Requirement for protein synthesis for survival of unmodified bacteriophage T1 in a restricting host.

At high multiplication of infection, a substantial fraction of restricting cells (P1 lysogens) could be productively infected by unmodified coliphage T1 (T1.0) provided that protein synthesis was uninhibited during the first 5 min of infection. Successful infection under restricting conditions was accompanied by more genetic recombination than was seen under nonrestricting host, the recombination frequency declined for markers on T1.0 genomes; no effect was seen on recombination between markers on modified (T1.P) genomes. This suggested that recombination between unmodified genomes may be essential for their survival under conditions of host restriction. In a restricting host, genetic markers on T1.0 could recombine with T1.P even when the rescuing phage was added 6 min after T1.0 infection. However, even marker rescue recombination was diminished when protein synthesis was inhibited during early infection. Since DNA restriction is an early event, protein synthesis may be required soon after infection of a restricting host by T1.0 in order to preserve restriction-damaged DNA in a form that can participate in recombination. Experiments are also described that rule out some possibilities for the role of such a protein(s).     

Physiological Study of Cooperative Infection by Restricted Bacteriophage T1

The ability of certain phages to successfully infect a restricting host at a high multiplicity of infection is known as cooperative infection or cooperation. We have examined the ability of unmodified T1 (T1.0) to participate in cooperative infection in cells possessing the P1 restriction system. We have found that cooperation is dependent upon protein synthesis during the first few minutes after phage infection. However, we have been unable to attribute the necessary protein to a known T1 cistron. Degradation of the restricted T1 genome is approximately equally extensive whether cooperative infection occurs or whether it is blocked by chloramphenicol. It is postulated that an inducible host repair mechanism may be responsible for the phenomenon of cooperative infection.     

The effect of B specific restriction and modification of DNA on linkage relationships in f1 bacteriophage. II. Evidence for a heteroduplex intermediate in f1 recombination

We have analyzed the results of three gene II amber × gene II amber f1 phage crosses. Each was done in a non-restricting (K) host, and in a restricting (B) host. In each cross, only one parent was sensitive to B restriction. The other parent was protected from B restriction, either because of a combination of genetic mutation at one site governing sensitivity to B restriction, and B specific modification at the other, or because of genetic mutation at both sites. In all cases, B restriction resulted in the disruption of linkage relationships between the gene II region and the unselected sensitivity site markers.Previously we have shown that when such crosses involve a protected parent which is B modified at both sensitivity sites, linkage relationships remain the same under restricting and non-restricting conditions. Hence, the SB sites seem to manifest a striking marker effect in restricted crosses in which protection is conferred by mutation rather than modification. Taken together, these results imply that, in a restricted cross, the B host specificity system can distinguish a protected parent which is B modified from one which is a sensitivity site mutant.Since such a distinction could be made most easily on an intermediate structure containing hybrid DNA, we interpret these results in terms of a recombination mechanism mediated by an asymmetric heteroduplex.     

Modulation of EcoKI restriction in vivo: role of the lambda Gam protein and plasmid metabolism.

Two novel types of alleviation of DNA restriction by the EcoKI restriction endonuclease are described. The first type depends on the presence of the gam gene product (Gam protein) of bacteriophage lambda. The efficiency of plating of unmodified phage lambda is greatly increased when the restricting Escherichia coli K-12 host carries a gam+ plasmid. The effect is particularly striking in wild-type strains and, to a lesser extent, in the presence of sbcC and recA mutations. In all cases, Gam-dependent alleviation of restriction requires active recBCD genes of the host and recombination (red) genes of the infecting phage. The enhanced capacity of Gam-expressing cells to repair DNA strand breaks might account for this phenomenon. The second type is caused by the presence of a plasmid in a restricting host lacking RecBCD enzyme. Commonly used plasmids such as the cloning vector pACYC184 can produce such an effect in strains carrying recB single mutations or in recBC sbcBC strains. Plasmid-mediated restriction alleviation in recBC sbcBC strains is independent of the host RecF, RecJ, and RecA proteins and phage recombination functions. The presence of plasmids can also relieve restriction in recD strains. This effect depends, however, on the RecA function in the host. The molecular mechanism of the plasmid-mediated restriction alleviation remains unclear.     

Marker Rescue in Haemophilus influenzae Bacteriophage

Rescue of wild-type markers from transfecting phage DNA in cómpetent Haemophilus influenzae cells by superinfection with temperature-sensitive phage (marker rescue) is approximately linearly dependent upon the concentration of transfecting DNA. The amount of marker rescue with a constant amount of transfecting DNA increases with increasing multiplicities of superinfecting phage up to about 4, and then decreases at higher multiplicities. Host restriction of transfecting DNA does not affect marker rescue. The frequency of wild-type recombinants from marker rescue is much greater than that from multiple infection with whole phages, and is comparable to that obtained with two mutant-transfecting DNAs. The amount of marker rescue decreases exponentially with time between entrance of the transfecting DNA and superinfection, and the rate of decrease is independent of map position of the rescued marker. Marker rescue is drastically reduced in the recombination-defective strains, rec1 and rec2.     

Mapping of Prophage and Mature Deoxyribonuleic Acid from Temperate Bacillus Bacteriophage φ105 by Marker Rescue

By using temperature-sensitive (ts) and suppressor-sensitive (sus) mutants, 11 essential genes have been identified in phage phi105. The order of the genes has been established in two- and three-factor crosses. The genes can be arranged in a linear order; this order is identical in the vegetative phage and in the prophage. One gene essential for phage deoxyribonucleic acid (DNA) synthesis has been found. Marker rescue from prophage and mature DNA, taken up by competent bacteria, was studied by superinfection with phage carrying one sus and one ts mutation. In prophage DNA, all single markers studied are rescued at similar frequencies. The frequency of co-rescue of two markers is proportional to the recombinational distance between the markers. Thus, colinearity between the genetic map and the position on the DNA molecule of those mutations used to establish the map is demonstrated. The results indicate that the recombination frequencies observed in vegetative crosses are a relative measure of the physical distance between markers. All single markers are not rescued at equal frequencies from mature DNA. The frequency of co-rescue of two markers is related to the recombinational distance only over a distance about one-fourth or less of the genetic map. Markers separated by 10% recombination, or more, are co-rescued at 5 to 10% of the frequency of rescue of single markers. Shearing of mature DNA into half-sized molecules reduces the efficiency by which single markers are rescued by a factor of 5 to 10. The results of experiments on co-rescue of two markers from half-sized mature DNA indicate a preferred break-point near the middle of the genetic map; the results are compatible with a nonpermuted sequence in mature DNA. It is pointed out and discussed that mature DNA exhibits several anomalies in marker rescue experiments.     

Genetic Analysis of tox+ and tox? Bacteriophages of Corynebacterium diphtheriae

A series of mutants derived from the temperate corynebacteriophages beta(tox+), gamma(tox-), and L(tox+) was isolated and characterized. In three-factor crosses between mutant beta phages the relative map order of the genetic markers determining extended host ranges (h and h') and loss of ability to lysogenize (c) was found to be h--c--h'. Recombination between markers was observed in matings between phage beta and the heteroimmune corynebacteriophages gamma and L. In such matings between heteroimmune phages the c markers of phages beta and gamma failed to segregate from the imm markers which determine the specificity of lysogenic immunity in these phages. The factor which directs the synthesis of diphtherial toxin during infection of appropriate corynebacterial hosts by toxinogenic corynebacteriophages is designated tox(+). It was possible to show that the tox(+) determinant of phage beta behaves as a single genetic element which occupies a position between the loci h and imm on the genetic map of this phage. Genetic recombination between mutants of phage beta occurred at very low frequencies in biparental matings performed by mixed infection of Corynebacterium diphtheriae C7(s)(-)(tox-). Considerably higher recombination frequencies were observed when lysogenic bacterial strains carrying one parental phage as prophage were induced by ultraviolet irradiation and then superinfected by the second parental phage. Maximal stimulation of genetic recombination between mutant beta phages was detected when superinfection followed ultraviolet irradiation of the lysogenic cells within a limited period of time. In matings between phages with incomplete genetic homology, the stimulation of recombination by ultraviolet radiation was much less effective.     

Salmonella recD mutations increase recombination in a short sequence transduction assay.

We have identified recD mutants of Salmonella typhimurium by their ability to support growth of phage P22 abc (anti-RecBCD) mutants, whose growth is prevented by normal host RecBCD function. As in Escherichia coli, the recD gene of S. typhimurium lies between the recB and argA genes at min 61 of the genetic map. Plasmids carrying the Salmonella recBCD+ genes restore ATP-dependent exonuclease V activity to an E. coli recBCD deletion mutant. The new Salmonella recD mutations (placed on this plasmid) eliminate the exonuclease activity and enable the plasmid-bearing E. coli deletion mutant to support growth of phage T4 gene 2 mutants. The Salmonella recD mutations caused a 3- to 61-fold increase in the ability of a recipient strain to inherit (by transduction) a large inserted element (MudA prophage; 38 kb). In this cross, recombination events must occur in the short (3-kb) sequences that flank the element in the 44-kb transduced fragment. The effect of the recD mutation depends on the nature of the flanking sequences and is likely to be greatest when those sequences lack a Chi site. The recD mutation appears to minimize fragment degradation and/or cause RecBC-dependent recombination events to occur closer to the ends of the transduced fragment. The effect of a recipient recD mutation was eliminated if the donor P22 phage expressed its Abc (anti-RecBC) function. We hypothesize that in standard (high multiplicity of infection) P22-mediated transduction crosses, recombination is stimulated both by Chi sequences (when present in the transduced fragment) and by the phage-encoded Abc protein which inhibits the host RecBCD exonuclease.     

Genetic Heterozygosity in Unreplicated Bacteriophage λ Recombinants

Bacteriophage crosses using density-labeled parents have been carried out under conditions restricting DNA synthesis. The parental material and genetic contributions to progeny manifesting recombination within a genetic interval sufficiently short to exhibit high negative interference have been examined. The unreplicated products of recombination isolated as phage particles appear to contain long continuous heteroduplex regions which are heterozygous for the closely linked markers. Recombination between closely linked markers seems to be the consequence of the removal of base-pair mismatches that are present within the heteroduplex regions. This localized reduction of heterozygosity within the heteroduplex regions that join the parental components of recombinant DNA molecules can account for high negative interference.     

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.     

Integration of the plasmid prophages P1 and P7 into the chromosome of Escherichia coli.

The prophages of the related temperate bacteriophages P1 and P7, which normally exist as plasmids, suppress Escherichia coli dnaA (ts) mutants by integrating into the host chromosome. The locations of the sites on the prophage used for integrative recombination were identified by restriction nuclease analysis and DNA-DNA hybridization techniques. The integration of P1 and P7 often involves a specific site on the host DNA and a specific site on the phage DNA; the latter is probably the end of the phage genetic map. When this site is utilized, the host Rec⁺ function is not required. In Rec⁺ strains, P1 and P7 may also recombine with homologous regions on the host chromosome; at least one of these regions is an IS1 element. In some integration events, prophage deletions are observed which are often associated with inverted repeat structures on the phage DNA. Thus, P1 and P7 may employ one of several different mechanisms for integration.     

Interruption-deficient mutants of bacteriophage T5: analysis of single-site mutants.

The properties of viable mutants of bacteriophage T5 that lack, singly, each of the four major sites at which single-chain interruptions normally occur in T5 DNA are described. The mutations responsible for loss of each interruption were mapped by analysis with HhaI, a restriction endonuclease with a cleavage site (pGCGC) that occurs at the 5' termini of the major interruptions (B. P. Nichols and J. E. Donelson, J. Virol. 22:520-526, 1977). For each mutant tested, loss of a specific interruption resulted in loss of a specific HhaI cleavage site. Multiple single-site mutants were constructed to determine the effect of loss of more than one interruption on phage viability. These recombinants, including a phage that lacks the four major interruptible sites, were fully viable and did not exhibit a compensating increase in the frequency of minor interruptions. The effect of loss of a specific interruption on genetic recombination was tested in two-factor crosses with markers that occur close to, but on opposite sites of, the interruption. Loss of the interruptible site did not affect recombination frequency.     

Isolation of a bacterial host selective for bacteriophage T4 containing cytosine in its DNA.

An Escherichia coli B strain, B834 galU56, has been isolated which supports growth of bacteriophage T4 with cytosine in its DNA while restricting growth of T4 with hydroxymethylcytosine. This host is partially deficient in uridine diphosphoglucose as determined by the ability of DNA isolated from T4 grown on it to accept glucose in an in vitro assay. In this mutant an intact rgl restriction system recognizes unglucosylated hydroxymethylcytosine residues in phage DNA, while the absence of a functional rB restriction function prevents degradation of unmodified DNA containing cytosine.     

An integrated genetic map and a new set of simple sequence repeat markers for pearl millet, <Emphasis Type="Italic">Pennisetum glaucum</Emphasis>

Over the past 10 years, resources have been established for the genetic analysis of pearl millet, Pennisetum glaucum (L.) R. Br., an important staple crop of the semi-arid regions of India and Africa. Among these resources are detailed genetic maps containing both homologous and heterologous restriction fragment length polymorphism (RFLP) markers, and simple sequence repeats (SSRs). Genetic maps produced in four different crosses have been integrated to develop a consensus map of 353 RFLP and 65 SSR markers. Some 85% of the markers are clustered and occupy less than a third of the total map length. This phenomenon is independent of the cross. Our data suggest that extreme localization of recombination toward the chromosome ends, resulting in gaps on the genetic map of 30 cM or more in the distal regions, is typical for pearl millet. The unequal distribution of recombination has consequences for the transfer of genes controlling important agronomic traits from donor to elite pearl millet germplasm. The paper also describes the generation of 44 SSR markers from a (CA)_n-enriched small-insert genomic library. Previously, pearl millet SSRs had been generated from BAC clones, and the relative merits of both methodologies are discussed.     

Action of ethyl and methyl methane sulfonates on DNA injection and genetic recombination in T7 bacteriophage.

After treatment with methyl or ethyl methane sulfonate, T7 amber mutants display a reduced capacity for recombination. Moreover, alkylation reduces recombination frequency involving markers on the right-hand side of the genetic map more than it reduces recombination frequency involving markers on the left-hand side. We interpret this to mean that alkylation can stop DNA injection at any point along the DNA molecule, and that T7 phage injects its DNA in a unique fashion starting from the end carrying the genes for early proteins.     

Isolation and characterization of a new ruminal bacteriophage lytic toStreptococcus bovis

A new bacteriophage, designated F4, was isolated from the ruminal fluid of a calf. The host range of F4 phage was limited to five strains ofStreptococcus bovis out of ten tested on which clear plaques 0.6–1.2 mm in diameter were found. Bacteriophage F4 had an elongated head 75 nm long and 33 nm wide with a noncontractile flexible tail 100 nm in length on average. This phage is defective in the generation of plaques at low multiplicities of infection. Its genome consists of double-stranded linear DNA of 60.38 kb lacking cohesive ends. The F4 DNA was analyzed with 13 restriction enzymes. The restriction enzymes that did not cleave it wereBamHI,EcoRI,PvuI, andSmaI. The circular restriction map was constructed with four restriction endonucleases (XbaI,EcoI,SalI, andBglI).     

Marker-Dependent Recombination in T4 Bacteriophage. II. the Evaluation of Mismatch Repairabilities in Crosses within Indicator Distances

The contribution of mismatch repair to genetic recombination in T4 phage has been evaluated by three independent approaches: (1) testing for non-additivity of recombinant frequencies; (2) measurements of double exchange frequencies in three-factor crosses: (3) comparisons of recombination abilities of mutations occupying the same site. Quantitative agreement among the results of these approaches suggests that within distances much less than the mean length of hybrid regions, mismatch repair accounts perfectly for high negative interference as measured in three-factor crosses and as manifested by non-additivity in two-factor crosses. The mismatch repair mechanism readily recognizes only particular mismatches, the repair frequency being dependent on the base sequence in both strands of the mismatched region.     

Break-Join Recombination in Phage λ

In phage lambda, when DNA replication is blocked, recombination mediated by the Red pathway occurs only near the double-chain break site, cos, that defines the termini of the virion chromosome. The recombinants initiated by cos contain newly synthesized DNA near cos, in amount corresponding to a few percent of the length of lambda. A restriction enzyme cut delivered to one parent far from cos results in elevated recombination near the restriction site. Recombinants induced by this cut have a similarly small amount of DNA synthesis in these replication-blocked crosses. When restriction cuts are introduced in the presence of normal amounts of all of the DNA replication enzymes, many of the resulting recombinants still enjoy, at most, a small amount of DNA synthesis associated with the exchange event. Thus, these experiments fail to support the previously considered possibility that Red-mediated recombination in lambda proceeds largely through a break-copy pathway.     

Asymmetry in the frequencies of reciprocal recombinants in crosses of T4 phage rIIB mutants]

The frequencies of reciprocal recombinants in crosses between rIIB mutants of T4 phage were shown to differ from each other. In terms of the correction model, this asymmetry of genetic recombination was used to measure the comparative correctability of the mismatched regions to the wild type and to the mutant alleles. The data obtained are in quantitative agreement with the analogous values for the same mismatched regions determined by comparison of the markers located at the same site. This strongly suggests that the asymmetry of genetic recombination in T4 reflects the corresponding difference in rates of correction of the mismatched regions in heteroduplexes in opposite directions.