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.     

The role of genes of the system of mismatched base correction in genetic recombination of Escherichia coli

A genetic system was elaborated to study intramolecular recombination of bacteriophages lambda and phi 80. Practically, the ideal complementation of nucleotide sequences in recombining DNA molecules is required to obtain recombinants resulting from RecA-dependent recombination in Escherichia coli cells. a hypothesis is proposed to which the correction of mismatched bases hinders recombinant formation during recombination of fully homologous DNAs. The increased yields of hybrid molecules during interaction of the same DNA in the cells with deficient genes for correction support the hypothesis as well as independent demonstration of mutation in a gene for correction according to the effect of the increased yield of recombinants. A series of Escherichia coli cells mutants with increased formation of recombinant clones has been obtained.     

Mismatch recognition in chromosomal interactions and speciation

Homologous chromosomes interact during meiosis by means of proteins involved in recombination and in the recognition and repair of mismatched base pairs. Recombination proteins bring homologous chromosomes or chromosomal regions together by facilitating the search for DNA homology and by catalyzing strand exchange between homologous molecules or regions. Mismatch recognition and repair proteins act as editors of recombination and appear to disrupt those DNA associations that contain mismatched base pairs. Thus, it may be that, as chromosomes diverge in their primary sequence and become increasingly polymorphic, recombinational interactions leading to chromosome pairing and recombination tend to be inhibited. Decreasing homologous interactions within and between chromosomes will clearly contribute to maintaing the integrity of individual chromosomes and may utimately lead, as a result of sterile meioses, to the reproductive isolation of closely related species.     

Contritution of correction to genetic recombination in T4 phage measured by the effect of map contraction

Marker-dependence of the fine structure map contraction in T4 phage is studied in two-factor crosses between rIIB mutants separated by indicator distances. The genetic intervals, which were short as compared with mean length of the heteroduplex region in hybrid DNA molecules but which exceeded the length of the DNA strand involved in a single correction event, were selected as indicator ones. On the basis of a deviation of measured frequencies from additivity (map contraction) the marker-specific frequencies of wild type recombinants arising as a result of correction to the wild type (kappa (- leads to +)) were calculated. For the most of the marker studied both of the base substitution and frame shift type the frequencies kappa (- leads to +) have the values below 2.10(-4). In the case of three most highly corrected frame shift markers with kappa (- leads to +) being 14.10(-4)--17.10(-4), about ten percent of all mismatched regions are corrected to the wild type.     

recB recC-dependent processing of heteroduplex DNA stimulates recombination of an adjacent gene in Escherichia coli.

The effect of DNA mismatched repair on the genetic recombination of a gene adjacent to the mismatch site (MS) was tested by using four mismatch configurations. An MS was constructed in a well-characterized plasmid recombination substrate, and recombination with a resident compatible plasmid was measured after transformation of the mismatched plasmid into Escherichia coli. The mismatched plasmids were constructed such that one of the DNA strands was methylated by the DNA adenine methylase (Dam), while the other strand was unmethylated. The processing of a hemimethylated single-base-pair mismatch had no effect on the recombination of the adjacent gene, suggesting that the most efficient (Dam-instructed) mismatch repair process does not secondarily promote genetic recombination. However, mismatches that could form an ordered secondary structure resembling a cruciform increased the recombination of this adjacent gene at least 20-fold. An identical mismatch that could not form an ordered secondary structure had no effect in this system. The increased frequency of recombination observed was found to require the recB or recC gene product or both. Furthermore, the recombination appeared unidirectional, in that the cruciform-containing plasmid did not produce stable transformants. Our results support a model in which the cruciform-containing plasmid can participate in recombination with the resident plasmid but is unable to produce stable transformant progeny. A proposed role for the RecBCD enzyme (ExoV) in this process is discussed.     

Differential Mismatch Repair Can Explain the Disproportionalities between Physical Distances and Recombination Frequencies of Cyc1 Mutations in Yeast

Recombination rates have been examined in two-point crosses of various defined cyc1 mutations that cause the loss or nonfunction of iso-1-cytochrome c in the yeast Saccharomyces cerevisiae. Recombinants arising by three different means were investigated, including X-ray induced mitotic recombination, spontaneous mitotic recombination, and meiotic recombination. Heteroallelic diploid strains were derived by crossing cyc1 mutants containing a series of alterations at or near the same site to cyc1 mutants containing alterations at various distances. Marked disproportionalities between physical distances and recombination frequencies were observed with certain cyc1 mutations, indicating that certain mismatched bases can significantly affect recombination. The marker effects were more pronounced when the two mutational sites of the heteroalleles were within about 20 base pairs, but separated by at least 4 base pairs. Two alleles, cyc1-163 and cyc1-166, which arose by G.C----C.G transversions at nucleotide positions 3 and 194, respectively, gave rise to especially high rates of recombination. Other mutations having different substitutions at the same nucleotide positions were not associated with abnormally high recombination frequencies. We suggest that these marker effects are due to the lack of repair of either G/G or C/C mismatched base pairs, while the other mismatched base pair of the heteroallele undergoes substantial repair. Furthermore, we suggest that diminished recombination frequencies are due to the concomitant repair of both mismatches within the same DNA tract.     

A cytogenetically based physical map of chromosome 1B in common wheat.

We have constructed a cytogenetically based physical map of chromosome 1B in common wheat by utilizing a total of 18 homozygous deletion stocks. It was possible to divide chromosome 1B into 17 subregions. Nineteen genetic markers are physically mapped to nine subregions of chromosome 1B. Comparison of the cytological map of chromosome 1B with an RFLP-based genetic linkage map of Triticum tauschii revealed that the linear order of the genetic markers was maintained between chromosome 1B of hexaploid wheat and 1D of T. tauschii. Striking differences were observed between the physical and genetic maps in relation to the relative distances between the genetic markers. The genetic markers clustered in the middle of the genetic map were physically located in the distal regions of both arms of chromosome 1B. It is unclear whether the increased recombination in the distal regions of chromosome 1B is due to specific regions of increased recombination or a more broadly distributed increase in recombination in the distal regions of Triticeae chromosomes.     

Differentiation between wheat chromosomes 4B and 4D.

A linkage map based on homoeologous recombination, induced by the absence of the Ph1 locus, between chromosome 4D of Triticum aestivum L. (genomes AABBDD) and chromosome 4B of T. turgidum L. (genomes AABB) was compared with a linkage map of chromosome 4Am of T. monococcum L. and a consensus map of chromosomes 4B and 4D of T. aestivum based on homologous recombination. The 4D/4B homoeologous map was only one-third the length of the homologous maps and all intervals were reduced relative to the 4B-4D consensus map. After the homoeologous map was corrected for this overall reduction in recombination, the distribution of recombination in the short arm was similar in both types of maps. In the long arm, homoeologous recombination declined disproportionally in the distal to proximal direction. This gradient was shown to be largely caused by severe segregation distortion reflecting selection against 4D genetic material. The segregation distortion had a maximum that coincided with the centromere and likely had a polygenic cause. Chromosomes 4D and 4B were colinear and recombination between them occurred in almost all intervals where homologous recombination occurred. These findings suggest that these chromosomes are not differentiated structurally and that the differentiation is not segmental. In the presence of Ph1, metaphase I chromosome pairing between chromosomes composed of homologous and differentiated regions correlated with the lengths of the homologous regions. No compensatory allocation of crossovers into the homologous regions was detected. In this respect, the present results are in dramatic contrast with the crossover allocation into the pseudoautosomal region in the mammalian male meiosis.     

Molecular heterozygotes in Bacillus subtilis and their correction

Summary Data are presented on the probability of correction of molecular heterozygotes during the transformation of Bacillus subtilis. This value varies between 0 and 1 for different mutants in the same genetic locus. The correction of closely linked markers is simultaneous but it is independent for distant loci. The efficiency of integration of different genetic markers during transformation depends on their ability to be corrected towards the structure of the recipient strain.The linked correction of neighboring markers explains quantitatively the asymmetric phenomena in reciprocal crosses.UV-irradiation of transforming DNA inhibits strongly the correction of molecular heterozygotes and eliminates the asymmetry in reciprocal crosses. The same effect is found after chemical damage of DNA by nitrous acid.     

A neutral explanation for the correlation of diversity with recombination rates in humans

One of the most striking findings to emerge from the study of genomic patterns of variation is that regions with lower recombination rates tend to have lower levels of intraspecific diversity but not of interspecies divergence. This uncoupling of variation within and between species has been widely interpreted as evidence that natural selection shapes patterns of genetic variability genomewide. We revisited the relationship between diversity, divergence, and recombination in humans, using data from closely related species and better estimates of recombination rates than previously available. We show that regions that experience less recombination have reduced divergence to chimpanzee and to baboon, as well as lower levels of diversity. This observation suggests that mutation and recombination are associated processes in humans, so that the positive correlation between diversity and recombination may have a purely neutral explanation. Consistent with this hypothesis, diversity levels no longer increase significantly with recombination rates after correction for divergence to chimpanzee.     

Drosophila cholinergic neurons and processes visualized with Gal4/UAS-GFP

Using 7.4 kb of 5' flanking DNA from the Drosophila cholinergic gene locus to drive Gal4 expression we can visualize essentially all cholinergic neurons and neuropiles after genetic recombination with a UAS-GFP (S65T) reporter gene. In contrast to previous methods somata and neuropiles can be observed in the same samples. Fluorescence intensity is strong enough to allow observations in live animals at all developmental stages. Three-dimensional reconstructions made from confocal sections of whole-mount preparations reveal the extensive cholinergic connections among various regions of the nervous system.     

Highly Mismatched Molecules Resembling Recombination Intermediates Efficiently Transform Mismatch Repair Proficient Escherichia Coli

The ability of related DNAs to undergo recombination decreases with increased sequence divergence. Mismatch repair has been proposed to be a key factor in preventing homeologous recombination; however, the contribution of mismatch repair is not universal. Although mismatch repair has been proposed to act by preventing strand exchange and/or inactivating multiply mismatched heteroduplexes, there has been no systematic study to determine at what step(s) in recombination mismatch repair acts in vivo. Since heteroduplex is a commonly proposed intermediate in many models of recombination, we have investigated the consequences of mismatch repair on plasmids that are multiply mismatched in heteroduplex structures that are similar to those that might arise during recombination. Plasmids containing multiply mismatched regions were transformed into wild-type and Mut(-) Eschericia coli mutants. There was only a 30-40% reduction in transformation of Mut(+) as compared to mutS and mutL strains for DNAs containing an 18% mismatched heteroduplex. The products obtained from mutS hosts differed from those obtained from Mut(+) hosts in that there were many more colonies containing mixtures of two plasmids, due to survival of both strands of the heteroduplex. There were nearly 10 times more recombinants obtained from the mutS as compared to the wild-type host. Based on these results and those from other studies with E. coli and yeast, we propose that the prevention of recombination between highly diverged DNAs may be at step earlier than heteroduplex formation.     

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.     

Repair of base-base mismatches in simian and human cells

Mismatched heteroduplexes arise as intermediates of several dissimilar genetic processes. The outcome of these genetic events will therefore be influenced by the efficiency and specificity of mismatch repair. We have studied the correction of base-base mispairs in simian and human fibroblasts by transfecting the cells with derivatives of SV40 DNA, each harboring a single mispair in a defined orientation. Analysis of plaques revealed that correction efficiencies for homomispairs followed the pattern G.G greater than C.C greater than or equal to A.A greater than T.T. Repair bias was influenced by flanking sequences. Correction efficiences for heteromispairs followed the pattern of G.T greater than A.C greater than C.T greater than A.G and repair favored the retention of G + C by a substantial margin. This repair specificity could lead to a gene conversion bias favoring the accumulation of G + C in sequences subject to high levels of recombination or unequal exchange.     

Justified chauvinism: advances in defining meiotic recombination through sperm typing

Sperm typing offers an efficient means of studying the quantitative and qualitative aspects of meiotic recombination that are virtually unapproachable by pedigree analysis. Since the initial development of the technique >10 years ago, several salient findings based on empirically derived recombination data have been described. The precise rates and distributions of recombination have been reported for specific regions of the genome, serving as the prototype for high-resolution genome-wide recombination patterns. Identification and characterization of molecular genetic events, such as unequal crossing over, gene conversion and crossover asymmetry, are under close inspection for the first time as a result of this technology. The influence of these phenomena on the evolution of the genome is of primary interest from a scientific and medical perspective. In this article, we review the novel discoveries in mammalian meiotic recombination that have been revealed through sperm typing.     

A comparison of the ability of the human IgG1 allotypes G1m3 and G1m1,17 to stimulate T-cell responses from allotype matched and mismatched donors

The immunogenicity of clinically administered antibodies has clinical implications for the patients receiving them, ranging from mild consequences, such as increased clearance of the drug from the circulation, to life-threatening effects. The emergence of methods to engineer variable regions resulting in the generation of humanised and fully human antibodies as therapeutics has reduced the potential for adverse immunogenicity. However, due to differences in sequence referred to as allotypic variation, antibody constant regions are not homogeneous within the human population, even within sub-classes of the same immunoglobulin isotype. For therapeutically administered antibodies, the potential exists for an immune response from the patient to the antibody if the allotype of patient and antibody do not match. Allotypic distribution in the human population varies within and across ethnic groups making the choice of allotype for a therapeutic antibody difficult. This study investigated the potential of human IgG1 allotypes to stimulate responses in human CD4⁺ T cells from donors matched for homologous and heterologous IgG1 allotypes. Allotypic variants of the therapeutic monoclonal antibody trastuzumab were administered to genetically defined allotypic matched and mismatched donor T cells. No significant responses were observed in the mismatched T cells. To investigate the lack of T-cell responses in relation to mismatched allotypes, HLA-DR agretopes were identified via MHC associated peptide proteomics (MAPPs). As expected, many HLA-DR restricted peptides were presented. However, there were no peptides presented from the sequence regions containing the allotypic variations. Taken together, the results from the T-cell assay and MAPPs assay indicate that the allotypic differences in human IgG1 do not represent a significant risk for induction of immunogenicity.     

The recombination, repair and modification of DNA

This article is an overview of the author's involvement in theoretical and experimental research on genetic recombination and DNA repair, and also on the enzymic modification of cytosine in DNA to 5-methyl cytosine. It includes the history of the discovery of the central intermediate in genetic recombination at the DNA level, and the repair of mismatched bases. These explain the major features of genetic fine structure. The first repair and recombination defective mutants in any eukaryote were isolated in the smut fungus Ustilago maydis. The hypothesis that DNA methylation has a role in gene expression in higher organism is now supported by abundant evidence. Direct evidence that gene silencing in mammalian cells is causally related to DNA methylation has been obtained.     

Gene conversion in Escherichia coli: the recF pathway for resolution of heteroduplex DNA.

The independent repair of mismatched nucleotides present in heteroduplex DNA has been used to explain gene conversion and map expansion after general genetic recombination. We have constructed and purified heteroduplex plasmid DNAs that contain heteroallelic 10-base-pair insertion-deletion mismatches. These DNA substrates are similar in structure to the heteroduplex DNA intermediates that have been proposed to be produced during the genetic recombination of plasmids. These DNA substrates were transformed into wild-type and mutant Escherichia coli strains, and the fate of the heteroduplex DNA was determined by both restriction mapping and genetic tests. Independent repair events that yielded a wild-type Tetr gene were observed at a frequency of approximately 1% in both wild-type and recB recC sbcB mutant E. coli strains. The independent repair of small insertion-deletion-type mismatches separated by 1,243 base pairs was found to be reduced by recF, recJ, and ssb single mutations in an otherwise wild-type genetic background and reduced by recF, recJ, and recO mutations in a recB recC sbcB genetic background (the ssb mutation was not tested in the latter background). Independent repair of small insertion-deletion-type mismatched nucleotides that were as close as 312 nucleotides apart was observed. There was no apparent bias in favor of the insertion or deletion of mutant sequences.     

Comparative Genetics of the T-Even Bacteriophages

A system of amber mutants has been developed for each of the T-even bacteriophages T2 and T6, to complement those already available in T4. In T2 these mutants identify 52 genes, of which 49 are homologous with T4 genes; in T6 they identify 45 genes, of which 42 have T4 homologs, and an additional one which is homologous to a T2 gene not yet identified in T4. In both T2 and T6, recombination between mutants is characterized by considerable negative interference, which is correctable by a mapping function designed for T4. Recombinational maps of T2 and T6 constructed with these mutants have the same gene order and nearly the same gene spacings as in T4, with the exception of the tail fiber region; T2 and T6 appear to lack a localized recombinational expansion of this region found in T4. Homologous gene products from all three phages are in general interchangeable, with the exception of those from two apparently "co-adapted" tail fiber genes, 37 and 38. The general genetic similarity of all three phages suggests that they are analogous to races of higher organisms, retaining the capacity for genetic exchange despite some clear genetic differences and some incipient isolating mechanisms.     

Species and Population Level Molecular Profiling Reveals Cryptic Recombination and Emergent Asymmetry in the Dimorphic Mating Locus of C. reinhardtii

Heteromorphic sex-determining regions or mating-type loci can contain large regions of non-recombining sequence where selection operates under different constraints than in freely recombining autosomal regions. Detailed studies of these non-recombining regions can provide insights into how genes are gained and lost, and how genetic isolation is maintained between mating haplotypes or sex chromosomes. The Chlamydomonas reinhardtii mating-type locus (MT) is a complex polygenic region characterized by sequence rearrangements and suppressed recombination between its two haplotypes, MT+ and MT−. We used new sequence information to redefine the genetic contents of MT and found repeated translocations from autosomes as well as sexually controlled expression patterns for several newly identified genes. We examined sequence diversity of MT genes from wild isolates of C. reinhardtii to investigate the impacts of recombination suppression. Our population data revealed two previously unreported types of genetic exchange in Chlamydomonas MT—gene conversion in the rearranged domains, and crossover exchanges in flanking domains—both of which contribute to maintenance of genetic homogeneity between haplotypes. To investigate the cause of blocked recombination in MT we assessed recombination rates in crosses where the parents were homozygous at MT. While normal recombination was restored in MT+×MT+ crosses, it was still suppressed in MT−×MT− crosses. These data revealed an underlying asymmetry in the two MT haplotypes and suggest that sequence rearrangements are insufficient to fully account for recombination suppression. Together our findings reveal new evolutionary dynamics for mating loci and have implications for the evolution of heteromorphic sex chromosomes and other non-recombining genomic regions.