Two kinds of insertions in bacterial genes

Summary Six insertion mutations in the gal operon of E. coli and two insertion mutations in the xycIIOP operon of bacteriophage lambda were tested for homology by annealing separated strands of lambda dgal DNA carrying the insertions, and inspection in the electron microscope.Class 1, consisting of the gal mutations OP 128, OP 141, T-N 116, OP 306, T-N 102 and the lambda mutation r14 are about 800 nucleotide pairs long, completely homologous and not circularly permuted. The first three insertions of class 1 are integrated in one direction with respect to the adjacent genes, the other three in the opposite direction. The DNA inserted in this class of mutations is called IS1.Class 2 consists of the gal insertion OP 308 and the lambda insertion r32. They are about 1400 nucleotide pairs long. The two are integrated in opposite direction with respect to the chromosome of dgal. The DNA in insertion mutations of class 2 will be called IS 2. IS1 and IS2 do not share any detectable homology.These data are supported by cross-hybridization experiments using RNA transcribed in vitro from lambda dgal or lambda DNA carrying one insertion and DNA carrying either the same or a different insertion.Similar results were obtained by Malamy, Fiandt, Szybalski and Fiandt, Szybalski, Malamy (accompanying papers).     

O0 and strong-polar mutations in the gal operon are insertions

Summary Three dg phages carrying strong-polar mutations in the gal operon are denser than the corresponding phages carrying the wildtype gal operon or reversions of the mutations to the Gal ⁺ phenotype. The latter phages have the same density. It is concluded that these strong-polar mutations are insertions of DNA into the gal operon.The amount of inserted DNA is different in the three mutations and is calculated to be 450, 1,080 and 1,800 nucleotide pairs respectively.The strong-polar phenotype is also found in a mutant supplied by A. Taylor which carries a Mu-1 phage integrated into the transferase gene.     

Deletion mapping of galactose mutants with transducing lambda phages

Summary The present mapping studies in the gal region of E. coli are a continuation of experiments reported previously (Pfeifer and Oellermann, 1967).By mapping of 238 gal mutants against 145 deletions of the gal region carried by dg phages the kinase gene could be divided into 14 and the transferase gene into 19 deletion groups¹. Results of quantitative transduction experiments strongly suggest that there are preferred endpoints for the deletions.     

Fertility functions of resistance factors

Summary The isolation of transducing phages carrying the tolPAB cluster is described. These genes map between gltA and gal in Escherichia coli, and thus are relatively close to att. To isolate these transducing phages, it was necessary to use a strain deleted of most of the intervening genes (nadA to chlD) between tolPAB and att. Using a lysogen of such a deletion strain, several defective dtol phages were isolated that carry different amounts of the tolPAB cluster.All of these dtolPAB phages were defective in both lysogenization and vegetative growth, and in this respect were similar to dgal transducing phages.The usefulness of such specialized transducing phages in studying the cell surface is discussed.Research Fellow of the National Cancer Institute of Canada.     

Fusion of the lac genes to the promotor for the cytidine deaminase gene of Escherichia coli K-12

Summary Phage Mu has been inserted into the structural gene for cytidine deaminase (cdd). By the use of phage (lac, Mu) the promoter for the cdd gene has been fused to lacZ. In these strains lacZ expression is regulated by the cytR repressor protein and is therefore induced by cytidine. The fusion strains were used for the isolation of cddo mutants. Plaque forming phages carrying the different cdd-lacZ fusions were isolated. Studies of the cdd-Mu strains showed that the cdd gene is transcribed clockwise with respect to the Escherichia coli map.     

Identification of the C. coli dnaK (groPC756) gene product.

Summary The E. coli dnaK (groPC756) gene product is essential for bacteriophage DNA replication. Bacterial DNA segments carrying this gene have been cloned onto a bacteriophage vector. The product of the dnaK gene has been identified on SDS polyacrylamide gels after infection of UV-irradiated E. coli cells. The dnaK gene codes for a polypeptide with an apparent molecular weight of 93,000-Mr. Transducing phages carrying amber mutations in the dnaK gene fail to induce the synthesis of the 93,000-Mr polypeptide chain upon infection of sup ⁺ bacteria, but do so upon infection of supF bacteria. E. coli carrying the dnaK756 mutation are, in addition, temperature sensitive for growth at 43° C. It is shown that the dnaK756 mutation results in an overproduction of the dnaK gene product at that temperature.     

Mapping of gal minus-mutants by transducing lambda dg carrying deletions of the gal-region

Summary To map numerousgal ^--mutants ofE. coli, advantage is taken of the fact that transducing dg's can carry different amounts of bacterial DNA of the host from which they originated (Adler andTempleton, 1963).A method is described with which a large number of transducing dg can be easily isolated, differing from each other with respect to the amount of bacterial DNA of thegal-region. By observing whethergal ⁺-colonies can arise as the result of recombination betweengal ^--mutants and dg's carrying deletions in thegal-region, so far 104 kinaseless mutants and 96 transferaseless mutants could be ordered into 26 groups. The mapping-tests were done by spotting the mutants with 52 HFT-lysates of dg's lacking more or less of the kinase- or the kinase- and transferase gene.     

Cloning of the replication gene P of bacteriophage lambda: Effects of increased P-protein synthesis on cellular and phage DNA replication

Summary A restriction fragment of DNA carrying the P gene was cloned in the high copy number plasmid RSF2124. Cells harbouring this new plasmid RSF2124/E complement Pam80 phage. A lac promoter-operator region (lacP), produced by EcoRI digestion of plasmid pKB252, was inserted into RSF2124/glE such that induction of the lac promoter by IPTG or lactose leads to increased production of the P gene product. A high amount of P protein in E. coli cells results in a slow inhibition of bacterial DNA synthesis, suggesting that the initiation reaction is blocked by P protein. Synthesis of DNA proceeds normally under these conditions.Nonsuppressing groPA15 mutant bacteria which are unable to support the replication of wild-type (wt), acquire the ability to replicate Pam80 phage but not wt when they are transformed with a plasmid carrying the P gene. When harbouring a plasmid containing the mutant Pamber 80 gene, groPA15 mutants are able to support the replication of wt phage when infected at a high multiplicity. Pam80 phage does not multiply in these cells.     

A transducing lambda phage carrying grpE, a bacterial gene necessary for lambda DNA replication, and two ribosomal protein genes, rpsP (S16) and rplS (L19).

Summary A grpE mutation of Escherichia coli K12, which blocks DNA replication of the phage (Saito and Uchida, 1977), was mapped at 56 min on the standard genetic map. A transducing phage, grpE22, carrying the wild type allele of the grpE gene was constructed in vitro. Structures of grpE22 and its viable deletion derivatives were determined by electron microscopic analyses of appropriate heteroduplexes. Proteins coded by the bacterial DNA incorporated into the transducing phages were detected by two-dimensional gel electrophoresis. The results showed that the product of the grpE gene is a weakly acidic protein of molecular weight 24,000. Structural genes for two ribosomal proteins, rplS (L19) and rpsP (S16) were also shown to be carried by grpE22.     

Studies on radiation-sensitive mutants of E. coli. II. Breakage and repair of ultraviolet irradiated intracellular DNA of phage lambda

Summary It has been shown that linear DNA molecules of phage are converted to the twisted circular structure (species I) by covalent closure of the both strands at the cohesive ends after infection to the immune bacteria and that the twisted circular molecules are transformed to the circular form (species II) by a single-strand break in one of the strands of their DNA. This system offers a very sensitive method to study on the strand breaks or their repair. For characterization of the defects of ultraviolet sensitive strains, the structural changes of ultraviolet irradiated DNA in these strains were studied.Ultraviolet irradiation to phage greatly reduced the extent of conversion of the molecules to the species I in the uvrD mutant while the irradiation showed little effect on the conversion in the uvrA, B and C mutants. When infected bacteria carrying species I molecules were irradiated, the species I molecules in the uvrD mutant were disrupted while most of the molecules in the uvrA, B and C mutants kept the structure. These results indicate that in the irradiated DNA strand breaks are rarely introduced or, if introduced, repaired rapidly in the uvrA, B and C mutants and they are introduced in the uvrD mutant leading to the degradation of the DNA. These results provide a firm evidence that the defect of the uvrD mutant is different from other Her^- mutants and in the process of repair synthesis.Ultraviolet irradiation to the uvrD mutants promote the formation of the species I molecules from the infected irradiated -DNA.Such effect was not observed with the uvrA mutant. Since the uvrD mutant has UV reactivation capacity and the uvrA mutant has not, the above phenomenon is probably caused by UV reactivation and may provide a more direct method to study the mechanisms of UV reactivation than the plaque assay.Abbreviations used UV Ultraviolet light - UVr Ultraviolet light reactivation This work was aided in part by a research grant GM 08384 from the United States Public Health Service.     

Host specificity of DNA produced by Escherichia coli. XVI. Phage lambda DNA carries a single site of affinity for A-specific restriction and modification

Summary Bacteria with A-specific restriction plate unmodified phage with an efficiency of 10^-2. One mutational event can produce restriction insensitive (sA^o) mutants of . These differ from the original sA form of by no other property than their response to A-host specificity. Two-parental phage crosses involving sA and sA^o, respectively, as non-selective marker allowed to map sA between genes cII and O. These data indicate that sA is the only site on DNA with affinity for A-specific restriction. DNA is thus an interesting substrate in in vitro A-specific restriction and modification. Using an assay based on the infectivity of DNA on helper-infected bacteria, A-specific modification activity was found in partially purified sonicates of bacteria with A-host specificity. In parallel to modification, ³H-methyl label from s-adenosylmethionine, the only cofactor required for modification, was transferred to unmodified DNA. No association of radioactivity was observed in control experiments with DNA from either modified ·A or from asA^o mutant. These data suggest that A-specific modification is brought about by DNA methylation and that the sA^o mutation not only abolished the affinity for A-specific restriction, but also for A-specific modification.     

Explanations accounting for transduction by bacteriophage lambda in maltose negative bacteriophage lambda resistant mutants of Escherichia coli K-12.

Summary Entry of DNA from phages particles into rMal^- mutants of Escherichia coli K-12 is shown to be due to two distinguishable processes. One, residual transduction, results from a low level expression of lamB. The other one, background transduction, is independent of gene lamB.Interpretations are presented for these results. It is proposed that residual transduction is due to a weak promoter pB3 located within or near the distal part of the gene preceeding lamB in the same operon. It is proposed that background transduction is due to a secondary receptor structure for phage . Finally a tentative hypothesis relating pB3 to insertion sequences is presented.     

Construction of a gene bank and identification of the ribulose bisphosphate carboxylase/oxygenase genes from the nutritionally versatile cyanobacterium Chlorogloeopsis fritschii

A gene bank of the nutritionally versatile, nitrogen-fixing cyanobacterium Chlorogloeopsis fritschii was constructed in Charon 4A. 2,800 recombinants containing 10–20 kbp C. fritschii DNA fragments were screened by Southern hybridization using probes containing the genes for the large (LSU) and small (SSU) subunits of ribulose bisphosphate carboxylase/oxygenase (RuBisCO) from Anacystis nidulans. A single recombinant plaque (CDG1) containing a 10.9 kbp EcoR1 fragment from C. fritschii hybridized to both the LSU and SSU probes, indicating a possible linkage of these RuBisCO genes in C. fritschii. RuBisCO activity and protein were detected in CDG1 lysates of Escherichia coli. Hybridization was also obtained between C. fritschii DNA and the LSU probe from Chlamydomonas reinhardtii, although no homology was detected using the LSU probe from maize or the SSU probe from pea.Abbreviations RuBisCO d-ribulose 1,5-bisphosphate carboxylase/oxygenase - RuBP d-ribulose 1,5-bisphosphate - LSU large subunit of RuBisCO - SSU small subunit of RuBisCO - SDS sodium dodecyl sulphate - DOC deoxycholate     

Integration specificity of an artificial kanamycin transposon constructed by the in vitro insertion of an internal Tn5 fragment into IS2

Summary IS2 has been marked genetically by the in vitro insertion into its HindIII site of a 3.3 Kb HindIII fragment of Tn5 conferring resistance to kanamycin. The transposition of the IS2::Km, thus obtained, to has been found and insertion sites were characterised. Each of ten independent IS2::Km insertions were found at the same site at 61.2% of the map, always in the same orientation (orientation II relative to the xis gene). The integration sites of IS2::Km in five of the kanamycin-transducing phages were determined by DNA sequence analysis, and were found to be identical at the nucleotide level. Further transposition of IS2::Km from to the bacterial chromosome was demonstrated.     

Investigations of the F conjugation gene traI:traI mutants and lambdatraI transducing phages.

Summary A series of traI point and deletion mutants of Flac, and a traM mutant, were characterised. Complementation tests with an amber Flac traI mutant confirmed their genotypes, and in addition all the traI mutants, but not the traM mutant, were complemented by pRS31 (pSC101 traDI) and ED109 (traI). Judging from the efficiencies of plating of F-specific phages, none of the mutations affected pilus formation. The traI products of F and of the F-like plasmid R1 were interchangeable with each other but not with that of R100, while the traM product of F could not be replaced by those of R1 or of R100. Neither traI nor traM were needed for conjugal transfer of ColE1.Three transducing phages carrying traI were isolated by in vivo or in vitro techniques, and characterised by genetic complementation tests, by analysis of the fragments produced by restriction endonucleases, and by measurement of heteroduplex molecules. The genetic structures together with the sizes and F coordinates, of the transfer regions carried by the phages were thereby determined.Comparison of the proteins synthesised in UV-irradiated cells by one of the raI phages with those made by a derivative carrying an amber traImutation, allowed the traI product to be identified as a protein of molecular weight 174,000. In addition, the molecular weights of the traD (84,000), traS (18,000), and traT (25,000) products made by the traSTDI phage ED107 were measured.The possible roles of the traI and traM products in conjugation are discussed.     

Construction and some properties of packageable plasmid F

Summary A derivative of plasmid F which is packageable in phage coat was constructed using techniques of in vitro recombination. This plasmid is composed of three DNA fragments generated by restriction enzyme EcoRI: a miniF fragment (fragment f5 of F'lac) which is able to replicate autonomously, a DNA fragment from Staphylococcus Plasmid that carries the -lactamase gene, and a portion of guaA (B) transducing phage DNA carrying cohesive ends (cos site) along with almost all the late genes but devoid of all those genes and sites that are needed for replication, regulation, and recombination. The hybrid plasmid has a molecular weight of 2.7×10⁷ daltons, about 84% size of phage genome, and can be packaged in coat when helper phage replicates in the plasmid-carrier cell. The package plasmid and the helper phage particles are separated by CsCl density gradient centrifugation. The replication characteristics of the recombinant plasmid are all those of F including the copy number, incompatibility, and curing with acidine orange. The packaged plasmid is injected into an F^- cell and establishes a plasmid state with normal efficiency. In F⁺ or Hfr cells, the resident F factor hinders this process.     

Structure and function of the repressor of bacteriophage lambda

Summary By mutagenizing a cIts (cI857) lysogen, a mutant has been isolated with a wild-type phenotype. This mutant phage lysogenizes with low efficiency and produces a low burst. Though the initial rates of repressor synthesis in Escherichia coli after infection with wild-type and mutant are the same, the maximum level of repressor that is synthesized in the latter case is only about 30% of that synthesized in the former. Virulent plates on the lysogen of mutant with slightly less efficiency producing very tiny plaques. Operator-binding studies made in vitro with purified mutant and wild-type repressors show that the binding curve of the former repressor is a rectangular hyperbola while that of the latter is sigmoid. The half-lives of the complexes of mutant and wild-type repressors with right operator are 133 and 27 min, respectively. All these results suggest that the mutant repressor possibly has a higher affinity for the operators. This mutant has been named cIha (ha=high affinity).     

Utilization of promoter regions of coliphage lambda in Bacillus subtilis

Summary In vivo studies with galactokinase monitoring system demonstrated that the coliphage lambda P_RP_L promoter regions could be utilized in B. subtilis. These promoter regions were preferentially utilized during the stationary growth phase of B. subtilis. However, these promoter regions were not controlled by the cI₈₅₇ gene at permissive or non-permissive temperature in B. subtilis, although the P _RM promoter was utilized in B. subtilis. S1-nuclease mapping suggests that B. subtilis RNA polymerase recognizes specific sequences in P _R promoter region that is not utilized in E. coli.     

Lambda phage mutants insensitive to temperature-sensitive repressor

Summary Weak-virulent mutants of temperate coli-phage were isolated which can grow on the CIts lysogen producing a temperature-sensitive repressor but which cannot grow on the wild type lysogen producing a normal repressor.Genetic analysis on the mutants shows that their weak-virulence is attributable to two mutations, one (virL) in the region between sus N₂₁₃ and c ₄₇ and the other (virR) in the region between c ₁ and sus O₈. Both mutations are located within the region of non-homology between and imm ⁴³⁴ phages.True virulent mutants which can grow on the wild type lysogen can be obtained easily from the weak-virulent mutant by an additional mutation, virC in a region very close to virR. The virulent mutants obtained are similar to the classical vir mutant (Jacob and Wollman, 1954). The virL and virR mutations are probably operator mutations which render the genome insensitive to the repressor.This work was reported at the XII th International Congress of Genetics, held in Tokyo, on August 23, 1968.     

Analysis of a temperature sensitive mutation in gene cII of bacteriophage lambda

Summary The mutation cIIts612 was found to map outside the immunity region of phage imm21 hybrid. As expected of a cII mutation, cIIts612 is unable to stimulate either cI repressor or Int synthesis during the establishment of lysogeny. These results indicate that part of the cII gene of is homologous to that of imm21 phage.