Defective infectious particles and rare packaged genomes produced by cells carrying terminal-repeat-negative epstein-barr virus

The Epstein-Barr virus (EBV) lytic program includes lytic viral DNA replication and the production of a viral particle into which the replicated viral DNA is packaged. The terminal repeats (TRs) located at the end of the linear viral DNA have been identified as the packaging signals. A TR-negative (TR(-)) mutant therefore provides an appropriate tool to analyze the relationships between EBV DNA packaging and virus production. Here, we show that supernatants from lytically induced 293 cells carrying TR mutant EBV genomes (293/TR(-)) contain large amounts of viral particles devoid of viral DNA which are nevertheless able to bind to EBV target cells. This shows that viral DNA packaging is not a prerequisite for virion formation and egress. Rather surprisingly, supernatants from lytically induced 293/TR(-) cells also contained rare infectious viruses carrying the viral mutant DNA. This observation indicates that the TRs are important but not absolutely essential for virus encapsidation.     

Optimal lengths for DNAs encapsidated by Epstein-Barr virus.

We measured the efficiency of DNA packaging by Epstein-Barr virus (EBV) as a function of the length of the DNA being packaged. Plasmids that contain oriP (the origin of latent EBV DNA replication), oriLyt (the origin of lytic EBV DNA replication), the viral terminal repeats (necessary for cleavage and packaging by EBV), and various lengths of bacteriophage lambda DNA were introduced into EBV-positive cells. Upon induction of the resident EBV's lytic phase, introduced plasmids replicated as concatemers and were packaged. Plasmid-derived concatemers of DNA with certain lengths were found to predominate in isolated virion particles. We measured the distribution of lengths of plasmid concatemers found within cells supporting the lytic phase of the viral life cycle and found that this distribution differed from the distribution of lengths of concatemers found in mature virion particles. This finding indicates that the DNA packaged into mature virions represents a selected subset of those present in the cell during packaging. These observations together indicate that the length of DNA affects the efficiency with which that DNA is packaged by EBV. Finally, we measured the length of the packaged B95-8 viral DNA and found it to be approximately 165 kbp, or 10 kbp shorter than the originally predicted size for B95-8 based on its sequence. Together with the results of other studies, these findings indicate that the packaging of DNAs by EBV is dependent on two imprecisely recognized elements: the viral terminal repeats and the length of the DNA being packaged by the virus.     

Human cytomegalovirus DNA replicates after early circularization by concatemer formation, and inversion occurs within the concatemer.

To determine the replicative mechanism for human cytomegalovirus (HCMV) DNA, field inversion gel electrophoresis was used to separate HCMV replicative DNAs during lytic infection. Unit-length circular HCMV genomes lacking terminal restriction fragments were detected starting 4 h after infection even when cells were treated with aphidicolin, phosphonoacetic acid, or cycloheximide. Viral DNA synthesis began 24 h after infection and produced large amounts of high-molecular-weight replicative DNA that was a precursor of progeny genomes. Replicative DNA contained rare terminal restriction fragments, and long-arm termini were much less frequent than short-arm termini. Replicative DNA was not composed of unit-length circles because low-dose gamma irradiation of replicative DNA generated numerous random high-molecular-weight fragments rather than unit-length molecules. PacI digestion of replicative DNA from a recombinant HCMV with two closely spaced PacI sites revealed that replicative DNA is concatemeric and genome segment inversion occurs after concatemer synthesis. These results show that after circularization of the parental genome, DNA synthesis produces concatemers and genomic inversion occurs within concatemeric DNA. The results further suggest that concatemers acquire genomic termini during the cleavage/packaging process which preferentially inserts short-arm termini into empty capsids, causing a predominance of short-arm termini on the concatemer.     

Signals for site-specific cleavage of HSV DNA: maturation involves two separate cleavage events at sites distal to the recognition sequences

Mature Herpes Simplex Virus (HSV) genomes are cleaved from concatemeric precursors by a site-specific mechanism. These cleavage events are probably coupled to the encapsidation process. Sequences within the terminal repeat of HSV DNA are necessary for the cleavage and packaging reactions, and are also thought to be responsible for high frequency genome isomerization events. Here we present evidence to show that two viral DNA cleavage and packaging signals reside within a 250 bp subfragment of the terminal repeat, that the termini of mature viral DNA are generated by a process involving two separate DNA cleavages at sites distal to the cleavage signals, and that the sequences between these two cleavage sites are duplicated by the DNA maturation system.     

The structure of the termini of the Epstein-Barr virus as a marker of clonal cellular proliferation

The linear virion form of Epstein-Barr virus (EBV) DNA has variable numbers of direct tandem 500 bp repeats at each terminus. The terminal restriction endonuclease fragments and the fused terminal fragments in the intracellular episomal form are heterogeneous in size, and vary by increments of 500 bp. The structure of the termini of EBV in carcinomas of the nasopharynx and the parotid gland was compared with the EBV termini in monoclonal and polyclonal tissues or cell lines. A single band representing the EBV joined termini was detected in each of the carcinomas and in the monoclonal lymphoid proliferations. Polyclonal cell lines contained multiple forms of the joined termini. The detection of a homogeneous episomal population suggests that EBV-associated epithelial malignancies are clonal expansions of a single EBV-infected progenitor cell.     

Circularization and cleavage of guinea pig cytomegalovirus genomes.

The mechanisms by which herpesvirus genome ends are fused to form circles after infection and are re-formed by cleavage from concatemeric DNA are unknown. We used the simple structure of guinea pig cytomegalovirus genomes, which have either one repeated DNA sequence at each end or one repeat at one end and no repeat at the other, to study these mechanisms. In circular DNA, two restriction fragments contained fused terminal sequences and had sizes consistent with the presence of single or double terminal repeats. This result implies a simple ligation of genomic ends and shows that circularization does not occur by annealing of single-stranded terminal repeats formed by exonuclease digestion. Cleavage to form the two genome types occurred at two sites, and homologies between these sites identified two potential cis elements that may be necessary for cleavage. One element coincided with the A-rich region of a pac2 sequence and had 9 of 11 bases identical between the two sites. The second element had six bases identical at both sites, in each case 7 bp from the termini. To confirm the presence of cis cleavage elements, a recombinant virus in which foreign sequences displaced the 6- and 11-bp elements 1 kb from the cleavage point was constructed. Cleavage at the disrupted site did not occur. In a second recombinant virus, restoration of 64 bases containing the 6- and 11-bp elements to the disrupted cleavage site restored cleavage. Therefore, cis cleavage elements exist within this 64-base region, and sequence conservation suggests that they are the 6- and 11-bp elements.     

Structure of the rat cytomegalovirus genome termini.

The lytic replication cycle of herpesviruses can be divided into the following three steps: (i) circularization, in which, after infection, the termini of the linear double-stranded viral genome are fused; (ii) replication, in which the circular DNA serves as template for DNA replication, which generates large DNA concatemers; and (iii) maturation, in which the concatemeric viral DNA is processed into unit-length genomes, which are packaged into capsids. Sequences at the termini of the linear virion DNA are thought to play a key role in both genome circularization and maturation. To investigate the mechanism of these processes in the replication of rat cytomegalovirus (RCMV), we cloned, sequenced, and characterized the genomic termini of this betaherpesvirus. Both RCMV genomic termini were found to contain a single copy of a direct terminal repeat (TR). The TR sequence is 504 bp in length, has a high GC content (76%), and is not repeated at internal sites within the RCMV genome. The TR comprises several small internal direct repeats as well as two sequences which are homologous to herpesvirus pac-1 and pac-2 sites, respectively. The organization of the RCMV TR is unique among cytomegaloviruses with respect to the position of the pac sequences: pac-1 is located near the left end of the TR, whereas pac-2 is present near the right end. Both RCMV DNA termini carry an extension of a single nucleotide at the 3' end. Since these nucleotides are complementary, circularization of the viral genome is likely to occur via a simple ligation reaction.     

Adenovirus types 2 and 5 functions elicit replication and late expression of adenovirus type 12 DNA in hamster cells.

A recombinant plasmid harboring both genomic termini of tupaia herpesvirus (THV) DNA was characterized by restriction enzyme analysis and by determination of the nucleotide sequence. A unique NotI cleavage site was found that is located approximately 19 base pairs upstream of the THV terminal junction. THV DNA fragments from virion DNA were analyzed by using the same restriction enzymes as for the recombinant plasmid. The comparative fine mapping of virion THV DNA revealed heterogeneous molecules of variable lengths with the NotI cleavage site conserved. A number of short direct and inverted repeats and palindromes were found surrounding the THV terminal joint. The THV repetitive sequences were compared with the repeats reported for the DNA termini of herpes simplex virus, varicella-zoster virus, and Epstein-Barr virus and are discussed in respect to signals for a site-specific endonuclease required for packaging.     

Sequences within the Herpesvirus-Conserved pac1 and pac2 Motifs Are Required for Cleavage and Packaging of the Murine Cytomegalovirus Genome

The DNA sequence motifs pac1 [an A-rich region flanked by poly(C) runs] and pac2 (CGCGGCG near an A-rich region) are conserved near herpesvirus genomic termini and are believed to mediate cleavage of genomes from replicative concatemers. To determine their importance in the cleavage process, we constructed a number of recombinant murine cytomegaloviruses with a second cleavage site inserted at an ectopic location within the viral genome. Cleavage at a wild-type ectopic site occurred as frequently as at the natural cleavage site, whereas mutation of this ectopic site revealed that some of the conserved motifs of pac1 and pac2 were essential for cleavage whereas others were not. Within pac1, the left poly(C) region was very important for cleavage and packaging but the A-rich region was not. Within pac2, the A-rich region and adjacent sequences were essential for cleavage and packaging and the CGCGGCG region contributed to, but was not strictly essential for, efficient cleavage and packaging. A second A-rich region was not important at all. Furthermore, mutations that prevented cleavage also blocked duplication and deletion of the murine cytomegalovirus 30-bp terminal repeat at the ectopic site, suggesting that repeat duplication and deletion are consequences of cleavage. Given that the processes of genome cleavage and packaging appear to be highly conserved among herpesviruses, these findings should be relevant to other members of this family.     

Terminally Repeated Sequences on a Herpesvirus Genome Are Deleted following Circularization but Are Reconstituted by Duplication during Cleavage and Packaging of Concatemeric DNA

The mechanisms underlying cleavage of herpesvirus genomes from replicative concatemers are unknown. Evidence from herpes simplex virus type 1 suggests that cleavage occurs by a nonduplicative process; however, additional evidence suggests that terminal repeats may also be duplicated during the cleavage process. This issue has been difficult to resolve due to the variable numbers of reiterated terminal repeats that the herpes simplex virus type 1 genome can contain. Guinea pig cytomegalovirus is a herpesvirus with a simple terminal repeat arrangement that defines two genome types. Type II genomes have a single copy of a 1-kb terminal repeat at both their left and right termini, whereas type I genomes have only one copy at their left termini and lack the repeat at their right termini. In a previous study, we constructed a recombinant guinea pig cytomegalovirus in which certain cis elements were disrupted such that only type II genomes were produced. Here we show that double repeats that are formed by circularization of infecting genomes are rapidly converted to single repeats, such that the junctions between genomes within replicative concatemers formed late in infection almost exclusively contain single copies of the terminal repeat. Therefore, for the recombinant virus, each cleavage event begins with a single repeat within a concatemer yet produces two repeats, one at each of the resulting termini, demonstrating that terminal repeat duplication occurs in conjunction with cleavage. For wild-type guinea pig cytomegalovirus, the formation of type I genomes further suggests that cleavage can also occur by a nonduplicative process and that duplicative and nonduplicative cleavage can occur concurrently. Other herpesviruses having terminal repeats, such as the herpes simplex viruses and human cytomegalovirus, may also utilize repeat duplication and deletion; however, the biological importance of these events remains unknown.     

Functional Identification and Analysis of cis-Acting Sequences Which Mediate Genome Cleavage and Packaging in Human Herpesvirus 6

Sequences present at the genomic termini of herpesviruses become linked during lytic-phase replication and provide the substrate for cleavage and packaging of unit length viral genomes. We have previously shown that homologs of the consensus herpesvirus cleavage-packaging signals, pac1 and pac2, are located at the left and right genomic termini of human herpesvirus 6 (HHV-6), respectively. Immediately adjacent to these elements are two distinct arrays of human telomeric repeat sequences (TRS). We now show that the unique sequence element formed at the junction of HHV-6B genome concatemers (pac2-pac1) is necessary and sufficient for virally mediated cleavage of plasmid DNAs containing the HHV-6B lytic-phase origin of DNA replication (oriLyt). The concatemeric junction sequence also allowed for the packaging of these plasmid molecules into intracellular nucleocapsids as well as mature, infectious viral particles. In addition, this element significantly enhanced the replication efficiency of oriLyt-containing plasmids in virally infected cells. Experiments revealed that the concatemeric junction sequence possesses an unusual, S1 nuclease-sensitive conformation (anisomorphic DNA), which might play a role in this apparent enhancement of DNA replication—although additional studies will be required to test this hypothesis. Finally, we also analyzed whether the presence of flanking viral TRS had any effect on the functional activity of the minimal concatemeric junction (pac2-pac1). These experiments revealed that the TRS motifs, either alone or in combination, had no effect on the efficiency of virally mediated DNA replication or DNA cleavage. Taken together, these data show that the cleavage and packaging of HHV-6 DNA are mediated by cis-acting consensus sequences similar to those found in other herpesviruses, and that these sequences also influence the efficiency of HHV-6 DNA replication. Since the adjacent TRS do not influence either viral cleavage and packaging or viral DNA replication, their function remains uncertain.     

Effects of mutations within the herpes simplex virus type 1 DNA encapsidation signal on packaging efficiency

The cis-acting signals required for cleavage and encapsidation of the herpes simplex virus type 1 genome lie within the terminally redundant region or a sequence. The a sequence is flanked by short direct repeats (DR1) containing the site of cleavage, and quasi-unique regions, Uc and Ub, occupy positions adjacent to the genomic L and S termini, respectively, such that a novel fragment, Uc-DR1-Ub, is generated upon ligation of the genomic ends. The Uc-DR1-Ub fragment can function as a minimal packaging signal, and motifs have been identified within Uc and Ub that are conserved near the ends of other herpesvirus genomes (pac2 and pac1, respectively). We have introduced deletion and substitution mutations within the pac regions of the Uc-DR1-Ub fragment and assessed their effects on DNA packaging in an amplicon-based transient transfection assay. Within pac2, mutations affecting the T tract had the greatest inhibitory effect, but deletion of sequences on either side of this element also reduced packaging, suggesting that its position relative to other sequences within the Uc-DR1-Ub fragment is likely to be important. No single region essential for DNA packaging was detected within pac1. However, mutants lacking the G tracts on either side of the pac1 T-rich motif exhibited a reduced efficiency of serial propagation, and alteration of the sequences between DR1 and the pac1 T element also resulted in defective generation of Ub-containing terminal fragments. The data are consistent with a model in which initiation and termination of packaging are specified by sequences within Uc and Ub, respectively.     

The ends on herpesvirus DNA replicative concatemers contain pac2 cis cleavage/packaging elements and their formation is controlled by terminal cis sequences

Herpesviruses have large double-stranded linear DNA genomes that are formed by site-specific cleavage from complex concatemeric intermediates. In this process, only one of the two genomic ends are formed on the concatemer. Although the mechanism underlying this asymmetry is not known, one explanation is that single genomes are cleaved off of concatemer ends in a preferred direction. This implies that cis elements control the direction of packaging. Two highly conserved cis elements named pac1 and pac2 lie near opposite ends of herpesvirus genomes and are important for cleavage and packaging. By comparison of published reports and by analysis of two additional herpesviruses, we found that pac2 elements lie near the ends formed on replicative concatemers of four herpesviruses: herpes simplex virus type 1, equine herpesvirus 1, guinea pig cytomegalovirus, and murine cytomegalovirus. Formation of pac2 ends on concatemers depended on terminal cis sequences, since ectopic cleavage sites engineered into the murine cytomegalovirus genome mediated formation of pac2 ends on concatemers regardless of the orientation of their insertion. These findings are consistent with a model in which pac2 elements at concatemer ends impart a directionality to concatemer packaging by binding proteins that initiate insertion of concatemer ends into empty capsids.     

Terminal structure and heterogeneity in human cytomegalovirus strain AD169.

We have characterized the heterogeneity occurring at the junction of the long (L) and short (S) segments and at the termini of the strain AD169 human cytomegalovirus (HCMV) genome by restriction endonuclease mapping and nucleotide sequence analyses. The HCMV a sequence was identified by its position at both termini and inverted orientation at the L-S junction. Heterogeneity at both termini and the L-S junction was generated by the presence of fused and tandem a sequences. Some S termini lacked an a sequence. In addition, near the L terminus and at the L-S junction there were a variable number of 217-base-pair (bp) XhoI fragments arranged in tandem. The 217-bp fragments consisted of a portion of the a and adjacent b sequences (in the L-segment repeat) bounded by the same direct repeats (DR1) found at the boundaries of the a sequence. A model for the generation of these heterogeneous fragments is presented. We also determined the sequence of seven cloned terminal fragments, five from the L terminus and two from the S terminus. All L termini contained identical terminal sequences ending with base 32 of a 33-bp DR1. The S termini differed from each other and from the L-segment termini. One S terminus lacked an a sequence and terminated within S-segment repeat (c) sequences. The second S terminus contained an a sequence and terminated with bases 20 to 33 of a 33-bp DR1. A comparison of the cloned L and S terminal sequences with cloned L-S junction sequences suggested that the termini contained 3' single base extensions which were removed during the cloning. We also show that the herpesvirus conserved sequence is in a similar position relative to the termini of HCMV and several other herpesviruses, thus adding further support for the role of the sequence in the maturation of viral DNA.     

Sequences of the Epstein-Barr Virus (EBV) large internal repeat form the center of a 16-kilobase-pair palindrome of EBV (P3HR-1) heterogeneous DNA.

We have previously characterized several genomic rearrangements of Epstein-Barr virus (EBV) DNA contained in one of the defective EBV genomes harbored by the P3HR-1 (HR-1) line (H. B. Jenson, M. S. Rabson, and G. Miller, J. Virol. 58:475-486, 1986). One recombinant clone of heterogeneous DNA (het DNA) from this defective genome is an EcoRI fragment of 16 kilobase pairs (kbp) which is a palindrome. DNA digestion fragments specific for the center of this palindrome were present in cells which contained het DNA but not in cells which lacked het DNA. Thus, the palindrome was not an artifact of DNA cloning. The organization of the center of this palindrome was studied by DNA sequencing. The comparable region of the parental HR-1 genome was also studied by DNA sequencing. The central 3,495 base pairs (bp) of the palindrome were composed of sequences derived exclusively from internal repeat 1 of EBV, represented by BamHI W fragment. At each end of the central 3,495 hp was a symmetrical recombination with sequences of BamHI-Z, located more than 50 kbp away on the standard EBV genome. The central 3,495 bp were composed of an unduplicated 341 bp flanked by two perfect palindromic repeats of 1,577 bp. The 341-bp unique region was a portion of a 387-bp region of standard HR-1 BamHI-W which was identical to the central 387 bp of the palindrome. This central 387-bp region contained numerous stretches of dyad symmetry capable of forming a large stem-and-loop structure. The palindromic rearrangement had created two novel open reading frames in het DNA derived from standard HR-1 BamHI-W sequences. These two het DNA open reading frames had different amino termini but identical carboxy termini derived from the large open reading frame in standard HR-1 BamHI-W (HR-1 BWRF1). The BamHI-W sequences found in het DNA did not include either the TATA box of standard HR-1 BamHI-W or the exons which are present in the potentially polycistronic latent mRNAs encoding EBV nuclear antigens. These marked alterations in genomic structure may relate to the unique biologic properties of virus stocks containing het DNA by creation of new polypeptides or by formation or deletion of regulatory or functional signals.     

Nucleotide sequence and properties of the cohesive DNA termini from bacteriophage HP1c1 of Haemophilus influenzae Rd

The termini of the mature DNA of phage HP1c1 of Haemophilus influenzae Rd have been characterized by DNA ligation, nucleotide sequencing, and deoxynucleotide incorporation experiments. A hybrid plasmid containing the joined phage termini (the cos site) inserted into pBR322 has been constructed. The phage DNA has cohesive termini composed of complementary 5' single-stranded extensions which are seven residues long. The left cohesive terminal extension consists only of pyrimidines and the right only of purines. When the ends of the phage are joined, the terminal sequences constitute the central 7 bp of an 11 bp sequence containing only purines on one strand and pyrimidines on the other strand. This oligopyrimidine/oligopurine sequence does not possess rotational symmetry. A 10-bp sequence and its inverted repeat are located approx. 20 bp to the left and right of the fused ends.     

Structure and heterogeneity of the a sequences of human herpesvirus 6 strain variants U1102 and Z29 and identification of human telomeric repeat sequences at the genomic termini.

The unit-length genome of human herpesvirus 6 (HHV-6) consists of a single unique component (U) bounded by direct repeats DRL and DRR and forms head-to-tail concatemers during productive infection. cis-elements which mediate cleavage and packaging of progeny virions (a sequences) are found at the termini of all herpesvirus genomes. In HHV-6, DRL and DRR are identical and a sequences may therefore also occur at the U-DR junctions to give the arrangement aDRLa-U-aDRRa. We have sequenced the genomic termini, the U-DRR junction, and the DRR.DRL junction of HHV-6 strain variants U1102 and Z29. A (GGGTTA)n motif identical to the human telomeric repeat sequence (TRS) was found adjacent to, but did not form, the termini of both strain variants. The DRL terminus and U-DRR junction contained sequences closely related to that of the well-conserved herpesvirus packaging signal Cn-Gn-Nn-Gn (pac-1), followed by tandem arrays of TRSs separated by single copies of a hexanucleotide repeat. HHV-6 strain U1102 contained repeat sequences not found in HHV-6 Z29. In contrast, the DRR terminus of both variants contained a simple tandem array of TRSs and a close homolog of a herpesvirus pac-2 signal (GCn-Tn-GCn). The DRR.DRL junction was formed by simple head-to-tail linkage of the termini, yielding an intact cleavage signal, pac-2.x.pac-1, where x is the putative cleavage site. The left end of DR was the site of intrastrain size heterogeneity which mapped to the putative a sequences. These findings suggest that TRSs form part of the a sequence of HHV-6 and that the arrangement of a sequences in the genome can be represented as aDRLa-U-a-DRRa.     

Concatameric replication of Epstein-Barr virus: structure of the termini in virus-producer and newly transformed cell lines.

The linear form of Epstein-Barr virus (EBV) DNA has homologous direct tandem repeats of approximately 500 bp at each terminus (TR). After infection, EBV DNA circularizes via the TR to form the intracellular episomal DNA. To analyze the mechanism of the synthesis of linear DNA through possible replicative intermediates, the terminal fragments were identified in the total intracellular DNA and the covalently closed circular DNA from a productively infected cell line after induction of replication or after treatment with an inhibitor of viral DNA synthesis. These studies indicate that some of the fused terminal fragments detected in the total intracellular DNA are replication-dependent forms which are selectively excluded from the covalently closed circular fraction and are eliminated after treatment with acyclovir. The EBV terminal restriction enzyme fragments were identified in three producer cell lines, each with a characteristic number of TR in the intracellular episomal DNA. Identification of the termini in cell lines established with the three virus strains revealed that the newly transformed cell lines had a greater number of TR than did the template DNA in the producer cell line. The increase in the number of TR in progeny episomes indicates that linear DNA is produced from concatameric replicative intermediates rather than from amplified catenated circular intermediates.     

Adenoviruses with nonidentical terminal sequences are viable.

Adenovirus genomes consist of linear DNA molecules containing inverted terminal repeat sequences (ITRs) of 100 to 200 base pairs. The importance of identical termini for viability of adenoviruses was investigated. The viral strains used in this study were wild-type adenovirus type 5 (Ad5) and a variant Ad2 strain with termini which were distinct from those of all other human adenoviruses sequenced to date. A hybrid virus (sub54), obtained by recombination between Ad2 and Ad5, derived the left 42 to 52% of its genome from Ad2 and the right 58 to 48% from Ad5. Southern blotting analysis with labeled oligodeoxynucleotides indicated that both Ad2 and Ad5 ITRs were present in sub54 viral DNA preparations, and successive plaque purifications of sub54 demonstrated that viruses with nonidentical terminal sequences were viable but were rapidly converted to viruses with identical ends. Cloning of the sub54 genome as a bacterial plasmid supported the observations made by analysis of sub54 virion DNA. A plasmid, pFG154, was isolated which contained the entire adenovirus genome with an Ad2 ITR at the left terminus covalently linked to an Ad5 ITR at the right terminus. Upon transfection of mammalian cells with pFG154, viral progeny were obtained which had all possible combinations of termini, thus confirming that molecules with nonidentical termini are viable. Pure populations of viruses with nonidentical termini could not be isolated, suggesting efficient repair of one end with the opposite terminus used as a template. A model for this process is proposed involving strand displacement replication and emphasizing the importance of panhandle formation (annealing of terminal sequences) as a replicative intermediate.     

Identification of sequences necessary for packaging DNA into lambda phage heads

Several species of DNA molecules are packaged into lambda phage heads if they carry the region around the cohesive end site of lambda phage (cos lambda). The minimal functional sequence around cos lambda needed for packaging was examined by cloning in pBR322. The results showed that the minimal region contained 85 bp around cos lambda; 45 bp of the left arm of lambda phage and 40 bp of the right arm. A 75-bp region located to the right of the minimal region seems to enhance packaging. A 223-bp fragment containing these regions can be used as a portable element for plasmid DNA packaging into lambda phage heads. Plasmid ppBest 322, a derivative of pBR322 carrying this portable packager and both amp and tet genes, was constructed. This plasmid is useful for cloning of large DNA fragments.