Restriction of lambda trp bacteriophages by Escherichia coli K

trp-transducing derivatives of phage λ have been used to study Escherichia coli K specific restriction in vivo. The expression of the trp genes from unmodified phages during infection of a rec⁺, restricting host is eliminated by restriction. In a K-restricting recB,C host, where degradation of restricted phage DNA is prevented, expression of the trp genes is little affected by the presence of a single unmodified, K-restriction recognition site, even when that site is within the trpE gene. RI restriction, in contrast to K restriction, prevents trp gene expression in a recB,C host when the restriction target is between the trp genes and the relevant promoter. The presence of two K-restriction recognition sites in a λtrp phage can have a marked effect on trp gene expression. This effect can be interpreted as the result of preferential breakage between the two restriction recognition sites. We conclude that K restriction does not break susceptible DNA at, or even preferentially near, a restriction recognition sequence.     

Requirement for maturation of Escherichia coli bacteriophage lambda

During infection a λ phage that is incapable of DNA replication requires recombination for maturation. If two prophages are situated in tandem, this requirement for DNA replication and recombination is bypassed. In physical experiments using the DNA cutting assay of Freifelder et al. (1973), the DNA of a sex factor containing one or two prophages defective in both excision and DNA replication is cut efficiently only when two prophages are in tandem. We interpret this to mean that λ can only be matured from a structure of greater than unit length, and hypothesize that the structure must contain two joined ends (AR-joints).     

Prophage lambda at unusual chromosomal locations. II. Mutations induced by bacteriophage lambda in Escherichia coli K12

An Escherichia coli strain deleted for the primary λ attachment site was lysogenized with λ at secondary sites. Some lysogens became mutants because of prophage insertion in the affected gene. Mutagenesis by phage λ is not random with respect to the gene affected: most mutants were pro, although certain other genes could be mutated at lower frequencies. In the case of several independent ilv and gal mutants, the sites of prophage insertion were in the same segment of the ilv region and galT gene respectively. The galT location may also be a preferred site for the insertion of DNAs other than prophage λ. Insertion of prophage λ within an operon can reduce the expression of operator-distal genes. A trpC λ insertion mutant expresses the operator-distal trpB function constitutively at a low level. This expression probably derives from a promoter located in the left arm of the prophage.     

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.     

Stimulation of groE synthesis in Escherichia coli by bacteriophage lambda infection

We found that infection of Escherichia cell by lambda results in at least a twofold stimulation in the rate of synthesis of one of the products of groE. To determine what lambda-coded factors were responsible for this stimulation, numerous phage lambda mutants carrying bio substitutions were analyzed for their ability to stimulate groE synthesis. Our results revealed that the main factor(s) which is responsible for stimulating groE synthesis is located between the endpoints of the lambda bio69 and lambda bio252 substitutions, a region of DNA coding for bet, gam, kil, and cIII.     

Kinetics of bacteriophage lambda deoxyribonucleic acid infection of Escherichia coli

Barnhart, Benjamin J. (Los Alamos Scientific Laboratory, University of California, Los Alamos, N.M.). Kinetics of bacteriophage lambda deoxyribonucleic acid infection of Escherichia coli. J. Bacteriol. 90:1617-1623. 1965.-The kinetics of Escherichia coli K-12 infection by phage lambda deoxyribonucleic acid (DNA) were determined. An initial lag of 55 to 80 sec was found to be the time required for infecting DNA to become deoxyribonuclease-insensitive at 33 C. When cell-DNA interactions were stopped by washing away unbound DNA, the already bound DNA continued to infect the cell at rates described by linear kinetics with no apparent lag. Whereas the lag period was relatively insensitive to DNA and cell concentrations, both the lag and the subsequent linear portions of the rate curves were temperature-sensitive. Cell and DNA dose-response curves prescribed hyperbolic functions. Similarities between lambda DNA infection of E. coli and bacterial transformation systems are discussed.     

Recombination of bacteriophage lambda in recD mutants of Escherichia coli

RecBCD enzyme is centrally important in homologous recombination in Escherichia coli and is the source of ExoV activity. Null alleles of either the recB or the recC genes, which encode the B and C subunits, respectively, manifest no recombination and none of the nuclease functions characteristic of the holoenzyme. Loss of the D subunit, by a recD mutation, likewise results in loss of ExoV activity. However, mutants lacking the D subunit are competent for homologous recombination. We report that the distribution of exchanges along the chromosome of Red-Gam-phage lambda is strikingly altered by recD null mutations in the host. When lambda DNA replication is blocked, recombination in recD mutant strains is high near lambda's right end. In contrast, recombination in isogenic recD+ strains is approximately uniform along lambda unless the lambda chromosome contains a chi sequence. Recombination in recD mutant strains is focused toward the site of action of a type II restriction enzyme acting in vivo on lambda. The distribution of exchanges in isogenic recD+ strains is scarcely altered by the restriction enzyme (unless the phage contains an otherwise silent chi). The distribution of exchanges in recD mutants is strongly affected by lambda DNA replication. The distribution of exchanges on lambda growing in rec+ cells is not influenced by DNA replication. The exchange distribution along lambda in recD mutant cells is independent of chi in a variety of conditions. Recombination in rec+ cells is chi influenced. Recombination in recD mutants depends on recC function, occurs in strains deleted for rac prophage, and is independent of recJ, which is known to be required for lambda recombination via the RecF pathway. We entertain two models for recombination in recD mutants: (i) recombination in recD mutants may proceed via double-chain break--repair, as it does in lambda's Red pathway and E. coli's RecE pathway; (ii) the RecBC enzyme, missing its D subunit, is equivalent to the wild-type, RecBCD, enzyme after that enzyme has been activated by a chi sequence.     

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.     

Bending of the bacteriophage lambda attachment site by Escherichia coli integration host factor

Escherichia coli integration host factor (IHF) is a small basic protein that is required for efficient integrative recombination of bacteriophage lambda. IHF binds specifically to sequences within attP, the site in bacteriophage lambda that undergoes recombination. It has been suggested that the binding of IHF creates bends in DNA so as to help attP condense into a compact structure that is activated for recombination. In this work we show that IHF binding to either of two sites found within attP does indeed produce bending of DNA. In contrast, the other recombination protein needed for integrative recombination, Int, does not appreciably bend the DNA to which it is bound. In agreement with the proposal that IHF bending is important for creating a condensed attP, bending by IHF persists in the presence of bound Int. Our conclusions about protein-directed bends in DNA are based on the study of the electrophoretic mobility of a set of permuted DNA fragments in the presence or absence of IHF and/or Int. To facilitate this study, we have constructed a novel vector that simplifies the generation of permuted fragments. This vector should be useful in studying the bending of other DNA sequences by specific binding proteins.     

Bacteriophage-induced functions in Escherichia coli K (lambda) infected with rII mutants of bacteriophage T4

Rutberg, Blanka (Karolinska Institutet, Stockholm, Sweden), and Lars Rutberg. Bacteriophage-induced functions in Escherichia coli K(lambda) infected with rII mutants of bacteriophage T4. J. Bacteriol. 91:76-80. 1966.-When Escherichia coli K(lambda) was infected with rII mutants of phage T4, deoxycytidine triphosphatase, one of the phage-induced early enzymes, was produced at initially the same rate as in r(+)-infected cells. Deoxyribonuclease activity was one-third to one-half of that of r(+)-infected cells. This lower deoxyribonuclease activity was observed also in other hosts or when infection was made with rI or rIII mutants. Presence of chloramphenicol did not allow a continued synthesis of phage deoxyribonucleic acid in rII-infected K(lambda). No phage lysozyme was detected nor was any antiphage serum-blocking antigen found in rII-infected K(lambda). It is suggested that the rII gene is of significance for the expression of phage-induced late functions in the host K(lambda).     

Recombination between bacteriophage lambda and plasmid pBR322 in Escherichia coli

Recombinant lambda phages were isolated that resulted from recombination between the lambda genome and plasmid pBR322 in Escherichia coli, even though these deoxyribonucleic acids (DNAs) did not share extensive regions of homology. The characterization of these recombinant DNAs by heteroduplex analysis and restriction endonucleases is described. All but one of the recombinants appeared to have resulted from reciprocal recombination between a site on lambda DNA and a site on the plasmid. In general, there were two classes of recombinants. One class appeared to have resulted from recombination at the phage attachment site that probably resulted from lambda integration into secondary attachment sites on the plasmid. Seven different secondary attachment sites on pBR322 were found. The other class resulted from plasmid integration at other sites that were widely scattered on the lambda genome. For this second class of recombinants, more than one site on the plasmid could recombine with lambda DNA. Thus, the recombination did not appear to be site specific with respect to lambda or the plasmid. Possible mechanisms for generating these recombinants are discussed.     

Degradation in vitro of bacteriophage lambda N protein by Lon protease from Escherichia coli

Lon protease from Escherichia coli degraded lambda N protein in a reaction mixture consisting of the two homogeneous proteins, ATP, and MgCl2 in 50 mM Tris, Ph 8.0. Genetic and biochemical data had previously indicated that N protein is a substrate for Lon protease in vivo (Gottesman, S., Gottesman, M., Shaw, J. E., and Pearson, M. L. (1981) Cell 24, 225-233). Under conditions used for N protein degradation, several lambda and E. coli proteins, including native proteins, oxidatively modified proteins, and cloned fragments of native proteins, were not degraded by Lon protease. Degradation of N protein occurred with catalytic amounts of Lon protease and required the presence of ATP or an analog of ATP. This is the first demonstration of the selective degradation of a physiological substrate by Lon protease in vitro. The turnover number for N protein degradation was approximately 60 +/- 10 min-1 at pH 8.0 in 50 mM Tris/HCl, 25 mM MgCl2 and 4 mM ATP. By comparison the turnover number for oxidized insulin B chain was 20 min-1 under these conditions. Kinetic studies suggest that N protein (S0.5 = 13 +/- 5 microM) is intermediate between oxidized insulin B chain (S0.5 = 160 +/- 10 microM) and methylated casein (S0.5 = 2.5 +/- 1 microM) in affinity for Lon protease. N protein was extensively degraded by Lon protease with an average of approximately six bonds cleaved per molecule. In N protein, as well as in oxidized insulin B chain and glucagon, Lon protease preferentially cut at bonds at which the carboxy group was contributed by an amino acid with an aliphatic side chain (leucine or alanine). However, not all such bonds of the substrates were cleaved, indicating that sequence or conformational determinants beyond the cleavage site affect the ability of Lon protease to degrade a protein.