Induction of lambdoid prophages by amino acid deprivation: Differential inducibility; Role of recA

Summary Lambda prophage in auxotrophic lysogens can be induced by omission of one or combinations of the required amino acids from the culture medium. Such amino acid deprivation can result in nearly as effective induction of lambda as thymine deprivation. Prophage 424 is also induced equally effectively under both conditions although to a lesser extent than lambda. By contrast prophage 21 and i²¹ are differentially induced effectively by thymine deprivation and virtually not at all during amino acid deprivation. The same differential induction of 21 and equivalent induction of and 424 occur when all three prophages are present in the same lysogen. Increasing the levels of repressor with a cI carrying-plasmid prevented amino acidless induction of as did the ind ^– mutation. A recA, but not a recB, mutation in the host prevented induction by amino acid deprivation. A recC mutant host showed increased spontaneous induction of and 21 prophages. The findings reported are used as an argument that the recA protease probably is not itself acting as the inducing protease and that a likely source of the observed specificity is an effector molecule. Different effector molecules may be produced in response to different exigent situations, to which the phage repressors may have evolved sensitivity. i⁸⁰ was inducible both by amino acid and thymine deprivation.     

Lysogenic induction of lambdoid phages in lexA mutants of Escherichia coli

Summary UV irradiation of lexA3 mutants of E. coli caused lysogenic induction of prophage , _i21, _i434 and 80. Maximal induction in lexA3 lysogens needed less UV than in lexA ⁺ bacteria and gave 25–100% of the normal levels of infective centres induced. Assays of gene expression arising from derepression of a defective prophage showed at least 40% of the normal levels of induction by mitomycin C in lexA3 bacteria. The need for post-irradiation protein synthesis for lysogenic induction in lexA3 lysogens was reduced by increasing the basal level of recA protein with a recA ⁺ plasmid. It is concluded that in lexA E. coli some recA protein synthesis, too small to be detected by physical means, is needed for UV induced lysogenic induction.     

Prophage induction and cell division in E. coli. II. Linked (recA, zab) and unlinked (lex) suppressors of tif-1-mediated induction and filamentation

Summary The pleiotropy of tif-1, a mutation in E. coli K12 causing, among other effects, cellular filamentation at 42° and thermal induction of lysogenic derivatives, can be explained by the participation of the tif ⁺ gene product in more than one reaction pathway. Pathways that involve the tif ⁺ product may be analyzed by selection of secondary mutations that reverse both tif-1-mediated prophage induction and cell filamentation. Among revertants of a tif-1 lysogen among 20% are recombination deficient. These appear to carry a recA mutation. In addition to this class is a rarer (7%) phenotypically distinguishable class of revertants, called zab, first described here. Markers tif-1, recA and zab are closely linked. Mutations lex which are dominant and located near malB also appear (3%) among tif-1 revertants. The lex ⁺ function is needed for normal UV, X-ray and mitomycin C induction of prophage .The zab mutation resembles recA in causing (1) high sensitivity to UV, X-rays and mitomycin C, (2) drastic DNA degradation following UV irradiation but normal capacity to repair UV-damaged infecting phage (Hcr⁺), (3) failure to carry out UV reactivation and UV mutagenesis of UV-irradiated bacteriophage , (4) a markedly reduced level of spontaneous induction of . In contrast, other capacities, strikingly diminished by recA, are affected less, if at all by zab. Thus zab (1) permits 30–60% normal recombination proficiency, (2) shows real, although very low inducibility of by UV or mitomycin C, (3) permits 100% efficiency of plating of red gam, and (4) does not degrade DNA spontaneously.The hypothesis is proposed that the tif-1 mutation is a regulatory mutation controlling the activity, or more likely the synthesis of repair enzyme(s). The level of these repair enzyme(s), rather than DNA lesions, may govern the stability of the prophage repressor and the capacity of the bacteria to form septa.     

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.     

Waves in a simple,excitable or oscillatory,reaction-diffusion model

A simple one variable caricature for oscillating and excitable reaction-diffusion systems is introduced. It is shown that as a parameter, , varies the system dynamics change from oscillatory ( > ₀) to excitable ( < ₀) and the frequency of the oscillation vanishes as for ₀. When such dynamics are coupled by continuous diffusion in a ring geometry (1-space dimension), propagating wave trains may be found. On an infinite ring excitable devices lead to unique solitary waves which are analogous to pulse waves. A solvable example is presented, illustrating properties of dispersion, excitability, and waves. Finally it is shown that the caricature arises in a natural way from more general excitable/oscillatory systems.     

Lambda transducing phages for the nalA gene of Escherichia coli and conditional lethal nalA mutations.

Summary Defective transducing phages for the nalA region of the Escherichia coli chromosome were isolated from a lysogen in which is inserted in the nearby glpT gene. The three classes of transducing phages designated nrdA, dubiG, and dnalA contained bacterial DNA extending from glpT through nrdA, ubiG, and nalA, respectively. The bacterial genes are in the left arm of the chromosome. Of the eleven polypeptides coded by dnalA that were resolved by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate only one was not also specified by dubiG This 105,000 dalton polypeptide is the nalA gene product. The electrophoretic mobility and isoelectric point of this protein were unaffected by a nalA mutation (nalA48) that confers nalidixic acid resistance. Temperature-sensitive and amber mutations in the nalA gene were isolated using a dnalA48 lysogen which is heterodiploid for nalA. The conditional lethality of these mutations proves that nalA is an essential locus.     

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.     

Correlation between decreased reparative capability of UV lesions and higher spontaneous mutability in a mutator strain of E. coli K-12

Summary The biauxotrophic strain of E. coli K-12 (), met 1/his 7, which exhibits an 8 times higher rate of met1met ⁺-backmutation as compared with the parent strain met 1, was found to be also more sensitive to UV irradiation. In addition, the maximum UV induction of prophage occurs at lower doses, and the capacity of the strain to propagate induced prophage is reduced. The mutant strain has also lost part of the ability to repair UV-induced lesions in phage T 1.The phenotypes high mutability and UV sensitivity could not be separated by means of recombination.From these findings it is concluded that part of the spontaneously occuring changes in DNA (premutations) which lead to met ⁺ genotype are similarly repaired as some UV induced ones, and that the mutator mum ⁺ of strain met 1/his 7 causes a reduced repair of both changes.     

lambdaimm P22dis: a hybrid of coliphage lambda with both immunity regions of Salmonella phage P22.

Summary Genetically marked and P22 phages were recombined in Escherichia coli-Salmonella typhimurium hybrid WR4028, a host sensitive to infection by both of these phages. Hybrid phages that acquired the immC region of P22, but retained the genes for the protein coat were selected on WR4027 (), a -immune, P22-resistant derivative of WR4028. In these immP22 hybrids, at least the c through P genes of were replaced with functionally related P22 genes. Phage recombinants with more extensive regions of the P22 genome were selected on the double lysogen WR4027 (, immP22). One such hybrid, immP22dis, was determined by heteroduplex analysis to contain approximately 40% of the P22 genome. Genetic studies established that immP22dis possesses the two widely separated immunity control regions of P22 (immC and immI) and that these loci are expressed in E. coli K-12 lysogenic for immP22dis. In addition, immP22dis contains the P22 a1 locus responsible for somatic 0–1 antigen conversion in Salmonella. Although the immP22dis phage particle has the head and tail, the phage genome also carries P22 tail gene 9 as evidenced by the production of free P22 tails. It also has the P22 att site as indicated by the integration of the immP22dis prophage near the proA locus on the bacterial chromosome.     

Regional replication of the bacterial chromosome induced by derepression of prophage lambda

Summary Derepression of prophage in E. coli strain K12 results in constitutive synthesis of the enzymes directed by the nearby bacterial operon, gal (escape synthesis). Phage 82 fails to cause escape synthesis despite that it lysogenizes the strain K12 at the site identical to that of on the host chromosome. The reason for the observed difference between 82 and is studied in the light of the recent finding that escape synthesis in -lysogen is closely associated to phage-promoted replication of bacterial chromosome contiguous to the prophage including gal operon (escape replication). Excision-defective mutants from 82, 82int or 82xis, do initiate escape synthesis, suggesting that the prophage 82 is normally excised too quickly after induction to allow sufficient escape replication. In support of this, much more DNA hybridizable to bacterial DNA contained in gal accumulates after induction of 82int than after induction of 82. Studies with various hybrid phages between 82 and have suggested: 1. The occurrence of gal escape synthesis depends on the nature of the region between b2 and N in the map. 2. Regions of the 82 genome on both sides of the attachment site contribute independently to prevent gal escape synthesis. Implications of these results are discussed with regard to the factors involved in the prophage excision.The IIIrd article of this series is in Molec. Gen. Genet. 159, 185–190 (1978)     

Mutations of coliphage lambda affecting the expression of replicative functions O and P

Summary A selection technique, using the thermoinducible prophage CI857Nsus7 Nsus53, has lead to the characterization of a new class of prophage mutations (called r), which prevent host killing upon thermal induction.N-defective r mutants efficiently complement i⁴³⁴ or O and P mutants, but not the corresponding mutants of i²¹. Complementation data suggest that the i²¹ hybrid fails to provide the positive regulatory mechanism dependent on the N-gene product, since it cannot activate the Q gene of a N-defective mutant. Thus, it seems possible that r mutants cannot express genes O and P unless the N-gene product is present in the cell. This interpretation is supported by the fact that r mutants are not defective and form plaques when their N-gene is functional. r mutation confer a clear phenotype, and map in the y-CII region. Results of a density gradient analysis suggest that they result from small insertions of DNA. Induced N-defective r prophages appear to be only poorly transcribed on strand H.Complementation tests performed in a strain lysogenic for indicate that the C17 mutation can suppress a r mutation in a cis position, even in the absence of the N-gene product.These results suggest that the expression of genes O and P, in addition to gene Q, is under the positive regulation of the N-gene product.     

Host controlled modification of phage λ in zygotic induction inEscherichia coli B

Experiments on zygotic induction of prophage inE. coli Hfr K 12 ×E. coli B F^– crosses are described. The prophage is not restricted inE. coli B zygotes. Most of the zygotes produce the host modified.B; about 10–50% of the zygotes also produce a few.K particles.     

RexAB proteins of bacteriophage lambda enhance the effect of photolyase-dimer complexes on lacZ gene expression in Escherichia coli.

Summary Expression of the lacZ gene in Escherichia coli is inactivated by exposure to ultraviolet light (UV). Inactivation is exceptionally effective when cells contain amplified levels of DNA photolyase (which forms complexes with pyrimidine dimers in the absence of light for actual photoreversal) and a prophage. Without amplified photolyase, the prophage or both, inactivation rates are similar and much lower. UV-inactivation of lacZ gene expression in the presence of both amplified photolyase and is even more effective if cI857 is used in place of the wildtype prophage but is wholly unexceptional if the prophage carries defects in the genes rexA or rexB. When Rex AB proteins are provided by expression from a plasmid and the cell also contains amplified photolyase, exceptional inactivation rates again obtain; in fact inactivation is most effective under these conditions. The data are considered to reveal a role for Rex AB proteins, which mediate superinfection exclusion, in the exceptional inactivation of gene expression by photolyase bound to pyrimidine dimers in DNA. Photolyase-dimer complexes may mimic the structure of certain complexes that arise during phage development and thus influence Rex A and/or B proteins, thereby shutting down cell metabolism.     

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.     

Genetic study of prophage excision with a temperature inducible mutant of Mu-1

Summary Escherichia coli strains, carrying F'episomes with a thermoinducible prophage of Mu were used to study the effect of heat induction on the ability of the cells to transfer these episomes to recipient cells. With this method information was obtained on the excision of the prophage after induction. Control studies were done with an episome containing a thermoinducible lambda prophage.The heat induction has opposite effects on the transfer of episomes containing Mu or : in the case of the number of sexductants in a -immune recipient is not significantly affected while sexduction into a non-immune recipient is increased by a factor 10–20. In contrast, the transfer of Mu-containing episomes into Mu-immune and also non-immune recipients is decreased by a factor of 100–200.The presented data exclude a precise -like excision of prophage Mu upon induction. A possible model for Mu excision is discussed.Colony forming units.     

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)     

Molecular genetic analysis of the Ta 25H deletion: Evidence for additional deleted loci

Seventeen linking clones sublocalized to the central region of the mouse X Chromosome (Chr) were screened against genomic DNA from male mice carrying the tabby-25H (Ta ^25H ) deletion. Two of these linking clones, EM131 and EM169, were found to be deleted in Ta ^25H /Y animals. Genetic mapping through Mus musculus domesticus/Mus spretus interspecific backcross progeny, segregating for the original tabby (Ta) gene mutation, was utilized to order these markers and to define nearest flanking markers to the Ta ^25H deletion (EM140 and EM171). The size of the Ta ^25H deletion was thus estimated as up to 4.5 centiMorgans (cM). The order of markers, proximal to distal, was found to be EM140/EM131, mouse androgen receptor gene (Ar)/EM169, Ta/EM171. A putative CpG-rich island and a highly evolutionarily conserved DNA probe were isolated from the DXCrc169 locus which co-segregates with the Ta locus in this study.