Replication and Recombination of Gene 59 Mutant of Bacteriophage T4D

After infection of Escherichia coli B with phage T4D carrying an amber mutation in gene 59, recombination between two rII markers is reduced two- to three-fold. This level of recombination deficiency persists even when burst size similar to wild type is induced by the suppression of the mutant DNA-arrest phenotype. In the background of two other DNA-arrest mutants in genes 46 and 47, a 10- to 11-fold reduction in recombination is observed. The cumulative effect of gene 59 mutation on gene 46-47 mutant suggests that complicated interactions must occur in the production of genetic recombinants. The DNA-arrest phenotype of gene 59 mutant can be suppressed by inhibiting the synthesis of late phage proteins. Under these conditions, DNA replicative intermediates similar to those associated with wild-type infection are induced. Synthesis of late phage proteins, however, results in the degradation of mutant 200S replicative intermediate into 63S DNA molecules even in the absence of capsid assembly. Although these 63S molecules are associated with membrane, they do not replicate. These results suggest a role for gene 59 product, in addition to a possible requirement of concatemeric DNA in late replication of phage T4 DNA.     

Recombination in phage T4 gene-43 (DNA polymerase) mutants.

Summary The effect of phage T4 gene 43 (DNA polymerase) mutations on recombination between adjacent base pairs was measured in rII amber and opal mutants.The mutator allele tsL56 did not promote recombination frequencies at the two sites in which its effect was studied. The antimutator allele tsCB87 caused slight or no reduction in recombination frequencies at five sites.Abbreviations A, T, G and C are adenine, thymine, guanine and 5-hydroxymethylcytosine, respectively     

Molecular Recombination in T4 Bacteriophage Deoxyribonucleic Acid I. Tertiary Structure of Early Replicative and Recombining Deoxyribonucleic Acid

A replicative hybrid resulting from the infection of heavy (substituted with 5-bromodeoxyuridine) bacteria with light (not substituted with 5-bromodeoxyuridine) radioactive bacteriophage was isolated from a CsCl density gradient. Sedimentation studies indicate that 60% of the deoxyribonucleic acid (DNA) behaves as if it were in units more than four times as large as an intact reference molecule. Under the electron microscope, hybrid molecules appeared tangled, showed puffs and loops, occupied a small area, and often had a total length twice that of mature phage. This indicates that sucrose gradient sedimentation is not applicable as a method for estimating the relative molecular size of replicative forms of DNA. After denaturation, the separated strands of hybrid were of the same size as those of reference DNA. CsCl density gradient analysis revealed no terminal covalent addition of new material to the old parental strand. The possibility of a continuous growth of the DNA molecule, either on a single-stranded level or as a double helical structure, is disproved. When chloramphenicol (CM) was added at critical times after infection, DNA synthesis continued at a constant rate. The parental label soon assumed and retained a hybrid density, despite concomitant synthesis of DNA, throughout the rest of the period of incubation in CM. The hybrid moiety, however, actively participated in replication and exchanged its partner strand for a new one; this was demonstrated by changing the density label during incubation in CM. A new enzyme synthesized shortly after infection introduced single-stranded "nicks" into the parental DNA. Since nicking can be inhibited by chloramphenicol, the responsible enzyme is not of host origin. The time of the appearance of this enzyme coincided with the onset of molecular recombination. Another enzyme, which mediates the repair of the continuity of the polynucleotide chain after recombination, appeared after recombination. If selectively inhibited by chloramphenicol, recombinant molecules remained unrepaired, and, upon denaturation, the parental fragment was liberated in pure form.     

Synthesis of recA protein and induction of bacteriophage lambda in single-strand deoxyribonucleic acid-binding protein mutants of Escherichia coli.

We investigated the capacity of Escherichia coli mutants defective in the single-strand deoxyribonucleic acid (DNA)-binding protein to amplify the synthesis of the recA protein, induce prophage lambda, and degrade their DNA after treatment with ultraviolet radiation, mitomycin C, or bleomycin. The thermosensitive ssbA1 strain induced recA protein and lambda phage normally at 30 degrees C, but no induction was observed at 42 degrees C when ultraviolet radiation or mitomycin C was used. The lexC113 mutant did not amplify recA protein synthesis or induce phage lambda at either 30 or 42 degrees C with those agents. Bleomycin was able to elicit induction of recA and phage lambda in both mutants at any temperature. After induction with ultraviolet radiation at the elevated temperature, no DNA degradation was observed for 40 min, but at later times there was increased degradation in the lexC113 strain, compared with the wild type, and even greater degradation in the ssbA1 mutant. We discuss the role of single-strand DNA-binding protein in induction and the possibility that the lexC product may exert its influence on recA and lambda induction at the level of the single-strand DNA gap.     

Characteristics of the intragenic recombination of T4B bacteriophage amber mutants under nonpermissive (su-) conditions

Intragenic recombination of bacteriophage T4B amber mutants in early genes 30, 32, 42, 43, 44, 56 and in late gene 7 in su- cells of Escherichia coli B was studied. The frequency of recombination under such conditions was increased in genes 30, 43 and 7, but it was lowered in genes 46 and 44, and was completely inhibited in genes 32, 42 and 56. The level of stimulation or inhibition of recombination frequencies in early genes was gene-specific and did not depend either on the distances between amber mutations, or on progeny phage maturation delay. On the other hand, the level of recombination stimulation in the late gene 7 was greatly influenced by the distances between amber mutations tested. Wild type alleles arising in su- cells during recombination proved to be functionally active, and their activity caused the increase in progeny phage yield and in a partial removal of phage maturation delay.     

Correlation between Pairing Initiation Sites, Recombination Nodules and Meiotic Recombination in Sordaria Macrospora

The decrease of meiotic exchanges (crossing over and conversion) in two mutants of Sordaria macrospora correlated strongly with a reduction of chiasmata and of both types of "recombination nodules." Serial section reconstruction electron microscopy was used to compare the synapsis pattern of meiotic prophase I in wild type and mutants. First, synapsis occurred but the number of synaptonemal complex initiation sites was reduced in both mutants. Second, this reduction was accompanied by, or resulted in, modifications of the pattern of synapsis. Genetic and synaptonemal complex maps were compared in three regions along one chromosome arm divided into well marked intervals. Reciprocal exchange frequencies and number of recombination nodules correlated in wild type in the three analyzed intervals, but disparity was found between the location of recombination nodules and exchanges in the mutants. Despite the twofold exchange decrease, sections of the genome such as the short arm of chromosome 2 and telomere regions were sheltered from nodule decrease and from pairing modifications. This indicated a certain amount of diversity in the control of these features and suggested that exchange frequency was dependent not only on the amount of effective pairing but also on the localization of the pairing sites, as revealed by the synaptonemal complex progression in the mutants.     

Effect of mutations in Escherichia coli genes PolAm RecA, RecB and RecC on the frequency of genetic recombination in amber-mutants involving the early genes of bacteriophage T4]

Effects of mutations in genes PolA, RecA, RecB and RecC of Escherichia coli on the recombination frequencies between rII markers of T4 have been studied in conditions of partial inhibition of some early functions. It was found that the presence of the mutations in genes PolA or RecA decreased significantly the recombination frequency of phage amber mutant in the gene 43 (DNA polymerase), increased it in the case of amber mutation in the gene 46 (exonuclease) and had no effect on the recombination of amber mutants in genes 30, 32, 33, 41, 42, 45, 44, 52. None of the amber mutants studied changed recombination frequencies in the presence of the mutations in genes RecB or RecC. Possible mechanisms of some of the effects observed are discussed.     

Single-strand regions in the deoxyribonucleic acid of competent Haemophilus influenzae.

The deoxyribonucleic acid (DNA) of competent wild-type Haemophilus influenzae and rec1 mutant cells contains single-strand regions, as judged by alkaline sucrose sedimentation, benzoylated naphthoylated diethylaminoethyl-cellulose fractionation, and digestion with an enzyme specific for single-strand regions in DNA. In contrast, the DNA of competent rec2 cells does not contain single-strand regions. Since transforming DNA does not associate with recipient DNA in the rec2 mutant as it does in wild type and rec1, it is concluded that the single-strand regions in the DNA of the competent cells are important for an early step in recombination between cell DNA and transforming DNA.     

Recombination of amber mutants of bacteriophage T4B. II. Localization of amber mutants on maps of genes 30, 34, 35, 36 and 38]

Localization of 275 amber mutants of five genes of phage T4B (30, 34, 35, 36 and 38) on genetic maps allowed us to determine the recombination length of these genes. Gene 34 substantially differs from the rest studied genes by numbers of amber mutants isolated in each gene and by recombination frequency. In particular, according to the results of crossing the flank markers, the recombination length of gene 34 is 10 times greater than in gene 38; using the summary value of recombination frequencies between elementary intervals a 20-fold excess of the length of gene 34 compared with the length of gene 38 was receieved. Molecular weight of the product of gene 34 is only 6 times as great as in gene 38. An elevated recombination frequency was also detected in gene 35. The data obtained indicate a local recombination anomaly at the region of genes 34--35 of bacteriophage T4 genome.     

Region-Specific Recombination in Phage T4. II. Structure of the Recombinants

In this paper, we present results of crosses designed to elucidate the structure of recombinants in the tail-fiber region of bacteriophage T4, in which a glucosylation-dependent recombinations mechanism is operative, and the cause of the "special" recombination in glycosylated crosses is discussed. We present evidence that, when phage are nonglycosylated, recombination in the tail-fiber region proceeds via long heteroduplex overlaps. Mismatched bases within such regions (in nonglycosylated phage) are repaired efficiently (as contrasted to those of glucosylated phage), but asymmetrically; that is, there may be an equal probability of resolving the mismatch to mutant or wild type.     

Physical map of the dispensable region of the genome of E. coli bacteriophage BF23

Using 13 deletion mutants of bacteriophage BF23, physical as well as genetic structures of that portion of the genome which is dispensable for phage growth were investigated. The dispensable region covers at least 15% of the genome of wild type BF23, extending from about 0.2 to 0.35 map unit. Restriction endonuclease (EcoRI and HindIII) cleavage sites and the sites of single-strand interruptions in this dispensable region were localized. It was found that the dispensable region contains an interruption site, which is missing in the mutant BF23st(0) used by Okada and Shimura (1980). Wild-type phage DNA is heterogeneous in the presence or absence of specific single-strand interruptions in this or in a neighboring region of the genome.     

Recombination of bacteriophage T7 in vivo

Summary Most recombination following infection with T7 was found to coincide with the time of most rapid DNA synthesis, at about 20 min after infection at 30° in minimal medium. Recombining DNA was investigated electron microscopically. Multiply branched DNA structures were observed after infection with T7 wild type, gene 3 ^–, gene 6 ^– and genes 3 ^–, 6 ^– phage, but not after infection with T7 gene 5 ^– phage. Evidence is presented indicating that these structures are T7 DNA molecules in the process of recombining. The detailed structures of these recombinational intermediates suggest mechanisms by which T7 DNA initiates recombination.     

Effects of x irradiation on a temperate bacteriophage of Haemophilus influenzae.

The inactivation of bacteriophage HP1c1 by X rays in a complex medium was found to be exponential, with a D0 (the X-ray exposure necessary to reduce the survival of the phage to 37%) of approximately 90 kR. Analysis of results of sucrose sedimentation of DNA from X-irradiated whole phage showed that the D0 for intactness of single strands was about 105kR, and for intactness of double strands, it was much higher. The D0 for attachment of X-irradiated phage to the host was roughly estimated as about 1,100 kR. Loss of DNA from the phage occurred and was probably due to lysis of the phage by X irradiation, but the significance of the damage is not clear. The production of single-strand breaks approaches the rate of survival loss after X irradiation. However, single-strand breaks produced by UV irradiation, in the presence of H2O2, equivalent to 215 kR of X rays, showed no lethal effect on the phage. Although UV-sensitive mutants of the host cell, Haemophilus influenzae, have been shown to reactivate UV-irradiated phage less than does the wild-type host cell, X-irradiated phage survive equally well on the mutants as on the wild type, a fact suggesting that other repair systems are involved in X-ray repair.     

Effects of DNA Heterologies on Bacteriophage λ Recombination

Previous studies of bacteriophage λ recombination have provided indirect evidence that substantial sequence nonhomologies, such as insertions and deletions, may be included in regions of heteroduplex DNA. However, the direct products of heterology-containing heteroduplex DNA--heterozygous progeny phage--have not been observed. We have constructed a series of small insertion and deletion mutations in the cI gene to examine the possibility that small heterologies might be accommodated in heterozygous progeny phage. Genetic crosses were carried out between λcI(-) Oam29 and λcI(+) Pam80 under replication-restricted conditions. Recombinant O(+)P(+) progeny were selected on mutL hosts and tested for cI heterozygosity. Heterozygous recombinants were readily observed with crosses involving insertions of 4 to 19 base pairs (bp) in the cI gene. Thus, nonhomologies of at least 19 bp can be accommodated in regions of heteroduplex DNA during λ recombination. In contrast, when a cI insertion or deletion mutation of 26 bp was present, few of the selected recombinants were heterozygous for cI. Results using a substitution mutation, involving a 26-bp deletion with a 22-bp insertion, suggest that the low recovery of cI heterozygotes containing heterologies of 26 bp or more is due to a failure to encapsidate DNA containing heterologies of 26 bp or more into viable phage particles.     

Bacteriophage-induced Inhibition of Host Functions : I. Degradation of Escherichia coli Deoxyribonucleic Acid After T4 Infection

The kinetics of degradation of bacterial deoxyribonucleic acid (DNA) after infection of Escherichia coli with T4D, ultraviolet-irradiated T4D, and two amber mutants, N122 and N94, was studied by zone sedimentation through linear glycerol gradients. Within 5 min after infection with any of the bacteriophages, breakdown of host genome was evident. The first product was a high-molecular-weight material (50S to 70S) and further degradation appeared to occur in discrete steps. Rapid and extensive breakdown of bacterial DNA was seen after infection with am N122 and T4D. Infection with ultraviolet-irradiated phage or with am N94 resulted in an accumulation of high-molecular-weight material. These results suggest that the observed degradation of host DNA begins early and requires sequential action of several phage-induced endo- as well as exodeoxyribonucleases.     

Molecular Recombination in T4 Bacteriophage Deoxyribonucleic Acid: III. Formation of Long Single Strands During Recombination

Evidence was presented to support the hypothesis that long single strands appearing at late times (15 min after infection) are produced as a result of recombination and not as a continuous elongation during the replication process. The production of long strands does not depend on the multiplicity of infection, and the first long strands appear at the time when 20 to 50 phage equivalent units of deoxyribonucleic (DNA) are synthesized, and not earlier. The addition of chloramphenicol at 5 min, which prevents molecular recombination but allows replication of DNA, prevents the formation of long, single strands. Chloramphenicol added between 8 and 10 min after infection, a time at which molecular recombination is fully expressed and covalent repair of recombinant molecules is allowed, does not prevent formation of long single strands. Cutting of single-strand DNA with a limited amount of endonuclease I allows confirmation that the fast-sedimenting characteristic of intracellular denatured DNA is caused primarily by the length of the strands, and not by the formation of aggregates. The computer simulation of two recombination models indicates the feasibility of random breakage and rejoining of molecules in generating long concatenates.     

Process of Infection with Bacteriophage φX174: XXXV. Cistron VIII

Twenty-two new amber and ochre mutants of phiX174 were isolated and classified into complementation groups. Three ochre mutants gave positive complementation tests with reference mutants in the seven previously defined groups and thus represent an eighth cistron. Studies of the physiology of infection in the nonpermissive condition for mutants in cistron VIII yielded the following information. (i) Replicative-form synthesis proceeds at a normal rate, and is turned off at the usual time. (ii) Synthesis of single-stranded deoxyribonucleic acid (DNA) is delayed until nearly 40 min after infection (in the absence of lysis), at which time a slow synthesis of infectious phage particles commences. The synthesis of infectious particles at late times is interpreted as a consequence of "leakage," and indicates that the cistron VIII product is required in very small quantities. (iii) During the normal period of single-strand synthesis, most of the replicative-form DNA is found in a form with properties similar to those of the transient intermediates of single-strand DNA synthesized during normal infection.     

Parent-to-Progeny Transfer and Recombination of T4rII Bacteriophage

Transfer of parental, light (not substituted with 5-bromodeoxyuridine) (32)P-deoxyribonucleic acid (DNA) from rII(-) mutants of T4 bacteriophage to heavy (5-bromodeoxyuridine-substituted) progeny in Escherichia coli B was less homogeneous than in wild phages. The net transfer was 5 to 20% of the value for wild T4 phage, and the parental contribution per progeny DNA molecule amounted to 7 to 100% of the genome. Three classes could be distinguished, based on the density distribution of parental label in CsCl analysis of the progeny phages. "Far recombined" phages contain parental material only in semiconservatively replicated subunits covalently attached to progeny DNA, amounting to 5 to 10% parental contribution per genome. "Intermediate recombinants" contain, aside from conventional recombinant DNA, parental DNA banding at the original, light density. This DNA may be unattached to heavy progeny DNA or attached by weak bonds which are very sensitive to shearing during the extraction procedure. The parental contribution is 10 to 50% per progeny DNA molecule in this class. "Conservative" phages band close to the parental, light density in CsCl; their DNA is purely light. When the parental phage is labeled with both (3)H-leucine (capsid) and (32)P (DNA), the specific activity of (3)H/(32)P in the "conservative progeny" is 10 to 40% of that in the parental, showing that at least some of the (32)P in this area belongs to phages with parental DNA as the sole DNA component inside an unlabeled capsid, i.e., parental DNA which has been injected into the host and matured in a new capsid without replication or recombination. This phenomenon occurs to about the same extent in both single and multiple infection.     

Recognition of Altered Deoxyribonucleic Acid in Recombination

Kinetics of inactivation of transduction by phage P1bt which had been treated with ultraviolet light (UV) or nitrous acid (NA) was examined. With Escherichia coli B/r (radiation-resistant), low doses of UV increased transduction frequency, but the frequency was exponentially inactivated by higher doses. Little initial stimulus was observed in strain B(s-1) (radiation-sensitive). The final rate of decay was the same as in B/r. The initial stimulus of transduction in B/r was probably a consequence of increased recombination resulting from dark repair. It was estimated that another nucleotide within 1000 nucleotide pairs had to be damaged by UV to prevent a given nucleotide from successful transduction. The NA dose response was the same for the two strains. An initial stimulus of transduction was followed by exponential decline. The UV-repair enzymes missing in B(s-1) were not required for repair of NA-induced damage to transducing or lytic phage DNA. Low recovery of new mutations in the transductants showed that mutagen-induced damage to transducing DNA was excluded from recombinant chromosomes. The few recovered mutants may have resulted from "normal" error in recombination.     

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.