Isolation and characterization of specialized lambda transducing bacteriophage carrying the metBJF methionine gene cluster.

Secondary attachment site lysogens of Deltaatt(lambda)Deltappc-argECBH strains of Escherichia coli with lambdacI857 integrated into the bfe gene (88 min) were isolated. Of 20 such lysogens examined, 2 produce lysates with transducing phage containing the metBJF gene cluster (87 min). Reintroduction of the ppc-argECBH chromosome segment (which lies between the bfe and met genes) into these strains virtually abolishes the production of met transducing phage. All of the phage examined have lost essential genes from the left arm of the lambda chromosome. Approximately 85% of the phage appear to have the same genetic composition, containing the metBJF gene cluster, but not the closely linked gene cytR, and having lost phage genes G and J. Analytical CsCl density gradient centrifugation of five representatives of this major class of phage shows four of them to have identical densities (lighter than lambda), while the fifth cannot be resolved from lambda. The four apparently identical phage were isolated from three separate lysates, which suggests the existence of preferred sites for illegitimate recombination on the bacterial and phage chromosomes. Three specialized transducing phage that carry cytR in addition to metB, metJ, and metF have also been studied. Each of these viruses has a different amount of phage deoxyribonucleic acid. Two of them have less deoxyribonucleic acid than lambda, whereas the third has about the same amount. The metB, metF, and cytR genes of the transducing phage have been shown to function in vivo. The phage-borne metB and metF genes are subject to metJ-mediated repression.     

Molybdenum cofactor requirement for biotin sulfoxide reduction in Escherichia coli.

The bisC gene of Escherichia coli is tentatively identified as the structural gene for biotin sulfoxide reductase by the isolation of bisC(Ts) mutants that make thermolabile enzyme. The products of four other E. coli genes (chlA, chlB, chlE and chlG) are also needed for enzymatic activity. Mutations previously assigned to the bisA, bisB, and bisD genes belong to genes chlA, chlE, and chlG, respectively. The biotin sulfoxide reductase deficiency of a chlG, mutant is partially reversed by the addition of 10 mM molybdate to the growth medium. Mutational inactivation of the chlD gene reduces the specific activity of biotin sulfoxide reductase about twofold. This effect is reversed by the addition of 1 mM molybdate to the growth medium. The specific activity of biotin sulfoxide reductase is decreased about 30-fold by the presence of tungstate in the growth medium, an effect that has been observed previously with nitrate reductase and other molybdoenzymes. The specific activity of biotin sulfoxide reductase is not elevated in a lysate prepared by derepressing a lambda cI857 chlG prophage. Whereas biotin sulfoxide reductase prepared by sonic extraction of growing cells is almost completely dependent on the presence of a small heat-stable protein resembling thioredoxin, much of the enzyme obtained from lysates of thermoinduced lambda cI857 lysogens does not require this factor.     

Isolation of Plaque-Forming, Galactose-Transducing Strains of Phage Lambda

Plaque-forming, galactose-transducing lambda strains have been isolated from lysogens in which bacterial genes have been removed from between the galactose operon and the prophage by deletion mutation.—A second class has been isolated starting with a lysogenic strain which carries a deletion of the genes to the right of the galactose operon and part of the prophage. This strain was lysogenized with a second lambda phage to yield a lysogen from which galactose-transducing, plaque-forming phages were obtained. These plaque-forming phages were found to be genetically unstable, due to a duplication of part of the lambda chromosome. The genetic instability of these partial diploid strains is due to homologous genetic recombindation between the two identical copies of the phage DNA comprising the duplication. The galactose operon and the duplication of phage DNA carried by these strains is located between the phage lambda P and Q genes.     

A functional domain of bacteriophage lambda terminase for prohead binding

Terminase is a multifunctional protein complex involved in DNA packaging during bacteriophage lambda assembly. Terminase is made of gpNul and gpA, the products of the phage lambda Nu1 and A genes. Early during DNA packaging terminase binds to lambda DNA to form a complex called complex I. Terminase is required for the binding of proheads by complex I to form a DNA: terminase: prohead complex known as complex II. Terminase remains associated with the DNA during encapsidation. The other known role for terminase in packaging is the production of staggered nicks in the DNA thereby generating the cohesive ends. Lambdoid phage 21 has cohesive ends identical to those of lambda. The head genes of lambda and 21 show partial sequence homology and are analogous in structure, function and position. The terminases of lambda and 21 are not interchangeable. At least two actions of terminase are involved in this specificity: (1) DNA binding; (2) prohead binding. The 1 and 2 genes at the left end of the 21 chromosome were identified as coding for the 21 terminase. gp1 and gp2 are analogous to gpNu1 and gpA, respectively. We have isolated a phage, lambda-21 hybrid 33, which is the product of a crossover between lambda and 21 within the terminase genes. Lambda-21 hybrid 33 DNA and terminase have phage 21 packaging specificity, as determined by complementation and helper packaging studies. The terminase of lambda-21 hybrid 33 requires lambda proheads for packaging. We have determined the position at which the crossover between lambda DNA and 21 DNA occurred to produce the hybrid phage. Lambda-21 hybrid 33 carries the phage 21 1 gene and a hybrid phage 2/A gene. Sequencing of lambda-21 hybrid 33 DNA shows that it encodes a protein that is homologous at the carboxy terminus with the 38 amino acids of the carboxy terminus of lambda gpA; the remainder of the protein is homologous to gp2. The results of these studies define a specificity domain for prohead binding at the carboxy terminus of gpA.     

New transducing phage with RNA polymerase beta- and beta'-subunit genes derived from a hybrid phage lambda att80: isolation, genetic analysis and physical mapping]

A hybrid lambda att 80 phage with the genetic structure lambda (A-J) phi 80 (att-int-xis) imm lambda..cI857s7 is shown to be a convenient vector for creating transducing phages. On the one hand, the restriction analysis indicates that it has 3 restriction sites for EcoRI in comparison with 5 and 9 sites for parental phages lambda and phi 80 respectively. On the other hand, its buoyant density is less than that of phage lambda and under centrifugation it is easier separated from the phage transducing particles. When lambda att 80 prophage was excluded from the bfe locus of Escherichia coli, transducing phages with genes of two RNA polymerase beta-subunits (rpoB and rpoC) were isolated. To identify the latter, a convenient genetic test was worked out. A physical map of lambda att 80 drifd 35 transducing phage, carrying rpoB and rpoC genes has been constructed using endonucleases EcoRI and HindIII. A comparison of this map and the corresponding maps of transducing phages lambda drifd 18 and lambda drifd 47, studied earlier, led to the discovery of two integration sites of phage lambda within the locus bfe spaced apart by about 1800 nucleotide pairs. At all the sites both phages (lambda and lambda att 80) have integrated in the locus bfe in the counter clockwise order.     

Isolation of Lambda Transducing Phage with the bio Genes Inserted between Lambda Genes P and Q

Plaque-forming, biotin-transducing phages were constructed with the bio genes inserted between lambda genes P and Q. These phages were isolated for the eventual aim of fusing the lambda Q gene to the bio operon. The following steps were used to construct these phages: A defective temperature-sensitive lysogen was constructed with the bio genes adjacent to and to the left of lambda genes beta NcI857OPQSRA. Heat-resistant survivors were screened for deletions with endpoints in the bio operon and to the right of lambda P and to the left of lambda A. Five of approximately 1,600 heat-resistant survivors had these properties. Two had the gene order bioAB .... lambda QSRA. When these two strains were lysogenized with lambda cI857b221 and heat induced, the desired transducing phages were obtained. We characterized these phages and studied one in detail. Two-thirds of the plaque-forming transducing phages isolated carried the entire bioB gene and only part of the bioA gene, and one-third carried the entire bioA and bioB genes. The phages isolated lost the bio genes upon propagation, indicating that they contain a partial duplication of phage genes. The duplication was shown not to involve the entire lambda Q gene in one of these phages, lambda bioq1b221. A recombinant of this phage, lambda Nam7am53c17b221, failed to form plaques under biotin-derepression conditions. We conclude that if the lambda Q gene was fused to the bio operon in this phage, not enough lambda Q gene product was made to allow phage propagation.     

Direct and general selection for lysogens of Escherichia coli by phage lambda recombinant clones.

We report a simple in vivo technique for introducing an antibiotic resistance marker into phage lambda. This technique could be used for direct selection of lysogens harboring recombinant phages from the Kohara lambda bank (a collection of ordered lambda clones carrying Escherichia coli DNA segments). The two-step method uses homologous recombination and lambda DNA packaging to replace the nonessential lambda DNA lying between the lysis genes and the right cohesive (cos) end with the neomycin phosphotransferase (npt) gene from Tn903. This occurs during lytic growth of the phage on a plasmid-containing host strain. Neomycin-resistant (npt+) recombinant phages are then selected from the lysates containing the progeny phage by transduction of a polA1 lambda lysogenic host strain to neomycin resistance. We have tested this method with two different Kohara lambda phage clones; in both cases, neomycin resistance cotransduced with the auxotrophic marker carried by the lambda clone, indicating complete genetic linkage. Linkage was verified by restriction mapping of purified DNA from a recombinant phage clone. We also demonstrate that insertion of the npt+ recombinant phages into the lambda prophage can be readily distinguished from insertion into bacterial chromosomal sequences.     

Mapping of the c-region of phage phi80

A set of c-mutants of the phage phi80 is isolated. These mutants fit into three genes. According to plaque morphology and frequency of lysogenization of mutants, the genes were named cI, cII and cIII as it was previously done for phage lambda. Their order, determinated by mutant phage crosses, is cIII-sus326-cI-cII-sus250. Sus326 is a mutation in the gene 15, so it is probably an analogue of the N gene of the phage lambda. Thermoinducible mutants of the phage phi80 cts11 and cts12 correspond to the mutant types cItsB and cItsA of the phage lambda and they complement each other. Thus, it is supposed that phi80 phage repressor molecules consist of few protein subunits.     

Isolation of dominant negative mutants and inhibitory antisense RNA sequences by expression selection of random DNA fragments.

Selective inhibition of specific genes can be accomplished using genetic suppressor elements (GSEs) that encode antisense RNA, dominant negative mutant proteins, or other regulatory products. GSEs may correspond to partial sequences of target genes, usually identified by trial and error. We have used bacteriophage lambda as a model system to test a concept that biologically active GSEs may be generated by random DNA fragmentation and identified by expression selection. Fragments from eleven different regions of lambda genome, encoding specific peptides or antisense RNA sequences, rendered E. coli resistant to the phage. Analysis of these GSEs revealed some previously unknown functions of phage lambda, including suppression of the cellular lambda receptor by an 'accessory' gene of the phage. The random fragment selection strategy provides a general approach to the generation of efficient GSEs and elucidation of novel gene functions.     

Transposition of lambda placMu is mediated by the A protein altered at its carboxy-terminal end

Lambda placMu phages are derivatives of bacteriophage lambda that use the transposition machinery of phage Mu to insert into chromosomal and cloned genes. When inserted in the proper fashion, these phages yield stable fusions to the Escherichia coli lac operon in a single step. We have determined the amount of DNA from the c end of phage Mu present in one of these phages, lambda placMu3, and have shown that this phage carries a 3137-bp fragment of Mu DNA. This DNA segment carries the Mu c-end attachment site and encodes the Mu genes cts62, ner+, and gene A lacking 179 bp at its 3' end (A'). The product of this truncated gene A' retains transposase activity and is sufficient for the transposition of lambda placMu. This was demonstrated by showing that lambda placMu derivatives carrying the A am1093 mutation in the A' gene are unable to transpose by themselves in a Su- strain, but their transposition can be triggered by coinfection with lambda pMu507(A+ B+). We have constructed several new lambda placMu phages that carry the A' am1093 gene and the kan gene, which confers resistance to kanamycin. Chromosomal insertions of these new phages are even more stable than those of the previously reported lambda placMu phages, which makes them useful tools for genetic analysis.     

Interspersion of histone and 5S RNA genes in Artemia

Four recombinant lambda phage containing histone genes were selected from a library of Artemia genomic DNA fragments. The histone gene organization of Artemia resembles that of other invertebrates in that all five genes are clustered and repeated in tandem with approximate repeat lengths of 8.5 kb and 9.3 kb. Each recombinant lambda phage isolate hybridizes with five histone mRNAs and unexpectedly also with 5S ribosomal RNA. Hybridization kinetics have shown the number of histone genes to be about 95-100 copies per haploid genome. An identical number of copies was determined for a hybridization probe containing the 5S gene but no histone genes. We have not found any evidence for a separate set of repeated 5S genes outside this histone + 5S block.     

Restrictase BamHI, HindII, EcoRI and SmaI mapping of hybrid lambda-phi 80 phages with recombination in the structural gene region

Hybrids lambda H lambda T80 with recombination in the region of structural genes have lambda head and phi 80 tail genes. In this paper the molecular structure of 5 independently isolated hybrids was established using restriction endonucleases. It has been shown that all of them have a recombinant head or tail. A deletion of 4,8% lambda was demonstrated in the immunity region of phi 80vir phage. Co-ordinates of restriction sites for BamHI, HindIII, EcoRI and SmaI restriction endonucleases on phi 80 DNA were calculated.     

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.     

Characterization of a bacteriophage that carries the genes for production of Shiga-like toxin 1 in Escherichia coli.

The Shiga-like toxin 1-converting bacteriophage H-19B was recently shown to carry the structural genes for the toxin and was shown to have DNA sequence homology with phage lambda. We present evidence that the linear genome of bacteriophage H-19B has cohesive termini which become covalently associated during prophage integration. Integration occurs through a site on a 4-kilobase-pair EcoRI fragment located near the center of the bacteriophage chromosome. The relationship between bacteriophages H-19B and lambda was examined by Southern hybridization. Homologous regions were mapped on the respective chromosomes which corresponded to the regions of the J gene, the int-xis area, and the O and P genes of phage lambda. The H-19B tox genes were mapped to the right of the O and P gene homology, which was far away from the phage attachment site. We concluded that H-19B is a lambdoid bacteriophage. Unlike other toxin-converting bacteriophages, the toxin genes were not located adjacent to the phage attachment site. It appeared that the Shiga-like toxin 1 genes were not picked up by a simple imprecise prophage excision. H-19B could, however, have acquired chromosomally located toxin genes by a series of events involving deletion and duplication followed by aberrant excision.     

Rec-Mediated Recombinational Hot Spot Activity in Bacteriophage Lambda. I. Hot Spot Activity Associated with Spi- Deletions and bio Substitutions

In order to survey the distribution along the bacteriophage lambda chromosome of Rec-mediated recombination events, crosses are performed using conditions which block essentially all DNA synthesis. One parent is density-labeled and carries a genetic marker in the left terminal lambda gene (A), while the other parent is unlabeled and carries a genetic marker in the right terminal lambda gene (R). Both parents are deleted for the lambda recombination genes int and red, together with other recombination-associated genes, by virtue of either (1) a pure deletion or (2) a bio insertion-deletion. The distribution in a cesium density gradient of the resulting A+R+ recombinant phage reflects the chromosomal distribution of the recombination events which gave rise to those phage.Crosses employing either of two different pure deletion phage strains exhibit recombinational hot spot activity located near the right end of the lambda chromosome, between the cI and R genes. This hot spot activity persists when unlimited DNA synthesis is allowed. Crosses employing bio1-substituted phage strains exhibit recombinational hot spot activity located to the right of the middle of the chromosome and to the left of the cI gene. Crosses employing either bio1 or bio69-substituted phage strains indicate that the bio-associated hot spot activity occurs in the presence of DNA synthesis, but is dependent on a functional host recB gene.