Repair of ultraviolet-light damaged ColE1 factor carrying Escherichia coli genes for guanine synthesis.

Summary Hybrid ColE1 plasmids called ColE1-cos-guaA or ColE1-cos-gal can be efficiently transduced into various E. coli K-12 cells through packaging into phage particles. Using these plasmids, repair of ultraviolet-light (UV) damaged ColE1 DNAs was studied in various UV sensitive E. coli K-12 mutants. (1) The host mutations uvrA and uvrB markedly reduced host-cell reactivation of UV-irradiated ColE1-cos-guaA. (2) Pre-existing hybrid ColE1 plasmids had no effect on the frequency of phage-mediated transduction of another differentially marked hybrid ColE1 DNAs. (3) ColE1-cos-guaA and ColE1-cos-gal DNAs could temporarily but not stably co-exist in E. coli K-12 recA cells. (4) The presence of ColE1-cos-gal in uvrB cells promoted the repair of super-infected UV-irradiated ColE1-cos-guaA about 7-fold. (5) The same ColE1-cos-gal plasmid in a uvrB recA double mutant did not have this promoting effect. These results indicate that the effect of resident hybrid ColE1 plasmids is manifested by the host recA ⁺ gen function(s) and suggest that ColE1 plasmid itself provides no recA ⁺-like functions.     

Evidence that pretreatment of Escherichia coli cells with N-methyl-N'-nitro-N-nitrosoguanidine enhances mutability of subsequently infecting phage lambda

Summary The frequency of mutations in is significantly higher for host cells of a rec ⁺ or recA ^- strain pretreated with N-methyl-N-nitro-N-nitrosoguanidine (NG) than for untreated control cells. Direct NG treatment of DNA-injected host cells results in about tenfold higher mutation frequency in than NG treatment of host cells alone. Since mutability of is enhanced by UV preirradiation of host cells in the rec ⁺ strain but not in the recA ^- strain, indirect NG mutagenesis is different in mechanism from indirect UV mutagenesis. It is concluded that NG mutagenesis in consists of at least two processes: induction of rec ⁺-independent mutagenic activity in the host bacterium and production of rec ⁺-independent mutational damage to intracellular DNA.     

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.     

The origin of Q-independent derivatives of phage lambda

Summary qsr (Q-independent) phages are characterised by the replacement of the region of the genome that contains Q, S, R, and the late gene promoter, P_R, with host-derived DNA that codes for functions analogous to those deleted. Restriction endonuclease analysis and DNA/DNA hybridisation methods have been used to show that p4 and qin A 3, two such Q-independent phages, are the product of recombination between and a defective lambdoid prophage (the qsr prophage) located at an as yet unidentified site in the E. coli K 12 chromosome. The qsr prophage is distinct from the defective lambdoid prophage Rac (Kaiser and Murray 1979). In the E. coli K 12 strain AB1157 from which qsr phages cannot be generated, the qsr prophage has suffered an internal deletion. That the qsr prophage appears not to carry a full complement of essential late genes suggests one explanation for its apparently defective nature.     

A hotspot of spontaneous and UV-induced illegitimate recombination during formation ofλbio transducing phage

To study the mechanism of spontaneous and UV-induced illegitimate recombination, we examined the formation of thebio specialized transducing phage inEscherichia coli. Because mostbio transducing phages have double defects in thered andgam genes and have the capacity to form a plaque on anE. coli P2 lysogen (Spi^– phenotype), we selectedbio transducing phage by their Spi^– phenotype, rather than using thebio marker. We determined sequences of recombination junctions ofbio transducing phages isolated with or without UV irradiation and deduced sequences of parental recombination sites. The recombination sites were widely distributed onE. coli bio and DNAs, except for a hotspot which accounts for 57% of UV-inducedbio transducing phages and 77% of spontaneously inducedbio transducing phages. The hotspot sites onE. coli and DNAs shared a short homology of 9 bp. In addition, we detected direct repeat sequences of 8 by within and near both thebio and hotspots. ArecA mutation did not affect the frequency of the recombination at the hotspot, indicating that this recombination is not a variant ofrecA-dependent homologous recombination. We discuss a model in which the short homology as well as the direct repeats play essential roles in illegitimate recombination at the hotspot.     

The p lambda CM system: phage immunity-specific incompatibility with IncP-1 plasmids

Summary A pCM2 replicon derived by an N^– deletion from ::Tn9 which carries the imm434 immunity region is incompatible with some (but not all) IncP-1 plasmids. The imm pCM1 replicon does not show the same incompatibility behavior.     

Negative complementation of recA protein by recA1 polypeptide: in vivo recombination requires a multimeric form of recA protein

Summary Recombination in vivo was studied in recA ^- heterozygous lacZ merodiploids by performing -galactosidase assays after infection with precA ⁺. Recombination as measured by -galactosidase production was a linear function of pecA ⁺ multiplicity of infection (MOI) when the strain contained a deletion of the chromosomal recA gene. However, when the strain carried a recA1 missense allele, a higher precA ⁺ MOI was required to obtain levels of recombination comparable to the (recA) strain, and the slope of the dose-response curve increased to approximately two. It is proposed that negative complementation occurs in mixed tetramers of wild-type and missense recA polypeptides, and that in vivo recombination is a property of a multimeric form of recA protein.     

Human λ light chain locus: Organization and DNA sequences of three genomicJ regions

Evidence for the genomic organization of human lambda light chain joining (J) region gene segments is presented. A mouse J probe was used in Southern hybridizations to localize joining region sequences in a cosmid clone containing the genomic cluster of six human lambda constant (C) region gene segments. The results of these hybridizations suggest the presence of at least one J gene segment upstream from each constant region gene segment. The DNA sequences indicate that the human JI, J2, and J3 gene segments have consensus nonamer and heptamer sequences, proposed to be involved in V-J joining, are capable of encoding the known amino acid sequences for the respective J peptides, and have a sequence which could give functional RNA splice site at the end of their coding regions. Our data show that a single functional J is located 1.3 or 1.6 kb upstream of each of the C gene segments known to encode the Mcg, Kern^– Oz^–, and Kern^–Oz⁺ isotypes. Therefore, the gene organization of this region of the human lambda locus is J1 CI -J2C2-J3C3. The DNA sequences ofJ 1,J 2, andJ 3 presented in this paper establish that a singleJ gene segment precedes each expressed C gene segment, and support a model for the evolution of the human JC clusters where JICI andJ2C2-J3C3. arose from different ancestral JC units.     

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.     

Cloning bacterial genes with plasmid λdv

Summary Fragments ofEscherichia coli DNA carrying genes for -galactosidase, or for biosynthesis of guanine or biotin were recombined in vitro with dv DNA. The cloned recombinant molecules recovered from transformedE. coli cells consisted of a biologically functional bacterial DNA fragment and, except for dv-bio30-7, two dv monomer units: one of the dv units was used as the insertion site for the bacterial DNA, whereas the other was intact, and seemed to be responsible for the replication of the recombinant plasmid. The process which gives rise to these recombinant molecules at high frequency from mixtures of monomeric dv DNA's and bacterial DNA fragments is discussed.