The Effect of Attachment Site Mutations on Strand Exchange in Bacteriophage λ Site-Specific Recombination

Recombination of phage λ attachment sites occurs by sequential exchange of the DNA strands at two specific locations. The first exchange produces a Holliday structure, and the second resolves it to recombinant products. Heterology for base substitution mutations in the region between the two strand exchange points (the overlap region) reduces recombination; some mutations inhibit the accumulation of Holliday structures, others inhibit their resolution to recombinant products. To see if heterology also alters the location of the strand exchange points, we determined the segregation pattern of three single and one multiple base pair substitution mutations of the overlap region in crosses with wild type sites. The mutations are known to differ in the severity of their recombination defect and in the stage of strand exchange they affect. The three single mutations behaved similarly: each segregated into both products of recombination,, and the two products of a single crossover were frequently nonreciprocal in the overlap region. In contrast, the multiple mutation preferentially segregated into one of the two recombinant products, and the two products of a single crossover appeared to be fully reciprocal. The simplest explanation of the segregation pattern of the single mutations is that strand exchanges occur at the normal locations to produce recombinants with mismatched base pairs that are frequently repaired. The segregation pattern of the multiple mutation is consistent with the view that both strand exchanges usually occur to one side of the mutant site. We suggest that the segregation pattern of a particular mutation is determined by which stage of strand exchange it inhibits and by the severity of the inhibition.     

Chi-Stimulated Recombination between Phage λ and the Plasmid λdv

Chi promotes Rec-mediated recombination between phage lambda DNA and the homologous plasmid lambda dv. In the absence of Chi, some of the interactions splice lambda dv into lambda, whereas others patch information from lambda dv into lambda. When Chi is in the phage DNA, splices and patches are increased in frequency by the same factor. This result strengthens the analogy between Chi and recombination-promoting elements in fungi. It also rules out one model for the previously reported orientation dependence of Chi phenotype.     

Initiation of V(D)J Recombination by Dβ-Associated Recombination Signal Sequences: A Critical Control Point in TCRβ Gene Assembly

T cell receptor (TCR) β gene assembly by V(D)J recombination proceeds via successive Dβ-to-Jβ and Vβ-to-DJβ rearrangements. This two-step process is enforced by a constraint, termed beyond (B)12/23, which prohibits direct Vβ-to-Jβ rearrangements. However the B12/23 restriction does not explain the order of TCRβ assembly for which the regulation remains an unresolved issue. The initiation of V(D)J recombination consists of the introduction of single-strand DNA nicks at recombination signal sequences (RSSs) containing a 12 base-pairs spacer. An RSS containing a 23 base-pairs spacer is then captured to form a 12/23 RSSs synapse leading to coupled DNA cleavage. Herein, we probed RSS nicks at the TCRβ locus and found that nicks were only detectable at Dβ-associated RSSs. This pattern implies that Dβ 12RSS and, unexpectedly, Dβ 23RSS initiate V(D)J recombination and capture their respective Vβ or Jβ RSS partner. Using both in vitro and in vivo assays, we further demonstrate that the Dβ1 23RSS impedes cleavage at the adjacent Dβ1 12RSS and consequently Vβ-to-Dβ1 rearrangement first requires the Dβ1 23RSS excision. Altogether, our results provide the molecular explanation to the B12/23 constraint and also uncover a ‘Dβ1 23RSS-mediated’ restriction operating beyond chromatin accessibility, which directs Dβ1 ordered rearrangements.     

Roles for λ Orf and Escherichia Coli Reco, Recr and Recf in λ Recombination

Bacteriophage λ lacking its Red recombination functions requires either its own gene product, Orf, or the product of Escherichia coli's recO, recR and recF genes (RecORF) for efficient recombination in recBC sbcB sbcC mutant cells (the RecF pathway). Phage crosses under conditions of a partial block to DNA replication have revealed the following: (1) In the presence of Orf, RecF pathway recombination is similar to λ Red recombination; (2) Orf is necessary for focusing recombination toward the right end of the chromosome as λ is conventionally drawn; (3) RecORF-mediated RecF pathway recombination is not focused toward the right end of the chromosome, which may indicate that RecORF travels along the DNA; (4) both Orf- and RecORF-mediated RecF pathway recombination are stimulated by DNA replication; and (5) low level recombination in the simultaneous absence of Orf and RecORF may occur by a break-copy mechanism that is not initiated by a double strand break. Models for the roles of Orf and RecO, RecR and RecF in recombination are presented.     

Mechanism for the Action of λ Exonuclease in Genetic Recombination

Lambda exonuclease degrades in vitro redundant single stranded regions which probably result in λ DNA from genetic recombination in vivo.     

Role of cis-Acting Sites in Stimulation of the Phage λ PRM Promoter by CI-Mediated Looping

The lysogenic state of phage λ is maintained by the CI repressor. CI binds to three operators each in the right operator (O_R) and left operator (O_L) regions, which lie 2.4 kb apart. At moderate CI levels, the predominant binding pattern is two dimers of CI bound cooperatively at each regulatory region. The resulting tetramers can then interact, forming an octamer and a loop of the intervening DNA. CI is expressed from the P_RM promoter, which lies in the O_R region and is subjected to multiple regulatory controls. Of these, the most recently discovered is stimulation by loop formation. In this work, we have investigated the mechanism by which looping stimulates P_RM. We find that two cis-acting sites lying in the O_L region are involved. One site, an UP element, is required for stimulation. Based on the behavior of other promoters with UP elements located upstream of the −35 region, we suggest that a subunit of RNA polymerase (RNAP) bound at P_RM binds to the UP element located in the O_L region. In addition, adjacent to the UP element lies a binding site for integration host factor (IHF); this site plays a less critical role but is required for stimulation of the weak prm240 allele. A loop with CI at the O_L2 and O_L3 operators does not stimulate P_RM, while one with CI only at O_L2 provides some stimulation. We discuss possible mechanisms for stimulation.     

Chain Bias in Chi-Stimulated Heteroduplex Patches in the λ Ren Gene Is Determined by the Orientation of λ Cos

Heteroduplex patch recombinants have received information in one DNA chain but have not recombined flanking markers. Evidence regarding which chain is exchanged bears on the structure of recombination intermediates. The direction of travel along DNA of RecBCD recombinase, the central enzyme in the Escherichia coli RecBCD pathway of homologous recombination, is determined in phage lambda by the orientation of the packaging origin, cos. cos is a double-chain cut site which serves as a preferred entry site for RecBCD. Using partially denaturing gels to resolve heteroduplex molecules, we have examined patch recombinants at the lambda ren gene. We report that the transferred information in Chi-stimulated patches at ren can occur on either chain, but is biased to the chain ending 5' at the right of the lambda map (the lambda r chain) in phage carrying cos in its normal orientation. The chain bias switches in favor of the chain that ends 3' at the right (the lambda l chain) when RecBCD travel direction is reversed by inverting cos. We entertain models that accommodate these and other results pertaining to the structure of RecBCD-mediated recombinants.     

Behavior of λ Bacteriophage in a Recombination Deficient Strain of Escherichia coli

The behavior of lambda phage in the Rec(-) strain JC-1569 is compared with that in the Rec(+) strain JC-1557. No difference deemed significant was noted in the adsorption rate, latent period, burst size, frequency of lysogenization, and frequency of vegetative phage recombination. The location of the prophage and its mode of insertion in the Rec(-) lysogen of wild-type lambda (lambda(+)) were inferred to be normal from the results of conjugational crosses. Spontaneous and ultraviolet (UV) irradiation induction of lambda(+) were markedly reduced in the Rec(-) lysogen. On the other hand, thermal induction of a mutant lambda (lambdacI857) lysogen of the Rec(-) strain was not reduced and was only slightly affected by UV irradiation. Phage subject to inhibition by lambda immunity failed to multiply in UV-irradiated cells of the Rec(-) lambda(+) lysogen, whereas those not inhibited by this immunity did multiply. It was concluded that the failure of UV to induce lambda(+) in the Rec(-) lysogen was not due to damage to the prophage, but rather to the inability of the irradiated cells to respond by lifting immunity. Preliminary evidence indicates that a single mutation confers recombination deficiency and the inability to lift immunity after UV irradiation. Possible relationships between recombination and the lifting of immunity are enumerated.     

Isolation and Characterization of Mutations in the β-Tubulin Gene of SACCHAROMYCES CEREVISIAE

Of 173 mutants of Saccharomyces cerevisiae resistant to the antimitotic drug benomyl (BenR), six also conferred cold-sensitivity for growth and three others conferred temperature-sensitivity for growth in the absence of benomyl. All of the benR mutations tested, including the nine conditional-lethal mutations, were shown to be in the same gene. This gene, TUB2, has previously been molecularly cloned and identified as the yeast structural gene encoding beta-tubulin. Four of the conditional-lethal alleles of TUB2 were mapped to particular restriction fragments within the gene. One of these mutations was cloned and sequenced, revealing a single amino acid change, from arginine to histidine at amino acid position 241, which is responsible for both the BenR and the cold-sensitive lethal phenotypes. The terminal arrest morphology of conditional-lethal alleles of TUB2 at their restrictive temperature showed a characteristic cell-division-cycle defect, suggesting a requirement for tubulin function primarily in mitosis during the vegetative growth cycle. The TUB2 gene was genetically mapped to the distal left arm of chromosome VI, very near the actin gene, ACT1; no CDC (cell-division-cycle) loci have been mapped previously to this location. TUB2 is thus the first cell-division-cycle gene known to encode a cytoskeletal protein that has been identified in S. cerevisiae.     

Recombination-Deficient Deletions in Bacteriophage λ and Their Interaction with CHI Mutations

We have isolated a new class of deletion mutants of phage lambda that extend from the prophage attachment site, att, into the gam and cIII genes. In this respect they are similar to certain of the λpbio transducing phage, but they differ in having a low burst size and in forming minute plaques. Lytically grown stocks of the deletions contain a variable proportion of phage that produce large plaques. These have been shown to carry an additional point mutation. Similar mutations, called chi, have been described by Lam et al. (1974), who showed that they result in a hot-spot for recombination produced by the host recombination system (Rec). We show that chi mutations can occur at several sites in the lambda genome and produce a Rec-dependent increase in the burst size of the one deletion tested.—In addition to reducing burst size, the one deletion tested reduces synthesis of DNA and endolysin but increases production of serum blocking protein. A chi mutation partially restores DNA synthesis and endolysin production and reduces serum blocking protein to normal levels. Our results are consistent with the hypothesis put forward by Lam et al., that chi enhances the frequency of Rec-promoted recombination, which provides the only pathway for production of maturable DNA in a red^- gam^- infection. The mechanism of the differential effect on protein production is, however, unclear.—Chi mutations are found to occur in DNA other than that of λ. We show that, as has been suggested elsewhere (McMilin, Stahl and Stahl 1974), the λpbio transducing phages carry a chi mutation within the E. coli DNA substitution. A chi mutation also arose in a new substitution of unknown origin isolated in the course of this work.     

Nonideal Statistics and Positive Correlation in Phage Recombination: Studies with λ Tandem Duplication Phages

The question of nonideality in phage recombination, that is, the extent to which recombinant frequencies differ from those expected from the proportions of the two parental types in the mass culture, was addressed by experiments with λ tandem duplication phages. Isolation and genotypic analysis of triplication-phage progeny, all of which must be the result of intermolecular recombination, yielded a value of about 0.5 for the nonideality parameter h, i.e., the frequency of unlike-parent matings was only about ½ the "ideal" value. This value was independent of multiplicity and about the same for the Rec or Red recombination systems. Similar analysis of single-copy phage progeny yielded estimates of k, the ratio of intramolecular to intermolecular recombination of about for the Rec system; no intramolecular events were detected in Red-mediated crosses. Consideration of known nonideality factors (finite input, limited number of intracellular sites for phage growth) suggests that the observed h values correspond to intracellular mixing efficiencies of 55 to 100%, depending on the number of intracellular phage growth sites assumed. Analysis of long-range positive correlation (negative interference) indicates that statistical effects caused unlike-parent double crossovers to be three to four times as frequent as an independent-event calculation would predict. In addition, Rec-mediated crosses showed a 1.3-fold positive correlation for unlike-parent crossovers (in a second interval) among the progeny of like-parent recombinations.     

Stimulation of Oligonucleotide-Directed Gene Correction by Redβ Expression and MSH2 Depletion in Human HT1080 Cells

The correction of disease-causing mutations by single-strand oligonucleotide-templated DNA repair (ssOR) is an attractive approach to gene therapy, but major improvements in ssOR efficiency and consistency are needed. The mechanism of ssOR is poorly understood but may involve annealing of oligonucleotides to transiently exposed single-stranded regions in the target duplex. In bacteria and yeast it has been shown that ssOR is promoted by expression of Redβ, a single-strand DNA annealing protein from bacteriophage lambda. Here we show that Redβ expression is well tolerated in a human cell line where it consistently promotes ssOR. By use of short interfering RNA, we also show that ssOR is stimulated by the transient depletion of the endogenous DNA mismatch repair protein MSH2. Furthermore, we find that the effects of Redβ expression and MSH2 depletion on ssOR can be combined with a degree of cooperativity. These results suggest that oligonucleotide annealing and mismatch recognition are distinct but interdependent events in ssOR that can be usefully modulated in gene correction strategies.     

Mutations of the Microsomal Triglyceride-Transfer–Protein Gene in Abetalipoproteinemia

Elevated plasma levels of apolipoprotein B (apoB)–containing lipoproteins constitute a major risk factor for the development of coronary heart disease. In the rare recessively inherited disorder abetalipoproteinemia (ABL) the production of apoB-containing lipoproteins is abolished, despite no abnormality of the apoB gene. In the current study we have characterized the gene encoding a microsomal triglyceride-transfer protein (MTP), localized to chromosome 4q22-24, and have identified a mutation of the MTP gene in both alleles of all individuals in a cohort of eight patients with classical ABL. Each mutant allele is predicted to encode a truncated form of MTP with a variable number of aberrant amino acids at its C-terminal end. Expression of genetically engineered forms of MTP in Cos-1 cells indicates that the C-terminal portion of MTP is necessary for triglyceride-transfer activity. Deletion of 20 amino acids from the carboxyl terminus of the 894-amino-acid protein and a missense mutation of cysteine 878 to serine both abolished activity. These results establish that defects of the MTP gene are the predominant, if not sole, cause of hereditary ABL and that an intact carboxyl terminus is necessary for activity.     

χ Recombination Activity in Phage λ Decays as a Function of Genetic Distance

In Escherichia coli, χ is a recombination hotspot that stimulates RecBCD-dependent exchange at and to one side of itself. χ activity is highest at χ and decreases with distance from χ. The decrease in χ activity may be a simple property of the physical distance over which χ can stimulate recombination. Alternatively, the decay in χ activity with distance may reflect the high likelihood that χ-stimulated recombination occurs in a single χ-proximal act, to the exclusion of additional χ-stimulated exchanges more distal to χ. To test the models, we determined if χ activity decreases as a function of physical distance (i.e., DNA base pairs) or genetic distance (homologous DNA base pairs). Our results indicate that χ activity decays as a function of genetic distance. In addition, we found that the sbcB gene product (exonuclease I, a 3' -> 5' ssDNA exonuclease) modulates the distance over which χ can act. In contrast, the recJ gene product (a 5' -> 3' ssDNA exonuclease) does not alter the decay of χ activity.     

Targeting of the Gi2α Gene in es cells with Replacement and Insertion Vectors

Abstract

Five replacement vectors (RV) and one insertion vector (IV) were constructed in which ca. 10 kb of genomic G_i2α sequence, flanked on one (IV) or both (RV) sides by a thymidine kinase (TK) marker, were disrupted by a Neo marker inserted into the Ncol site of exon 3. G418^RFIAU^R clones corresponding to ca. 4×10⁸ ES cells electroporated with replacement vectors were analyzed and revealed no targeting event. The insertion vector, however, was integrated by a single reciprocal recombination resulting in a duplication of homology (Hit step; G418^RFIAUS^S, which was lost-together with the plasmid and the TK sequences - by intrachromosomal recombination (Run step; G418^RFIAU^R). Thus, the Hit and Run strategy can be used with a selectable marker disrupting the targeted gene, giving rise to the same targeted product that would have been expected to arise from a double crossover with a replacement vector.     

The λ Red Proteins Promote Efficient Recombination between Diverged Sequences: Implications for Bacteriophage Genome Mosaicism

Genome mosaicism in temperate bacterial viruses (bacteriophages) is so great that it obscures their phylogeny at the genome level. However, the precise molecular processes underlying this mosaicism are unknown. Illegitimate recombination has been proposed, but homeologous recombination could also be at play. To test this, we have measured the efficiency of homeologous recombination between diverged oxa gene pairs inserted into λ. High yields of recombinants between 22% diverged genes have been obtained when the virus Red Gam pathway was active, and 100 fold less when the host Escherichia coli RecABCD pathway was active. The recombination editing proteins, MutS and UvrD, showed only marginal effects on λ recombination. Thus, escape from host editing contributes to the high proficiency of virus recombination. Moreover, our bioinformatics study suggests that homeologous recombination between similar lambdoid viruses has created part of their mosaicism. We therefore propose that the remarkable propensity of the λ-encoded Red and Gam proteins to recombine diverged DNA is effectively contributing to mosaicism, and more generally, that a correlation may exist between virus genome mosaicism and the presence of Red/Gam-like systems.