Chromosome end formation in phage lambda, catalyzed by terminase, is controlled by two DNA elements of cos, cosN and R3, and by ATP.

The terminase enzyme of phage lambda is a site-specific endonuclease that nicks DNA concatemers to regenerate the 12 nucleotide cohesive ends of the mature chromosome. The enzyme's DNA target, cos, consists of a nicking domain, cosN, and a binding domain, cosB. cosB, situated to the right of cosN, comprises three 16 bp repeat sequences, R1, R2 and R3. A similar sequence, R4, is present to the left of cosN. It is shown here that terminase has an intrinsic specificity for cosN which is independent of the R sites. The interaction with cosN is mediated by binding to target sites that include 12 bp on the 5', and 2-7 bp on the 3' side of the nick. Of the four R sites, only R3 is required for the proper formation of ends. When R3 is present, an ATP-charged terminase system correctly catalyzes the production of staggered nicks in cosN, at sites N1 and N2 on the bottom and top strands, respectively. When ATP is omitted, the bottom strand is nicked incorrectly, at the site Nx, 8 bp to the left of N1. If R3 is removed or disabled by a point mutation, nicking in cosN becomes dependent upon ATP but, even in the presence of ATP, bottom strand nicking is divided between sites N1, the correct site, and Nx, the incorrect one. Thus, R3 is an important regulatory element and must reside in cis in respect to cosN. Furthermore, cosN substrates bearing point mutations at N1 and N2 are nicked at sites Nx and Ny, 8 bp to the left of N1 and N2, respectively. When R3 is present and ATP is added, nicking is redirected to the N1 and N2 positions despite the mutations present. Thus, terminase binding to R3, on one side of cosN, regulates the rotationally symmetric nicking reactions on the bottom and top strands within cosN.     

Structure of the bacteriophage lambda cohesive end site. Genetic analysis of the site (cosN) at which nicks are introduced by terminase.

A collection of mutations affecting the site (cosN) at which the bacteriophage lambda DNA packaging enzyme, terminase, introduces nicks to generate mature lambda chromosomes has been studied. A good correlation was found for mutational effects on burst size, accumulation of unused proheads, packaging of DNA into heads and cos cutting by terminase in vitro, indicating that defective cosN cleavage by terminase is the molecular explanation for the phenotypic effects of the mutations. Although the base-pairs of cosN display partial twofold rotational symmetry, cosN was found to be asymmetric functionally. Certain mutations to the left side of the center of rotational symmetry have more pronounced phenotypic effects than rotationally symmetric mutations to the right. The cosN11G mutation has no phenotypic effects when present as a single mutation, but does affect DNA packaging and cosN cutting in the presence of the symmetrically disposed cosN2C mutation. Mutations that decrease cosN cleavage result in the accumulation of unexpanded proheads, indicating that prohead expansion depends on cosN cutting.     

The functional asymmetry of cosN, the nicking site for bacteriophage lambda DNA packaging, is dependent on the terminase binding site, cosB.

cosN is the site at which terminase, the DNA packaging enzyme of phage lambda, introduces staggered nicks into viral concatemeric DNA to initiate genome packaging. Although the nick positions and many of the base pairs of cosN show 2-fold rotational symmetry, cosN is functionally asymmetric. That is, the cosN G2C mutation in the left half-site (cosNL) causes a strong virus growth defect whereas the symmetrically disposed cosN C11G mutation in the right half-site (cosNR) does not affect virus growth. The experiments reported here test the proposal that the genetic asymmetry of cosN results from terminase interactions with cosB, a binding site to the right of cosN. In the presence of cosB, the left half-site mutation, cosN G2C, strongly affected the cos cleavage reaction, while the symmetric right half-site mutation, cosN C11G, had little effect. In the absence of cosB, the two mutations moderately reduced the rate of cos cleavage by the same amount. The results indicated that the functional asymmetry of cosNdepends on the presence of cosB. A model is discussed in which terminase-cosN interactions in the nicking complex are assisted by anchoring of terminase to cosB.     

Defining cosQ, the site required for termination of bacteriophage lambda DNA packaging

Bacteriophage lambda is a double-stranded DNA virus that processes concatemeric DNA into virion chromosomes by cutting at specific recognition sites termed cos. A cos is composed of three subsites: cosN, the nicking site; cosB, required for packaging initiation; and cosQ, required for termination of chromosome packaging. During packaging termination, nicking of the bottom strand of cosN depends on cosQ, suggesting that cosQ is needed to deliver terminase to the bottom strand of cosN to carry out nicking. In the present work, saturation mutagenesis showed that a 7-bp segment comprises cosQ. A proposal that cosQ function requires an optimal sequence match between cosQ and cosNR, the right cosN half-site, was tested by constructing double cosQ mutants; the behavior of the double mutants was inconsistent with the proposal. Substitutions in the 17-bp region between cosQ and cosN resulted in no major defects in chromosome packaging. Insertional mutagenesis indicated that proper spacing between cosQ and cosN is required. The lethality of integral helical insertions eliminated a model in which DNA looping enables cosQ to deliver a gpA protomer for nicking at cosN. The 7 bp of cosQ coincide exactly with the recognition sequence for the Escherichia coli restriction endonuclease, EcoO109I.     

Processive action of terminase during sequential packaging of bacteriophage lambda chromosomes

Bacteriophage lambda chromosomes are packaged in a polarized, sequential fashion from a multimeric DNA substrate. Mature chromosomes are generated when terminase introduces staggered nicks in the cohesive end sites (cos sites) bounding a chromosome. Packaging is polarized, to the initial and terminal cos sites for packaging a chromosome can be defined. To initiate packaging, terminase binds to cos at cosB, and subsequently cuts at cosN. To terminate packaging of a chromosome, a functional cosB is not required at the terminal cos. To explain this finding, it was proposed earlier that terminase scans for the terminal cosN, rather than any subsequent cosB, during packaging. In the work described here we performed helper packaging experiments to see whether processive action of terminase occurs during sequential packaging of lambda chromosomes. The helper packaging experiments involve trilysogens; strains carrying three prophages in tandem. Infection by a hetero-immune helper phage results in packaging of the repressed prophage chromosomes, since the prophage structure is analogous to the normal DNA substrate. Two chromosomes can be packaged from between the three cos sites of the prophages of a trilysogen. Both chromosomes are packaged even when the central cos is cosB-. Our interpretation of these data is that terminase is brought to the central cos by packaging; following cleavage of the central cos, the terminase remains bound to the distal chromosome; and terminase acts to begin packaging of the distal chromosome. The frequency at which terminase reads across the central cos to initiate packaging of the distal chromosome is in the range from 0.3 to 0.5 in our experiments. Reading across cos was found not to be greatly dependent on the state of cosB, indicating that cosB binding is only needed for packaging the first chromosome in a packaging series. A multilysogen was constructed in which the initial cos was cos+ and the distal cos sites were all cosB-. The initial and downstream chromosomes were found to be packaged. This result indicates that terminase that is brought to the central cos by packaging is not only able to initiate packaging of a downstream chromosome, but can also scan and terminate packaging of the downstream chromosome. A model is presented in which processive action of terminase is the basis for sequential packaging of lambda chromosomes.     

Genetic analysis of cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda.

cosB, the binding site for terminase, the DNA packaging enzyme of bacteriophage lambda, consists of three binding sites (called R3, R2 and R1) for gpNu1, the small subunit of terminase; and I1, a binding site for integration host factor (IHF), the DNA bending protein of Escherichia coli. cosB is located between cosN, the site where terminase introduces staggered nicks to generate cohesive ends, and the Nu1 gene; the order of sites is: cosN-R3-I1-R2-R1-Nu1. A series of lambda mutants have been constructed that have single base-pair C-to-T transition mutations in R3, R2 and R1. A single base-pair transition mutation within any one of the gpNul binding sites renders lambda dependent upon IHF for plaque formation. lambda phage with mutations in both R2 and R3 are incapable of plaque formation even in the presence of IHF. Phages that carry DNA insertions between R1 and R2, from 7 to 20 base-pairs long, are also IHF-dependent, demonstrating the requirement for a precise spacing of gpNu1 binding sites within cosB. The IHF-dependent phenotype of a lambda mutant carrying a deletion of the R1 sequence indicates that IHF obviates the need for terminase binding to the R1 site. In contrast, a lambda mutant deleted for R2 and R1 fails to form plaques on either IHF+ or IHF- cells, indicating terminase binding of R2 is involved in suppression of R mutants by IHF. A fourth R sequence, R4, is situated on the left side of cosN; a phage with a mutant R4 sequence shows a reduced burst size on both an IHF+ and an IHF- host. The inability of the R4- mutant to be suppressed by IHF, plus the fact that R4 does not bind gpNu1, suggests R4 is not part of cosB and may play a role in DNA packaging that is distinct from that of cosB.     

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

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

The last duplex base-pair of the phage lambda chromosome. Involvement in packaging, ejection and routing of lambda DNA.

cosN is the site at which the bacteriophage lambda DNA packaging enzyme, terminase, introduces staggered nicks to generate the cohesive ends of mature lambda chromosomes. Genetic and molecular studies show that cosN is recognized specifically by terminase and that effects of cosN mutations on lambda DNA packaging and cosN cleavage are well correlated. Mutations affecting a particular base-pair of cosN are unusual in being lethal in spite of causing only a moderate defect in cosN cleavage and DNA packaging. The particular base-pair is the rightmost duplex base-pair in mature chromosomes, at position 48,502 in the numbering system of Daniels et al; herein called position - 1. A G.C to T.A transversion mutation at position - 1, called cosN - 1T, reduces the particle yield of lambda fivefold, and the particles formed are not infectious. lambda cosN - 1T particles have wild-type morphology, and contain chromosomes that have normal cohesive ends. The chromosomes of lambda cosN - 1T particles, like the chromosomes of lambda + particles, are associated with the tail. lambda cosN - 1T particles, in spite of being normal structurally, are defective in injection of DNA into a host cell. Only approximately 25% of lambda cosN - 1T particles are able to eject DNA from the capsid in contrast to 100% for lambda +. Furthermore, for the 25% that do eject, there is a further injection defect because the ejected lambda cosN - 1T chromosomes fail to cyclize, in contrast to the efficient cyclization found for wild-type chromosomes following injection. The cosN - 1T mutation has no effect on Ca2+ mediated transformation by lambda DNA, indicating that the effect of the mutation on DNA fate is specific to the process of DNA injection. Models in which specific DNA : protein interactions necessary for DNA injection, and involving the rightmost base-pair of the lambda chromosome, are considered.     

Structure of the bacteriophage lambda cohesive end site: location of the sites of terminase binding (cosB) and nicking (cosN)

The extents of the sites for nicking (cosN) and binding (cosB) of bacteriophage lambda DNA by terminase have been determined by studying cos cleavage and terminase binding in vitro. The cosN site is located in the segment from -22 to +24 bp (numbered from the center of the cohesive end sequence in the circular lambda genome). The cosB site is located in the segment from +51 to +120 (the +120 boundary determined by Miwa and Matsubara, 1983). Additional sequences are necessary for packaging into infectious phage particles, including regions to the left (Rz gene side) of cosN, and between cosN and cosB. Small deletions (7 and 11 bp) between cosN and cosB abolish packaging in vivo without affecting cos binding and cleavage in vitro, whereas a large deletion (26 bp) abolishes packaging in vivo and cleavage in vitro.     

The Nul subunit of bacteriophage lambda terminase binds to specific sites in cos DNA.

The maturation and packaging of bacteriophage lambda DNA are under the control of the multifunctional viral terminase enzyme, which is composed of the protein products of Nu1 and A, the two most leftward genes of the phage chromosome. Terminase binds selectively to the cohesive end site (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12-base single-stranded cohesive ends of the mature phage genome. The purified gpNu1 subunit of terminase forms specific complexes with cos lambda DNA. DNase I footprinting experiments showed that gpNu1 bound to three distinct regions near the extreme left end of the lambda chromosome. These regions coincided with two 16-base-pair sequences (CTGTCGTTTCCTTTCT) that were in inverted orientation, as well as a truncated version of this sequence. Bear et al. (J. Virol. 52:966-972,1984) isolated a mutant phage which contained a CG to TA transition at the 10th position of the rightmost 16-base-pair sequence, and this phage (termed lambda cos 154) exhibits a defect in DNA maturation when it replicates in Escherichia coli which is deficient in integration host factor. Footprinting experiments with cos 154 DNA showed that gpNu1 could not bind to the site which contained the mutation but could protect the other two sites. Since the DNA-packaging specificity of terminase resides in the gpNu1 subunit, these studies suggest that terminase uses these three sites as recognition sequences for specific binding to cos lambda.     

Bacteriophage lambda DNA packaging: DNA site requirements for termination and processivity

Bacteriophage lambda chromosomes are processively packaged into preformed shells, using end-to-end multimers of intracellular viral DNA as the packaging substate. A 200 bp long DNA segment, cos, contains all the sequences needed for DNA packaging. The work reported here shows that efficient DNA packaging termination requires cos's I2 segment, in addition to the required termination subsite, cosQ, and the nicking site, cosN. Efficient processivity requires cosB, in addition to cosQ and cosN. An initiation-defective mutant form of cosB sponsored efficient processivity, indicating that the terminase-cosB interactions required for termination are less stringent than those required at initiation. The finding that an initiation-defective form of cosB is functional for processivity allows a re-interpretation of a similar finding, obtained previously, that the initiation-defective cosB of phage 21 is functional for processivity by the lambda packaging machinery. The cosBphi21 result can now be interpreted as indicating that interactions between cosBphi21 and lambda terminase, while insufficient for initiation, function for processivity.     

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.     

Integration host factor (IHF) stimulates binding of the gpNu1 subunit of lambda terminase to cos DNA.

The lambda terminase enzyme binds to the cohesive end sites (cos) of multimeric replicating lambda DNA and introduces staggered nicks to regenerate the 12 bp single-stranded cohesive ends of the mature phage genome. In vitro this endonucleolytic cleavage requires spermidine, magnesium ions, ATP and a host factor. One of the E. coli proteins which can fulfill this latter requirement is Integration Host Factor (IHF). IHF and the gpNu1 subunit of terminase can bind simultaneously to their own specific binding sites at cos. DNase I footprinting experiments suggest that IHF may promote gpNu1 binding. Although no specific gpNu1 binding to the left side of cos can be detected, this DNA segment does play a specific role since a cos fragment that does not include the left side or whose left side is replaced by non-cos sequences, is unable to bind gpNu1 unless either spermidine or IHF is present. Binding studies on the right side of cos using individual or combinations of gpNu1 binding sites I, II and III indicate that binding at sites I and II is not optimal unless site III is present.     

Site-specific dissection of E. coli chromosome by lambda terminase.

We have succeeded the targeted cleavage of chromosomes by lambda terminase that introduces double-strand cleavages in DNA recognizing the lambda cos sequence. When chromosomal DNAs of various Escherichia coli K-12 strains were subjected to terminase digestion, all were found to contain two common cleavage sites. Therefore, DNAs from lambda lysogens in which lambda DNA was inserted at different chromosomal sites were specifically cleaved at one more additional site. The two sites, termed ecos1 and ecos2, were mapped at approximately 35.1' and 12.7' of E. coli genetic map. The ecos1 and ecos2 sites were included in qin and qsr' regions, respectively. Therefore, the cleavage sites were associated with cryptic prophages. Sequences at the ecos1 and ecos2 sites showed 98% homology to the lambda cos sequence, indicating high fidelity of sequence recognition by the terminase. Since the strategy for integration of a DNA segment into chromosomal DNA through homologous recombination has been established, the dissection method that uses lambda terminase should be applicable for gene mapping as well as construction of macrophysical maps of larger genomes.     

The actions of Neurospora endo-exonuclease on double strand DNAs

Neurospora crassa endo-exonuclease, an enzyme implicated in recombinational DNA repair, was found previously to have a distributive endonuclease activity with a high specificity for single strand DNA and a highly processive exonuclease activity. The activities of endo-exonuclease on double strand DNA substrates have been further explored. Endo-exonuclease was shown to have a low bona fide endonuclease activity with completely relaxed covalently closed circular DNA and made site-specific breaks in linear double strand DNA at a low frequency while simultaneously generating a relatively high level of single strand breaks (nicks) in the DNA. Sequencing at nicks induced by endo-exonuclease in pBR322 restriction fragments showed that the highest frequency of nicking occurred at the mid-points of two sites with the common sequence, p-AGCACT-OH. In addition, sequencing revealed less frequent nicking at identical or homologous hexanucleotide sequences in all other 54 cases examined where these sequences either straddled the break site itself or were within a few nucleotides on either side of the break site. The exonucleolytic action of endo-exonuclease on linear DNA showed about 100-fold preference for acting in the 5' to 3' direction. Removal of the 5'-terminal phosphates substantially reduced this activity, internal nicking, and the ability of endo-exonuclease to generate site-specific double strand breaks. On the other hand, nicking of the dephosphorylated double strand DNA with pancreatic DNase I stimulated the exonuclease activity by almost 5-fold, but no stimulation was observed when the DNA was nicked by Micrococcal nuclease. Thus, 5'-p termini either at double strand ends or at nicks in double strand DNA are entry points to the duplex from which endo-exonuclease diffuses linearly or "tracks" in the 5' to 3' direction to initiate its major endo- and exonucleolytic actions. The results are interpreted to show how it is possible for endo-exonuclease to generate single strand DNA for switching into a homologous duplex either at a nick or while remaining bound at a double strand break in the DNA. Such mechanisms are consistent with current models for recombinational double strand break repair in eukaryotes.     

Molecular analysis of the cos region of the Lactobacillus casei bacteriophage A2. Gene product 3, gp3, specifically binds to its downstream cos region

The terminal nucleotide sequence of the Lactobacillus casei bacteriophage A2 DNA revealed a single-stranded extension 13 bases in length (5'-AACGGTCGGCCTC-3') at its 3' termini that defines the packaging initiation nicking site ( cosN ). The cosN sequence is bisected by an axis of hyphenated twofold rotational symmetry. Directly and inverted repeated sequences located to the left ( cosL ) and the right ( cosR ) of the cosN site were observed. Analysis of the 3.4 kb Eco RI DNA sequence surrounding the cos region revealed four complete and one incomplete open reading frames ( orf s). Northern blots indicated that all were cotranscribed in a single mRNA molecule in excess of 10 kb that appeared late during infection. Minicell studies indicated that the four orf s were translated into protein. From the ORF3 amino acid sequence DNA-binding and NTP-binding domains can be predicted. The purified ORF3 (predicted molecular mass 16.8 kDa) shows specific binding to the A2 cos region, so it was renamed gp3. Gp3 forms a specific complex with a 369 bp cos DNA segment in the presence of ATP. Gp3 interaction with the intrinsically bent cos DNA segment induces intramolecular ligation in the presence of T4 DNA ligase. The data presented here suggest that gp3 is the small subunit of the terminase enzyme.     

The F plasmid origin of transfer: DNA sequence of wild-type and mutant origins and location of origin-specific nicks.

The DNA sequence of the F plasmid origin of conjugal DNA transfer, oriT , has been determined. The origin lies in an intercistronic region which contains several inverted repeat sequences and a long AT-rich tract. Introduction of a nick into one of the DNA strands in the oriT region precedes the initiation of conjugal DNA replication, and the position of the strand-specific nicks acquired by a lambda oriT genome upon propagation in Flac-carrying cells has been determined. The nicks were not uniquely positioned, rather there was a cluster of three major and up to 20 minor sites: the biological significance of this observation is not yet fully clear. Nine independent point mutations which inactivate oriT function have been sequenced and found to alter one or other of two nucleotide positions which lie 14 and 19 bp to one side of the rightmost (as drawn) major nick site. These key nucleotides may lie in a recognition sequence for the oriT endonuclease, since mutations at these sites prevent nicking at oriT .     

DNA nicks inflicted by restriction endonucleases are repaired by a RecA- and RecB-dependent pathway in Escherichia coli

Two mutants of the EcoRI endonuclease (R200K and E144C) predominantly nick only one strand of the DNA substrate. Temperature sensitivity of the mutant enzymes allowed us to study the consequences of inflicting DNA nicks at EcoRI sites in vivo. Expression of the EcoRI endonuclease mutants in the absence of the EcoRI methyltransferase induces the SOS DNA repair response and greatly reduces viability of recA56, recB21 and lexA3 mutant strains of Escherichia coli. In parallel studies, overexpression of the EcoRV endonuclease in cells also expressing the EcoRV methyltransferase was used to introduce nicks at non-cognate EcoRV sites in the bacterial genome. EcoRV overproduction was lethal in recA56 and recB21 mutant strains and moderately toxic in a lexA3 mutant strain. The toxic effect of EcoRV overproduction could be partially alleviated by introduction into the cells of multiple copies of the E. coli DNA ligase gene. These observations suggest that an increased number of DNA nicks can overwhelm the repair capacity of DNA ligase, resulting in the conversion of a proportion of DNA nicks into DNA lesions that require recombination for repair.     

Energy-independent helicase activity of a viral genome packaging motor

The assembly of complex double-stranded DNA viruses includes a genome packaging step where viral DNA is translocated into the confines of a preformed procapsid shell. In most cases, the preferred packaging substrate is a linear concatemer of viral genomes linked head-to-tail. Viral terminase enzymes are responsible for both excision of an individual genome from the concatemer (DNA maturation) and translocation of the duplex into the capsid (DNA packaging). Bacteriophage λ terminase site-specifically nicks viral DNA at the cos site in a concatemer and then physically separates the nicked, annealed strands to mature the genome in preparation for packaging. Here we present biochemical studies on the so-called helicase activity of λ terminase. Previous studies reported that ATP is required for strand separation, and it has been presumed that ATP hydrolysis is required to drive the reaction. We show that ADP and nonhydrolyzable ATP analogues also support strand separation at low (micromolar) concentrations. In addition, the Escherichia coli integration host factor protein (IHF) strongly stimulates the reaction in a nucleotide-independent manner. Finally, we show that elevated concentrations of nucleotide inhibit both ATP- and IHF-stimulated strand separation by λ terminase. We present a model where nucleotide and IHF interact with the large terminase subunit and viral DNA, respectively, to engender a site-specifically bound, catalytically competent genome maturation complex. In contrast, binding of nucleotide to the low-affinity ATP binding site in the small terminase subunit mediates a conformational switch that down-regulates maturation activities and activates the DNA packaging activity of the enzyme. This affords a motor complex that binds tightly, but nonspecifically, to DNA as it translocates the duplex into the capsid shell. These studies have yielded mechanistic insight into the assembly of the maturation complex on viral DNA and its transition to a mobile packaging motor that may be common to all of the complex double-stranded DNA viruses.     

Investigation of site-specific DNA binding with nicking endonuclease Nt.BspD6I at single molecule level by atomic force microscopy

Nicking endonuclease Nt.BspD6I is a heterodimeric restriction endonuclease, one subunit of which exhibits specific nicking activity. It gets bound to double-stranded DNA and makes a break (nick) in one chain at a distance of 4 nucleotides from the binding site. In this work, for visualization of the specific binding and protein landing site, atomic force microscopy was used. In five minutes after incubation of DNA solution with nicking endonuclease, DNA molecules with associated proteins which located at the expected binding site and “shared” the DNA strand into two segments (approximately, 1/3 and 2/3 of length) were observed in the images. In addition, near the binding site the DNA molecule had a height corresponding to a single-stranded DNA molecule, which was in good agreement with single-stranded cleavage by nickase in the course of complex formation.