interactions at the N and C Termini of the Large Subunit of Bacteriophage λ Terminase

The large subunit of phage lambda terminase, gpA, the gene product of the phage A gene, interacts with the small subunit, gpNul, to form functional terminase. Terminase binds to lambda DNA at cosB to form a binary complex. The terminase:DNA complex binds a prohead to form a ternary complex. Ternary complex formation involves an interaction of the prohead with gpA. The amino terminus of gpA contains a functional domain for interaction with gpNul, and the carboxy-terminal 38 amino acids of gpA contain a functional domain for prohead binding. This information about the structure of gpA was obtained through the use of hybrid phages resulting from recombination between lambda and the related phage 21. lambda and 21 encode terminases that are analogous in structural organization and have ca. 60% sequence identity. In spite of these similarities, lambda and 21 terminases differ in specificity for DNA binding, subunit assembly, and prohead binding. A lambda-21 hybrid phage produces a terminase in which one of the subunits is chimeric and had recombinant specificities. In the work reported here; a new hybrid, lambda-21 hybrid 67, is characterized. lambda-21 hybrid 67 is the result of a crossover between lambda and 21 in the large subunit genes, such that the DNA from the left chromosome end is from 21, including cosB phi 21, the 1 gene, and the first 48 codons for the 2 gene. The rest of the hybrid 67 chromosome is lambda DNA, including 593 codons of the A gene. The chimeric gp2/A of hybrid 67 binds gp1 to form functional terminase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Large Terminase Conformational Change Induced by Connector Binding in Bacteriophage T7

During bacteriophage morphogenesis DNA is translocated into a preformed prohead by the complex formed by the portal protein, or connector, plus the terminase, which are located at an especial prohead vertex. The terminase is a powerful motor that converts ATP hydrolysis into mechanical movement of the DNA. Here, we have determined the structure of the T7 large terminase by electron microscopy. The five terminase subunits assemble in a toroid that encloses a channel wide enough to accommodate dsDNA. The structure of the complete connector-terminase complex is also reported, revealing the coupling between the terminase and the connector forming a continuous channel. The structure of the terminase assembled into the complex showed a different conformation when compared with the isolated terminase pentamer. To understand in molecular terms the terminase morphological change, we generated the terminase atomic model based on the crystallographic structure of its phage T4 counterpart. The docking of the threaded model in both terminase conformations showed that the transition between the two states can be achieved by rigid body subunit rotation in the pentameric assembly. The existence of two terminase conformations and its possible relation to the sequential DNA translocation may shed light into the molecular bases of the packaging mechanism of bacteriophage T7.     

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.     

Specificity of interactions among the DNA-packaging machine components of T4-related bacteriophages

Tailed bacteriophages use powerful molecular motors to package the viral genome into a preformed capsid. Packaging at a rate of up to ～2000 bp/s and generating a power density twice that of an automobile engine, the phage T4 motor is the fastest and most powerful reported to date. Central to DNA packaging are dynamic interactions among the packaging components, capsid (gp23), portal (gp20), motor (gp17, large "terminase"), and regulator (gp16, small terminase), leading to precise orchestration of the packaging process, but the mechanisms are poorly understood. Here we analyzed the interactions between small and large terminases of T4-related phages. Our results show that the gp17 packaging ATPase is maximally stimulated by homologous, but not heterologous, gp16. Multiple interaction sites are identified in both gp16 and gp17. The specificity determinants in gp16 are clustered in the diverged N- and C-terminal domains (regions I-III). Swapping of diverged region(s), such as replacing C-terminal RB49 region III with that of T4, switched ATPase stimulation specificity. Two specificity regions, amino acids 37-52 and 290-315, are identified in or near the gp17-ATPase "transmission" subdomain II. gp16 binding at these sites might cause a conformational change positioning the ATPase-coupling residues into the catalytic pocket, triggering ATP hydrolysis. These results lead to a model in which multiple weak interactions between motor and regulator allow dynamic assembly and disassembly of various packaging complexes, depending on the functional state of the packaging machine. This might be a general mechanism for regulation of the phage packaging machine and other complex molecular machines.     

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.     

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.     

ATPase center of bacteriophage lambda terminase involved in post-cleavage stages of DNA packaging: identification of ATP-interactive amino acids

Terminase is the enzyme that mediates lambda DNA packaging into the viral prohead. The large subunit of terminase, gpA (641 amino acid residues), has a high-affinity ATPase activity (K(m)=5 microM). To directly identify gpA's ATP-interacting amino acids, holoterminase bearing a His(6)-tag at the C terminus of gpA was UV-crosslinked with 8-N(3)-[alpha-(32)P]ATP. Tryptic peptides from the photolabeled terminase were purified by affinity chromatography and reverse-phase HPLC. Two labeled peptides of gpA were identified. Amino acid sequencing failed to show the tyrosine residue of the first peptide, E(43)SAY(46)QEGR(50), or the lysine of the second peptide, V(80)GYSK(84)MLL(87), indicating that Y(46) and K(84) were the 8-N(3)-ATP-modified amino acids. To investigate their roles in lambda DNA packaging, Y(46) was changed to E, A, and F, and K(84) was changed to E and A. Purified His(6)-tagged terminases with changes at residues 46 and 84 lacked the gpA high-affinity ATPase activity, though the cos cleavage and cohesive end separation activities were near to those of the wild-type enzyme. In virion assembly reactions using virion DNA as a packaging substrate, the mutant terminases showed severe defects. In summary, the results indicate that Y(46) and K(84) are part of the high-affinity ATPase center of gpA, and show that this ATPase activity is involved in the post-cos cleavage stages of lambda DNA packaging.     

In vitro packaging of DNA of the Bacillus subtilis bacteriophage SPP1

In vitro packaging of bacteriophage SPP1 DNA into procapsids is described and the requirements of this process were determined. Combination of proheads with an extract supplying terminase, DNA and phage tails yielded up to 10(7 )viable phages per milliliter of in vitro reaction under optimized conditions. The presence of neutral polymers and polyamines had a concentration and type dependent effect in the packaging reaction. The terminase donor extract lost rapidly activity at 30 degrees C in contrast to the stability of the prohead donor extract. Maturation to infective virions was observed using both procapsids assembled in SPP1 infected cells and procapsid-like structures assembled in Escherichia coli that overexpressed the SPP1 prohead gene clusters. Neither a majority of aberrant capsid-related structures present in the latter material nor procapsids lacking the portal protein inhibited DNA packaging. Addition of purified portal protein reduced DNA packaging activity in vitro only at concentrations 20-fold higher than those found in the SPP1 infected cell. The SPP1 DNA packaged in vitro originated exclusively from the terminase donor extract. This packaging selectivity was not observed in vivo during mixed infections. The data are compatible with a model for processive headful DNA packaging in which terminase and DNA co-produced in the same cell are tightly associated and can effectively discriminate the portal vertex of DNA packaging-proficient proheads from aberrant structures, from portal-less procapsids, and from isolated portal protein.     

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.     

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.