Early events in DNA packaging in a defined in vitro system of bacteriophage T3

Revolution rather than rotation of AAA+ hexameric phi29 nanomotor for viral dsDNA packaging without coiling

It has long been believed that the DNA-packaging motor of dsDNA viruses utilizes a rotation mechanism. Here we report a revolution rather than rotation mechanism for the bacteriophage phi29 DNA packaging motor. The phi29 motor contains six copies of the ATPase (Schwartz et al., this issue); ATP binding to one ATPase subunit stimulates the ATPase to adopt a conformation with a high affinity for dsDNA. ATP hydrolysis induces a new conformation with a lower affinity, thus transferring the dsDNA to an adjacent subunit by a power stroke. DNA revolves unidirectionally along the hexameric channel wall of the ATPase, but neither the dsDNA nor the ATPase itself rotates along its own axis. One ATP is hydrolyzed in each transitional step, and six ATPs are consumed for one helical turn of 360°. Transition of the same dsDNA chain along the channel wall, but at a location 60° different from the last contact, urges dsDNA to move forward 1.75 base pairs each step (10.5 bp per turn/6ATP=1.75 bp per ATP). Each connector subunit tilts with a left-handed orientation at a 30° angle in relation to its vertical axis that runs anti-parallel to the right-handed dsDNA helix, facilitating the one-way traffic of dsDNA. The connector channel has been shown to cause four steps of transition due to four positively charged lysine rings that make direct contact with the negatively charged DNA phosphate backbone. Translocation of dsDNA into the procapsid by revolution avoids the difficulties during rotation that are associated with DNA supercoiling. Since the revolution mechanism can apply to any stoichiometry, this motor mechanism might reconcile the stoichiometry discrepancy in many phage systems where the ATPase has been found as a tetramer, hexamer, or nonamer.

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.

Functional identification of the DNA packaging terminase from Pseudomonas aeruginosa phage PaP3

Terminase proteins are responsible for DNA recognition and initiation of DNA packaging in phages. We previously reported the genomic sequence of a temperate Pseudomonas aeruginosa phage, PaP3, and determined its precise integration site in the host bacterial chromosome. In this study, we present a detailed functional identification of the DNA packaging terminase for phage PaP3. The purified large subunit p03 was demonstrated to possess ATPase and nuclease activities, as well as the ability to bind to specific DNA when it is unassembled. In addition, a small terminase subunit (p01) of a new type was found and shown to bind specifically to cos-containing DNA and stimulate the cos-cleavage and ATPase activities of p03. The results presented here suggest that PaP3 utilizes a typical cos site mechanism for DNA packaging and provide a first step towards understanding the molecular mechanism of the PaP3 DNA packaging reaction.

Stepwise motion of a microcantilever driven by the hydrolysis of viral ATPases

The biomolecular machines involved in DNA packaging by viruses generate one of the highest mechanical powers observed in nature. One component of the DNA packaging machinery, called the terminase, has been proposed as the molecular motor that converts chemical energy from ATP hydrolysis into mechanical movement of DNA during bacteriophage morphogenesis. However, the conformational changes involved in this energy conversion have never been observed. Here we report a real-time measurement of ATP-induced conformational changes in the terminase of bacteriophage T7 (gp19). The recording of the cantilever bending during its functionalization shows the existence of a gp19 monolayer arrangement confirmed by atomic force microscopy of the immobilized proteins. The ATP hydrolysis of the gp19 terminase generates a stepped motion of the cantilever and points to a mechanical cooperative effect among gp19 oligomers. Furthermore, the effect of ATP can be counteracted by non-hydrolyzable nucleotide analogs.

Biophysics of viral infectivity: matching genome length with capsid size

In this review, we discuss recent advances in biophysical virology, presenting experimental and theoretical studies on the physical properties of viruses. We focus on the double-stranded (ds) DNA bacteriophages as model systems for all of the dsDNA viruses both prokaryotic and eukaryotic. Recent studies demonstrate that the DNA packaged into a viral capsid is highly pressurized, which provides a force for the first step of passive injection of viral DNA into a bacterial cell. Moreover, specific studies on capsid strength show a strong correlation between genome length, and capsid size and robustness. The implications of these newly appreciated physical properties of a viral particle with respect to the infection process are discussed.

A defined in vitro system for DNA packaging by the bacteriophage SPP1: insights into the headful packaging mechanism

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

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.

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.

Structure and function of phi29 hexameric RNA that drives the viral DNA packaging motor: review

One notable feature of linear dsDNA viruses is that, during replication, their lengthy genome is squeezed with remarkable velocity into a preformed procapsid and packed into near crystalline density. A molecular motor using ATP as energy accomplishes this energetically unfavorable motion tack. In bacterial virus phi29, an RNA (pRNA) molecule is a vital component of this motor. This 120-base RNA has many novel and distinctive features. It contains strong secondary structure, is tightly folded, and unusually stable. Upon interaction with ion and proteins, it has a knack to adapt numerous conformations to perform versatile function. It can be easily manipulated to form stable homologous monomers, dimers, trimers and hexamers. As a result, many unknown properties of RNA have been and will be unfolded by the study of this extraordinary molecule. This article reviews the structure and function of this pRNA and focuses on novel methods and unique approaches that lead to the illumination of its structure and function.

BPV1 E2 protein enhances packaging of full-length plasmid DNA in BPV1 pseudovirions

We studied determinants of efficient encapsidation of circular DNA, incorporating a PV early region DNA sequence (nt 584-1978) previously shown to enhance packaging of DNA within papillomavirus (PV)-like particles (VLPs). Insect coelomic cells (Sf-9) and cultured monkey kidney cells (Cos-1) were transfected with an 8-kb reporter plasmid incorporating the putative BPV packaging sequence and infected with BPV1 L1 and L2 recombinant baculovirus or vaccinia virus. Heavy (1.34 g/ml) and light (1.30 g/ml) VLPs were produced, and each packaged some of the input plasmid. In light VLPs, truncated plasmids, which nevertheless incorporated the PV-derived DNA packaging sequence, were more common than full-length plasmids. Packaging efficiency of the plasmid was estimated at 1 plasmid per 10(4) VLPs in both Cos-1 and Sf-9 cells. In each cell type, expression of the BPV1 early region protein E2 in trans doubled the quantity of heavy but not light VLPs and also increased the packaging efficiency of full-length circular plasmids by threefold in heavy VLPs. The resultant pseudovirions incorporated significant amounts of E2 protein. Pseudovirions, comprising plasmids packaged within heavy VLPs, mediated the delivery of packaged plasmid into Cos-1 cells, whereby "infectivity" was blocked by antisera to BPV1 L1, but not antisera to BPV1 E4. We conclude that (a) packaging of DNA within PV L1+L2 pseudovirions is enhanced by BPV1 E2 acting in trans, (b) E2 may be packaged with the pseudovirion, and (c) E2-mediated enhancement of packaging favors 8-kb plasmid incorporation over incorporation of shorter DNA sequences.

Genetic evidence that recognition of cosQ, the signal for termination of phage lambda DNA packaging, depends on the extent of head filling

Packaging a phage lambda chromosome involves cutting the chromosome from a concatemer and translocating the DNA into a prohead. The cutting site, cos, consists of three subsites: cosN, the nicking site; cosB, a site required for packaging initiation; and cosQ a site required for termination of packaging. cosB contains three binding sites (R sequences) for gpNu1, the small subunit of terminase. Because cosQ has sequence identity to the R sequences, it has been proposed that cosQ is also recognized by gpNu1. Suppressors of cosB mutations were unable to suppress a cosQ point mutation. Suppressors of a cosQ mutation (cosQ1) were isolated and found to be of three sorts, the first affecting a base pair in cosQ. The second type of cosQ suppression involved increasing the length of the phage chromosome to a length near to the maximum capacity of the head shell. A third class of suppressors were missense mutations in gene B, which encodes the portal protein of the virion. It is speculated that increasing DNA length and altering the portal protein may reduce the rate of translocation, thereby increasing the efficiency of recognition of the mutant cosQ. None of the cosQ suppressors was able to suppress cosB mutations. Because cosQ and cosB mutations are suppressed by very different types of suppressors, it is concluded that cosQ and the R sequences of cosB are recognized by different DNA-binding determinants.

The in vitro translocase activity of lambda terminase and its subunits. Kinetic and biochemical analysis

The terminase holoenzyme of bacteriophage lambda is a multifunctional protein composed of two subunits, gpNu1 and gpA. In vitro, under certain conditions, terminase can render DNAs from various sources, of varying lengths and termini, resistant to degradation by high concentrations of DNase I. This reaction is completely dependent on the presence of terminase, proheads, a hydrolyzable triphosphate, and a divalent metal ion, and we propose that it is the result of translocation of DNA into proheads by terminase. This reaction is stoichiometric with respect to terminase, DNA, and proheads and can be supported by all deoxyribo- and ribonucleoside triphosphates, but not by the corresponding diphosphates or nonhydrolyzable ATP analogs. Mg2+ and Ca2+ promote the reaction, but Mn2+ and Zn2+ do not. In the absence of spermidine, translocase activity is low, but addition of the Escherichia coli protein integration host factor (IHF) promotes specific translocation of only those DNA fragments containing the terminase-binding site, cosB. When spermidine is present, nonspecific translocation of DNA from any source is stimulated. Under these conditions IHF no longer promotes specificity, but translocation of only cosB-containing DNA fragments can be restored by addition of small amounts of a dialyzed and RNase-treated E. coli extract, suggesting that additional host factor(s) may be involved in determination of packaging specificity. To a limited extent, gpA alone can promote translocation, but gpNu1, which has no translocase activity on its own, must be added to approach the holoenzyme-like activity levels. Formation of viable phage cannot be accomplished by gpA in the absence of gpNu1.

Analysis of functional domains of the packaging proteins of bacteriophage T3 by site-directed mutagenesis

Intracellular phage T3 DNA is synthesized as a concatemer in which unit-length molecules are jointed together in head-to-tail fashion through terminally redundant sequences. The concatemeric DNA is processed and packaged into the prohead with the aid of non-capsid proteins, gp18 and gp19. We have developed a defined system, composed of purified gp18, gp19 and proheads, and a crude system, composed of lysates of T3 infected cells, for in vitro packaging of T3 DNA. The defined system displays an ATPase activity which is composed of DNA packaging-dependent and -independent ATPases (pac- and nonpac-ATPases, respectively). In the crude system, DNA is packaged by a way of concatemer as an intermediate. gp19 has ATP binding activity and three ATP binding and two Mg2+ binding consensus motifs in its amino acid sequence. We have expanded the previous studies on the roles of these domains in the DNA packaging reaction by more extensive analysis by site-directed mutagenesis. gp19 mutants, including the previously isolated four mutants, were divided into four groups according to the DNA packaging activity in the defined and crude systems: group 1 mutants were defective in both systems (gp19-G61D, which is a gp19 mutant with Gly to Asp at amino acid 61 and so on, and gp19-H344D); the group 2 mutant had decreased activity in both systems (gp19-G429R); group 3 mutants were active in the defined system but defective in the crude system (gp19-G63D, gp19-H347R, gp19-G367D, gp19-G369D, gp19-G424E); group 4 mutants had almost the same activity as gp19-wt (gp19-K64T, gp19-K370I, gp19-G429L, gp19-K430T and gp19-H553L). Group 1 mutants had an altered conformation, resulting in defective interaction with ATP and in abortive binding to the prohead, and lost specifically the pac-ATPase activity. The group 2 mutant had an increased pac-ATPase activity in spite of the decreased DNA packaging activity, indicating that this mutant is inefficient in coupling of ATP hydrolysis to DNA translocation. The inability of the group 3 mutants except gp19-H347R to package DNA in the crude system would be due to a defect in processing of concatemer DNA. gp19-H347R would be a mutant defective in the initiation event(s) of DNA packaging.

Pulsed field agarose gel electrophoresis in the study of morphogenesis: packaging of double-stranded DNA in the capsids of bacteriophages

To understand how comparatively simple macromolecular components become biological systems, studies are made of the morphogenesis of bacteriophages. Pulsed field agarose gel electrophoresis (PFGE) has contributed to these studies by: (i) improving the length resolution of both mature, linear, double-stranded bacteriophage DNAs and the concatemers formed both in vivo and in vitro by the end-to-end joining of these mature bacteriophage DNAs, (ii) improving the resolution of circular conformers of bacteriophage DNAs, (iii) improving the resolution of linear single-stranded bacteriophage DNAs, (iv) providing a comparatively simple technique for analyzing protein-DNA complexes, and (v) providing a solid-phase quantitative assay for all forms of bacteriophage DNA; solid-phase assays are both less complex and more efficient than liquid-phase assays such as rate zonal centrifugation. Conversely, studies of bacteriophages have contributed to PFGE the DNA standards used for determining the length of nonbacteriophage DNAs. Among the solid-phase assays based on PFGE is an assay for excluded volume effects.

Biochemical activities of the parA partition protein of the P1 plasmid

The unit-copy P1 plasmid depends for stability on a plasmid-encoded partition region called par, consisting of the parA and parB genes and the parS site. ParA is absolutely required for partition, but its partition-critical role is not known. Purified ParA protein is shown to possess an ATPase activity in vitro which is specifically stimulated by purified ParB protein and by DNA. ParA is responsible for regulation of expression of parA and parB, and purified ParA has an ATP-dependent, site-specific DNA binding activity which recognizes a sequence that overlaps the parA promoter. The role of the ATP-dependence of the binding activity, as well as other possible functions of the ATPase activity in partition, is discussed.

DNA sequences necessary for packaging bacteriophage T3 DNA

A recombinant plasmid, pUCE1-TR, carrying a target for processing of the concatemer joint (TR) and sequences to the left of the target (E1), is efficiently packaged into transducing particles during T3 phage infection. Using this plasmid packaging/transduction system, the minimal sequences necessary for packaging of T3 DNA were determined. The TR sequence contains the targets for initiation cleavage and termination cleavage of concatemer processing (pacCR and pacCL, respectively). A plasmid lacking pacCL was packaged as efficiently as pUCE1-TR but one deleted for pacCR was packaged at a very low efficiency, showing that pacCR is essential for production of transducers but that pacCL is dispensable. DNA from transducing particles carrying a recombinant plasmid lacking pacCL or pacCR had the same right or left end as T3 DNA, respectively, but its other end was not unique. In the absence of pacCL, packaging is initiated from the DNA end created by cleavage at the pacCR and terminated at any sequence after packaging a headful of DNA. In the absence of pacCR, packaging is initiated from the DNA end created by nonspecific, inefficient cleavage and terminated by cleavage at the pacCL after packaging a headful of DNA. A 23-bp segment flanking the site where the mature right end is formed was found to support efficient formation of transducing particles. A 53-bp sequence, including a consensus sequence for the promoter for T3 RNA polymerase, was a responsible element in the E1 sequence for packaging of plasmid DNA. Deletions of the 5'-upstream sequence of the promoter sequence from the left decreased the promoter and packaging activities in parallel, but with those of the 3'-downstream sequence from the right, the packaging activity was impaired before the promoter activity, indicating that transcription from the promoter is necessary but not sufficient for T3 DNA packaging.

Analysis of interactions among factors involved in the bacteriophage T3 DNA packaging reaction in a defined in vitro system

During head assembly of phage T3, DNA is packaged into the cavity of a preformed protein shell, called the prohead, with the aid of noncapsid, packaging proteins, the products of genes 18 and 19 (gp18 and gp19). gp18 and gp19 separately form complexes with DNA and proheads, respectively. These complexes associate to form a precursor which can be converted to filled heads by the addition of ATP. Interactions among factors involved in DNA packaging were analyzed. In the presence of ATP, gp19 formed functional complexes with proheads. Formation of gp19-prohead complex showed a sigmoidal dependence on ATP concentration with a half maximal concentration of about 7.5 microM. Six molecules of gp19 bound to the prohead at a saturating amount of gp19. gp19 did not bind to proheads lacking the connector of gp8 (8- prohead). In the absence of ATP, proheads were inactivated by gp19. The gp19-prohead complexes formed in the absence of ATP contained 20-30 gp19 molecules per prohead and formed multimeric aggregates. 8- proheads did not bind gp19 and did not form such aggregates even in the absence of ATP. From these results, we conclude that 6 molecules of gp19 bind to the gp8 connector structure in the portal vertex of the prohead. The cleavage patterns of gp19 by several proteases were altered by the addition of ATP, indicating that ATP induces a conformational change in gp19, gp18 bound only to linear, duplex DNA.

In vitro cleavage of the concatemer joint of bacteriophage T3 DNA

Mature DNA from phage T3 or T7 is a linear duplex DNA with direct repeats at its ends known as "terminally redundant sequences." The DNA of these phages is synthesized as concatemers in which unit length molecules are joined together in a head-to-tail fashion through the terminally redundant sequences and processed to form mature DNA with coupling to DNA packaging. When linearized plasmid DNA carrying a concatemer joint, a terminally redundant sequence and its flanking sequences from the concatemer, was incubated in a defined in vitro system for packaging T3 DNA, composed of purified proheads and packaging proteins (gp 18 and gp 19), DNA was cleaved at the left end of the terminally redundant sequence. The cleavage reaction required all factors necessary for DNA packaging. The DNA fragment with the left end was preferentially protected from DNase I digestion, indicating that the cleavage reaction occurs at the left end of the terminally redundant sequence in the concatemer when DNA is packaged leftward, corresponding to the direction from the right to the left end of the T3 genome. The cleavage reaction was stimulated by high concentrations of NaCl and ATP, a condition in which DNA translocation into the head is slowed down. The cleavage reaction was not specific between T3 and T7. The right end of the concatemer joint was not required for cleavage at the left end. In the absence of ATP, DNA was extensively degraded by gp 19. gp 19 by itself had nonspecific endonuclease activity, making double-stranded breaks. The activity was inhibited by either ATP or gp 18.

In vitro packaging of bacteriophage phi 29 DNA restriction fragments and the role of the terminal protein gp3

Restriction fragments of bacteriophage phi 29 DNA-gp3 (DNA-gene product 3 complex) were packaged in a completely defined in vitro system that included purified proheads, the DNA packaging protein gp16 and ATP. Both left and right end DNA-gp3 fragments were packaged in this system, in contrast to the oriented and selective packaging of left end DNA-gp3 fragments in extracts; left ends could be packaged quantitatively in the defined system, while the packaging efficiency of right ends was generally about threefold lower. In addition, certain internal (non-end) DNA fragments were packaged at efficiencies of about 10% to 15%. Digestion of the gp3 with trypsin or proteinase K reduced the packaging of whole-length DNA by a factor of 2 or 4, respectively, and removal of the gp3 from whole-length DNA or end fragments with piperidine reduced packaging to the level of internal fragments. Though the terminal protein gp3 was non-essential for DNA translocation in the defined system, it stimulated packaging of left and right end fragments, and stabilized packaging of the left end. The packaging of end and internal DNA fragments of the related phage M2Y into phi 29 proheads was similar to that of phi 29 DNA fragments, and certain fragments of lambda DNA were packaged at the efficiency of the internal phi 29 DNA fragments. Selective packaging of DNA-gp3 left ends was restored by the addition of bacterial cell extracts or glycerol to the defined system, and these packaging conditions discriminated between phi 29 and M2Y DNAs that have distinct terminal proteins.

Packaging and transduction of non-T3 DNA by bacteriophage T3

A defined in vitro system for packaging T3 DNA also packaged other linear DNAs, including T4, lambda, and plasmid DNAs. The packaging capacity was determined to be 40 kb (kilobase pairs) by measuring the packaged length of T4 DNA. Packaged lambda and plasmid DNAs were injected into host cells to form plaques and transductants, respectively. The yield of transducers increased by using artificially ligated plasmid oligomers. The T3 mutant in gene 3 endonuclease (T3 3-) packaged plasmid DNA during abortive infection and transduced it into the recipient. Transduction of recombinant plasmids was not affected by the presence of the terminally redundant sequence (TR sequence) but increased by 4 orders of magnitudes when the genetic right-end 2.7-kb sequences, containing gene 19 (E1) but lacking TR, were present and by 7 orders when both E1 and TR sequences were present. However, these sequences did not increase transduction of these plasmids by T7 3-. Analysis of the structure of transduced plasmid DNAs indicates that transducing particles carry head-to-tail oligomers of plasmid DNA with the same termini as those of T3 genomic DNA. The mechanism of formation of transducing particles is discussed.

Late stages in bacteriophage lambda head morphogenesis: in vitro studies on the action of the bacteriophage lambda D-gene and W-gene products

The in vitro maturation of bacteriophage lambda can be divided into discrete steps. Concatemers of lambda DNA bind terminase to form complex I. This DNA-terminase complex then binds a prohead to form a ternary complex (II). Complex II in turn can be converted to infectious phage by the addition of extracts containing the products of the phage genes D, W, FII, as well as phage tails. By using in vitro complementation assays gpD and gpW have been partially purified and their interactions with complex II studied. gpD can bind to complex II in vitro to form a new complex (III) which can be isolated by sedimentation on neutral sucrose gradients. This complex requires only the addition of gpW, gpFII, and phage tails to form mature phage particles. The sedimentation of complex III is virtually identical to that of complex II; however, the resistance of the former to inactivation by DNase is higher, likely due to the partial packaging of the DNA. In similar experiments it was shown that gpW cannot bind to complex II but can effectively interact with complex III. This latter reaction converts complex III to a DNase-resistant form which sediments in a manner identical to that of full phage heads (complex IV). After isolation of the complex IV only gpFII and tails are required for mature phage formation in vitro. gpW is a heat-stable protein of molecular weight approximately 10,000.

On the molecular mechanism of DNA translocation during in vitro packaging of bacteriophage T3 DNA

The process of packaging of bacteriophage T3 DNA in a defined in vitro system can be separated into two stages: formation of a precursor complex (50 S complex) in the presence of adenosine-5'-O-(3'-thiotriphosphate) (ATP-gamma-S) and subsequent translocation of DNA into the head by the addition of ATP. Packaged DNA exits when DNA translocation is interrupted by the addition of ATP-gamma-S (M. Shibata, H. Fujisawa, and T. Minagawa, 1987, Virology, in press; M. Shibata, H. Fujisawa, and T. Minagawa, 1987, J. Mol. Biol., in press). The in vitro system packaged nicked and cross-linked DNAs but did not package single-stranded DNA. DNA packaging was inhibited by intercalating reagents such as ethidium bromide, acridine orange, and 4',6-diamino-2-phenylindole dihydrochloride. The inhibitory effect was proportional to the ability of intercalating agents to unwind DNA. Ethidium bromide did not inhibit the formation of 50 S complex but blocked translocation of DNA into and out of the capsid. DNA packaging was inhibited by actinomycin D and distamycin A which bind to the minor groove of the DNA helix. From these results, we conclude that DNA packaging mechanism utilizes the exterior structure of duplex DNA for translocating the DNA into the capsid.

Characterization of ATPase activity of a defined in vitro system for packaging of bacteriophage T3 DNA

We have developed a defined in vitro system for packaging phage T3 DNA which is composed of purified proheads and the noncapsid proteins gp18 and gp19, products of genes 18 and 19 (K. Hamada, H. Fujisawa, and T. Minagawa, 1986, Virology 151, 119-123). The in vitro system displayed an ATPase activity. The requirements for ATPase activity were the same as those for DNA packaging. ATPase was inhibited by a nonhydrolyzable ATP analog, adenosine-5'-O-(3'-thiotriphosphate) (ATP-gamma-S). ATPase activity did not display specificity for T3 DNA. A reaction mixture containing 8- proheads, proheads deficient in gp8, a portal protein for DNA entrance, or mature heads had no gp18- gp19-dependent ATPase activity. gp8 itself had no ATPase activity and did not complement 8- proheads for ATPase activity. Photoaffinity labeling of proheads, gp18 and gp19 with 8-azidoadenosine-5'-[alpha-32P]triphosphate([32P]8-N3ATP) resulted in preferential labeling of gp19. Protection from incorporation of [32P]8-N3ATP was afforded by ATP but not by AMP and ADP. From these results, it is concluded that gp19 has an ATP binding site(s). A conserved sequence of ATP-binding site containing Gly-X-Gly-X-X-Gly-X-Val is found in gp19.