Molecular genetics of bacteriophage P22

A quantitative model for nonrandom generalized transduction, applied to the phage P22-Salmonella typhimurium system

A mathematical model for nonrandom generalized transduction is proposed and analyzed. The model takes into account the finite number of transducing particle classes for any given marker. The equations for estimation of the distance between markers from contransduction frequency data are derived and standard errors of the estimates are given. The obtained relationships depend significantly on the number of classes of transducing fragments. The model was applied to estimate the number of transducing fragment classes for a given marker in transduction with phage P22 of Salmonella typhimurium. It was found that the literature data on frequencies of contransduction in crosses with mutual substitution of selective and nonselective markers can be rationalized most accurately by assuming that the mean number of classes is equal to 2. An improved method for analysis of cotransduction data is proposed on the basis of our model and the results of calculation. The method relies on solving a set of algebraic equations for cotransduction frequencies of markers located within one phage length. The method allows a relatively precise determination of distances between markers, positions of transducing particle ends and deletion or insertion lengths. The approach is applied to the trp-cysB-pyrF and aroC-hisT-purF-dhuA regions of the Salmonella typhimurium chromosome.

Identification and characterization of mutations in Escherichia coli that selectively influence the growth of hybrid lambda bacteriophages carrying the immunity region of bacteriophage P22

Mutations in two Escherichia coli genes, sipA and sipB, result in a specific inhibition of the growth of certain hybrid lambdoid bacteriophages, lambda immP22, that have the early regulatory regions and adjacent genes from bacteriophage P22. The sipB391 mutation maps near minute 56 and exerts the strongest inhibitory effect on the growth of the hybrid phages. The sipA1 mutation maps near minute 72 and plays an auxiliary role: enhancing the action of sipB391. Such a role is not limited to sipA1, since there is a similar enhancement by the nusA1 and nusE71 mutations. The Sip-imposed restriction on the growth of lambda immP22 phages is not observed if the phage carries a mutation in the c1 gene. Perhaps this reflects the fact that the c1 product regulates phage DNA replication and is a major determinant in the decision governing whether the phage takes the lytic or lysogenic pathway. Consistent with this idea is the observation that lambda immP22 DNA replication is severely inhibited in bacteria carrying the sipB391 mutation. It is suggested that sip mutations exaggerate the normal role of c1 in limiting lytic growth. This causes a failure in the expression of sufficient amounts of some or all of the lytic gene products required for phage growth.

Map of DNA homology between the genomes of Salmonella bacteriophages P22 and L

The genomes of temperate Salmonella typhimurium phages P22 and L share approximately 69% homology, as measured by DNA heteroduplex analysis. Alignment of the P22/L heteroduplex molecules with a P22 physical map places most of this homology between the capsid genes and genes in the vicinity of the prophage attachment sites. The degree of genetic relatedness between these phages and the lambdoid phages is also discussed.

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.

Bacteriophage P22 tail protein gene expression

We have found that mutations which block bacteriophage P22 head assembly at or before the DNA packaging stage (1-, 2-, 3-, 5-, and 8-) cause up to a 20-fold increase in the amount of tail (gene 9) protein made during infection. This correlation seems strong enough to warrant consideration of a control mechanism in which the failure to package DNA per se causes a large increase in the synthesis of tail protein. Our results indicate that one of the repressors required for maintenance of lysogeny, the mnt gene product, may be partially responsible for this phenomenon.

Assembly-controlled autogenous modulation of bacteriophage P22 scaffolding protein gene expression

In the assembly of bacteriophage P22, precursor particles containing two major proteins, the gene 5 coat protein and the gene 8 scaffolding protein, package the DNA molecule. During the encapsidation reaction all of the scaffolding protein molecules are released intact and subsequently participate in further rounds of DNA encapsidation. We have previously shown that even though it lies in the center of the late region of the genetic map, the scaffolding protein gene is not always expressed coordinately with the remainder of the late proteins and that some feature of the phage assembly process affects its expression. We present here in vivo experiments which show that there is an inverse correlation between the amount of unassembled scaffolding protein and the rate of scaffolding protein synthesis and that long amber fragments of the scaffolding protein can turn down the synthesis of intact scaffolding protein in trans. These results support a model for scaffolding protein regulation in which the feature of the assembly process which modulates the rate of scaffolding protein synthesis is the amount of unassembled scaffolding protein itself.

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.

Posttranscriptional modulation of bacteriophage P22 scaffolding protein gene expression

The bacteriophage P22 late operon contains 2 genes whose products are required for cell lysis and 13 genes whose products are involved in the morphogenesis of the phage particle. This operon is under the positive control of the phage gene 23 product and is thought to have a single promoter. The expression of one of these late genes, the scaffolding protein gene, is autogenously modulated independently from the remainder of the late genes. When unassembled, scaffolding protein turns down the rate of synthesis of additional scaffolding protein, and when it is assembled into phage precursor structures, it does not. Experiments presented here show (i) that the mRNA from the scaffolding protein gene is functionally threefold more stable when most of the scaffolding protein is assembled than when it is unassembled and (ii) that no new promoter near the scaffolding protein gene is activated at the high level of synthesis. These data support the model that this autogenous modulation occurs at a posttranscriptional level. We also observed that another message, that of coat protein, appears to become increasingly stable with time after phage infection.

Effect of bacteriophage P1 lysogeny on lipopolysaccharide composition and the lambda receptor of Escherichia coli

The outer membrane of Escherichia coli was altered as a consequence of lysogeny by bacteriophages P1 and P1 cmts. The predominant change was a reduction in the size of lipopolysaccharide to a heptose-deficient form. P1 cmts lysogens were still sensitive to several bacteriophages but were resistant to lambda vir. Neither whole cells nor solubilized outer membranes from P1 cmts lysogens were able to inactivate lambda vir, and 32P-labeled lambda vir was unable to adsorb to P1 cmts lysogens. P1 cmts lysogens were also affected in maltose transport. The level of periplasmic maltose-binding protein was reduced somewhat, but there was no significant reduction in the level of the outer membrane lambda receptor (LamB). These membrane abnormalities were all corrected in strains cured of P1 cmts. It is suggested that P1 cmts affects lipopolysaccharide biosynthesis by a phage conversion mechanism and consequently the function of the lambda receptor.

Conserved regions in mammalian beta-globins: could they arise by cross-species gene exchange?

Comparison of the nucleotide sequences from the coding regions of the four mammalian beta-globin genes shows that different parts of these genes have evolved at two different rates. Those codons designating amino acids 1-20, 41-91 and 109-146 have accumulated substitutions in a random fashion as the molecular clock hypothesis would predict. The codons at positions 21-40 and 91 to 108 behave as if they evolved at a much slower rate. Each of the slowly evolved regions contains an intron. Conservation of the coding sequences flanking the introns are hypothesized to be the result of corss-species gene exchange.

Replication-control functions block the induction of an SOS response by a damaged P1 bacteriophage

UV-damaged bacteriophage P1 causes an SOS response in infected bacteria that can be measured colorimetrically with the aid of a lambda pL-lacZ fusion strain of Escherichia coli. This response is blocked by a P1 prophage. Evidence is offered that the blockage is caused by the concerted action of the incompatibility determinant incA and the immunity (c1 and c4) repressors of the prophage. We suggest that indirect induction of lambda by damaged P1 is caused by the abortive initiation of replication in either of two modes, one under incA control, the other under c1 control and indirectly (via ant, the determinant of a repression antagonist) under c4 control.

P22 antirepressor protein prevents in vivo recA-dependent proteolysis of P22 repressor

A method was developed to demonstrate recA-dependent P22-repressor breakdown in vivo by SDS-polyacrylamide electrophoresis of unfractionated extracts of phage-infected, lysogenic Salmonella typhimurium strains TA1530 rec+ and TA1530 recA1-. The antirepressor of P22 is not cleaved by recA protein. Under conditions of unregulated ant-overproduction (Harvey et al. 1981) antirepressor protects c2-repressor in vivo against proteolytic cleavage by recA protein.

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.

Genetic and physical characterization of lysogeny by bacteriophage MX8 in Myxococcus xanthus

Myxophage MX8 can initiate a lysogenic cycle in Myxococcus xanthus. The lysogenic phage was gentically stable in vegetative cells and persisted in the latent state through many cell generations in the absence of extracellular phage reinfection. The latent state also was stable during the host developmental cycle, since myxospores transmitted latent MX8 genetic information to future progeny cells. DNA hybridization experiments to probe the structure of the lysogenic phage provided physical evidence that MX8 formed a prophage. During lysogenization, MX8 DNA was cut at a specific site (attP) on phage DNA, and we have concluded that genetic recombination between attP and a bacterial DNA site (attB) leads to integration of MX8 DNA and formation of stable MX8 prophage. The genetic and physical properties of MX8 that we describe should make MX8 useful in the analysis of development of M. xanthus by genetic methods.

Control of phage P22 tail protein expression by transcription termination

The structural gene for Salmonella bacteriophage P22 tail protein, gene 9, is separated from the remainder of the P22 late operon genes by the immI region. Early transcription of immI gene ant, which is immediately promoter proximal to gene 9, occurs in the same direction as late gene transcription but does not enter gene 9 coding sequences (Susskind & Youderian, 1982). We have cloned gene 9 and surrounding sequences into pBR322 and subsequently positioned lac UV5 promoters at varying distances before the start of gene 9 by DNA manipulations in vitro. Using an in vitro phage assembly assay to measure in vivo expression of tail protein from these plasmids and in vitro transcription reactions to measure transcriptional template activity of DNA fragments isolated from these plasmids, we have identified a region of DNA between gene ant and gene 9 that behaves as a transcription termination signal. The DNA sequence of this region shows hyphenated dyad symmetry followed by a run of seven thymine residues on the coding strand. This sequence can be drawn in a potential stem-and-loop secondary structure similar to known rho-independent transcription termination signal sequences. We discuss the role of this transcriptional terminator sequence in gene 9 expression and the early to late transcriptional switch in the P22 infection cycle.

Construction of a genetic map for Caulobacter crescentus

RP4-mediated conjugation has been used to transfer large fragments of chromosomal material in Caulobacter crescentus. In this system, conjugation proceeds from multiple origins, and haploid recombinants are recovered at frequencies of 10(-6) and 10(-7) per donor cell. The data from five-factor crosses were subjected to computer-assisted crossover analyses as a rapid method to determine marker order. Using this information and data from additional two- and three-factor crosses mediated by RP4 or the generalized transducing bacteriophage phi Cr30, we constructed the first genetic map for C. crescentus.

Salmonella toxin synthesis is unrelated to the presence of temperate bacteriophages

Several strains of Salmonella were examined for an association between the capacity to produce Salmonella toxin and the presence of bacteriophages. Based on the data obtained from this study, we concluded that genetic information responsible for Salmonella toxin synthesis was not inherited by lysogenic conversion.

Kinetics of P22 early gene expression suggests a cro-like regulatory function

Analysis of phage-specified protein synthesis after phage infection of UV-irradiated cells shows a turn-off of early gene expression, a regulatory event that is independent of the known P22 regulatory functions. This supports the suggestion of a cro lambda-like function in P22. We have identified the products of genes 18 and int as contributing to the complex 40,000 dalton band in our SDS-polyacrylamide gels. Both gene products appear to be subject to regulation by the cro-like function of P22. Proteins of 33,000, 29,000, 27,000, 25,000, and 24,000 MW, specified by as yet unidentified P22 genes of the early leftward operon, are regulated by the same function. Our data suggest that the cro-like function is expressed from the early rightward operon.

Transduction in Streptomyces hygroscopicus mediated by the temperate bacteriophage SH10

The temperate actinophage SH10 mediates generalized transduction in Streptomyces hygroscopicus at low frequency. The efficiency of transduction depends on the average phage input, age of outgrowing spores of the recipient and on the selective marker. The highest EOT was found for the auxotrophic mutants 21(phe-) and 5(try-) (4.2 x 10(-6) and 2.7 x 10(-6), respectively). Transduction of the thermosensitive mutant NG14-216 ts 35 was two orders of magnitude lower (2.5 x 10(-8)). The transductant colonies segregated into stable and unstable clones. Stable transductants were never found to be lysogenic for phage SH10.

Adsorption of bacteriophage phi 29 to Bacillus subtilis through the neck appendages of the viral particle

Phage phi 29 particles produced under restrictive conditions by mutants in gene 12 have normal amounts of all of the structural proteins except the appendage protein, p12*, which is missing. These particles are not infective and do not adsorb to Bacillus subtilis cells. By in vitro complementation of 12- particles with extracts containing protein p12* or with purified protein p12*, the defective particles could bind the appendage protein and become infective and able to adsorb to bacteria. Therefore, the neck appendages of phage phi 29, formed by protein p12*, are involved in the interaction of the phage with the cell wall receptors. Protein p12*, purified in its native state, competed with wild-type phage for adsorption to bacteria. Also, protein p12* could displace adsorbed phage from bacteria. Since the displaced phage was infective, protein p12* does not seem to be modified after phage adsorption.

Maturation of bacteriophage SPPI DNA: limited precision in the sizing of mature bacteriophage genomes

Maturation of bacteriophage SPPI is imprecise. Although terminally redundant and circularly permuted molecules were always formed, individual molecules varied by more than 200 base pairs from each other.

General Transduction in Vibrio cholerae

Evidence was obtained for general transduction in Vibrio cholerae. Transduction of three amino acid markers and three antibiotic resistance characters was demonstrated using strains of biotype eltor and biotype cholerae. Some of the genetic characters were transduced from a biotype eltor donor (and its mutant derivatives) to biotype cholerae and eltor recipients. For the genetic traits examined, the frequencies of transduction ranged between 10(-5) and 10(-8). Maximal frequencies were obtained with transducing phage lysates that were irradiated with ultraviolet light. The development of a system of general transduction will now aid in fine structure analysis and detailed mapping of the chromosome of V. cholerae.

Repression of ant synthesis early in the lytic cycle of phage P22

Using SDS-polyacrylamide gel electrophoresis to study the early expression of P22 genes we show that early expression of the ant-gene (imm I region) is turned off after 6-8 min, independent of the 'late' acting mnt-repressor. A semi-clear mutant called cir5 is defective for this early ant turn-off. The mutation cir5 maps in the imm I region of P22 between genes mnt and ant. P22 cir5 mutants are defective for a repressor which acts in trans to regulate early ant synthesis. There appears to be no absolute requirement of the cir5 allele for the establishment of lysogeny. The overproduction of ant in the P22 cir5 mutant leads to a marked increase in abortive infections, killing the infected cells. The cir5-phenotype can be suppressed by an ant- mutation.

The variation in frequency with which markers are transduced by phage P1 is primarily a result of discrimination during recombination

The efficiency of recovery of P1 transductants is marker dependent and normally varies over a 25-fold range. UV irradiation of either transducing lysates for recipient cells results in a selective stimulation of the transduction of markers which are normally transduced poorly. As a result the range in frequency of transduction is reduced to about 3-fold and resembles the gene frequency distribution expected in the donor cells. We conclude that P1 transducing lysates are likely to contain a random sample of donor DNA but that the recombination system of the recipient cell exhibits a preference for the DNA of some regions over that of others. Damage to DNA presumably overrides this specificity.

Regulation of coat protein polymerization by the scaffolding protein of bacteriophage P22

In the morphogenesis of double stranded DNA phages, a precursor protein shell empty of DNA is first assembled and then filled with DNA. The assembly of the correctly dimensioned precursor shell (procapsid) of Salmonella bacteriophage P22 requires the interaction of some 420 coat protein subunits with approximately 200 scaffolding protein subunits to form a double shelled particle with the scaffolding protein on the inside. In the course of DNA packaging, all of the scaffolding protein subunits exit from the procapsid and participate in further rounds of procapsid assembly (King and Casjens. 1974. Nature (Lond.). 251:112-119). To study the mechanism of shell assembly we have purified the coat and scaffolding protein subunits by selective dissociation of isolated procapsids. Both proteins can be obtained as soluble subunits in Tris buffer at near neutral pH. The coat protein sedimented in sucrose gradients as a roughly spherical monomer, while the scaffolding protein sedimented as if it were an elongated monomer. When the two proteins were mixed together in 1.5 M guanidine hydrochloride and dialyzed back to buffer at room temperature, procapsids formed which were very similar in morphology, sedimentation behavior, and protein composition to procapsids formed in vivo. Incubation of either protein alone under the same conditions did not yield any large structures. We interpret these results to mean that the assembly of the shell involves a switching of both proteins from their nonaggregating to their aggregating forms through their mutual interaction. The results are discussed in terms of the general problem of self-regulated assembly and the control of protein polymerization in morphogenesis.

Membrane binding of bacteriophage SPP1 DNA

A fast sedimenting complex was isolated from B. subtilis cells infected with bacteriophage SPP1 by renografin centrifugation. This complex was identified as membrane bound parental and replicating SPP1 DNA. Synthesis of SPP1 DNA takes place in close association with the membrane. This newly synthesized DNA is then released into the cytoplasm. During release, concatemeric SPP1 DNA is sized into monomeric DNA molecules.

Growth of Salmonella bacteriophage P22 in Escherichia coli dna(Ts) mutants

Salmonella bacteriophage P22 grows in two deoxyribonucleic acid initiation mutants of Escherichia coli under nonpermissive conditions, dnaA and dnaC. Functional products of genes dnaE, dnaZ, lig, dnaK, and dnaG are indispensable for deoxyribonucleic acid replication of P22. In 11 E. coli dnaB mutants belonging to all phenotypic groups, phage were produced at 42 degrees C.

Studies on the mechanism of transduction by bacteriophage phi gamma. II. Formation of transducing elements

The formation of the transducing elements (TE) of bacteriophage phi gamma, analyzed in lysogens of the thermo-inducible derivative phi gamma hyI, has been found to parallel the formation of plaque-forming particles with a frequency of 2 X 10(-2) TE/PFU, but is mor sensitive to temperature and ti UV. Deletion of one of the prophage termini (attR) prevents normal excision and formation of plaque-forming particles, but does not affect the formation of transducing elements, which arise at a rate of nearly 10(-1) TE per induced bacterium. Transducing elements, would be formed by in situ encapsulation of a hybrid segment from a specidic point in the induced prophage, possibly the presumed packaging initiation site of the normal phage genome, before excision of the latter has occurred. Analysis of the mechanism of transduction to partly heterologous lysogens has revealed the participation of a co-infecting genome arranged in a linear fashion and has given evidence for a permutation in the sequence of transducing and nontransducing genomes. The data re consistent with a mechanism of encapsidation distinct from the Ter system even for hybrids inheriting part of the phi 80 genome, but endowed with the property to form transducing elements like those of phi gamma. Upon infection, transducing elements are formed after one cycle of lytic development with the same characteristics as those resulting from induction, but with a frequency 50 to 100 times lower. This process is dependent on the efficiency of Int promoted recombination. Superinfection experiments performed under conditions preventing Int promoted recombination reveal that any superinfecting phi gamma can promote the formation of transducing particles, depending on the presence within the host prophage of a site from which transducing genome packaging initiates.

Phaseolotoxin transport in Escherichia coli and Salmonella typhimurium via the oligopeptide permease

Phaseolotoxin [(N delta-phosphosulfamyl)ornithylalanylhomoarginine], a phytotoxic tripeptide produced by Pseudomonas syringae pv. phaseolicola that inhibits ornithine carbamoyltransferase, is transported into Escherichia coli and Salmonella typhimurium via the oligopeptide transport system (Opp). Mutants defective in oligopeptide permease (Opp-) were resistant to phaseolotoxin. Spontaneous phaseolotoxin-resistant mutants (Toxr) lacked the Opp function as evidenced by their cross-resistance to triornithine and failure to utilize glycylhistidylglycine as a source of histidine. Growth inhibition by phaseolotoxin was prevented by peptides known to be transported via the Opp system and by treatment of the toxin with L-aminopeptidase. In both E. coli and S. typhimurium, Toxr mutations were cotransducible with trp, suggesting that the opp locus occupies similar positions in genetic maps of these bacteria.

Fluorescence changes of a membrane-bound dye during bacteriophage T5 infection of Escherichia coli

The fluorescence intensity of membrane-bound N-phenyl-1-naphthylamine increases dramatically when T5 bacteriophage infect colicin Ib plasmid-containing hosts. This dramatic increase is not seen during normal infections or in infections wherein either the plasmid or the phage contain mutations which allow productive infection to occur. Two smaller increases in fluorescence intensity are seen, however, in all T5 infections in which the characteristic two-step injection of DNA can proceed.

Host transcription in bacteriophage P22-infected Salmonella typhimurium

The kinetics of host RNA synthesis, as measured by pulse-label kinetics and RNA-DNA hybridization, is inhibited 10-fold shortly after infection with bacteriophage P22. This early inhibition lasts through the first 6 min of infection and affects not only RNA synthesis but several other energy-requiring cellular functions. In lysogenic infections, the rate of bacterial transcription rapidly recovers to the value of uninfected controls. In lytic infections, the rate of host transcription increases only to about 20 to 25% of the original level, indicating a second mechanism for the inhibition of RNA synthesis in the lytic response. The early inhibition is multiplicity dependent, bhloramphenicol insensitive, and independent of phage gene 24. The lytic inhibition is dependent upon the expression of gene 24 but independent of gene 23.

Regulation of late functions in Salmonella bacteriophages P22 and L studied by assaying endolysin synthesis

The rate of endolysin synthesis in Salmonella typhimurium cells infected by bacteriophage P22 or L was taken as a measure for the activity of 23 gene product (the positive regulator for the "late" genes of P22 and L). Endolysin in coded for by gene 19. The amber mutations in gene 23 of P22 and L, used in this study, reduced the rate of endolysin synthesis by a factor of ca. 90 for P22 and of ca. 20 for L. In mixed infections with 19- and 23- mutants the 23 gene products of P22 and L ACT As positive regulators for the respective gene 19 in cis and in trans. Cross-specificity of the 23 gene products, i.e., turning on expression of gene 19 on a chromosome of the other species, could not be demonstrated.

Specificity in formation of type II F' plasmids

Eight new F' plasmids derived from Hfr strains in which F is integrated at the chromosomal element alpha 3 beta 3 have been isolated and subjected to restriction enzyme, hybridization, and electron microscope heteroduplex analysis. Plasmids carrying extensive amounts of bacterial deoxyribonucleic acid were produced even though they were obtained by selection for transfer of lac, which is closely linked to F in the parental Hfr strains. Seven plasmids were type II Flac+ proC+ purE+ plasmids, and one was a type I Flac+ proC+ plasmid. Five of the Flac+ proC+ purE+ plasmids contain approximately 284 kilobases of bacterial deoxyribonucleic acid, which is identical for all five within the resolution of the restriction enzyme analysis. Theses results indicate that type II F' plasmids are the predominant tra+ F' type from this region of the Escherichia coli K-12 chromosome and that the recombination events leading to formation of these plasmids exhibit site specificity.

Origin and binding specificity of protein(s) coded for by Mu prophages

Crude extracts of bacteria lysogenic for temperature phage Mu contain proteins that retain specifically Mu DNA on nitrocellulose filters. The amount of binding protein is directly proportional to the number of Mu prophages per E. coli genome. Specificity of the binding reaction could be demonstrated by using heterologous DNAs as substrate and by a competition experiment. By using hybrid plasmids containing different amounts of the immunity end and extending to various degrees into MuDNA, it was found that the binding activity is coded for by the left 1,000 nucleotide-pair HindIII fragment. When using these hybrid plasmids as binding substrate, two different binding sites for the immunity product were detected. Joining of the MucI gene to the left lambda early promoter resulted in increased production of immunity protein at elevated temperature. A possible explanation for the relatively low amounts of immunity protein in all of the different strains studied is discussed.