Realignment of the Genetic Map of the Terminus of the rIIB Cistron of Bacteriophage T4

Duplication end-point mapping in the rIIB cistron indicates that the order of the BS-B10b segments is the inverse of that presented in Benzer's (1961) genetic maps. This findings is supported by two- and three-factor crosses and the phenotypes of rII deletions extending into the D region.     

Stationary phase-like properties of the bacteriophage λ Rex exclusion phenotype

The rex genes of bacteriophage lambda were found to protect lysogenic Escherichia coliK host cells against killing by phage T4 rII, when compared in parallel to isogenic Rex(-) lysogens and nonlysogens. This protective effect was abrogated upon mutation of the host stationary-phase sigma factor RpoS. Rex(+) lysogens infected by T4 rII contracted, formed aggregates and shed flagella, thus resembling cells entering stationary phase. These phenotypes were accentuated in nonlysogenic cells carrying multicopy plasmids expressing rexA-rexB: cells were about two-fold contracted in length, expressed membrane-bound and detached flagella, were insensitive to infection by a variety of phages and clumped extensively; in addition, cultures of these cells were odorous. Our observations support the hypothesis that the Rex system can cause a stationary-phase-like response that protects the host against infection by T4 rII.     

Novel rII duplications in bacteriophage T4.

The properties of two rII complementation heterozygotes (D5B and D7A) of bacteriophage T4 are described. These strains are characterized by their stability, each forming less than 10-3 r segregants among their viable progeny, and by their segregation of only one of the two parental types. No increase in r progeny was found on crossing D7A or D5B with T4r+, indicating that the duplications in these strains are not separated by an essential region of the phage genome. Both D5B and D7A from h-2+/h-4+ heterozygotes at frequencies similar to T4r+, suggesting that the duplicated regions in these strains are short. The progeny of these h-2+/h-4+ heterozygotes retain heterozygosity for rII but not for h: therefore, D5B and D7A are not stabilized terminal redundancy complementation heterozygotes. We conclude that D5B and D7A contain very short tandem duplications and we present structures consistent with the observed characteristics of these phages.     

The Genetic Constitution of Tandem Duplications of the rII of Bacteriophage T4d

Methods for genetically mapping the end points of tandem duplications of the rII region of bacteriophage T4D are presented. Analysis of ten duplications indicates (1) that the position of duplication end points and therefore the length of the duplicated segment differ in strains of independent origin; (2) that there is a direct relationship between segregation frequency and length; (3) that segregation is more frequent than expected on the basis of standard genetic mapping; and (4) that while duplications frequently include non-rII genetic material, frequently they do not include the entire rII region. The duplications studied range from less than two to about five cistrons in length.     

Point Mutants in the D2a Region of Bacteriophage T4 Fail to Induce T4 Endonuclease IV

We have studied the properties of presumptive point mutants in the D2a region of bacteriophage T4. Dominance tests showed that the D2a mutation was recessive to the wild-type allele. The mutations were shown to map in the D2a region by complementation against rII deletions. The D2a mutations were also located between gene 52 and rIIB by two- and three-factor crosses. The mutants are located at at least two distinct loci in the D2a region. The point mutants grow normally on all hosts tested and none of the mutants makes T4 endonuclease IV. We propose the name "denB" for the D2a locus.     

The structure of rII diploids of phage T4

Summary Crosses between the rII deletion 1589 and an overlapping deletion such as 638 which lies entirely within the rIIB cistron generate a few T4 phage particles, the so-called rII diploids, which contain two copies of the rII region, one derived from each parent in the cross. A specific model is proposed to account for the properties of these rII diploids. This model postulates: 1) the rII diploids contain a tandem duplication, 2) the duplicated region extends both to the left and right of the rII region itself, and 3) during phage multiplication recombination occurs between homologous regions of the duplication. These assumptions lead to precise predictions on the following points: 1) the frequency at which haploid 1589 and 638 phage particles are generated during multiplication, 2) the ratio of 1589 and 638 phage amongst the segregants, 3) the relative lengths of terminal redundancy to be found in the rII diploids, the 1589 and 638 segregants and wild-type T4, and 4) the formation and properties of homozygous diploids containing two copies either of the 1589 or 638 region.Experiments are reported which validate the model on these points and also indicate how the homozygous diploids can be utilized to generate new rII diploids with structures which would otherwise be unobtainable.     

Ligase-Defective Bacteriophage T4 II. Physiological Studies

The timing of the suppression of gene 30 (deoxyribonucleic acid ligase) mutations by rII mutations was studied by temperature shift-down experiments with a temperature-sensitive rII mutation. The rII function must remain inactivated for about 5 to 8 min at 37 C for suppression to occur, thus making suppression an early function. This result is in agreement with the timing of expression of other rII functions. A gene 30 defect can also be overcome by replacing the Na(+) cation in the growth medium with the Mg(2+) cation, a result similar to the relief of the lethality of rII mutations in lambda lysogens. Prior infection with bacteriophages T3 or T7, which produce their own deoxyribonucleic acid ligases, can also partially overcome the lethality of gene 30 mutations.     

Effects of Uvsx, Uvsy and DNA Topoisomerase on the Formation of Tandem Duplications of the Rii Gene in Bacteriophage T4

We have characterized tandem duplications in the rII regions of phage T4. The rII deletion r1589 blocks only the function of the rIIA cistron, although it extends into the B cistron. Another rII deletion, r1236, blocks the function of the rIIB cistron and overlaps r1589. When a cross is made between r1589 and r1236, true rII(+) progeny cannot form. Instead, anomalous phenotypically rII(+) phages are detected carrying an rII region from each parent. Analyses of nucleotide sequences of the recombination junctions indicate that recombination takes place between short regions of homology (from 2 to 10 bp). Open reading frames of the recombinants deduced from the nucleotide sequences reveal that they contain a normal rIIA cistron and one of a variety of fused, duplicated rIIB cistrons. The T4 uvsX and uvsY genes, which participate in homologous recombination, are involved in this duplication formation. T4 DNA topoisomerase is encoded by genes 39, 52 and 60. Mutations in 52 and 60 reduced the frequency of such duplications, but mutations in gene 39 and some in gene 52 did not. Hence, the effects of topoisomerase mutations are allele-specific. Models are proposed in which these proteins are involved in tandem duplication.     

Selective Allele Loss in Mixed Infections with T4 Bacteriophage

Evidence is presented that when E. coli B is mixedly infected with T4D wild type and rII deletion mutants, the excess DNA of the wild type allele is lost. No loss is seen in mixed infections with rII point mutants and wild type. In similar experiments with lysozyme addition mutants, the mutant allele is lost. We believe these results demonstrate a repair system which removes "loops" in heteroduplex DNA molecules. A number of phage and host functions have been tested for involvement in the repair of the excess DNA, and T4 genes x and v have been implicated in this process.     

Analysis of expression of the rII gene function of bacteriophage T4.

Temperature-sensitive (ts) mutants of the T4 phage rII gene were islated and used in temperature shift experiments that revelaed two different expressions for the normal rII (rII+) gene function in vivo: (i) an early expression (0 to 12 min postinfection at 30 C) that prevents restriction of T4 growth in Escherichia coli hosts lysogenic for gamma phage, and (ii) a later expression (12 to 18 min postinfection at 30 C) that results in restriction of T4 growth when the phage DNA ligase (gene 30) is missing. The earlier expression appeared to coincide with the period of synthesis of the protein product of the T4 rIIA cistron, whereas the later expression occurred after rIIA protein synthesis had stopped. The synthesis of the protein product of the rIIB cistron continues for several minutes after rIIA protein synthesis ceases (O'Farrell and Gold, 1973). The two rII+ gene expressions might require different molar ratios of the rIIA and rIIB proteins. It is possible that the separate expressions of rII+ gene function are manifestations of different associations between the two rII proteins and other T4-induced proteins that are synthesized or activated at different times after phage infection.     

Recombination and transfection mapping of cistron 5 of bacteriophage sp82g

Following infection of E. coli B with ligase-deficient rII bacteriophage T4D recombination between linked markers is increased 4.2 fold and heterozygote frequency increased 2.3 fold. In such infection recombination occurs at a rapid rate for an extended period. This is in contrast to the time course of recombination observed in wild-type, lysis-inhibited, or lysis-defective (gene t defective) infection. In all of these cases recombination under standard cross conditions occurs early in the vegetative cycle. The increased recombination in ligase-deficient rII infection is reduced in a bacterial strain which produces greater than normal levels of host ligase. These results indicate that ligase has a crucial role not only in the replication of DNA but also in recombination. The level of ligase may determine whether DNA replication occurs with or without concomitant recombination.     

Correlation between genetic map and map of cleavage sites for sequence-specific endonucleases SalI, KpnI, BglI, and BamHI in bacteriophage T4 cytosine-containing DNA.

Cleavage sites for SalI, KpnI, BglI, and BamHI in cytosine-containing DNA from T4 alc10(alc) nd28(denA) D2a2(denB) amE51x5(56) amN55x5(42) have been mapped relative to each other, and the positions of deletions sa delta 9 (D1-stp), r1589(rII), del(39-56)12, and tk2(rI-tk) relative to these cleavage sites have been determined. Based on these analyses, a physical map of the T4 genome containing 166 kilobase pairs has been constructed.     

Wild-type bacteriophage T4 is restricted by the lambda rex genes.

The bacteriophage T4 rII genes and the lambda rex (r exclusion) genes interact; rII mutants are unable to productively infect rex+ lambda lysogens. The relationship between rex and rII has been found to be quantitative, and plasmid clones of rex have excluded not only rII mutants but T4 wild type and most other bacteriophages as well. Mutations in the T4 motA gene substantially reversed exclusion of T4 by rex.     

Synthesis of Bacteriophage and Host DNA in Toluene-Treated Cells Prepared from T4-Infected Escherichia coli: Role of Bacteriophage Gene D2a

We investigated the synthesis of DNA in toluene-treated cells prepared from Escherichia coli infected with bacteriophage T4. If the phage carry certain rII deletion mutations, those which extend into the nearby D2a region, the following results are obtained: (i) phage DNA synthesis occurs unless the phage carries certain DNA-negative mutations; and (ii) host DNA synthesis occurs even though the phage infection has already resulted in the cessation of host DNA synthesis in vivo. The latter result indicates that the phage-induced cessation of host DNA synthesis is not due to an irreversible inactivation of an essential component of the replication apparatus. If the phage are D2a(+), host DNA synthesis in toluene-treated infected cells is markedly reduced; phage DNA synthesis is probably also reduced somewhat. These D2a effects, considered along with our earlier work, suggest that a D2a-controlled nuclease, specific for cytosine-containing DNA, is active in toluene-treated cells.     

Reversion of Frameshift Mutations Stimulated by Lesions in Early Function Genes of Bacteriophage T4

Temperature-sensitive (ts) mutants representative of a number of genes of phage T4 were crossed with rII mutants to allow isolation of ts, rII double-mutant recombinants. The rII mutations used were characterized as frameshift mutations primarily on the basis of their revertability by proflavine. For each ts, rII double mutant, the effect of the ts mutation on spontaneous reversion of the rII mutation was determined over a range of incubation temperatures. A strong enhancement in reversion of two different rII mutants was detected when they were combined with tsL56, a mutation in gene 43 [deoxyribonucleic acid (DNA) polymerase]. Three other mutants defective in gene 43 enhanced reversion about fourfold. Two mutations in gene 32, which specifies a protein necessary for DNA replication, enhanced reversion about 5-fold and 18-fold, respectively. Two additional mutations in gene 43 and two in gene 32 had no effect. Fivefold and threefold enhancements in reversion were also found with mutations in genes 44 (DNA synthesis) and 47 (deoxyribonuclease), respectively. No significant effect was found with mutations in seven additional genes. The results of other workers suggest that frameshift mutations arise from errors in strand alignment during repair synthesis occurring at chromosome tips. Our results show that such errors can be enhanced by mutations in the DNA polymerase, the gene 32 protein, and the enzymes specified by genes 44 and 47. This implies that these proteins are employed in the repair process occurring at chromosome tips and that mutational errors in these proteins can lead to loss of ability to recognize and reject strand misalignments.     

Properties of Bacteriophage T4 Mutants Defective in Gene 30 (Deoxyribonucleic Acid Ligase) and the rII Gene

In Escherichia coli K-12 strains infected with phage T4 which is defective in gene 30 [deoxyribonucleic acid (DNA) ligase] and in the rII gene (product unknown), near normal levels of DNA and viable phage were produced. Growth of such T4 ligase-rII double mutants was less efficient in E. coli B strains which show the "rapidlysis" phenotype of rII mutations. In pulse-chase experiments coupled with temperature shifts and with inhibition of DNA synthesis, it was observed that DNA synthesized by gene 30-defective phage is more susceptible to breakdown in vivo when the phage is carrying a wild-type rII gene. Breakdown was delayed or inhibited by continued DNA synthesis. Mutations of the rII gene decreased but did not completely abolish the breakdown. T4 ligase-rII double mutants had normal sensitivity to ultraviolet irradiation.     

Induction of mutation in phage T4 by extracellular treatment with methylene blue and visible light

Summary Photodynamic inactivation with methylene blue and light (MB+Li) of maximally sensitized phages T4 and T4rII nearly followed single-hit kinetics. Not so mutation induction, which in one phage (T4rII N₁₇) tested showed multi-hit kinetics. This difference and the fact that T4rII phages with a GC base pair at the site of the rII-mutation showed no enhanced backmutation when compared to rII phages with an AT base pair or to sign mutants suggests that there is no guanine specificity for MB+Li-induced mutation in phage T4.