A mutation in Escherichia coli enhancing the UV-mutability of phage lambda but not of its infectious DNA in a spheroplast assay

Summary A mutant (called mul) has been isolated from E. coli AB1157 which increases up to 13 fold the rate of clear plaque mutations of extracellularly UV-irradiated phage . The mul-mutation does not affect the UV-mutability of T4rII mutants or various bacterial markers and therefore seems to act specifically on UV-irradiated phage . However, when spheroplasts prepared from mul cells were infected with either irradiated or unirradiated -DNA equal frequencies of clear plaques were produced. As there is indirect evidence (host cell reactivation) that the spheroplasts do not significantly exclude irradiated phage DNA it seems that the mul phenotype can be expressed only in complete cells.The mutation responsible for the mul phenotype has been mapped by conjugation and transduction to be located between the markers pyrE and ilv and probably marks a new gene. The mul mutation does not increase the UV-sensitivity of the cells nor does it affect their ability to perform host cell reactivation. The presence of a recA allel in a mul mutant abolishes the UV-mutability of phage .Part of this work is from the thesis of the first author in partial fullfilment of the requirements for the doctoral degree of the University of Bochum. Some of the results have already been presented at the 32. Kongreß für Hygiene und Mikrobiologie at Münster, 1969.     

The requirement of nonsense suppression for the development of several phages

Summary A spontaneous streptomycin-resistant Escherichia coli mutant which is temperature-sensitive for suppression of a nonsense codon was studied for its ability to propagate phages T2, T4D, T5, K, f2, MS2, R17, Q, as well as filamentous phages fl, fd and M13. Of all phages tested, only the growth of Q, , and filamentous phages is inhibited in the mutant at 42° C. This selective inhibition suggests that, like Q, and filamentous phages also require a read-through protein(s) which results from suppression of a termination codon.     

Cloning and characterization of the Escherichia coli chromosomal region surrounding the dnaG gene, with a correlated physical and genetic map of dnaG generated via transposon Tn5 mutagenesis

Summary A 24 kilobase pair region of the E. coli chromosome surrounding the dnaG gene has been cloned and characterized. A phage library was first constructed by ligating a Sau3A (GATC) partial DNA digest of the entire E. coli chromosome into the BamHI (G GATCC) cloning vector charon 28. Partial digestion was performed to generate overlapping chromosomal fragments and to allow one to walk along the chromosome. This library was probed with a nick-translated plasmid (pRRB1) containing the rpoD gene, which maps adjacent to dnaG at 66 min. Four bacteriophages: 3, 4, 5, 6 that hybridized to the probe were isolated from the 2,500 plaques screened. One phage recombinant 4, was shown to contain the dnaG gene. Three recombinant plasmids containing dnaG: pGL444, pGL445, pBS105, were constructed via subcloning of 4 using different restriction fragments. Plasmids pGL444 and pBS105 were subjected to transposon Tn5 mutagenesis and 88 Tn5 inserts into the cloned region were isolated. The location of the Tn5 inserts were mapped by restriction enzyme analysis of the plasmids and the insertion mutations were checked for ability to complement a dnaGts chromosomal marker at nonpermissive 40° C. In this manner a correlated physical and genetic map of dnaG was determined. A large number of Tn5 inserts map to a specific 900 b.p. region which we propose may be involved in the regulation of dnaG gene expression.     

Effect of mutant host RNA polymerase on the bifunctional activities of P22 gene c1.

Summary A phage has been isolated which specifically transduces the Escherichia coli pheS and pheT genes coding for the and subunits of the phenylalanyl-tRNA synthetase (PRS). This phage transduces with high frequency (i) several temperaturesensitive PRS mutants to thermoresistance and (ii) a p-fluorophenylalanine resistant PRS mutant to sensitivity against this amino-acid analog. The in vitro PRS activities of such lysogens suggest that the and subunits coded by the transducing phage complement the mutant host PRS-subunits in vivo by means of formation of hybrid enzymes.The transducing phages were also used to infect UV light irradiated cells. The SDS-gel electrophoretic analysis of the proteins synthesized in such cells revealed that the phage codes at least for four different E. coli proteins. Two proteins with molecular weights of 94,000 and 38,000 daltons cross-reacted with an anti PRS serum and were thus identified as the and subunits of PRS, respectively. A third protein with w molecular weight of 22,000 daltons is identical with the ribosomal initiation factor IF3 (Springer et al., 1977b). The other protein (M_r 78,000) is still unidentified.     

Plasmid formation from bacteriophage lambda in Escherichia coli

Summary Among the survivors of Escherichia coli derivatives infected with phage c1 or vir that are unable to establish ordinal lysogeny, clones arise which perpetuate the nondefective phage genome. When the bacteria bears a mutation(s) that makes the cell tolerant to the phage multiplication, such clones appear readily.The bacteria- complex was studied genetically and chemically, and it was concluded that the intact phage genomes, about two to four circular copies per bacterial chromosome, are perpetuated in bacterial cytoplasm as plasmids or in lysogenic state in cytoplasm.Several lines of evidence suggests that the phage genome in the lysogenic state in cytoplasm is under a different regulatory system from that in the normal prophage state on chromosome.     

Dependence of transfection efficiency of calcium treated Escherichia coli cells on bacterial genotype and form of lambda DNA

Summary The transfecting activity of linear DNA is 100 times higher in calcium treated E. coli K 12 (ⁱ⁴³⁴) than in non-lysogenic strains: the levels of transfection are 1–2.10⁷ and 1–2.10⁵ infective centers per 1 g of DNA, respectively. The high efficiency of lysogenic cells transfection is not due to the spontaneously liberated helper phage. Evidently, it is called forth by transfecting DNA-prophage recombination or/and by inhibition of nuclease activity in lysogenic cells. Both ring forms DNA (supercoiled and open circles) show very low infectivity, if any, in calcinated cells.     

Physiological relationship between the temperate phages lambda and phi80

Summary This work deals with the ability of phage 80 to provide defective mutants of with their missing functions. Functions Involved in Recombination. As shown by others, the Int mechanism of 80 cannot excise prophage . However, 80 efficiently excises recombinants from tandem dilysogens, using its Ter mechanism. Likewise, the nonspecific mechanism Red is interchangeable between 80 and . Maturation of DNA by 80. The Ter recombinants excised by 80 from tandem dilysogens are packaged into a 80 protein coat. This contrasts with the fact, already mentionned by Dove, that 80 is extremely inefficient for packaging phage superinfecting a -lysogen. The latter result is also found when the helper phage is a hybrid with the left arm of (80hy4 or 80hy41 — see Fig. 1). However, the maturation of the superinfecting is much more efficient if the 80hy used as a helper has the att-N region of (like 80hy1). Conversely a with the att-N region of 80 (hy6 — see Fig. 1) is packaged more efficiently by 80 or 80hy4 than by 80hy1. It is suggested that the maturation of chromosome superinfecting an immune cell requires a recombination with the helper phage. Vegetative Functions. Among the replicative functoons O and P, the latter only can be supplied by 80. That N mutants are efficiently helped by 80 does not tell that 80 provides the defective with an active N product; the chromosomes are simply packaged into a 80 coat. This shows that 80 is unable to switch on the late genes of . That neither 80 nor any of the 80hy tested can provide an active N product is shown in a more direct way by their complete failure to help N ^-r₁₄; this phage carries a polar mutation which makes the expression of genes O and P entirely N-dependant. The maturation of a N ^- by 80 contrasts with the fact that mutants affected in late genes (A, F or H) are not efficiently helped by 80. This suggests that the products coded by these genes are not interchangeable between 80 and , and that packaging of DNA into 80 coats is possible but inhibited when late proteins are present in the cell. Activation of the Late Genes. Among the im ₈₀ h ⁺ hybrids tested, only 80hy41 is able to switch on the late genes of a N defective mutant. This hybrid differs from the other hybrids studied here, by the fact that it has the Q-S-R region of (see Fig. 1). The results are consistant with the view that the product of Q gene is sufficient for activating the late genes of a DNA. N would thus control the expression of late genes only indirectly by controlling the expression of gene Q (Couturier & Dambly have independantly reached the same conclusion, 1970). Furthermore the failure of 80 and of the 80hy1 and 80hy4 to activate the late genes of would imply that these phages are unable to provide an Q product active on the chromosome Reciprocally, switches on the late genes of prophage 80hy41, but not of prophages 80hy1 and 80hy4. This suggests that the initiation of late genes expression takes place at a main specific site located in the Q-S-R region of the chromosome. The expression of the late genes would thus be sequential, and proceed through the left arm only when steaky ends cohere. Similar conclusions were reached independantly by Toussaint (1969) and by Herskowitz and Signer (1970).

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Ce travail a été réalisé dans le cadre du contrat d'association Euratom-U. L. B. 007-61-10 ABIB et avec l'aide du Fonds de la Recherche Fondamentale Collective.     

Normal expression of the viral gene N interferes with growth of bacteriophage lambda in Escherichia coli 15T-.

Summary Growth of and of some lambdoid phages is considerably inhibited on strain 3057 derived from E. coli 15T^-. Mutants of which overcome this inhibition map in gene N. Some of these hty mutants are temperature sensitive for growth on E. coli K12. Thus plating of on strain 3057 allows one to isolate temperature sensitive N mutants. The hty mutants produce less than normal N activity as judged by their low efficiency of plating on a nus ^- host and by the extended latent period of some of them on normal hosts. The inability of strain 3057 to propagate can be at least partially reversed by addition of thymidine to the medium and the growth difference between hty and in 3057 increases with decreasing thymidine concentration. The amount of DNA produced by in 3057 at low thymidine concentration is lower than that produced by hty under the same conditions. Only a small percentage of the DNA produced by in 3057 is packaged into viable phage particles. This suggests that not only produces less DNA in 3057 than hty but that an important part of the DNA in 3057 is in a form which can not be packaged or which is noninfective for other reasons. A hypothesis is discussed that hty mutations enable to grow on E. coli 15T^- at low thymidine concentration because they lead to reduction in the number of single strand nicks in the DNA by reducing the intracellular endonuclease activity. Under permissive conditions conditional lethal N mutants are favored for growth on 3057 over N ⁺ which confirms the idea that N activity or the activity of a gene under N control interferes with growth in 3057 at low thymidine concentration.     

Studies on the E. coli groNB (nusB) gene which affects bacteriophage lambda N gene function

Summary Escherichia coli mutants, called groNB, which block the growth of bacteriophage at the level of action of the gene N product, have been isolated as survivors at 42°C of bacteria carrying a) the defective prophage bio1 1 i cI857 H1 or b) the pcR1 plasmid containing the EcoRI immunity fragment of phage cI857. In addition, groNB bacterial mutants have been isolated at 37° C, as large colony formers in the presence of i cI h ⁴³⁴, i cI h , and i cI h ⁸⁰ phage. The groNB locus is located at 9 minute of the E. coli genetic map with the order of the neighboring loci being proC tsx groNB purE. Most groNB mutations isolated at 42° C were found to interfere in addition with bacterial growth at low temperatures, since (a) the GroNB phenotypes of growth inhibition and bacterial cold sensitivity cannot be separated by P1 transduction, and (b) some cold resistant revertants simultaneously become Gro⁺ for growth. Lambda transducing phages carrying the groNB ⁺ bacterial gene have been isolated. GroNB mutant bacterial lysogenized by the transducing phage acquire the Gro⁺ phenotype and simultaneously the cold resistant phenotype, suggesting that the groNB mutations are recessive to the wild-type gene.     

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.     

Bacteriophage lambda replication proteins: formation of a mixed oligomer and binding to the origin of lambda DNA

Summary The purified bacteriophage replication proteins O and P sediment separately in metrizamide gradients of low ionic strength as dimers. Together they interact with each other forming an oligomer, composed of two molecules of O and one molecule of P. The O-P oligomer is active in the in vitro replication of ori-containing DNA.Equilibrium sedimentation in preformed metrizamide density gradients under conditions that separate DNA-protein complexes from free proteins was employed in order to study possible interactions among the replication proteins and ori DNA. It was found that the P protein binds specifically to ori-containing plasmid DNA only in the presence of O protein. About 100 molecules of O and 10 molecules of P form a complex with the ori DNA. The DNA-O-P complex was shown to be active in an in vitro replication system.Since the physical interactions between ori and O and between P and the Escherichia coli dnaB replication protein are well documented, the evidence for a O-P interaction presented in this paper provides the missing link in the molecular mechanism that enables to direct the host replication machinery to the replication of its own DNA.     

Role of the recF gene of Escherichia coli K-12 in lambda recombination

Summary When Escherichia coli K12() lysogens are infected with heteroimmune phage, which are unable to replicate, general recombination between phage and prophage depends on the bacterial recF gene. It has been shown that in E. coli K12 postconjugational recombination, the RecF pathway only works with full efficiency if exonuclease I is absent (Clark 1973). However, results presented in this paper indicate that under conditions in which replication is blocked, the recombination pathway dependant on the recF gene is fully active in producing viral recombinants even, if the phage is Red⁺, in the presence of exonuclease I. In contrast, removal of exonuclease and protein requires elimination of exonuclease I for an efficient RecF pathway. It is concluded that the Red system cooperates with the RecF pathway and that this cooperation involves overcoming the inhibitory effects of exonuclease I. In the absence of exonuclease, protein stimulates recF-dependent recombination but does not suffice to prevent the negative effect of exonuclease I. In the presence of protein, full efficiency of the RecF pathway can be obtained either via cooperation with exonuclease I or, if the viral exonuclease is defective, via inactivation of exonuclease I. Since activity of exonuclease appears necessary to overcome the inhibitory effects of exonuclease I, it is proposed here that exonuclease diverts material from the RecF pathway in a shunt reaction which allows completion of recF-initiated recombinational intermediates via a mechanism insensitive to exonuclease I.When replication is allowed, the Rec system produces viral recombinants mainly via a recF-independent mechanism. However, a major contribution of the RecF pathway to recombination is observed after removal of the Red system and exonuclease I.Obra social de la Caja de Ahorros de Valencia (Director: S. Grisolía)     

Tandem duplication induced by an unusual ampA1-, ampC-transducing lambda phage: A probe to initiate gene amplification

Summary Secondary attachment site -lysogens were isolated in an Escherichia coli strain carrying multiple tandem 9.8 kb repeats. The repeat carried the structural gene for chromosomal -lactamase, ampC. One lysogen produced lysates with amp-transducing activity. Three types of phages with different densities were obtained from this lysogen. The one with the lowest density was found to be a helper cI857S7 phage. The other two phages showed identical restriction endonuclease fragmentation patterns. The difference in density was due to the presence or absence of phage tail. In damp the right cohesive end segment was deleted in a random fashion with the majority ending between 81.0% and 82.4% of . The chromosomal segment of damp was most likely located at the attachment site. The damp DNA was compared to that of a ColE1 hybrid carrying the chromosomal amp segment and a ColE1 hybrid carrying the same 9.8 kb amp repeat as the lysogen from which damp was isolated. It was found that the chromosomal part of damp constituted 9.8 kb, i.e. the size of one repeat. Moreover, the novel joint between adjacent repeats was present. In a attB-deleted E. coli K-12 strain, lysogenic for damp, highly ampicillin-resistant mutants occurred at an exceedingly high frequency. They were found to contain in the chromosome an amplified 9.8 kb repeat. This suggested that integration of the novel joint from damp into the amp region gives rise to an amplifiable duplication. In E. coli lysogenized for damp at attB highly ampicillin-resistant clones were also found at a high frequency. These clones carried multiple tandem repeats of damp DNA, each with an intact right end segment.     

On the mode of antirepressor action in anti-immune cells

Summary The mode of antirepressor action in anti-immune cells was analysed in respect to its two main features, low lysogenization and high cell killing. By means of complementation experiments between and i434 in anti-immune cells, it was shown that the antirepressor no longer channels phages towards lysis in such cells if the genes which are needed for lysogenization are provided in trans by the heteroimmune phage i434. Since complementation could be demonstrated, it was possible to exclude that direct action of the antirepressor over repressor production is responsible for the feature under analysis. It was also shown that both int- and cII-product are required to improve lysogenization and to prevent high levels of killing.Recipient of an EMBO predoctoral fellowship.     

Molecular cloning of the T4 genome: organization and expression of the tail fiber gene cluster 34--38

Summary T4 derivatives that carry T4 tail fiber genes 34–38 have been isolated and characterized by genetic, structural and functional analysis. 32 T4 recombinants were identified by a marker rescue screen of 310 T4 clones generated by restriction of partial cytosine-containing T4 DNA with either HindIII or EcoRI and ligation into appropriately cleaved vectors. These tests defined 15 recombinant classes with respect to the contiguous stretches of genome recovered. Restriction enzyme structural analysis identified 7 HindIII fragments and 7 EcoRI fragments, established a restriction map covering about 11 kb, and indicated the orientation of the DNA inserts within the vectors. The cloned tail fiber genes are expressed efficiently from promoters and complement in vivo T4 phage carrying amber mutations in the tail fiber genes. Polypeptides corresponding to gp34-gp38 have been detected by SDS polyacrylamide gel electrophoresis of ³⁵S-labeled extracts of appropriate T4 recombinant infected UV-treated host cells. The genetic, structural and functional maps of the T4 tail fiber gene cluster have been correlated, and provide a rational approach to genetically directed DNA sequence analysis of genes 34–38 and their mutant variants that affect the assembly, structure and function of the tail fibers.