EcoRI analysis of bacteriophage P22 DNA packaging

A molecular analysis of terminase cuts in headful packaging of Salmonella phage P22

Fragments of DNA molecules of Salmonella phage 22 which represent the molecular termini created by the terminase reaction have been cloned and sequenced. The terminase cleavage separates a headful-sized piece of DNA from the concatemeric precursor; by successful cloning strategy it was shown that the terminase produces blunt ends. The termini of 20 different phage DNA molecules fall into a region located between about 600 and 4000 bp from the pac signal and show a Gaussian distribution. The average terminal redundancy was calculated to be about 2230 bp (= 5.3%) and is therefore higher than was previously reported. A comparison of the nucleotides flanking the terminal bases of 20 different end clones does not support the suggestion that the terminase recognizes some specific sequence and/or structural information in determining the actual cleavage site.

Isolation of fragments with pac function for phage P22 from phage LP7 DNA and comparison of packaging gene 3 sequences

Three PstI DNA fragments of the P22-related Salmonella phage, LP7, have been cloned. They contain sequences recognized as pac signals by the packaging apparatus of P22. One of these fragments corresponds to the P22 DNA fragment carrying gene 3 which comprises the pac signal of phage P22. The product of gene 3, Gp3, is involved in the recognition of pac and the packaging process. Gene 3 of LP7 and most of the adjacent gene 2 have been sequenced. The pac analogous segments of the other two PstI fragments have been narrowed down by subcloning and by transduction of the resulting hybrid plasmids under recombination-defective conditions.

Organization of Methanobacterium thermoautotrophicum bacteriophage psi M1 DNA

psi M1 is a virulent bacteriophage of Methanobacterium thermoautotrophicum strain Marburg. Restriction enzyme analysis of the linear, 30.4 kb phage DNA led to a circular map of the 27.1 kb psi M1 genome. psi M1 is thus circularly permuted and exhibits terminal redundancy of approximately 3 kb. Packaging of psi M1 DNA from a concatemeric precursor initiates at the pac site which was identified at coordinate 4.6 kb on the circular genome map. It proceeds clockwise for at least five packaging rounds. Headful packaging was also shown for psi M2, a phage variant with a 0.7 kb deletion at coordinate 23.25 on the map.

Bacteriophage association of streptococcal pyrogenic exotoxin type C

A gene encoding streptococcal pyrogenic exotoxin type C (SPE C) was isolated from bacteriophage DNA derived from Streptococcus pyogenes CS112. The gene, designated speC2, was shown to reside near the phage attachment site of phage CS112. A restriction endonuclease map of the CS112 phage was generated, and the location and orientation of the speC2 gene were determined. Hybridization analyses of eight SPE C-producing strains revealed restriction fragment length polymorphism of the speC gene-containing DNA fragments and further showed that each speC was linked to a common CS112 phage-derived DNA fragment.

Circular Permutation of the Genome of a Temperate Bacteriophage from Streptococcus cremoris BK5

The temperate bacteriophage BK5-T was isolated from Streptococcus cremoris BK5 by induction with mitomycin C. Electron microscopy revealed that BK5-T DNA consists of linear molecules, ranging in size from 39.7 to 46 kilobase pairs. Restriction analysis of self-ligated BK5-T DNA showed that the ends of the DNA were not cohesive. The Eco RI restriction fragments of the phage genome were cloned into pACYC184. Restriction enzyme analysis of both the phage DNA and the cloned Eco RI fragments with Eco RI, Bst EII, Pst I, Cla I, and Xba I yielded a 37.6-kilobase-pair-long circular restriction map for the phage genome. It was concluded that the BK5-T DNA molecules in the population differ in their sequence by a circular permutation and that individual DNA molecules are terminally redundant. The map location of the sites at which packaging of BK5-T DNA into phage heads is initiated ( pac ) and at which the phage integrates into the bacterial chromosome ( att ) were established.

Analysis in vivo of the bacteriophage P22 headful nuclease

Bacteriophage P22 packages its double-stranded DNA chromosomes from concatemeric replicating DNA in a processive, sequential fashion. According to this model, during the initial packaging event in such a series the packaging apparatus recognizes a nucleotide sequence, called pac, on the DNA, and then condenses DNA within the coat protein shell unidirectionally (rightward) from that point. DNA ends are generated near the pac site before or during the condensation reaction. The right end of the mature chromosome is created by a cut made in the DNA by the "headful nuclease" after a complete chromosome is condensed within the phage head. Subsequent packaging events on that concatemeric DNA begin at the end generated by the headful cut of the previous event and proceed in the same direction as the previous event. We report here accurate measurements of the P22 chromosome length (43,400( +/- 750) base-pairs, where the uncertainty is the range in observed lengths), genome length (41,830( +/- 315) base-pairs, where the uncertainty represents the accuracy with which the length is known), the terminal redundancy (1600( +/- 750) base-pairs or 3.8( +/- 1.8)%, where the uncertainty is the observed range) and the imprecision in the headful measuring device ( +/- 750 base-pairs or +/- 1.7%). In addition, we present evidence for a weak nucleotide sequence specificity in the headful nuclease. These findings lend further support to, and extend our understanding of, the sequential series model of P22 DNA packaging.

Isolation of Salmonella typhimurium cys genes by transduction with a library of recombinant plasmids packaged in bacteriophage P22HT capsids

We have prepared a library of Salmonella typhimurium genomic fragments cloned in pBR322 and packaged in P22HT capsids. Plasmids carrying 24 of 26 specific genes searched for were isolated by transduction at frequencies of 1 to 344 per 10(6) plasmid transductants. All 11 known genes of the cysteine regulon were isolated from this library, including cysK, which we had previously been unable to clone in a recombinant plasmid with an Escherichia coli host. This library provides a simple and rapid method for isolating most S. typhimurium genes by using S. typhimurium itself as a host and should be particularly useful for cloning genes that might be deleterious to E. coli.

Bacteriophages of Saccharopolyspora erythraea

Five bacteriophages infecting only Saccharopolyspora erythraea (formerly Streptomyces erythreus) among 43 Streptomyces spp. tested were classified into two groups by phage-host relationships, restriction enzyme mapping, cohesive-end determinations, and Southern hybridizations. phi SE6, the most frequently isolated phage, produced clear plaques on all hosts tested, while phi SE45, phi SE57, phi SE60, and phi SE69 produced turbid plaques. phi SE6 DNA was linear, had a molecular weight of (27.6 +/- 1) X 10(6) and, like the DNAs of phi SE45, phi SE57, and phi SE69, lacked cohesive ends. The characteristic patterns of of ClaI and HindIII restriction digests of phi SE6 DNA and the results of Southern hybridizations with three different ClaI fragments of phi SE6 DNA as probes indicated that phi SE6 DNA was partially circularly permuted and terminally redundant, suggesting that it was packaged by a headful packaging mechanism. Southern hybridization data also showed that phi SE45, phi SE57, and phi SE69 were closely related to phi SE6. phi SE60 DNA, in contrast, had cohesive ends, and restriction mapping plus Southern hybridization data showed that phi SE60 was unrelated to the other four phages.

Recognition and cleavage of the bacteriophage P1 packaging site (pac). I. Differential processing of the cleaved ends in vivo

The packaging of bacteriophage P1 DNA into viral capsids is initiated at a specific DNA site called pac. During packaging, that site is cleaved and at least one of the resulting ends is encapsidated into a P1 virion. We show here that pac is located on a 620 base-pair fragment of P1 DNA (EcoRI-20). When that fragment is inserted into the chromosome of cells that are then infected with P1, packaging of host DNA into phage particles is initiated at pac and proceeds down the chromosome, unidirectionally, for about five to ten P1 "headfuls" (about 5 X 10(5) to 10 X 10(5) bases of DNA). Using an assay for pac cleavage that does not depend on DNA packaging, we have identified a set of five amber mutations that are mapped adjacent to pac, and that define a gene (gene 9) essential for pac cleavage. Amber mutations that are located in genes necessary for viral capsid formation (genes 4, 8 and 23), or in a gene necessary for "late" protein synthesis (gene 10), do not affect pac cleavage. The latter result suggests that the synthesis of the pac cleavage protein is not regulated co-ordinately with other phage morphogenesis proteins. The products of pac cleavage were analyzed using two different DNA substrates. In one case, a single copy of pac was placed in the chromosome of P1-sensitive cells. When those cells were infected with P1, we could detect the cleavage of as much as 70% of the pac-containing DNA. The pac end destined to be packaged in the virion was detected five to 20 times more efficiently than was the other end. Since this result is obtained whether or not the infecting P1 phage can encapsidate the cut pac site, the differential detection of pac ends is not simply a consequence of one end being packaged and the other not. In a second case, pac was located in cells on a small (5 X 10(3) bases) multicopy plasmid. When those cells were infected with P1, neither pac end was detected efficiently after P1 infection, unless the cells carried a recBCD- mutation. In recBCD- cells, the results with plasmid-pac substrates were similar to those obtained with chromosomally integrated pac substrates. We interpret these results to mean that, following pac cleavage, the end destined to be packaged is protected from cellular nucleases while the other end is degraded by the action of at least two nucleases, one of which is the product of the host recBCD gene.(ABSTRACT TRUNCATED AT 400 WORDS)

Recognition and cleavage of the bacteriophage P1 packaging site (pac). II. Functional limits of pac and location of pac cleavage termini

Bacteriophage P1 initiates the processive packaging of its DNA at a unique site called pac. We show that a functional pac site is contained within a 161 base-pair segment of P1 EcoRI fragment 20. It extends from a position 71 base-pairs to a position 232 base-pairs from the EcoRI-22 proximal side of that fragment. The 3' and 5' pac termini are located centrally within that 161 base-pair region and are distributed over about a turn of the DNA helix. The DNA sequence of the terminus region is shown below, with the large arrows indicating the positions of termini that are frequently represented in the PI population and the small arrows indicating the positions of termini that are rarely represented in the P1 population. (Sequence: in text). Digestion of P1 virus DNA with EcoRI generates two major EcoRI-pac fragments, which differ in size by about five or six base-pairs. While the structure and position of the double-stranded pac ends of these fragments have not been determined precisely, the 5' termini at those ends probably correspond to the two major pac cleavage sites in the upper strand of the sequences shown above. The 161 base-pair pac site contains the hexanucleotide sequence 5'-TGATCAG-3' repeated four times at one end and three times at the other. Removal of just one of those elements from either the right or left ends of pac reduces pac cleavage by about tenfold. Moreover, the elements appear to be additive in their effect on pac cleavage, as removal of one and a half elements or all three elements from the right side of pac reduces pac cleavage 100-fold, and greater than 1000-fold, respectively.

Initiation of bacteriophage P22 DNA packaging series. Analysis of a mutant that alters the DNA target specificity of the packaging apparatus

Bacteriophage P22 is thought to package its double-stranded DNA chromosome from concatemeric replicating DNA in a "processive" sequential fashion. According to this model, during the initial packaging event in such a series the packaging apparatus recognizes a nucleotide sequence, called pac, on the DNA, and then condenses DNA within the coat protein shell unidirectionally from that point. DNA ends are generated near the pac site before or during the condensation reaction. The opposite end of the mature chromosome is created by a cut made in the DNA after a complete chromosome is condensed within the phage head. Subsequent packaging events on that concatemeric DNA begin at the end generated by the headful cut of the previous event and proceed in the same direction as the previous event. We report here the identification of a consensus nucleotide sequence for the pac site, and present evidence that supports the idea that the gene 3 protein is a central participant in this recognition event. In addition, we tentatively locate the portion of the gene 3 protein that contacts the pac site during the initiation of packaging.

Phage T1-mediated transduction of a plasmid containing the T1 pac site

The T1 pac site has been cloned into a plasmid vector. This recombinant plasmid was tested for T1-mediated transduction efficiency in comparison with a plasmid containing the phage lambda T1-pac-like site esp-lambda, plasmids containing T1 sequences other than the pac site, and plasmids containing neither T1 sequences nor known pac sites. The data obtained indicate that there are at least two distinct mechanisms of T1-mediated plasmid transduction. One requires the presence of any T1 sequence on the plasmid and probably takes place via cointegrate formation with the homologous region of an infecting T1 genome. The other is specifically dependent on the presence of a pac site on the plasmid. Plasmids are packaged as head-to-tail multimers that have one heterogeneous molecular end and the other terminated at pac, and the direction of packaging with respect to the pac site is the same for plasmids as for T1. Possible roles of pac in plasmid packaging and their implications with regard to the packaging of phage DNA are discussed.

Selection of bacterial pac sites recognized by Salmonella phage P22

A gene library of chromosomal PstI fragments from Salmonella typhimurium strain DB5575 has been established. By means of phage P22 mediated transduction, ten different clones which contained inserts that promoted plasmid transduction were selected out of a total of about 7,000 clones. Seven of these clones carried inserts that stimulated transduction independently of general and int-promoted recombination and were interpreted as carrying pac analogous signals. The remaining three clones carried inserts that promoted transduction under recombination proficient conditions, whereas transduction occurred at reduced rate in the absence of recombination. These were believed to have short regions of homology with P22 DNA.

Physical and genetic characterization of the genome of Lactobacillus lactis bacteriophage LL-H

Bacteriophage LL-H is a virulent phage of Lactobacillus lactis LL23. A restriction map of the phage genome was constructed with various restriction endonucleases. This chromosome has a 34-kilobase size and seems to be circularly permuted. We used a bank of LL-H restriction fragments to study the expression of five of the seven main phage particle proteins. Immunoblotting experiments permitted the mapping on the chromosome of several genes coding for phage particle proteins. We also show that the gene of the main capsid protein is expressed from its own promoter in an Escherichia coli strain.

End structure and mechanism of packaging of bacteriophage T4 DNA

We analyzed by restriction enzyme digestion the end structure of T4 phage DNA by comparing mature, concatemeric, first-packaged, and incompletely packaged DNAs. The structure of mature DNA was also studied using 3' end labeling with terminal transferase. Our data support the hypothesis that T4 DNA packaging is not initiated at specific packaging initiation sequences on the concatemeric precursor (cos or pac site mechanisms) but by a different packaging mechanism.

T1 pip: a mutant which affects packaging initiation and processive packaging of T1 DNA

The pip mutation of phage T1 is located between the tar (gene 2.5) and am6 (gene 3) mutations in the region of the T1 genome which codes for early functions. The tar and pip mutations are additive in increasing the efficiency of transduction by T1. When T1 carries the pip mutation the initiation of DNA packaging by the phage at the non-T1, esp-lambda site is more efficient than when the phage is pip+; the small average burst size of 8 to 10 by T1pip suggests that pip causes a reduction in the efficiency with which T1 utilizes pac, the normal packaging initiation site of the phage. The presence of the BglII-D fragment (cut at one end at pac and the other by BglII) after digestion of T1pip DNA by BglII shows that T1pip continues to initiate DNA packaging at pac. The increased molarity of BglII-D coupled with the absence of the BglII-C fragment (which contains DNA on both sides of pac and can only be cut from processively packaged genomes) shows that T1pip packages only genomes which are initiated at pac and is defective in processive packaging.

Bacteriophage L: chromosome physical map and structural proteins

Restriction endonuclease cleavage site mapping was used to locate the regions of highest sequence homology in the chromosomes of Salmonella typhimurium bacteriophages L and P22. These lie in the DNA packaging, tail, early transcription antitermination, and perhaps integration "gene modules." Other regions of the two genomes are substantially less closely related. Phage L, which has no functional immunity I region, lacks approximately 1300 bp of DNA when compared to P22 in this section of the chromosome. At least some of the virion structural proteins are interchangeable between the two phages, which suggests that the two phage structural protein genes are very closely related. In addition, the apparent molecular weights of most P22 and L phage structural proteins are very similar. However, the phage L virion contains about 140 molecules of a 15K capsid protein which apparently has no P22 analog.

A coupled in vitro system for the formation and packaging of concatemeric phage T1 DNA

Extracts derived from E. coli cells infected non-permissively with phage T1 amber mutants were used in an in vitro system to investigate the packaging of T1 DNA into phage heads. The standard extract used infections with amber mutants in genes 1 and 2 (g1- g2-) which are defective in T1 DNA synthesis but can synthesis the proteins required for particle morphogenesis. g1- g2- extracts packaged T1+ virion DNA molecules with an efficiency of 3 X 10(5) pfu/micrograms DNA. Extracts from cells infected with phage also defective in DNA synthesis but carrying additional mutations in genes 3.5 or 4 which are required for concatemer formation in vivo (g1- g3.5- and g1- g4- extracts) package T1 virion DNA at substantially lower efficiencies. Analysis of the DNA products from these in vitro reaction showed that concatemeric DNA is formed very efficiently by g1- g2- extracts but not by g1- g3.5- or g1- g4- extracts. These results are interpreted as evidence that the T1 in vitro DNA packaging system primarily operates in a similar manner to the in vivo headful mechanism. This is achieved in vitro by the highly efficient conversion of T1 virion DNA into concatemers which are then packaged with a much lower efficiency into heads to form infectious particles. A secondary pathway for packaging T1 DNA into heads and unrelated to the headful mechanism may also exist.

DNA packaging initiation of Salmonella bacteriophage P22: determination of cut sites within the DNA sequence coding for gene 3

DNA packaging of Salmonella phage P22 starts at a defined site on a concatemer of P22 genomes. The molecular ends formed at the packaging initiation site (pac) map within a region of ca. 120 base pairs and may contain any of the four nucleotides at their 5' end. The determination of the positions of the cuts within the sequence demonstrates a characteristic distribution of cut sites which apparently cannot be attributed to the sequence organization of the involved regions. Symmetric elements of the sequence might serve as signals for a recognition event(s) at pac in a separate process preceding the cutting reaction. The region of packaging initiation is located within the sequence coding for gene 3. The 3 protein is responsible for the site specificity of this process. We find no significant homology to Nu1 protein, which appears to have an analogous or similar function in the DNA maturation of Escherichia coli phage lambda.

In vitro packaging of plasmid DNA oligomers by Salmonella phage P22: independence of the pac site, and evidence for the termination cut in vitro

In vitro packaging experiments with phage P22 using artificially ligated plasmid concatemers have shown that the pac site is not necessary for DNA packaging although in vivo this initiation signal is indispensable. This indicates that the phage-coded protein gp3 also executes other important functions during phage maturation in addition to the recognition of pac, or that its site specificity is lost in vitro. It has been shown previously that gp3 is necessary for in vitro packaging. Further, it was demonstrated that DNA which is only 74% of headful size cannot be packaged. Oversized DNA, however, is cut in vitro to unit length.

A late gene product of phage P22 affecting virus infectivity

Gene 14 is a recently discovered late gene of phage P22, mapping between the DNA injection and head completion genes (P. Youderian and M. Susskind (1980), Virology 107, 258-269). The gene 14 product has not been detected in phage particles. We have studied the defective phenotype of amber mutants in gene 14 to determine the role of gp14. The yield of physical particles from 14- infections is normal, but the infectivity of those particles is reduced by 60-80%. The noninfectious particles adsorb to but do not kill the host cell, as if they were defective in DNA injection. No differences in morphology, DNA composition, DNA permutation, or protein composition have been detected between 14- and wild-type particles. Procapsids, the capsid precursor to DNA packaging, exhibit a similar reduction in viability when isolated from 14- infected cells, assayed by in vitro DNA packaging. This is consistent with the gene 14 product functioning in the assembly or maturation of the procapsid. The three DNA injection proteins, encoded by genes 7, 16, and 20, are assembled into the particle at the procapsid stage. The defect in 14- particles may arise from improper organization or modification of one or more of the three proteins needed for DNA injection.

Physical characterization of the genome of the Myxococcus xanthus bacteriophage MX-8

We have constructed a restriction map for the genome of bacteriophage MX-8 from Myxococcus xanthus using the enzymes PvuII, MboI, and EcoRI. The phage genome size, as determined by restriction analysis, is 51.7 +/- 0.6 Kb. Double digestions, redigestions of isolated fragments, and crossed-contact hybridization of partial digestion products show that the restriction map is circular. Restriction analysis and Southern hybridization show that the phage DNA molecules are packaged sequentially from a concatemer starting from a specific site which we have mapped. The DNA molecules have an average terminal redundancy of approximately 8% and are circularly permuted over at least 40% of the genome.

Characterization and physical map of choleraphage phi 149 DNA

Choleraphage phi 149 DNA is a linear double-stranded molecule 69 X 10(6) Da or 104 kilobase pairs (kbp). From restriction enzyme analysis, it has been concluded that the DNA is circularly permuted. There are at least three S1 nuclease-sensitive sites along the length of the molecule. These sites represent single-strand interruptions repairable by T4 DNA ligase. A physical map of the DNA has been constructed using the restriction endonucleases BamH1 and BglII.

Autoregulation of the bacteriophage P22 scaffolding protein gene

During the formation of each bacteriophage P22 head, about 250 molecules of the product of gene 8, scaffolding protein, coassemble with and dictate correct assembly of the coat protein into a proper shell structure. At approximately the time that DNA is inserted inside the coat protein shell, all of the scaffolding protein molecules leave the structure. They remain active and participate in several subsequent rounds of shell assembly. Previous work has shown that scaffolding protein gene expression is affected by the head assembly process and has generated the hypothesis that unassembled scaffolding protein negatively modulates the expression of its own gene but that it lacks this activity when complexed with coat protein in proheads. To test this model, a P22 restriction fragment containing the scaffolding and coat protein genes was cloned under control of the lac promoter. These cloned genes were then expressed in an in vitro DNA-dependent transcription-translation reaction. The addition of purified scaffolding protein to this reaction resulted in reduced scaffolding protein synthesis relative to coat and tail protein synthesis to an extent and at a protein concentration that was consistent with the observed reduction in vivo. We conclude that scaffolding protein synthesis is autoregulated and that scaffolding protein is the only phage-coded protein required for this process. In addition, these experiments provide additional evidence that this autoregulation is posttranscriptional.

DNA injection proteins are targets of acridine-sensitized photoinactivation of bacteriophage P22

Viruses and other nucleoprotein complexes are inactivated on exposure to white light in the presence of acridine and related dyes. The mechanism is thought to involve generation of singlet oxygen or related species, but the actual molecular targets of the inactivating event have not been well defined. We have re-examined the mechanism of dye-sensitized photoinactivation taking advantage of the well characterized bacteriophage P22. Though the inactivated phage absorb to their host cells, the cells are not killed and genetic markers cannot be rescued from the inactivated phage. These observations indicate that the chromosome is not injected into the host cell. However, the DNA of the damaged particles shows no evidence of double-stranded breaks or crosslinking. The DNA injection process of P22 requires three particle-associated proteins, the products of genes 7, 16 and 20. Gp16, which can act in trans during injection, is inactivated in the killed particles. Sodium dodecyl sulfate/polyacrylamide gel analysis reveals that gp16, gp7 and gp20 are progressively covalently damaged during photoinactivation. However, this damage does not occur in particles lacking DNA, indicating that it is DNA-mediated. Similar findings were obtained with acridine orange, acridine yellow, proflavin and acriflavin. These results indicate that the actual targets for inactivation are the DNA injection proteins, and that the lethal events represent absorption of photons by acridine molecules stacked in a region of DNA closely associated with the injection proteins.

Selective transduction of recombinant plasmids with cloned pac sites by Salmonella phage P22

Recombinant plasmids having PstI fragments of P22 DNA inserted in the vector pBR322 can be transduced efficiently by Salmonella phage P22, irrespective of the cloned phage sequences. When the rec function of the donor cells and the corresponding recombination system erf of the infecting phage are simultaneously inactivated, only plasmids containing the P22 pac site can be transduced. By this selective, generalized transduction an EcoRV DNA fragment of the P22 related phage L has been identified that carries a base sequence recognized by phage P22 as a packaging signal. Experiments in which only one of the two recombination systems was inactivated, showed that the bacterial rec system obviously promotes cointegrate formation between plasmid and phage DNA much more efficiently than the phage-coded erf system, allowing the specialized plasmid transduction observed by Orbach and Jackson (1982).

Vibrio cholerae bacteriophage CP-T1: characterization of bacteriophage DNA and restriction analysis

Temperature bacteriophage CP-T1 of Vibrio cholerae has a capsid that is 45 nm in diameter, a contractile tail 65 nm long and 9.5 nm wide, and a baseplate with several spikes or short tail fibers. The linear double-stranded DNA is 43.5 +/- 1.4 kilobases long, and the phage genome is both terminally redundant and partially circularly permuted. The extent of terminal redundancy is ca. 4%, and circular permutation is up to ca. 44%. Circular restriction maps have been constructed for the enzymes HindIII, EcoRI, BamHI, and PstI. By restriction endonuclease and heteroduplex analyses of phage DNA, the presence and location of a site (pac) at which packaging of phage DNA is initiated was established.

pac sites are indispensable for in vivo packaging of DNA by phage P22

F' pro+ plasmids were selected and used as donors to prepare P22 transducing phages. Two types of result were observed. pro+ from type I donors cannot be packaged by wild-type P22 to yield transducing particles unless a prophage pac site is introduced into the plasmid. Transposon Tn10 also allows initiation of packaging. pro+ from type II plasmids can be transduced with the same efficiency as pro+ DNA on the chromosome, indicating that a chromosomal pac site was included when the F' pro+ was excised from the Hfr strain. The usefulness of type I plasmids as a test substrate for pac signals is discussed.

Initiation by bacteriophage T1 of DNA packaging at a site between the P and Q genes of bacteriophage lambda

The growth of phage T1 on cells tandemly lysogenic for heteroimmune lambdoid prophages leads to a nonrandom packaging of lambda DNA by T1. A site, called esp-lambda, is located between the P and Q genes of lambda and results in increased packaging to the left by T1. When cloned into pBR322, the esp-lambda site causes a significant increase in transduction of the plasmid by T1. The nin5 deletion inactivates esp-lambda.

In vitro packaging of mature phage DNA by Salmonella phage P22

Mature, headful-sized DNA extracted from the Salmonella phages P22 and L, and P22/L-hybrid phages can be encapsulated in vitro by means of a packaging system for exogenous DNA. The probability of packaging reaches about 10(-3) per headful-sized molecule. The absence of in vitro recombination was demonstrated, to eliminate the possibility that such a process had created concatemers. The endonucleolytic cut at the pac site, which initiates sequential packaging in vivo, does not occur with the mature DNA substrate in vitro. The position of pac on the molecule is not important but the pac-recognizing phage protein gp3 is indispensable for in vitro encapsulation.

A restriction map and analysis of the terminal redundancy in the group a streptococcal bacteriophage SP24

The DNA isolated from the group A streptococcal bacteriophage SP24 is a linear double-stranded molecule 42.0 kb in length. The DNA has been characterized by electron microscopy, and by agarose gel electrophoresis after cleavage with the restriction endonucleases SalI, BglII, XbaI, PvuI, HindIII, and BamHI. Analysis of SalI digests indicates that two fragments are present in submolar amounts and exist as a subset of sequences present in another SalI fragment. Moreover, overlapping endonuclease fragments suggested that the physical map is circular. This was confirmed when homoduplex phage DNA revealed circular structures with single-stranded tails that were 7.7% of the circumference of the genome length molecule. Tails were observed to be separated by as much as 42% of the circular homoduplex structure. These results indicate that the phage SP24 genome is terminally redundant and circularly permuted; and the data are consistent with a model in which DNA packaging into phage heads is initiated at a specific site on concatermeric DNA and proceeds sequentially to package up to five "headfuls" of DNA per concatemer.

On the sequential packaging of bacteriophage P22 DNA

Bacteriophage P22 is thought to package daughter chromosomes serially along concatemeric DNA. We present experiments which show that the average DNA packaging series length increases with time after infection, which supports this model. In addition, we have analyzed the effect on average series length of lowering the amount of the various individual proteins involved in DNA packaging. These results support the notion that the protein products of gene 2 and gene 3 are both more stringently required for initiation of sequential DNA packaging series than for their extension, and they are compatible with a model for the control of series length in which that length is determined, at least in part, by a competition between series initiation events and extension events.

A physical map of the group A streptococcal pyrogenic exotoxin bacteriophage T12 genome

A physical map of group A streptococcal bacteriophage T12 was constructed with restriction endonucleases Sal/I, PstI, and EcoRI. The map is circularly permuted with a total length of 36.0 kb. Sub-molar quantities of certain restriction fragments, some of very precise MW and some of heterogeneous MW, were observed. This observation, together with mapping data, suggests that DNA packaging is initiated at a precise site on a concatemeric precursor and proceeds for a limited number of rounds.

An assay for the rates of cleavage of specific sites in DNA by restriction endonucleases: its use to study the cleavage of phage lambda DNA by EcoRI and phage P22 DNA containing thymine or 5-bromouracil by HindIII

A method to measure the rates of cleavage of specific sites in DNAs by restriction endonucleases is described. Partial digests are prepared by incubating DNAs with limiting amounts of endonuclease. The termini generated by cleavage are labeled with 32P by the polynucleotide kinase-exchange reaction. The labeled termini are then identified by completing the digestion with the same endonuclease and separating the products by gel electrophoresis. As the products of complete digestion of DNA are often easily separated and can be unequivocally identified, this procedure permits comparison of the rates of cleavage of specific sites in DNAs; furthermore, because detection of the products of cleavage utilizes radioautography and does not depend upon their size, or amount, only small amounts of DNA need to be utilized. This method has been used to examine the cleavage of phage lambda DNA by EcoRI endonuclease, and to demonstrate that 5-bromouracil substitution in phage P22 DNA reduces the rate of cleavage of most sites by HindIII endonuclease approximately threefold and the rate of cleavage of one site approximately tenfold.

Additional restriction endonuclease cleavage sites on the bacteriophage P22 genome

We present complete restriction endonuclease cleavage site maps of the bacteriophage P22 chromosome for 16 enzymes with six base recognition sequences, thereby positioning 116 new sites on the chromosome. Twenty-four such restriction maps for P22 DNA, containing 162 sites, have now been completed, and three enzymes were found that did not cut P22 DNA. Our results are consistent with the ideas that ClaI does not cleave the methylated recognition sequence ATCGA(me)T or A(me)TCGAT and StuI does not cleave the methylated recognition sequence AGGCC(me)T.

Morphogenesis of bacteriophage phi 29 of Bacillus subtilis: oriented and quantized in vitro packaging of DNA protein gp3

The assembly of phage phi 29 occurs by a single pathway, and the DNA protein (DNA-gp3) of "packaging intermediates" can be obtained after DNase I interruption of in vitro complementation. A broad spectrum of DNA molecules of variable length was isolated from DNase I-treated proheads. Restriction endonuclease EcoRI digestion and electrophoretic analysis of these DNA molecules suggested that DNA-gp3 packaging was oriented with respect to the physical map and was a complex process. Proteinase K-treated exogenous DNA was not packaged. When exogenous DNA-gp3 was predigested with the restriction endonucleases BstEII. EcoRI, HpaI, and HpaII, the left-end fragments, ranging in size from 8 to 0.9 megadaltons, were selectively and efficiently packaged. During in vivo and in vitro assembly, DNA-gp3 is packaged into proheads, the "core-scaffolding" protein gp7 exits from the particles, and the DNA-filled heads assume the angular morphology of phage phi 29. The packaging of a 4.1-megadalton DNA-gp3 left-end fragment (one third of the genome) resulted in the exit of gp7 and the transition to angularity.

Interactions of Tn7 and temperate phage F116L of Pseudomonas aeruginosa

Tn7 insertions into the genome of F116L, a Pseudomonas aeruginosa generalized transducing phage, were isolated by repeated cycles of transduction and induction isolated by repeated cycles of transduction and induction of strains lysogenic for F116cts mutants with selection for trimethoprim resistance (Tpr). Two non-defective F116Lcts:: Tn7 phage were characterized. They have reduced plaquing ability, produced non-lysogenic Tpr transductants, and have yielded a deletion mutant of the phage genome upon selection for plaque formation in single infection. F116L DNA is circularly permuted and terminally redundant. A circular restriction map of 61.7 kb has been defined, and a cleavage site common to many enzymes has been identified at coordinate 23.3 kb on the map. It is presumed that this site represents the sequence for the initiation of DNA encapsidation by a headful packaging mode. The Tn7 insertion targets and a 13.4 kb deletion define regions of the F116L genome non-essential for either vegetative growth or lysogenization. The restriction map of Tn7 has been determined for five enzymes. Non-lysogenic Tpr transductants reveal a Tn7 insertion hot-spot in the P. aeruginosa genome.

The packaging initiation site of phage P22. Analysis of packaging events by transduction

P22 lysates were grown on Salmonella strains carrying P22 prophages deleted to various extents. Transducing bacterial markers at both sides of the prophage insertion site it could be shown that: (i) transduction of markers can be enhanced by the prophage pac site; (ii) the recognition signal pac is in the area of gene 3 on the phage genome and thus close to the cutting site(s); (iii) transposon Tn10 may also act as a signal for packaging initiation; (iv) (at least) Tn10 initiates packaging sequences in both directions.

Accessory replicons of species of Salmonella and Shigella

Shigella and Salmonella strains isolated from clinical samples were examined. Out of 42 Shigella strains tested, 17 (40%) were found to be colicinogenic and another 3 were lysogenic. All three lysogens yielded a phage antigenically homologous to coliphage P2. Out of 30 strains tested, only 1 was found to be resistant to both neomycin and sulfamethoxazole. Out of 48 strains of Salmonella tested for drug resistance, only 2 showed multiple drug resistance. In contrast to Shigella isolates, the Salmonella isolates were infrequently (approximately 5%) bacteriocinogenic. The frequency of lysogeny in Salmonella strains was found to be 6% when tested on Salmonella typhimurium LT2, but by using a set of five indicators belonging to species Salmonella potsdam, Salmonella mbadanka, Salmonella dublin, Salmonella london, and Salmonella wandsworth, 50% of the strains were shown to be lysogenic. Salmonella phages related to P22 were recoverable from Salmonella saintpaul, Salmonella indiana, and Salmonella heidelberg. Some isolates of S. typhimurium yielded a temperature-sensitive and P22-heterologous phage which was found to be a more efficient transducer of bacterial genetic markers than P22. EcoRI-generated fragments of the DNA of some phages permitted the establishment of a clonal descent for some of the wild-type lysogenic bacterial strains. This last observation points out the potential usefulness of prophages as epidemiological markers.

Packaging signals for phage P22 on the chromosome of Salmonella typhimurium

Numbers of transducing particles for a set of 28 different chromosomal markers were determined in a lysate of Salmonella phage P22. The results were plotted with regard to the map positions of the transduced loci. Maxima of the resulting curve are interpreted as positions of start signals ("pac-sites") for packaging series on the Salmonella chromosome. 5-6 pac-sites could be found as a minimum estimate.

Transfer of chimeric plasmids among Salmonella typhimurium strains by P22 transduction

Salmonella typhimurium bacteriophage P22 transduced plasmids having P22 sequences inserted in the vector pBR322 with high frequency. Analysis of the structure of the transducing particle DNA and the transduced plasmids indicates that this plasmid transduction involves two homologous recombination events. In the donor cell, a single recombination between the phage and the homologous sequences on the plasmid inserted the plasmid into the phage chromosome, which was then packaged by headfuls into P22 particles. The transducing particle DNA contained duplications of the region of homology flanking the integrated plasmid vector sequences and lacked some phage genes. When these defective phage genomes containing the inserted plasmid infected a recipient cell, recombination between the duplicated regions regenerated the plasmid. A useful consequence of this sequence of events was that genetic markers in the region of homology were readily transferred from phage to plasmid. Plasmid transduction required homology between the phage and the plasmid, but did not depend on the presence of any specific P22 sequence in the plasmid. When the infecting P22 carried a DNA sequence homologous to the ampicillin resistance region of pBR322, the vector plasmid having no P22 insert could be transduced. P22-mediated transduction is a useful way to transfer chimeric plasmids, since most S. typhimurium strains are poorly transformed by plasmid DNA.

MB78, a virulent bacteriophage of Salmonella typhimurium

The isolation and some properties of a virulent bacteriophage of Salmonella typhimurium, MB78, which is morphologically, serologically, and physiologically unrelated to P22, are reported. The phage has a noncontractile long tail with partite ends. It cannot multiply in minimal medium in the presence of citrate. MB78-infected cells are, however, killed in such medium. This phage cannot grow in rifampin-resistant mutants of the host. The latent period of growth of this phage is much shorter than that of P22. Both sieA and sieB genes of the resident P22 prophage are required to exclude the superinfecting MB78 phage, whereas all temperate phages related to P22 are excluded by either one or both of the genes individually. Restriction endonuclease cleavage patterns of P22 and MB78 are distinctly different. The absence of homology between the two phages P22 and MB78 suggests that MB78 is not related to phage P22.