Replication and recombination intersect

A bacterial housekeeping function, which requires both recombination and replication enzymes, has been identified that re-establishes inactivated replication forks under normal growth conditions. Some long-tract gene-conversion events initiated by double-strand breaks in yeast and mammalian cells can be attributed to recombination-directed DNA replication. Double-strand break repair in yeast has been shown to require both leading- and lagging-strand DNA synthesis. These observations suggest that the recombination and replication machinery cooperate to maintain genomic integrity.     

Site-specific recombination in bacteriophage lambda

Lambda attB-attP is a derivative of bacteriophage lambda that contains both attB and attP, two sites required for integrative recombination. Lambda attB-attP can undergo int-mediated recombination to yield progeny phages whose DNA is 15% shorter than that of the parental phage. We have studied intracellular phage DNA from an infection of lysogenic bacteria with λattB-attP in the presence of int gene product, rifampicin and chloramphenicol. The majority of the intracellular phage DNA consisted of circles with lengths of 17.51, 15.09 and 2.38 μm. Partial denaturation mapping confirmed that the 15.09 and the 2.38-μm molecules arose by an int-mediated intramolecular recombination reaction of the type predicted by the Campbell (1962) model. A minor proportion of the circles (3%) were much larger (33.9, 30.2 and 4.7 μm); in these cases denaturation mapping indicated that both intra- and intermoleeular recombination could take place.     

Replication fork arrest and DNA recombination

Replication arrests are associated with genome rearrangements, which result from either homologous or non-homologous recombination. Interestingly, proteins involved in homologous recombination are able to convert an arrested replication fork into a recombination intermediate, which promotes replication restart and thus presumably prevents genome rearrangements.     

Site-specific recombination Xis-independent excisive recombination of bacteriophage lambda

The integration of bacteriophage lambda into the Escherichia coli chromosome depends on the phage-encoded Int protein; prophage excision depends on Int and a second phage function, Xis. Limited excisive recombination has been observed in vivo with certain xis mutants, suggesting that Int may be able to carry out excision without Xis.We report here that purified Int protein carries out lambda site-specific excisive recombination in vitro in the absence of Xis. This reaction requires host factors derived from a non-lysogenic E. coli strain and is influenced strongly by ionic strength. Excision in the absence of Xis occurs slowly at low salt concentrations (40 mm-NaCl) and very little excision occurs at high salt concentrations (100 mm-NaCl). In the presence of Xis, excisive recombination proceeds rapidly at both low and high ionic strengths. These observations are consistent with previous experiments that suggested the partial dispensability of Xis for excision.     

Replication and recombination of herpes simplex virus DNA

Replication of herpes simplex virus takes place in the cell nucleus and is carried out by a replisome composed of six viral proteins: the UL30-UL42 DNA polymerase, the UL5-UL8-UL52 helicase-primase, and the UL29 single-stranded DNA-binding protein ICP8. The replisome is loaded on origins of replication by the UL9 initiator origin-binding protein. Virus replication is intimately coupled to recombination and repair, often performed by cellular proteins. Here, we review new significant developments: the three-dimensional structures for the DNA polymerase, the polymerase accessory factor, and the single-stranded DNA-binding protein; the reconstitution of a functional replisome in vitro; the elucidation of the mechanism for activation of origins of DNA replication; the identification of cellular proteins actively involved in or responding to viral DNA replication; and the elucidation of requirements for formation of replication foci in the nucleus and effects on protein localization.     

Orientation-dependent recombination hotspot activity in bacteriophage lambda.

Promoters of genetic exchange by the Escherichia coli Rec system, Chi elements, have been analyzed in λ phages carrying bacterial EcoRI restriction fragments. Some fragments confer Chi⁺ phenotype in one orientation and Chi^? in the opposite orientation. The inactivity of Chi in one orientation explains why all active Chi elements in λ manifest a certain recombinational bias of the same sense.When these studies were undertaken, we rather expected to find two classes of Chi, one class which stimulated recombinant formation stronger to its left and one class stimulating recombinant formation more strongly to its right. The failure to find the second class is now understandable by supposing that the orientation of Chi which would have permitted it to act rightward is the orientation in which Chi has no activity at all. Several models are proposed for the orientation dependence of Chi activity.     

Generalized recombination in tandem duplications of bacteriophage lambda

Summary Recombination between the tandem duplicated segments of b221a106-15 yields unduplicated (single-copy) b221 phage. The apparent frequency of intramolecular events among these recombinations was determined for both cellular (Rec) and bacteriophage (Red) generalized recombination systems. The progeny from single-cycle growth experiments with genetically marked duplication phages were treated with EDTA to inactivate all but the singlecopy phages produced by recombination. Analysis of the genotypes of the EDTA-resistant phages suggested that intramolecular events were about 1 to 5 times as frequent as intermolecular ones. While the results suggest that intramolecular events are not intrinsically forbidden, the quantitative values for the ratio depend on the assumption that intracellular phage chromosomes are completely mixed.     

Vegetative recombination of bacteriophage Mu-1 in Escherichia coli

Summary Twenty-two amber mutants of the thermoinducible mutator phage Mu-c4ts were isolated. These mutants fall into 11 complementation groups. The data obtained by crossing these amber mutants suggest that bacteriophage Mu-1 has a linear vegetative linkage map. In a recombination deficient host of the RecA type the recombination frequencies are extremely low, indicating that Mu-1, in contrast to many other E. coli phages, is dependent on the recombination system of its host. With as a helper phage, recombination between Mu phages in a RecA host is restored to about 1/3 of the frequency in a Rec⁺ host. Although Mu-1 is able to integrate efficiently into the chromosome of a RecA strain, it seems that its integration system does not contribute to vegetative recombination.The survival of UV-irradiated Mu-1 was measured on different radiation sensitive mutants of E. coli. The survival on a UvrB strain was very low as compared to the wild-type; the survival on a RecA strain was almost the same as on the wild-type.Research Fellow from the Laboratory of Genetics, State University, Leiden, The Netherlands.     

Gene rIIB from bacteriophage T4 in genetic recombination

The effect of the rIIB gene on genetic recombination in bacteriophage T4 was studied. Relationships between recombination frequency and the physical distance were determined in three series of isomarker two-factor crosses between rII mutants. In the first series of intergenic crosses (rIIa x rIIb), the rII gene function was restored owing to complementation. In the second series of crosses, identical to the first one, the rIIB gene function was suppressed, because the rIIa parent carried an additional amberlike mutation in the rIIB gene. The recombinants were scored by plating lysates on the amber-suppressor Escherichia coli strain, on which an amberlike mutation was not expressed phenotypically. In the third series, all crosses were intragenic (rIIb x rIIb). In two series of crosses in the absence of the rIIB function, the relationships between recombination frequency and the physical distance were identical, whereas enhanced recombination frequencies were observed in the rIIB+ background. The magnitude of the rIIB-related effect depended on distance, reaching the maximum in the region located 100 to 200 bp from the beginning of the rIIB gene. The possible role of the rIIB protein in genetic recombination is discussed.     

Early intermediates in bacteriophage T4 DNA replication and recombination.

We investigated, by density gradients and subsequent electron microscopy, vegetative T4 DNA after single or multiple infection of Escherichia coli with wild-type T4. Our results can be summarized as follows. (i) After single infection (i.e., when early intermolecular recombination could not occur), most, if not all, T4 DNA molecules initiated the first round of replication with a single loop. (ii) After multiple infection, recombinational intermediates containing label from both parents first appeared as early as 1 min after the onset of replication, long before all parental DNA molecules had finished their first round and before secondary replication was detectable. (iii) At the same time, in multiple infections only, complex, highly branched concatemeric T4 DNA first appeared. (iv) Molecules in which two loops or several branches were arranged in tandem were only found after multiple infections. (v) Secondary loops within primary loops were seen after both single and multiple infections, but they were rare and many appeared off center. Thus, recombination in wild-type T4-infected cells occurred very early, and the generation of multiple tandem loops or branches in vegetative T4 DNA depended on recombination. These results are consistent with the previous finding (A. Luder and G. Mosig, Proc. Natl. Acad. Sci. U.S.A. 79:1101-1105, 1982) that most secondary growing points of T4 are not initiated from origin sequences but from recombinational intermediates. By these and previous results, the various DNA molecules that we observed are most readily explained as intermediates in DNA replication and recombination according to a model proposed earlier to explain various other aspects of T4 DNA metabolism (Mosig et al., p. 277-295, in D. Ray, ed., The Initiation of DNA Replication, Academic Press, Inc., New York, 1981).     

Replication and recombination in adenovirus-infected cells are temporally and functionally related.

We have studied the temporal and functional relationships between DNA replication and recombination in adenovirus-infected cells by using Southern blot hybridization to detect recombinant products among intracellular viral genomes. The data show that recombination can be detected soon after DNA replication has commenced and that the proportion of recombinant products increases thereafter. To determine the functional relationship between DNA replication and recombination, replication was blocked with the protein synthesis inhibitor anisomycin, the replication inhibitor cytosine arabinoside, and conditionally lethal mutations in either the virus-specified DNA-binding protein or the DNA polymerase. All treatments that directly or indirectly blocked DNA replication caused a delay in the appearance of recombinant products and a marked decline in their abundance relative to products of parental genotype. These data strongly suggest that DNA replication and recombination are interrelated, either because both processes share functions or because DNA structures produced by replication are suitable substrates for recombination. In addition, we have shown that some recombination function(s) is intrinsically thermolabile at 40.9 degrees C, even in wild-type crosses, since the appearance of recombinant products is delayed and their extent is reduced compared with that from crosses performed at 39.9 degrees C.