Genetic studies of coliphage P1. II. Relatedness to P7.

Using semiquantitative spot tests, 107 independently isolated amber mutants of P1 were shown to be rescued by a nonpermissive strain of Escherichia coli lysogenic for P7 (previously called phiamp), indicating extensive genetic relatedness between P1 and P7. The amount of rescue observed varied with mutants from different genetic linkage clusters of P1. Although these rescue tests cannot distinguish between recombination, complementation, transactivation, or combinations thereof, a major role is indicated for recombination.     

Genetic studies of coliphage P1. I. Mapping by use of prophage deletions.

One hundred and ten amber mutants of coliphage P1 were isolated and localized into groups with respect to the existing genetic map by use of nonpermissive Escherichia coli K-12 strains lysogenic for P1 with deletions. These lysogens contain one of three types of deletion prophages: P1cry and its derivatives, P1dlacs, and P1dpros. Fourteen such lysogens were tested for their ability to rescue the amber mutants which were then assigned to one of nine deletion segments of the P1 genome defined by the termini of the various prophage deletions. The relationship of the nine deletion segments with the published P1 map is described, two new segments having been added. The deletions of the 14 prophages overlapped sufficiently to indicate that the P1 genetic prophage map should be represented in circular form, which is consistent with the fact that P1 is normally a circular plasmid in the prophage state. The distribution of mutants into deletion segments is nonrandom for at least one segment. In addition, the deletion termini of the 14 defective prophages coincided in five out of nine regions separating the nine deletion segments. Various possible explanations are discussed for the nonrandom recurrence of these deletion termini, including the evidence of hot spots of recombination.     

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).     

Fine-structure mapping of herpes simplex virus type 1 temperature-sensitive mutations within the short repeat region of the genome.

Cloned herpes simplex virus type 1 (HSV-1) DNA fragments were used to fine-structure map the temperature-sensitive (ts) lesions from four mutants, ts T, D, c75, and K, by marker rescue. These mutants all overproduced immediate-early viral polypeptides at the nonpermissive temperature. Although one of these viruses, ts K, gave a more restricted infected-cell polypeptide profile under these conditions than the other three, no complementation was detected between pairwise crosses of these mutants in the yield test. Recombination, however, was obtained between all mutant pairs except ts T and D. In physical mapping experiments, ts+ virus was recovered from cells coinfected with DNA of ts T, D, or c75 and BamHI fragment k from wild-type strain 17 HSV-1 DNA cloned in pAT153, whereas ts K was rescued by cloned HSV-1 BamHI-y. Both of these cloned DNA fragments contained sequences from the short repeat region of the HSV-1 genome. The ts mutations were more precisely mapped by marker rescue, using restriction enzyme fragments within BamHI-k and -y from cloned DNA. The smallest fragment able to rescue a mutant was 320 base pairs long. The order of the four mutations derived from these studies was consistent with the assignment by genetic recombination. All four lesions mapped within the coding sequences of the immediate-early polypeptide Vmw IE 175 (ICP4) which lie outside the "a" sequence. The results showed that mutations in different regions of the gene encoding Vmw IE 175 could produce similar phenotype effects at the nonpermissive temperature.     

Immunoglobulin molecular genetics: the prospects for mutational analysis of the chromosomal immunoglobulin genes

Homologous recombination between transferred and chromosomal DNA can be used to effect precise, predetermined modifications of the chromosomal genes. Ultimately this phenomenon should allow the assessment of genetic regulatory elements as they function in the normal chromosomal environment. We have previously described a system for isolating mutant hybridoma cells that are defective in immunoglobulin (Ig) production, with a view toward using these mutants to define cis-acting elements that influence Ig gene expression. Here we describe results that indicate that homologous recombination between transferred and chromosomal Ig genes can be used to map Ig mutations by marker rescue.     

Conjugational recombination in resolvase-deficient ruvC mutants of Escherichia coli K-12 depends on recG.

ruvC mutants of Escherichia coli appear to lack an activity that resolves Holliday intermediates into recombinant products. Yet, these strains produce close to normal numbers of recombinants in genetic crosses. This recombination proficiency was found to be a function of recG. A "mini-kan" insertion in recG was introduced into ruvA, ruvB, and ruvC strains. Conjugational recombination was reduced by more than 100-fold in recG ruvA::Tn10, recG ruvB, and recG ruvC strains and by about 30-fold in a recG ruvA strain carrying a ruvA mutation that is not polar on ruvB. The double mutants also proved very deficient in P1 transduction and are much more sensitive to UV light than ruv single mutants. Since mutation of recG alone has very modest effects on recombination and sensitivity to UV, it is concluded that there is a functional overlap between the RecG and Ruv proteins. However, this overlap does not extend to circular plasmid recombination. The possibility that RecG provides a second resolvase that can substitute for Ruv is discussed in light of these findings.     

Bacteriophage P1 site-specific recombination: I. Recombination between loxP sites

We have studied P1 site-specific recombination by cloning a 6·5 × 10³ base EcoRI fragment (fragment 7) of P1 DNA into a λ vector and then asking whether that fragment can promote efficient recombination for λ markers that flank the fragment. Our results indicate that fragment 7 can reassort these markers very efficiently, and that this recombination can occur in the absence of the bacterial recA and recBC functions. The fragment 7 recombination system has been dissected by an analysis of deletion mutations into two components, a site (called loxP) that must be present in both partners in the recombination in order for recombination to occur, and a P1 gene (called cre), whose product is necessary for recombination. The location of the loxP site at the end of the P1 genetic map suggests that this site-specific recombination system is responsible for the lack of linkage between terminal P1 markers and therefore for the linearity of that map.     

Genetic recombination of bacteriophage T7 in vivo studied by use of a simple physical assay.

A new physical method was developed to assay genetic recombination of phage T7 in vivo. The assay utilized T7 mutants that carry unique restriction sites and was based on the detection of a new restriction fragment generated by recombination. Using this assay, we reexamined the genetic requirements for recombination of T7 DNA. Our results were in total agreement with previous findings in that recombination required the products of genes 3 (endonuclease), 4 (primase), 5 (DNA polymerase), and 6 (exonuclease). Recombination was found to be independent of DNA ligase and DNA packaging and maturation functions.     

Identification of key structural determinants of the IntI1 integron integrase that influence attC x attI1 recombination efficiency

The integron platform codes for an integrase (IntI) from the tyrosine family of recombinases that mediates recombination between a proximal double-strand recombination site, attI and a single-strand target recombination site, attC. The attI site is only recognized by its cognate integrase, while the various tested attCs sites are recombined by several different IntI integrases. We have developed a genetic system to enrich and select mutants of IntI1 that provide a higher yield of recombination in order to identify key protein structural elements important for attC × attI1 recombination. We isolated mutants with higher activity on wild type and mutant attC sites. Interestingly, three out of four characterized IntI1 mutants selected on different substrates are mutants of the conserved aspartic acid in position 161. The IntI1 model we made based on the VchIntIA 3D structure suggests that substitution at this position, which plays a central role in multimer assembly, can increase or decrease the stability of the complex and accordingly influence the rate of attI × attC recombination versus attC × attC. These results suggest that there is a balance between the specificity of the protein and the protein/protein interactions in the recombination synapse.     

Genetic analysis of temperature-sensitive mutants which define the genes for the major herpes simplex virus type 2 DNA-binding protein and a new late function.

Eleven temperature-sensitive mutants of herpes simplex virus type 2 (HSV-2) exhibit overlapping patterns of complementation that define four functional groups. Recombination tests confirmed the assignment of mutants to complementation groups 1 through 4 and permitted the four groups to be ordered in an unambiguous linear array. Combined recombination and marker rescue tests (A. E. Spang, P. J. Godowski, and D. M. Knipe, J. Virol. 45:332-342, 1983) indicate that the mutations lie in a tight cluster near the center of UL to the left of the gene for DNA polymerase in the order 4-3-2-1-polymerase. The seven mutants that make up groups 1 and 2 fail to complement each other and mutants in HSV-1 complementation group 1-1, the group thought to define the structural gene for the major HSV-1 DNA-binding protein with a molecular weight of 130,000. At 38 degrees C, mutants in groups 1 and 2 synthesize little or no viral DNA, and unlike cells infected with the wild-type virus, mutant-infected cells exhibit no detectable nuclear antigen reactive with monoclonal or polypeptide-specific antibody to the major HSV-2 DNA-binding protein. The four mutants that make up groups 3 and 4 do not complement each other, nor do they complement mutants in group 2. They do, however, complement mutants in group 1 as well as representative mutants of HSV-1 complementation group 1-1. At 38 degrees C, mutants in groups 3 and 4 are phenotypically DNA+, and nuclei of mutant-infected cells contain the HSV-2 DNA-binding protein. Thus, the four functional groups appear to define two closely linked genes, one encoding an early viral function affecting both viral DNA synthesis and expression of the DNA-binding protein with a molecular weight of 130,000 (groups 1 and 2), and the other encoding a previously unidentified late viral function (groups 3 and 4). The former gene presumably represents the structural gene for the major HSV-2 DNA-binding protein.     

Mutations in the CD-loop region of the D2 protein in Synechocystis sp. PCC 6803 modify charge recombination pathways in photosystem II in vivo

The lumenal CD-loop region of the D2 protein of photosystem II contains residues that interact with the primary electron donor P680 and the redox active tyrosyl residue Y(D). Photosystem II properties were studied in a number of photoautotrophic mutants of Synechocystis sp. PCC 6803, most of which carried combinatorial mutations in residues 164-170, 179-186, or 187-194 of the D2 protein. To facilitate characterization of photosystem II properties in the mutants, the CD-loop mutations were introduced into a photosystem I-less background. According to variable fluorescence decay measurements in DCMU-treated cells, charge recombination of Q(A)(-) with the donor side was faster in the majority of mutants (t(1/2) = 45-140 ms) than in the control (t(1/2) = 180 ms). However, in one mutant (named C7-3), the decay of Q(A)(-) was 2 times slower than in the control (t(1/2) = 360 ms). The decay half-time of each mutant correlated with the yield of the Q-band of thermoluminescence (TL) emitted due to S(2)Q(A)(-) charge recombination. The C7-3 mutant had the highest TL intensity, whereas no Q-band was detected in the mutants with fast Q(A)(-) decay (t(1/2) = 45-50 ms). The correlated changes in the rate of recombination and in TL yield in these strains suggest the existence of a nonradiative pathway of charge recombination between Q(A)(-) and the donor side. This may involve direct electron transfer from Q(A)(-) to P680(+) in a way not leading to formation of excited chlorophyll. Many mutations in the CD-loop appear to increase the equilibrium P680(+) concentration during the lifetime of the S(2)Q(A)(-) state, for example, by making the midpoint potential of the P680(+)/P680 redox couple more negative. The nonradiative charge recombination pathway involves a low activation energy and is less temperature-dependent than the formation of excited P680 that leads to TL emission. Therefore, during the TL measurements in these mutants, the S(2)Q(A)(-) state can recombine nonradiatively before temperatures are reached at which radiative charge recombination becomes feasible. The results presented here highlight the presence of two charge recombination pathways and the importance of the CD-loop of the D2 protein in determination of the energy gap between the P680(+)S(1) and P680S(2) states.     

Method for induction of mutations in physically defined regions of the herpes simplex virus genome

A procedure was developed for inducing mutations in isolated restriction enzyme fragments of herpes simplex virus type 1 (HSV-1) DNA with nitrous acid. The mutations were then transferred to the viral genome by genetic recombination during cotransfection of rabbit kidney cells with the mutagenized fragments and intact HSV-1 DNA. The HpaI restriction enzyme fragments LD, B, LG, I, and J were mutagenized. Temperature-sensitive mutants were found at frequencies of 1 to 5% among the progeny of the transfections. Syncytial mutants also were found at high frequency when fragment B or LD was used for mutagenesis. Fifteen of these mutants, 11 temperature sensitive and 4 syncytial, were used for further studies, including complementation analysis, DNA synthesis, and marker rescue. Marker rescue data presented here and in the accompanying publication (A. L. Goldin, R. M. Sandri-Goldin, M. Levine, and J. C. Glorioso, J. Virol. 38: 50-58, 1981) confirm the map position of some of the newly isolated mutants.     

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.     

Map locations of mouse hepatitis virus temperature-sensitive mutants: confirmation of variable rates of recombination.

Using standard genetic recombination techniques, studies in our laboratory suggest that recombination rates are very high and vary in different portions of the mouse hepatitis virus (MHV) genome. To determine the actual recombination frequencies in the MHV genome and localize the nucleotide boundaries of individual viral genes, we have sequenced temperature-sensitive and revertant viruses to identify the location of specific mutant alleles. Complementation group F RNA+ ts mutants (LA7, NC6, and NC16) each contained a unique mutation which was tightly linked to the ts phenotype and resulted in a conservative or nonconservative amino acid change in the MHV S glycoprotein gene. In agreement with previous recombination mapping studies, the mutation in LA7 and NC6 mapped within the S1 domain while NC16 mapped within the S2 domain. To determine the map coordinates of the MHV polymerase genes, several RNA- mutants and their revertants belonging to complementation groups C (NC3 and LA9) and E (LA18 and NC4) were also sequenced. Mutations were identified in each virus that were tightly linked to the ts phenotype and resulted in either a conservative or nonconservative amino acid change. The group C allele spanned the ORF 1a/ORF 1b junction, while the group E mutants mapped at the C terminus of ORF 1b about 20 to 22 kb from the 5' end of the genome. Mutation rates, calculated from the reversion frequencies of plaque-purified ts viruses requiring a single nucleotide alteration for reversion, approached 1.32 (+/- 0.89) x 10(-4) substitutions per nucleotide site per round of template copying. Detailed recombination mapping studies across known distances between these different ts alleles has confirmed that homologous recombination rates approached 25% and varied within different portions of the MHV genome.     

Deletions in bacteriophage P2. Circularity of the genetic map and its orientation relative to the DNA denaturation map

Several types of viable chromosomal deletions of bacteriophage P2 were isolated. One type gives the immunity insensitive phenotype and may extend to the genes for the immunity repressor (C) and for integrative recombination (int). Two other types delete genes (old and fun) known to be active in the lysogenic state. For such deletion mutants the relationship between particle density and DNA length was established. The deletions were located in respect to previously mapped genes and the results were compared with electron microscopical studies (by Inman and collaborators) of the P2 chromosome. It is concluded that the best representation of the genetic map of P2 is circular. The cohesive ends of the linear P2 DNA molecule are most likely formed between genes old and Q. Except for the neighborhood of gene old, the previously published, linear genetic map of P2 (Lindahl) is colinear with the melting map of the P2 chromosome (Inman). Preliminary evidence for some specific recombination event often accompanying integrative recombination between phage chromosomes is presented.     

Marker rescue of temperature-sensitive mutations of vaccinia virus WR: correlation of genetic and physical maps

The physical map locations of 62 temperature-sensitive mutations of vaccinia virus WR have been determined by marker rescue experiments, using cloned HindIII fragments of wild-type DNA. Since vaccinia virus DNA is not infectious, marker rescue was performed by infecting monolayers of cells at the nonpermissive temperature with a low multiplicity of the mutant to be rescued and transfecting with calcium phosphate-precipitated recombinant DNA. Wild-type recombinants were measured by using either a direct plaque assay technique or a two-step procedure in which the final yield of virus from the transfected cells was assayed at the permissive and nonpermissive temperatures. Mutants that had been previously assigned to the same complementation-recombination group were rescued by the same HindIII fragment, with the exception of three mutants in one group that were rescued by either one of two adjacent fragments. A comparison between the genetic linkage map of the temperature-sensitive mutations in 30 mutants with their physical locations demonstrated that not only was the order of the genetic map correct but also recombination frequencies generally reflected actual physical distances.     

Genetic Control of Intrachromosomal Recombination in Saccharomyces Cerevisiae. I. Isolation and Genetic Characterization of Hyper-Recombination Mutations

Eight complementation groups have been defined for recessive mutations conferring an increased mitotic intrachromosomal recombination phenotype (hpr genes) in Saccharomyces cerevisiae. Some of the mutations preferentially increase intrachromosomal gene conversion (hpr4, hpr5 and hpr8) between repeated sequences, some increase loss of a marker between duplicated genes (hpr1 and hpr6), and some increase both types of events (hpr2, hpr3 and hpr7). New alleles of the CDC2 and CDC17 genes were recovered among these mutants. The mutants were also characterized for sensitivity to DNA damaging agents and for mutator activity. Among the more interesting mutants are hpr5, which shows a biased gene conversion in a leu2-112::URA3::leu2-k duplication; and hpr1, which has a much weaker effect on interchromosomal mitotic recombination than on intrachromosomal mitotic recombination. These analyses suggest that gene conversion and reciprocal exchange can be separated mutationally. Further studies are required to show whether different recombination pathways or different outcomes of the same recombination pathway are controlled by the genes identified in this study.     

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.     

Genetic analysis of the recG locus of Escherichia coli K-12 and of its role in recombination and DNA repair.

We describe a transposon insertion that reduces the efficiency of homologous recombination and DNA repair in Escherichia coli. The insertion, rec-258, was located between pyrE and dgo at min 82.1 on the current linkage map. On the basis of linkage to pyrE and complementation studies with the cloned rec+ gene, rec-258 was identified as an allele of the recG locus first reported by Storm et al. (P. K. Storm, W. P. M. Hoekstra, P. G. De Haan, and C. Verhoef, Mutat. Res. 13:9-17, 1971). The recG258 mutation confers sensitivity to mitomycin C and UV light and a 3- to 10-fold deficiency in conjugational recombination in wild-type, recB recC sbcA, and recB recC sbcB sbcC genetic backgrounds. It does not appear to affect plasmid recombination in the wild-type. A recG258 single mutant is also sensitive to ionizing radiation. The SOS response is induced normally, although the basal level of expression is elevated two- to threefold. Further genetic studies revealed that recB recG and recG recJ double mutants are much more sensitive to UV light than the respective single mutants in each case. However, no synergistic interactions were discovered between recG258 and mutations in recF, recN, or recQ. It is concluded that recG does not fall within any of the accepted groups of genes that affect recombination and DNA repair.     

Stimulation of IS1 excision by bacteriophage P1 ref function.

Lysogenization by a c1ts variant of coliphage P1, P1c1.100, markedly increased the frequency of reversion of a galT::IS1 mutation. The formation of Gal+ colonies presumably occurs by microhomologous recombination between the 9-base-pair repeats in galT (CGCCGCTAC) generated by the transposition of IS1. The responsible P1 gene, ref, has been cloned and sequenced. ref encodes a 22.8-kilodalton protein and is located near the P1 site-specific recombination function, cre. Expression of ref was repressed by P1 c+. The absence of a distinctive ribosome-binding site is consistent with a poor translation of ref from an expression vector in vivo. Placement of a ribosome-binding site before ref resulted in the extensive synthesis of the Ref protein. Ref stimulated precise excision in recB or himA cells, but not in recA mutants. Ref was active in lexA3 mutants, suggesting that the recombination activity of RecA was directly involved in the reaction. We have constructed a P1c1.100 ref::Tn10 mutant. The absence of Ref did not appear to restrict dramatically the ability of P1 to grow lytically or to form lysogens. Thus, the role of ref in the physiology of P1 remains to be determined.