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

Hybrid Vigor: Importance of Hybrid λ Phages in Early Insights in Molecular Biology

Laboratory-generated hybrids between phage λ and related phages played a seminal role in establishment of the λ model system, which, in turn, served to develop many of the foundational concepts of molecular biology, including gene structure and control. Important λ hybrids with phages 21 and 434 were the earliest of such phages. To understand the biology of these hybrids in full detail, we determined the complete genome sequences of phages 21 and 434. Although both genomes are canonical members of the λ-like phage family, they both carry unsuspected bacterial virulence gene types not previously described in this group of phages. In addition, we determined the sequences of the hybrid phages λ imm21, λ imm434, and λ h434 imm21. These sequences show that the replacements of λ DNA by nonhomologous segments of 21 or 434 DNA occurred through homologous recombination in adjacent sequences that are nearly identical in the parental phages. These five genome sequences correct a number of errors in published sequence fragments of the 21 and 434 genomes, and they point out nine nucleotide differences from Sanger's original λ sequence that are likely present in most extant λ strains in laboratory use today. We discuss the historical importance of these hybrid phages in the development of fundamental tenets of molecular biology and in some of the earliest gene cloning vectors. The 434 and 21 genomes reinforce the conclusion that the genomes of essentially all natural λ-like phages are mosaics of sequence modules from a pool of exchangeable segments.

Viral Small Terminase: A Divergent Structural Framework for a Conserved Biological Function

The genome packaging motor of bacteriophages and herpesviruses is built by two terminase subunits, known as large (TerL) and small (TerS), both essential for viral genome packaging. TerL structure, composition, and assembly to an empty capsid, as well as the mechanisms of ATP-dependent DNA packaging, have been studied in depth, shedding light on the chemo-mechanical coupling between ATP hydrolysis and DNA translocation. Instead, significantly less is known about the small terminase subunit, TerS, which is dispensable or even inhibitory in vitro, but essential in vivo. By taking advantage of the recent revolution in cryo-electron microscopy (cryo-EM) and building upon a wealth of crystallographic structures of phage TerSs, in this review, we take an inventory of known TerSs studied to date. Our analysis suggests that TerS evolved and diversified into a flexible molecular framework that can conserve biological function with minimal sequence and quaternary structure conservation to fit different packaging strategies and environmental conditions.

Enteric Chromosomal Islands: DNA Packaging Specificity and Role of λ-like Helper Phage Terminase

The phage-inducible chromosomal islands (PICIs) of Gram-negative bacteria are analogous to defective prophages that have lost the ability to propagate without the aid of a helper phage. PICIs have acquired genes that alter the genetic repertoire of the bacterial host, including supplying virulence factors. Recent work by the Penadés laboratory elucidates how a helper phage infection or prophage induction induces the island to excise from the bacterial chromosome, replicate, and become packaged into functional virions. PICIs lack a complete set of morphogenetic genes needed to construct mature virus particles. Rather, PICIs hijack virion assembly functions from an induced prophage acting as a helper phage. The hijacking strategy includes preventing the helper phage from packaging its own DNA while enabling PICI DNA packaging. In the case of recently described Gram-negative PICIs, the PICI changes the specificity of DNA packaging. This is achieved by an island-encoded protein (Rpp) that binds to the phage protein (TerS), which normally selects phage DNA for packaging from a DNA pool that includes the helper phage and host DNAs. The Rpp–TerS interaction prevents phage DNA packaging while sponsoring PICI DNA packaging. Our communication reviews published data about the hijacking mechanism and its implications for phage DNA packaging. We propose that the Rpp–TerS complex binds to a site in the island DNA that is positioned analogous to that of the phage DNA but has a completely different sequence. The critical role of TerS in the Rpp–TerS complex is to escort TerL to the PICI cosN, ensuring appropriate DNA cutting and packaging.

Viral genome packaging machines: Structure and enzymology

Although the process of genome encapsidation is highly conserved in tailed bacteriophages and eukaryotic double-stranded DNA viruses, there are two distinct packaging pathways that these viruses use to catalyze ATP-driven translocation of the viral genome into a preassembled procapsid shell. One pathway is used by ϕ29-like phages and adenoviruses, which replicate and subsequently package a monomeric, unit-length genome covalently attached to a virus/phage-encoded protein at each 5'-end of the dsDNA genome. In a second, more ubiquitous packaging pathway characterized by phage lambda and the herpesviruses, the viral DNA is replicated as multigenome concatemers linked in a head-to-tail fashion. Genome packaging in these viruses thus requires excision of individual genomes from the concatemer that are then translocated into a preassembled procapsid. Hence, the ATPases that power packaging in these viruses also possess nuclease activities that cut the genome from the concatemer at the beginning and end of packaging. This review focuses on proposed mechanisms of genome packaging in the dsDNA viruses using unit-length ϕ29 and concatemeric λ genome packaging motors as representative model systems.

The coevolution of large and small terminases of bacteriophages is a result of purifying selection leading to phenotypic stabilization

Genome packaging in many dsDNA phages requires a series of precisely coordinated actions of two phage-coded proteins, namely, large terminase (TerL) and small terminase (TerS) with DNA and ATP, and with each other. Despite the strict functional conservation, TerL and TerS homologs exhibit large sequence variations. We investigated the sequence variability across eight phage types and observed a coevolutionary framework wherein the genealogy of TerL homologs mirrored that of the corresponding TerS homologs. Furthermore, a high purifying selection observed (dN/dS«1) indicated strong structural constraints on both TerL and TerS, and identify coevolving residues in TerL and TerS of phage T4 and lambda. Using the highly coevolving (correlation coefficient of 0.99) TerL and TerS of phage N4, we show that their biochemical features are similar to the phylogenetically divergent phage λ terminases. We also demonstrate using the Surface Plasma Resonance (SPR) technique that phage N4 TerL transiently interacts with TerS.

Hijacking the Hijackers: Escherichia coli Pathogenicity Islands Redirect Helper Phage Packaging for Their Own Benefit

Phage-inducible chromosomal islands (PICIs) represent a novel and universal class of mobile genetic elements, which have broad impact on bacterial virulence. In spite of their relevance, how the Gram-negative PICIs hijack the phage machinery for their own specific packaging and how they block phage reproduction remains to be determined. Using genetic and structural analyses, we solve the mystery here by showing that the Gram-negative PICIs encode a protein that simultaneously performs these processes. This protein, which we have named Rpp (for redirecting phage packaging), interacts with the phage terminase small subunit, forming a heterocomplex. This complex is unable to recognize the phage DNA, blocking phage packaging, but specifically binds to the PICI genome, promoting PICI packaging. Our studies reveal the mechanism of action that allows PICI dissemination in nature, introducing a new paradigm in the understanding of the biology of pathogenicity islands and therefore of bacterial pathogen evolution.

Physical and Functional Characterization of a Viral Genome Maturation Complex

Genome packaging is strongly conserved in the complex double-stranded DNA viruses, including the herpesviruses and many bacteriophages. In these cases, viral DNA is packaged into a procapsid shell by a terminase enzyme. The packaging substrate is typically a concatemer composed of multiple genomes linked in a head-to-tail fashion, and terminase enzymes perform two essential functions: 1) excision of a unit length genome from the concatemer (genome maturation) and 2) translocation of the duplex into a procapsid (genome packaging). While the packaging motors have been described in some detail, the maturation complexes remain ill characterized. Here we describe the assembly, physical characteristics, and catalytic activity of the λ-genome maturation complex. The λ-terminase protomer is composed of one large catalytic subunit tightly associated with two DNA recognition subunits. The isolated protomer binds DNA weakly and does not discriminate between nonspecific DNA and duplexes that contain the packaging initiation sequence, cos. The Escherichia coli integration host factor protein (IHF) is required for efficient λ-development in vivo and a specific IHF recognition sequence is found within cos. We show that IHF and the terminase protomer cooperatively assemble at the cos site and that the small terminase subunit plays the dominant role in complex assembly. Analytical ultracentrifugation analysis reveals that the maturation complex is composed of four protomers and one IHF heterodimer bound at the cos site. Tetramer assembly activates the cos-cleavage nuclease activity of the enzyme, which matures the genome end in preparation for packaging. The stoichiometry and catalytic activity of the complex is reminiscent of the type IIE and IIF restriction endonucleases and the two systems may share mechanistic features. This study, to our knowledge, provides our first detailed glimpse into the structural and functional features of a viral genome maturation complex, an essential intermediate in the development of complex dsDNA viruses.

Walker-A Motif Acts to Coordinate ATP Hydrolysis with Motor Output in Viral DNA Packaging

During the assembly of many viruses, a powerful ATP-driven motor translocates DNA into a preformed procapsid. A Walker-A "P-loop" motif is proposed to coordinate ATP binding and hydrolysis with DNA translocation. We use genetic, biochemical, and biophysical techniques to survey the roles of P-loop residues in bacteriophage lambda motor function. We identify 55 point mutations that reduce virus yield to below detectable levels in a highly sensitive genetic complementation assay and 33 that cause varying reductions in yield. Most changes in the predicted conserved residues K76, R79, G81, and S83 produce no detectable yield. Biochemical analyses show that R79A and S83A mutant proteins fold, assemble, and display genome maturation activity similar to wild-type (WT) but exhibit little ATPase or DNA packaging activity. Kinetic DNA cleavage and ATPase measurements implicate R79 in motor ring assembly on DNA, supporting recent structural models that locate the P-loop at the interface between motor subunits. Single-molecule measurements detect no translocation for K76A and K76R, while G81A and S83A exhibit strong impairments, consistent with their predicted roles in ATP binding. We identify eight residue changes spanning A78-K84 that yield impaired translocation phenotypes and show that Walker-A residues play important roles in determining motor velocity, pausing, and processivity. The efficiency of initiation of packaging correlates strongly with motor velocity. Frequent pausing and slipping caused by changes A78V and R79K suggest that these residues are important for ATP alignment and coupling of ATP binding to DNA gripping. Our findings support recent structural models implicating the P-loop arginine in ATP hydrolysis and mechanochemical coupling.

DNA Topology and the Initiation of Virus DNA Packaging

During progeny assembly, viruses selectively package virion genomes from a nucleic acid pool that includes host nucleic acids. For large dsDNA viruses, including tailed bacteriophages and herpesviruses, immature viral DNA is recognized and translocated into a preformed icosahedral shell, the prohead. Recognition involves specific interactions between the viral packaging enzyme, terminase, and viral DNA recognition sites. Generally, viral DNA is recognized by terminase’s small subunit (TerS). The large terminase subunit (TerL) contains translocation ATPase and endonuclease domains. In phage lambda, TerS binds a sequence repeated three times in cosB, the recognition site. TerS binding to cosB positions TerL to cut the concatemeric DNA at the adjacent nicking site, cosN. TerL introduces staggered nicks in cosN, generating twelve bp cohesive ends. Terminase separates the cohesive ends and remains bound to the cosB-containing end, in a nucleoprotein structure called Complex I. Complex I docks on the prohead’s portal vertex and translocation ensues. DNA topology plays a role in the TerS^λ-cosB^λ interaction. Here we show that a site, I2, located between cosN and cosB, is critically important for an early DNA packaging step. I2 contains a complex static bend. I2 mutations block DNA packaging. I2 mutant DNA is cut by terminase at cosN in vitro, but in vivo, no cos cleavage is detected, nor is there evidence for Complex I. Models for what packaging step might be blocked by I2 mutations are presented.

DNA Packaging Specificity of Bacteriophage N15 with an Excursion into the Genetics of a Cohesive End Mismatch

During DNA replication by the λ-like bacteriophages, immature concatemeric DNA is produced by rolling circle replication. The concatemers are processed into mature chromosomes with cohesive ends, and packaged into prohead shells, during virion assembly. Cohesive ends are generated by the viral enzyme terminase, which introduces staggered nicks at cos, an approx. 200 bp-long sequence containing subsites cosQ, cosN and cosB. Interactions of cos subsites of immature concatemeric DNA with terminase orchestrate DNA processing and packaging. To initiate DNA packaging, terminase interacts with cosB and nicks cosN. The cohesive ends of N15 DNA differ from those of λ at 2/12 positions. Genetic experiments show that phages with chromosomes containing mismatched cohesive ends are functional. In at least some infections, the cohesive end mismatch persists through cyclization and replication, so that progeny phages of both allelic types are produced in the infected cell. N15 possesses an asymmetric packaging specificity: N15 DNA is not packaged by phages λ or 21, but surprisingly, N15-specific terminase packages λ DNA. Implications for genetic interactions among λ-like bacteriophages are discussed.

Function and horizontal transfer of the small terminase subunit of the tailed bacteriophage Sf6 DNA packaging nanomotor

Bacteriophage Sf6 DNA packaging series initiate at many locations across a 2kbp region. Our in vivo studies show that Sf6 small terminase subunit (TerS) protein recognizes a specific packaging (pac) site near the center of this region, that this site lies within the portion of the Sf6 gene that encodes the DNA-binding domain of TerS protein, that this domain of the TerS protein is responsible for the imprecision in Sf6 packaging initiation, and that the DNA-binding domain of TerS must be covalently attached to the domain that interacts with the rest of the packaging motor. The TerS DNA-binding domain is self-contained in that it apparently does not interact closely with the rest of the motor and it binds to a recognition site that lies within the DNA that encodes the domain. This arrangement has allowed the horizontal exchange of terS genes among phages to be very successful.

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.

Bacteriophage protein-protein interactions

Bacteriophages T7, λ, P22, and P2/P4 (from Escherichia coli), as well as ϕ29 (from Bacillus subtilis), are among the best-studied bacterial viruses. This chapter summarizes published protein interaction data of intraviral protein interactions, as well as known phage-host protein interactions of these phages retrieved from the literature. We also review the published results of comprehensive protein interaction analyses of Pneumococcus phages Dp-1 and Cp-1, as well as coliphages λ and T7. For example, the ≈55 proteins encoded by the T7 genome are connected by ≈43 interactions with another ≈15 between the phage and its host. The chapter compiles published interactions for the well-studied phages λ (33 intra-phage/22 phage-host), P22 (38/9), P2/P4 (14/3), and ϕ29 (20/2). We discuss whether different interaction patterns reflect different phage lifestyles or whether they may be artifacts of sampling. Phages that infect the same host can interact with different host target proteins, as exemplified by E. coli phage λ and T7. Despite decades of intensive investigation, only a fraction of these phage interactomes are known. Technical limitations and a lack of depth in many studies explain the gaps in our knowledge. Strategies to complete current interactome maps are described. Although limited space precludes detailed overviews of phage molecular biology, this compilation will allow future studies to put interaction data into the context of phage biology.

Structure and function of the small terminase component of the DNA packaging machine in T4-like bacteriophages

Tailed DNA bacteriophages assemble empty procapsids that are subsequently filled with the viral genome by means of a DNA packaging machine situated at a special fivefold vertex. The packaging machine consists of a "small terminase" and a "large terminase" component. One of the functions of the small terminase is to initiate packaging of the viral genome, whereas the large terminase is responsible for the ATP-powered translocation of DNA. The small terminase subunit has three domains, an N-terminal DNA-binding domain, a central oligomerization domain, and a C-terminal domain for interacting with the large terminase. Here we report structures of the central domain in two different oligomerization states for a small terminase from the T4 family of phages. In addition, we report biochemical studies that establish the function for each of the small terminase domains. On the basis of the structural and biochemical information, we propose a model for DNA packaging initiation.

Evolution of mosaically related tailed bacteriophage genomes seen through the lens of phage P22 virion assembly

The mosaic composition of the genomes of dsDNA tailed bacteriophages (Caudovirales) is well known. Observations of this mosaicism have generally come from comparisons of small numbers of often rather distantly related phages, and little is known about the frequency or detailed nature of the processes that generate this kind of diversity. Here we review and examine the mosaicism within fifty-seven clusters of virion assembly genes from bacteriophage P22 and its "close" relatives. We compare these orthologous gene clusters, discuss their surprising diversity and document horizontal exchange of genetic information between subgroups of the P22-like phages as well as between these phages and other phage types. We also point out apparent restrictions in the locations of mosaic sequence boundaries in this gene cluster. The relatively large sample size and the fact that phage P22 virion structure and assembly are exceptionally well understood make the conclusions especially informative and convincing.

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.

Crystal structure of the DNA-recognition component of the bacterial virus Sf6 genome-packaging machine

In herpesviruses and many bacterial viruses, genome-packaging is a precisely mediated process fulfilled by a virally encoded molecular machine called terminase that consists of two protein components: A DNA-recognition component that defines the specificity for packaged DNA, and a catalytic component that provides energy for the packaging reaction by hydrolyzing ATP. The terminase docks onto the portal protein complex embedded in a single vertex of a preformed viral protein shell called procapsid, and pumps the viral DNA into the procapsid through a conduit formed by the portal. Here we report the 1.65 A resolution structure of the DNA-recognition component gp1 of the Shigella bacteriophage Sf6 genome-packaging machine. The structure reveals a ring-like octamer formed by interweaved protein monomers with a highly extended fold, embracing a tunnel through which DNA may be translocated. The N-terminal DNA-binding domains form the peripheral appendages surrounding the octamer. The central domain contributes to oligomerization through interactions of bundled helices. The C-terminal domain forms a barrel with parallel beta-strands. The structure reveals a common scheme for oligomerization of terminase DNA-recognition components, and provides insights into the role of gp1 in formation of the packaging-competent terminase complex and assembly of the terminase with the portal, in which ring-like protein oligomers stack together to form a continuous channel for viral DNA translocation.

DNA packaging by lambda-like bacteriophages: mutations broadening the packaging specificity of terminase, the lambda-packaging enzyme

The DNA-packaging specificities of phages lambda and 21 depend on the specific DNA interactions of the small terminase subunits, which have support helix-turn-recognition helix-wing DNA-binding motifs. lambda-Terminase with the recognition helix of 21 preferentially packages 21 DNA. This chimeric terminase's ability to package lambdaDNA is reduced approximately 20-fold. Phage lambda with the chimeric terminase is unable to form plaques, but pseudorevertants are readily obtained. Some pseudorevertants have trans-acting suppressors that change codons of the recognition helix. Some of these codons appear to remove an unfavorable base-pair contact; others appear to create a novel nonspecific DNA contact. Helper-packaging experiments show that these mutant terminases have lost the ability to discriminate between lambda and 21 during DNA packaging. Two cis-acting suppressors affect cosB, the small subunit's DNA-binding site. Each changes a cosB(lambda)-specific base pair to a cosB(21)-specific base pair. These cosB suppressors cause enhanced DNA packaging by 21-specific terminase and reduce packaging by lambda-terminase. Both the cognate support helix and turn are required for strong packaging discrimination. The wing does not contribute to cosB specificity. Evolution of packaging specificity is discussed, including a model in which lambda- and 21-packaging specificities diverged from a common ancestor phage with broad packaging specificity.

The bacteriophage DNA packaging motor

An ATP-powered DNA translocation machine encapsidates the viral genome in the large dsDNA bacteriophages. The essential components include the empty shell, prohead, and the packaging enzyme, terminase. During translocation, terminase is docked on the prohead's portal protein. The translocation ATPase and the concatemer-cutting endonuclease reside in terminase. Remarkably, terminases, portal proteins, and shells of tailed bacteriophages and herpes viruses show conserved features. These DNA viruses may have descended from a common ancestor. Terminase's ATPase consists of a classic nucleotide binding fold, most closely resembling that of monomeric helicases. Intriguing models have been proposed for the mechanism of dsDNA translocation, invoking ATP hydrolysis-driven conformational changes of portal or terminase powering DNA motion. Single-molecule studies show that the packaging motor is fast and powerful. Recent advances permit experiments that can critically test the packaging models. The viral genome translocation mechanism is of general interest, given the parallels between terminases, helicases, and other motor proteins.

Assembly of bacteriophage lambda terminase into a viral DNA maturation and packaging machine

Terminase enzymes are common to complex double-stranded DNA viruses and function to package viral DNA into the capsid. We recently demonstrated that the bacteriophage lambda terminase gpA and gpNu1 proteins assemble into a stable heterotrimer with a molar ratio gpA1/gpNu1(2). This terminase protomer possesses DNA maturation and packaging activities that are dependent on the E. coli integration host factor protein (IHF). Here, we show that the protomer further assembles into a homogeneous tetramer of protomers of composition (gpA1/gpNu1(2))4. Electron microscopy shows that the tetramer forms a ring structure large enough to encircle duplex DNA. In contrast to the heterotrimer, the ring tetramer can mature and package viral DNA in the absence of IHF. We propose that IHF induced bending of viral DNA facilitates the assembly of four terminase protomers into a ring tetramer that represents the catalytically competent DNA maturation and packaging complex in vivo. This work provides, for the first time, insight into the functional assembly state of a viral DNA packaging motor.

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

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

Binding of pRNA to the N-terminal 14 amino acids of connector protein of bacteriophage phi29

During assembly, bacterial virus phi29 utilizes a motor to insert genomic DNA into a preformed protein shell called the procapsid. The motor contains one twelve-subunit connector with a 3.6 nm central channel for DNA transportation, six viral-encoded RNA (packaging RNA or pRNA) and a protein, gp16, with unknown stoichiometry. Recent DNA-packaging models proposed that the 5-fold procapsid vertexes and 12-fold connector (or the hexameric pRNA ring) represented a symmetry mismatch enabling production of a force to drive a rotation motor to translocate and compress DNA. There was a discrepancy regarding the location of the foothold for the pRNA. One model [C. Chen and P. Guo (1997) J. Virol., 71, 3864–3871] suggested that the foothold for pRNA was the connector and that the pRNA–connector complex was part of the rotor. However, one other model suggested that the foothold for pRNA was the 5-fold vertex of the capsid protein and that pRNA was the stator. To elucidate the mechanism of phi29 DNA packaging, it is critical to confirm whether pRNA binds to the 5-fold vertex of the capsid protein or to the 12-fold symmetrical connector. Here, we used both purified connector and purified procapsid for binding studies with in vitro transcribed pRNA. Specific binding of pRNA to the connector in the procapsid was found by photoaffinity crosslinking. Removal of the N-terminal 14 amino acids of the gp10 protein by proteolytic cleavage resulted in undetectable binding of pRNA to either the connector or the procapsid, as investigated by agarose gel electrophoresis, SDS–PAGE, sucrose gradient sedimentation and N-terminal peptide sequencing. It is therefore concluded that pRNA bound to the 12-fold symmetrical connector to form a pRNA–connector complex and that the foothold for pRNA is the connector but not the capsid protein.

Self-association properties of the bacteriophage lambda terminase holoenzyme: implications for the DNA packaging motor

Terminases are enzymes common to complex double-stranded DNA viruses and are required for packaging of viral DNA into a protective capsid. Bacteriophage lambda terminase holoenzyme is a hetero-oligomer composed of the A and Nu1 lambda gene products; however, the self-association properties of the holoenzyme have not been investigated systematically. Here, we report the results of sedimentation velocity, sedimentation equilibrium, and gel-filtration experiments studying the self-association properties of the holoenzyme. We find that purified, recombinant lambda terminase forms a homogeneous, heterotrimeric structure, consisting of one gpA molecule associated with two gpNu1 molecules (114.2 kDa). We further show that lambda terminase adopts a heterogeneous mixture of higher-order structures, with an average molecular mass of 528(+/-34) kDa. Both the heterotrimer and the higher-order species possess site-specific cos cleavage activity, as well as DNA packaging activity; however, the heterotrimer is dependent upon Escherichia coli integration host factor (IHF) for these activities. Furthermore, the ATPase activity of the higher-order species is approximately 1000-fold greater than that of the heterotrimer. These data suggest that IHF bending of the duplex at the cos site in viral DNA promotes the assembly of the heterotrimer into a biologically active, higher-order packaging motor. We propose that a single, higher-order hetero-oligomer of gpA and gpNu1 functions throughout lambda development.

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.

Initial cos cleavage of bacteriophage lambda concatemers requires proheads and gpFI in vivo

The development of bacteriophage lambda and double-stranded DNA viruses in general involves the convergence of two separate pathways: DNA replication and head assembly. Clearly, packaging will proceed only if an empty capsid shell, the prohead, is present to receive the DNA, but genetic evidence suggests that proheads play another role in the packaging process. For example, lambda phages with an amber mutation in any head gene or in FI, the gene encoding the accessory packaging protein gpFI, are able to produce normal amounts of DNA concatemers but they are not cut, or matured, into unit length chromosomes for packaging. Similar observations have been made for herpes simplex 1 virus. In the case of lambda, a negative model proposes that in the amber phages, unassembled capsid components are inhibitory to maturation, and a positive model suggests that assembled proheads are required for cutting. We tested the negative model by using a deletion mutant devoid of all prohead genes and FI in an in vivo cos cleavage assay; in this deleted phage, the cohesive ends were not cut. When lambda proheads and gpFI were provided in vivo via a second prophage, cutting was restored, and gpFI was required, results that support the positive model. Phage 21 is a sister phage of lambda, and although its capsid proteins share approximately 60% residue identity with lambda's, phage 21 proheads did not restore cutting, even when provided with the accessory protein gpFI. Models for the role of proheads and gpFI in cos cutting are discussed.

DNA cleavage and packaging proteins encoded by genes U(L)28, U(L)15, and U(L)33 of herpes simplex virus type 1 form a complex in infected cells

Previous studies have indicated that the U(L)6, U(L)15, U(L)17, U(L)28, U(L)32, and U(L)33 genes are required for the cleavage and packaging of herpes simplex viral DNA. To identify proteins that interact with the U(L)28-encoded DNA binding protein of herpes simplex virus type 1 (HSV-1), a previously undescribed rabbit polyclonal antibody directed against the U(L)28 protein fused to glutathione S-transferase was used to immunopurify U(L)28 and the proteins with which it associated. It was found that the antibody specifically coimmunoprecipitated proteins encoded by the genes U(L)28, U(L)15, and U(L)33 from lysates of both HEp-2 cells infected with HSV-1(F) and insect cells infected with recombinant baculoviruses expressing these three proteins. In reciprocal reactions, antibodies directed against the U(L)15- or U(L)33-encoded proteins also coimmunoprecipitated the U(L)28 protein. The coimmunoprecipitation of the three proteins from HSV-infected cells confirms earlier reports of an association between the U(L)28 and U(L)15 proteins and represents the first evidence of the involvement of the U(L)33 protein in this complex.

The large subunit of bacteriophage lambda's terminase plays a role in DNA translocation and packaging termination

The DNA packaging enzyme of bacteriophage lambda, terminase, is a heteromultimer composed of a small subunit, gpNu1, and a large subunit, gpA, products of the Nu1 and A genes, respectively. The role of terminase in the initial stages of packaging involving the site-specific binding and cutting of the DNA has been well characterized. While it is believed that terminase plays an active role in later post-cleavage stages of packaging, such as the translocation of DNA into the head shell, this has not been demonstrated. Accordingly, we undertook a generalized mutagenesis of lambda's A gene and found ten lethal mutations, nine of which cause post-cleavage packaging defects. All were located in the amino-terminal two-thirds of gpA, separate from the carboxy-terminal region where mutations affecting the protein's endonuclease activity have been found. The mutants fall into five groups according to their packaging phenotypes: (1) two mutants package part of the lambda chromosome, (2) one mutant packages the entire chromosome, but very slowly compared to wild-type, (3) two mutants do not package any DNA, (4) four mutants, though inviable, package the entire lambda chromosome, and (5) one mutant may be defective in both early and late stages of DNA packaging. These results indicate that gpA is actively involved in late stages of packaging, including DNA translocation, and that this enzyme contains separate functional domains for its early and late packaging activities.

Purification and functional characterization of p16, the ATPase of the bacteriophage Phi29 packaging machinery

Bacteriophage Phi29 codes for a protein (p16) that is required for viral DNA packaging both in vivo and in vitro. Co-expression of p16 with the chaperonins GroEL and GroES has allowed its purification in a soluble form. Purified p16 shows a weak ATPase activity that is stimulated by either DNA or RNA, irrespective of the presence of any other viral component. The stimulation of ATPase activity of p16, although induced under packaging conditions, is not dependent of the actual DNA packaging and in this respect the Phi29 enzyme is similar to other viral terminases. Protein p16 competes with DNA and RNA in the interaction with the viral prohead, which occurs through the N-terminal region of the connector protein (p10). In fact, p16 interacts in a nucleotide-dependent fashion with the viral Phi29-encoded RNA (pRNA) involved in DNA packaging, and this binding can be competed with DNA. Our results are consistent with a model for DNA translocation in which p16, bound and organized around the connector, acts as a power stroke to pump the DNA into the prohead, using the hydrolysis of ATP as an energy source.

Endonuclease and helicase activities of bacteriophage lambda terminase: changing nearby residue 515 restores activity to the gpA K497D mutant enzyme

Terminase, the DNA packaging enzyme of bacteriophage lambda, is a heteromultimer of gpNu1 and gpA subunits. In an earlier investigation, a lethal mutation changing gpA residue 497 from lysine to aspartic acid (K497D) was found to cause a mild change in the high-affinity ATPase that resides in gpA and a severe defect in the endonuclease activity of terminase. The K497D terminase efficiently sponsored packaging of mature lambda DNA into proheads. In the present work, K497D terminase was found to have a severe defect in the cohesive end separation, or helicase, activity. Plaque-forming pseudorevertants of lambda A K497D were found to carry mutations in A that suppressed the lethality of the A K497D mutation. The two suppressor mutations identified, A E515G and A E515K, affected residue 515, which is located near the putative P-loop of gpA. A codon substitution study of codon 515 showed that hydrophobic and basic residues suppress the K497D defect, but hydrophilic and acidic residues do not. The E515G change was demonstrated to reverse the endonuclease and helicase defects caused by the K497D change. Moreover, the gpA K497D E515G enzyme was found to have kinetic constants for the high-affinity ATPase center similar to those of the wild type enzyme, and the endonuclease activity of the K497D E515G enzyme was stimulated by ATP to an extent similar to the ATP stimulation of the endonuclease activity of the wild type enzyme.

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.

A mutation correcting the DNA interaction defects of a mutant phage lambda terminase, gpNu1 K35A terminase

Terminase, the DNA packaging enzyme of bacteriophage lambda, is a heteromultimer composed of gpNu1 (181 aa) and gpA (641 aa) subunits, encoded by the lambda Nu1 and A genes, respectively. Similarity between the deduced amino acid sequences of gpNu1 and gpA and the nucleotide binding site consensus sequence suggests that each terminase subunit has an ATP reactive center. Terminase has been shown to have two distinct ATPase activities. The gpNu1 subunit has a low-affinity ATPase stimulated by nonspecific DNA and gpA has a high-affinity ATPase. In previous work, a mutant terminase, gpNu1 K35A holoterminase, had a mild defect in interactions with DNA, such that twofold increased DNA concentrations were required both for full stimulation of the low-affinity ATPase and for saturation of the cos cleavage reaction. In addition, the gpNu1 K35A terminase exhibited a post-cleavage defect in DNA packaging that accounted for the lethality of the Nu1 K35A mutation [Y. Hwang and M. Feiss (1997) Virology 231, 218-230]. In the work reported here, a mutation in the turn of the putative helix-turn-helix DNA binding domain has been isolated as a suppressor of the gpNu1 K35A change. This suppressor mutation causes the change A14V in gpNu1. A14V reverses the DNA-binding defects of gpNu1 K35A terminase, both for stimulation of the low-affinity ATPase and for saturation of the cos cleavage defect. A14V suppresses the post-cleavage DNA packaging defect caused by the gpNu1 K35A change.

Domain structure of gpNu1, a phage lambda DNA packaging protein

The terminase enzyme from bacteriophage lambda is responsible for the insertion of a dsDNA genome into the confines of the viral capsid. The holoenzyme is composed of gpA and gpNu1 subunits in a gpA(1) x gpNu1(2) stoichiometry. While genetic studies have described regions within the two proteins responsible for DNA binding, capsid binding, and subunit interactions in the holoenzyme complex, biochemical characterization of these domains is limited. We have previously described the cloning, expression, and biochemical characterization of a soluble DNA binding domain of the terminase gpNu1 subunit (Met1 to Lys100) and suggested that the hydrophobic region spanning Lys100 to Pro141 defines a domain responsible for self-association interactions, and that is important for cooperative DNA binding [Yang et al. (1999) Biochemistry 38, 465-477]. We further suggested that the genetically defined gpA-interactive domain in the C-terminal half of the protein is limited to the C-terminal approximately 40 amino acids of gpNu1. Here we describe the cloning, expression, and biochemical characterization of gpNu1DeltaP141, a deletion mutant of gpNu1 that comprises the DNA binding domain and the putative hydrophobic self-assembly domain of the full-length protein. Purified gpNu1DeltaP141 shows a strong tendency to aggregate in solution; However, the protein remains soluble in 0.4 M guanidine hydrochloride, and circular dichroism (CD) and fluorescence spectroscopic studies demonstrate that the protein is folded under these conditions. Moreover, CD spectroscopy and thermally induced unfolding studies suggest that the DNA binding domain and the self-association domain represent independent folding domains of gpNu1DeltaP141. The mutant protein interacts weakly with the gpA subunit, but does not form a catalytically competent holoenzyme complex, suggesting that the C-terminal 40 residues are important for appropriate subunit interactions. Importantly, gpNu1DeltaP141 binds DNA tightly, but with less specificity than does full-length protein, and the data suggest that the C-terminal residues are further required for specific DNA binding activity. The implications of these results in the assembly of a functional holoenzyme complex are discussed.

Cloning, expression, and biochemical characterization of hexahistidine-tagged terminase proteins

The terminase enzyme from bacteriophage lambda is composed of two viral proteins (gpA, 73.2 kDa; gpNu1, 20.4 kDa) and is responsible for packaging viral DNA into the confines of an empty procapsid. We are interested in the genetic, biochemical, and biophysical properties of DNA packaging in phage lambda and, in particular, the nucleoprotein complexes involved in these processes. These studies require the routine purification of large quantities of wild-type and mutant proteins in order to probe the molecular mechanism of DNA packaging. Toward this end, we have constructed a hexahistidine (hexa-His)-tagged terminase holoenzyme as well as hexa-His-tagged gpNu1 and gpA subunits. We present a simple, one-step purification scheme for the purification of large quantities of the holoenzyme and the individual subunits directly from the crude cell lysate. Importantly, we have developed a method to purify the highly insoluble gpNu1 subunit from inclusion bodies in a single step. Hexa-His terminase holoenzyme is functional in vivo and possesses steady-state and single-turnover ATPase activity that is indistinguishable from wild-type enzyme. The nuclease activity of the modified holoenzyme is near wild type, but the reaction exhibits a greater dependence on Escherichia coli integration host factor, a result that is mirrored in vivo. These results suggest that the hexa-His-tagged holoenzyme possesses a mild DNA-binding defect that is masked, at least in part, by integration host factor. The mild defect in hexa-His terminase holoenzyme is more significant in the isolated gpA-hexa-His subunit that does not appear to bind DNA. Moreover, whereas the hexa-His-tagged gpNu1 subunit may be reconstituted into a holoenzyme complex with wild-type catalytic activities, gpA-hexa-His is impaired in its interactions with the gpNu1 subunit of the enzyme. The results reported here underscore that a complete biochemical characterization of the effects of purification tags on enzyme function must be performed prior to their use in mechanistic studies.

Cloning, expression, and characterization of a DNA binding domain of gpNu1, a phage lambda DNA packaging protein

Terminase is an enzyme from bacteriophage lambda that is required for insertion of the viral genome into an empty pro-capsid. This enzyme is composed of the viral proteins gpNu1 (20.4 kDa) and gpA (73.3 kDa) in a holoenzyme complex. Current models for terminase assembly onto DNA suggest that gpNu1 binds to three repeating elements within a region of the lambda genome known as cosB which, in turn, stimulates the assembly of a gpA dimer at the cosN subsite. This prenicking complex is the first of several stable nucleoprotein intermediates required for DNA packaging. We have noted a hydrophobic region within the primary amino acid sequence of the terminase gpNu1 subunit and hypothesized that this region constitutes a protein-protein interaction domain required for cooperative assembly at cosB and that is also responsible for the observed aggregation behavior of the isolated protein. We therefore constructed a mutant of gpNu1 in which this hydrophobic "domain" has been deleted in order to test these hypotheses. The deletion mutant protein, gpNu1DeltaK, is fully soluble and, unlike full-length protein, shows no tendency toward aggregation; However, the protein is a dimer under all experimental conditions examined as determined by gel permeation and sedimentation equilibrium analysis. The truncated protein is folded with evidence of secondary and tertiary structural elements by circular dichroism and NMR spectroscopy. While physical and biological assays demonstrate that gpNu1DeltaK does not interact with the terminase gpA subunit, the deletion mutant binds with specificity to cos-containing DNA. We have thus constructed a deletion mutant of the phage lambda terminase gpNu1 subunit which constitutes a highly soluble DNA binding domain of the protein. We further propose that the hydrophobic amino acids found between Lys100 and Pro141 define a self-association domain that is required for the assembly of stable nucleoprotein packaging complexes and that the C-terminal tail of the protein defines a distinct gpA-binding site that is responsible for terminase holoenzyme formation.

Mutations that extend the specificity of the endonuclease activity of lambda terminase

Terminase, an enzyme encoded by the Nu1 and A genes of bacteriophage lambda, is crucial for packaging concatemeric DNA into virions. cosN, a 22-bp segment, is the site on the virus chromosome where terminase introduces staggered nicks to cut the concatemer to generate unit-length virion chromosomes. Although cosN is rotationally symmetric, mutations in cosN have asymmetric effects. The cosN G2C mutation (a G-to-C change at position 2) in the left half of cosN reduces the phage yield 10-fold, whereas the symmetric mutation cosN C11G, in the right half of cosN, does not affect the burst size. The reduction in phage yield caused by cosN G2C is correlated with a defect in cos cleavage. Three suppressors of the cosN G2C mutation, A-E515G, A-N509K, and A-R504C, have been isolated that restore the yield of lambda cosN G2C to the wild-type level. The suppressors are missense mutations that alter amino acids located near an ATPase domain of gpA. lambda A-E515G, A-N509K, and A-R504C phages, which are cosN+, also had wild-type burst sizes. In vitro cos cleavage experiments on cosN G2C C11G DNA showed that the rate of cleavage for A-E515G terminase is three- to fourfold higher than for wild-type terminase. The A-E515G mutation changes residue 515 of gpA from glutamic acid to glycine. Uncharged polar and hydrophobic residues at position 515 suppressed the growth defect of lambda cosN G2C C11G. In contrast, basic (K, R) and acidic (E, D) residues at position 515 failed to suppress the growth defect of lambda cosN G2C C11G. In a lambda cosN+ background, all amino acids tested at position 515 were functional. These results suggest that A-E515G plays an indirect role in extending the specificity of the endonuclease activity of lambda terminase.

ATP-reactive sites in the bacteriophage lambda packaging protein terminase lie in the N-termini of its subunits, gpA and gpNu1

ATP-reactive sites in terminase and its subunits have been successfully identified using three different affinity analogs of ATP (2-and 8-azidoATP and FITC) GpA, the larger subunit of terminase, was shown to have a higher affinity for these analogs than gpNu1, the smaller subunit. The suitability of these reagents as affinity analogs of ATP was demonstrated by ATP protection experiments and in vitro assays done with the modified proteins. These analogs were thus shown to modify the ATP-reactive sites. The results obtained from these experiments also indicate the importance of subunit-subunit interactions in the holoenzyme. Terminase, gpA, and gpNu1 were modified with these analogs and the ATP-reactive sites were identified by isolating the modified peptide by reverse-phase chromatography. The sequence analysis of the modified peptides indicates a region including amino acids 18-35 in the N-terminus of gpNu1 and a region including amino acids 59-85 in the N-terminus of gpA as being the ATP-reactive sites.

Characterization of the small subunit of the terminase enzyme of the Bacillus subtilis bacteriophage SPP1

The small subunit of bacteriophages SPP1 and SF6 terminase, G1P, share 71% identity clustered in three conserved segments (I, II, and III). Within segment I the helix-turn-helix DNA-binding domain was mapped, whereas segment III was found to be nonessential. For terminase activity, chimeric G1Ps, obtained by domain swapping between gene 1 of SPP1 and the SF6 origin (Chi1 to Chi4), were purified. The chimeric proteins behave in all respects similarly to the G1P of SPP1 or SF6. The major determinant for G1P:G1P interactions was found to lie within segment II. We showed that a G1P derivative (G1P*) lacking the 62 N-terminal residues (segment I), and Chi1 lacking the 45 C-terminal residues (segment III) interact with G1P. The N-terminal domain of G1P is necessary for terminase subunit assembly, because the large subunit of the terminase (G2P) interacts only with G1P and Chi1, but fails to do so with G1P*. These results suggest that segment III and the extended C-terminal part of SPP1 G1P do not play a major role in DNA recognition and that G1P recognizes an extended nucleotide sequence and DNA structure.

Mutations affecting lysine-35 of gpNu1, the small subunit of bacteriophage lambda terminase, alter the strength and specificity of holoterminase interactions with DNA

The small subunit of lambda terminase, gpNu1, contains a low-affinity ATPase activity that is stimulated by nonspecific dsDNA. The location of the gpNu1 ATPase center is suggested by a sequence match between gpNu1 (29-VLRGGGKG-36) and the phosphate-binding loop, or P-loop (GXXXXGKT/S), of known ATPase. The proposed P-loop of gpNu1 is just downstream of a putative helix-turn-helix DNA-binding motif, located between residues 5 and 24. Published work has shown that changing lysine-35 of the proposed P-loop of gpNu1 alters the response of the ATPase activity to DNA, as follows. The changes gpNu1 k35A and gpNu1 K35D increase the level of DNA required for maximal stimulation of the gpNu1 ATPase by factors of 2- and 10-fold, respectively. The maximally stimulated ATPase activities of the mutant enzymes are indistinguishable from that of the wild-type enzyme. In the present work, the effects of changing lysine-35 on the cos-cleavage and DNA-packaging activities of terminase were examined. In vitro, the gpNu1 K35A enzyme cleaved cos as efficiently as the wild-type enzyme, but required a 2-fold increased level of substrate DNA for saturation, suggesting a slight reduction in DNA affinity. In a crude DNA-packaging system using cleaved lambda DNA as substrate, the gpNu1 K35A enzyme had a 10-fold defect. In vivo, lambda Nu1 K35A showed a 2-fold reduction in cos cleavage, but no packaged DNA was detected. The primary defect of the gpNu1 K35A enzyme was concluded to be in a post-cos-cleavage step of DNA packaging. In in vitro cos-cleavage experiments, the gpNu1 K35D enzyme had a 10-fold increased requirement for saturation by substrate DNA. Furthermore, the cos-cleavage activity of gpNu1 K35D enzyme was strongly inhibited by the presence of nonspecific DNA, indicating that the gpNu1 K35D enzyme is unable to discriminate effectively between cos and nonspecific DNA. No cos cleavage was observed in vivo for lambda Nu1 K35D, a result consistent with the discrimination defect found in vitro for the gpNu1 K35D enzyme. In a crude packaging system the gpNu1 K35D enzyme had a 200-fold defect; in a purified packaging system, the gpNu1 K35D enzyme was found to be unable to discriminate between lambda DNA and nonspecific phage T7 DNA, a result indicating that the gpNu1 K35D enzyme is also defective in discriminating between lambda DNA and nonspecific DNA during DNA packaging.

In vivo packaging of bacteriophage lambda monomeric chromosomes

There is an apparent paradox between the reported requirements for lambda DNA packaging in vivo and in vitro. In vivo, DNA concatemers are required for packaging. On the other hand, in vitro, packaging extracts can encapsidate either linear or circular monomeric lambda DNA. Perhaps cellular nucleases restrict the in vivo ability of monomers to package by degrading a free double chain end present as an intermediate in the packaging reaction. Consistent with this hypothesis, enhanced packaging of monomers was found in an ExoV- host. No additional enhancement was noted in a host also mutant for sbcB and sbcC. We isolated a mutant phage for which in vivo packaging of monomeric lambda chromosomes is increased about 10(3)-fold. The responsible mutation (plm1 for packages lambda monomers) was mapped to cro, sequenced, and found to cause a change from Ala29 to Ser in the alpha3 helix of Cro's DNA binding domain. Density transfer experiments showed that packaging of both plm1 and wild-type lambda was aided by allowing some DNA synthesis. However, the packaged chromosomes had not themselves undergone a full round of replication and therefore were not part of a canonical concatemer made by replication. Other tests showed that packaged phage had not been part of concatemers made by recombination or by annealing at cos. Our results with wild-type lambda also favor models in which two cos sites are needed for packaging, but these sites need not be in cis. In lambda plm1, replication intermediates may serve as substrates for encapsidation.

Purification and characterization of the small subunit of phage T4 terminase, gp16, required for DNA packaging

Phage T4 terminase is an enzyme that binds to the portal protein of proheads and cuts and packages concatemeric DNA. The T4 terminase is composed of two subunits, gene products (gp) 16 and 17. The role of the small subunit, gp16, in T4 DNA packaging is not well characterized. We developed a new purification procedure to obtain large quantities of purified gp16 from an overexpression vector. The pure protein is found in two molecular weight forms, due to specific C-terminal truncation, displays in vitro packaging activity, and binds but does not hydrolyze ATP. gp16 forms specific oligomers, rings, and side-by-side double rings, as judged by native polyacrylamide gel electrophoresis and scanning transmission electron microscopy measurements. The single ring contains about eight monomers, and the rings have a diameter of about 8 nm with a central hole of about 2 nm. A DNA-binding helix-turn-helix motif close to the N terminus of gp16 is predicted. The oligomers do not bind to DNA, but following denaturation and renaturation in the presence of DNA, binding can be demonstrated by gel shift and filter binding assays. gp16 binds to double-stranded DNA but not single-stranded DNA, and appears to bind preferentially to a gene 16-containing DNA sequence.

Kinetic and mutational dissection of the two ATPase activities of terminase, the DNA packaging enzyme of bacteriophage Chi

Terminase the DNA packaging enzyme of bacteriophage chi, is a heteromultimer of gpNul (21 kDa) and gpA (74 kDa) subunits, encoded by the chi Nul and A genes, respectively. Sequence comparisons indicate that both gpNu1 and gpA have a match to the P-loop motif of ATPase centers, which is a glycine-rich segment followed by a lysine. By site-specific mutagenesis, we changed the lysines of the putative P-loops of gpNul (k35) and gpA (K497) to arginine, alanine, or aspartic acid, and studied the mutant enzymes by kinetic analysis and photochemical cross-linking with 8-azido-ATP. Both the gpNul and gpA subunits of wild-type terminase were covalently modified with 8-N3[32P] ATP in the presence of UV light. Saturation occurred with apparent dissociation constants of 508 and 3.5 microM for gpNul and gpA, resepctively. ATPase assays showed two activities: a low-affinity activity (Km=469 microM), and a high-affinity activity (Km=4.6 microM). The gpNul K35A and gpNul K35D mutant terminases showed decreased activity in the low-affinity ATPase activity. The reduced activities of these enzymes were recovered when 10 times more DNA was added, suggesting that the primary defect of the enzymes is alteration of the nonspecific, double-stranded DNA binding activity of terminase. ATPase assays and photolabeling of the gpA K497A and gpA K497D mutant terminases showed reduced affinity for ATP at the high-affinity site which was not restored by increased DNA. In summary, the results indicate the presence of a low-affinity, DNA-stimulated ATPase center in gpNul, and a high-affinity site in gpA.

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.

Virus DNA packaging: the strategy used by phage lambda

Phage lambda, like a number of other large DNA bacteriophages and the herpesviruses, produces concatemeric DNA during DNA replication. The concatemeric DNA is processed to produce unit-length, virion DNA by cutting at specific sites along the concatemer. DNA cutting is co-ordinated with DNA packaging, the process of translocation of the cut DNA into the preformed capsid precursor, the prohead. A key player in the lambda DNA packaging process is the phage-encoded enzyme terminase, which is involved in (i) recognition of the concatemeric lambda DNA; (ii) initiation of packaging, which includes the introduction of staggered nicks at cosN to generate the cohesive ends of virion DNA and the binding of the prohead; (iii) DNA packaging, possibly including the ATP-driven DNA translocation; and (iv) following translocation, the cutting of the terminal cosN to complete DNA packaging. To one side of cosN is the site cosB, which plays a role in the initiation of packaging; along with ATP, cosB stimulates the efficiency and adds fidelity to the endonuclease activity of terminase in cutting cosN. cosB is essential for the formation of a post-cleavage complex with terminase, complex I, that binds the prohead, forming a ternary assembly, complex II. Terminase interacts with cosN through its large subunit, gpA, and the small terminase subunit, gpNu1, interacts with cosB. Packaging follows complex II formation. cosN is flanked on the other side by the site cosQ, which is needed for termination, but not initiation, of DNA packaging. cosQ is required for cutting of the second cosN, i.e. the cosN at which termination occurs. DNA packaging in lambda has aspects that differ from other lambda DNA transactions. Unlike the site-specific recombination system of lambda, for DNA packaging the initial site-specific protein assemblage gives way to a mobile, translocating complex, and unlike the DNA replication system of lambda, the same protein machinery is used for both initiation and translocation during lambda DNA packaging.

Structure of viral connectors and their function in bacteriophage assembly and DNA packaging

The viruses have been an attractive model for the study of basic mechanisms of protein/protein and protein/nucleic acid interactions involved in the assembly of macromolecular aggregates. This has been due primarily to their relative genetic simplicity as compared to their structural and functional complexity. Although most of the initial studies were carried out on bacterial and plant viruses, increasing data has also been accumulated from animal viruses, which has led to an understanding of some basic principles, as well as to many specific strategies in every system. The study of virus assembly has been a source of ideas that underlie our present knowledge of the organization of biological systems. It has also provided, since the production of bacteriophage mutants which have allowed the study of assembly intermediates, the first system in which the genetic studies played a dominant role. The increasing volume of data over the last years has revealed how the structural components can interact sequentially through an ordered pathway to yield macromolecular assemblies that satisfy the demands of stability required for a successful transfer of genetic information from host to host.

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.

Sites and gene products involved in lambdoid phage DNA packaging

21 is a temperate lambdoid coliphage, and the genes that encode the head proteins of lambda and 21 are descended from a common ancestral bacteriophage. The sequencing of terminase genes 1 and 2 of 21 was completed, along with that of a segment at the right end of 21 DNA that includes the R4 sequence. The R4 sequence, a site that is likely involved in termination of DNA packaging, was found to be very similar to the R4 sequences of lambda and phi 80, suggesting that R4 is a recognition site that is not phage specific. DNA packaging by 21 is dependent on a host protein, integration host factor. A series of mutations in gene 1 (her mutations), which allow integration host factor-independent DNA packaging by 21, were found to be missense changes that affect predicted alpha-helixes in gp1. gp2, the large terminase subunit, is predicted to contain an ATP-binding domain and, perhaps, a second domain important for the cos-cutting activity of terminase. orf1, an open reading frame analogous in position to FI, a lambda gene involved in DNA packaging, shares some sequence identity with FI. orf1 was inactivated with nonsense and insertion mutations; these mutations were found not to affect phage growth. 21 was also not able to complement a lambda FI mutant.

Genetic analysis of mutations affecting terminase, the bacteriophage lambda DNA packaging enzyme, that suppress mutations in cosB, the terminase binding site

Terminase, the DNA packaging enzyme of phage lambda, binds to lambda DNA at a site called cosB, and introduces staggered nicks at an adjacent site, cosN, to generate the cohesive ends of virion lambda DNA molecules. Terminase also is involved in separation of the cohesive ends and in binding the prohead, the empty protein shell into which lambda DNA is packaged. Terminase is a DNA-dependent ATPase, and both subunits, gpNu1 and gpA, have ATPase activity. cosB contains a series of gpNu1 binding sites, R3, R2 and R1; between R3 and R2 is a binding site, I1, for integration host factor (IHF), the Escherichia coli DNA bending protein. In this work, a series of mutations in Nu1 have been isolated as suppressors of cosB mutations. One of the Nu1 mutations is identical to the previously described Nu1ms1/ohm1 mutation predicted to cause the change L40F in the 181 amino acid-long gpNu1. Three other Nu1 missense mutations, the Nu1ms2 (L40I), ms3 (Q97K) and ms4 (A92G) mutations, have been isolated; the relative strengths of suppression of cosB mutations by the Nu1ms mutations are: ms1 > ms2 > ms3 > ms4. The Nu1 missense mutations all affect amino acid residues that lie outside of the putative helix-turn-helix DNA binding motif of gpNu1. The Nu1ms1 and Nu1ms2 mutations alter an amino acid residue (L40) that lies directly between two segments of gpNu1 proposed to be involved in ATP binding and hydrolysis; thus these mutations are likely to alter the gpNu1 ATP-binding site. The Nu1ms3 and Nu1ms4 mutations both affect amino acid residues in the central region of gpNu1 that is predicted to form a hydrophilic alpha-helix. To explain how the Nu1ms mutations suppress cosB defects, models involving alterations of the DNA binding and/or catalytic properties of terminase are considered. The results also indicate that terminase occupancy of a single gpNu1 binding site (R3) is necessary and sufficient for the efficient initiation of DNA packaging; the Nu1ms1, ms2 and ms3 mutations permit IHF-independent plaque formation by a phage lacking R2 and R1.

Bacteriophage P1 genes involved in the recognition and cleavage of the phage packaging site (pac)

The packaging of bacteriophage P1 DNA is initiated by cleavage of the viral DNA at a specific site, designated pac. The proteins necessary for that cleavage, and the genes that encode those proteins, are described in this report. By sequencing wild-type P1 DNA and DNA derived from various P1 amber mutants that are deficient in pac cleavage, two distinct genes, referred to as pacA and pacB, were identified. These genes appear to be coordinately transcribed with an upstream P1 gene that encodes a regulator of late P1 gene expression (gene 10). pacA is located upstream from pacB and contains the 161 base-pair pac cleavage site. The predicted sizes of the PacA and PacB proteins are 45 kDa and 56 kDa, respectively. These proteins have been identified on SDS-polyacrylamide gels using extracts derived from Escherichia coli cells that express these genes under the control of a bacteriophage T7 promoter. Extracts prepared from cells expressing both PacA and PacB are proficient for site-specific cleavage of the P1 packaging site, whereas those lacking either protein are not. However, the two defective extracts can complement each other to restore functional pac cleavage activity. Thus, PacA and PacB are two essential bacteriophage proteins required for recognition and cleavage of the P1 packaging site. PacB extracts also contain a second P1 protein that is encoded within the pacB gene. We have identified this protein on SDS-polyacrylamide gels and have shown that it is translated in the same reading frame as is PacB. Its role, if any, in pac cleavage is yet to be determined.