The Tn3 β-Lactamase Gene Acts as a Hotspot for Meiotic Recombination in Yeast

Although genetic distances are often assumed to be proportional to physical distances, chromosomal regions with unusually high (hotspots) or low (coldspots) levels of meiotic recombination have been described in a number of genetic systems. In general, the DNA sequences responsible for these effects have not been determined. We report that the 5' region of the beta-lactamase (ampR) gene of the bacterial transposon Tn3 is a hotspot for meiotic recombination when inserted into the chromosomes of the yeast Saccharomyces cerevisiae. When these sequences are homozygous, both crossing over and gene conversion are locally stimulated. The 5' end of the beta-lactamase gene is about 100-fold "hotter" for crossovers than an average yeast DNA sequence.     

Hybrid DNA Extension and Reciprocal Exchanges: Alternative Issues of an Early Intermediate during Meiotic Recombination?

Large heterologies in gene b2 strongly increase the frequencies of reciprocal exchanges on their left border, towards the high conversion end. In a previous study, we observed that heterozygous point mutations located in the high conversion end (region F) stimulate the reciprocal exchanges instigated by the large heterology 138. We have defined some properties of this stimulation. The effect does not depend on the nature of the large heterology used. It is effective only with point mutations located on the left side of the large heterology. It does not depend on the number of heterozygosities accumulated in region F. It is not specific on the location of point mutations in region F: it decreases from region F (left end) to region E (middle part of b2). It is correlated with the mismatch correction efficiencies of the point mutations used. It is not observed in the absence of a large heterology. Point mutation heterozygosities which stimulate reciprocal exchanges also decrease the frequency of HDNA formation in gene b2. We propose a model in which reciprocal exchanges on the one hand and hybrid DNA formation on the other hand correspond to alternative processings of a common recombination intermediate.     

Topoisomerase 3α and RMI1 Suppress Somatic Crossovers and Are Essential for Resolution of Meiotic Recombination Intermediates in Arabidopsis thaliana

Topoisomerases are enzymes with crucial functions in DNA metabolism. They are ubiquitously present in prokaryotes and eukaryotes and modify the steady-state level of DNA supercoiling. Biochemical analyses indicate that Topoisomerase 3α (TOP3α) functions together with a RecQ DNA helicase and a third partner, RMI1/BLAP75, in the resolution step of homologous recombination in a process called Holliday Junction dissolution in eukaryotes. Apart from that, little is known about the role of TOP3α in higher eukaryotes, as knockout mutants show early lethality or strong developmental defects. Using a hypomorphic insertion mutant of Arabidopsis thaliana (top3α-2), which is viable but completely sterile, we were able to define three different functions of the protein in mitosis and meiosis. The top3α-2 line exhibits fragmented chromosomes during mitosis and sensitivity to camptothecin, suggesting an important role in chromosome segregation partly overlapping with that of type IB topoisomerases. Furthermore, AtTOP3α, together with AtRECQ4A and AtRMI1, is involved in the suppression of crossover recombination in somatic cells as well as DNA repair in both mammals and A. thaliana. Surprisingly, AtTOP3α is also essential for meiosis. The phenotype of chromosome fragmentation, bridges, and telophase I arrest can be suppressed by AtSPO11 and AtRAD51 mutations, indicating that the protein is required for the resolution of recombination intermediates. As Atrmi1 mutants have a similar meiotic phenotype to Attop3α mutants, both proteins seem to be involved in a mechanism safeguarding the entangling of homologous chromosomes during meiosis. The requirement of AtTOP3α and AtRMI1 in a late step of meiotic recombination strongly hints at the possibility that the dissolution of double Holliday Junctions via a hemicatenane intermediate is indeed an indispensable step of meiotic recombination.     

Break-Join Recombination in Phage λ

In phage lambda, when DNA replication is blocked, recombination mediated by the Red pathway occurs only near the double-chain break site, cos, that defines the termini of the virion chromosome. The recombinants initiated by cos contain newly synthesized DNA near cos, in amount corresponding to a few percent of the length of lambda. A restriction enzyme cut delivered to one parent far from cos results in elevated recombination near the restriction site. Recombinants induced by this cut have a similarly small amount of DNA synthesis in these replication-blocked crosses. When restriction cuts are introduced in the presence of normal amounts of all of the DNA replication enzymes, many of the resulting recombinants still enjoy, at most, a small amount of DNA synthesis associated with the exchange event. Thus, these experiments fail to support the previously considered possibility that Red-mediated recombination in lambda proceeds largely through a break-copy pathway.     

Recombination in human mitochondrial DNA?

The possibility of recombination in human mitochondrial DNA (mtDNA) has been hotly debated over the last few years. In this study, a general model of recombination in circular molecules is developed and applied to a recently published African sample (n = 21) of complete mtDNA sequences. It is shown that the power of correlation measures to detect recombination in circular molecules can be vanishingly small and that the data are consistent with the given model and no recombination only if the overall heterogeneity in mutation rate is <0.09.     

Meiotic Checkpoints: Repair or Removal?

Defects in meiosis can produce different checkpoint responses in female and male animals, suggesting that meiotic checkpoints exhibit sexual dimorphism. A recent study in Caenorhabditis elegans indicates that meiotic checkpoint activation is similar between the sexes and the primary difference lies in the downstream consequences.     

EGFR Intron Recombination in Human Gliomas: Inappropriate Diversion of V(D)J Recombination?

The epidermal growth factor receptor (EGFR) is a membrane-bound, 170 kDa, protein tyrosine kinase that plays an important role in tumorigenesis. The EGFR gene, which is composed of over 168 kb of sequence, including a 123-kb first intron, is frequently amplified and rearranged in malignant gliomas leading to the expression of oncogenic deletion (DM) and tandem duplication (TDM) mutants. The most common DM in gliomas is EGFRvIII, which arises from recombination between introns 1 and 7 with deletion of exons 2 through 7 and intervening introns. In addition, some human gliomas express 180- to 190-kDa TDM, which are constitutively active and highly oncogenic. Both DM and TDM arise by recombination of introns that contain sequences with homology to the recombination signal sequence (RSS) heptamers and nonamers present in the V(D)J region of the immunoglobin and T lymphocyte antigen receptor genes. V(D)J RSS have also been identified in certain proto-oncogenes like bcl-2 that are involved in translocations associated with the development of human lymphomas and in other genes such as hypoxanthine-guainine phosphoribosyl transferase (HPRT) in which deletion mutations and intron rearrangements are a common phenomenon. Together with the expression of recombination associated gene (RAG) and nonhomologous end-joining (NHEJ) proteins in gliomas, these observation suggest that aberrant activity of the V(D)J recombinase may be involved in the activation of proto-oncogenes in both liquid and solid tumors.     

Genetic Recombination in Bacteriophage φX174

Genetic recombination in bacteriophage X174 usually takes place early in the infection process and involves two parental replicative form (double-stranded) DNA molecules. The host recA protein is required; none of the nine known X174 cistron products is essential. The products of a single recombination event are nonreciprocal and asymmetric. Typically, only one of the parental genotypes and one recombinant genotype are recovered from a single cell. An alternative, less efficient recombination mechanism which requires an active X174 cistron A protein is observed in the absence of the host recA gene product.     

Annealing Vs. Invasion in Phage λ Recombination

Genetic recombination catalyzed by λ's Red pathway was studied in rec(+) and recA mutant bacteria by examining both intracellular λ DNA and mature progeny particles. Recombination of nonreplicating phage chromosomes was induced by double-strand breaks delivered at unique sites in vivo. In rec(+) cells, cutting only one chromosome gave nearly maximal stimulation of recombination; the recombinants formed contained relatively short hybrid regions, suggesting strand invasion. In contrast, in recA mutant cells, cutting the two parental chromosomes at non-allelic sites was required for maximal stimulation; the recombinants formed tended to be hybrid over the entire region between the two cuts, implying strand annealing. We conclude that, in the absence of RecA and the presence of non-allelic DNA ends, the Red pathway of λ catalyzes recombination primarily by annealing.     

Recombination and RNA processing: a common strand?

Genetic recombination is a basic cellular process required for altering genome structure. The RecA protein of Escherichia coli has a central role in homologous recombination, and a eukaryotic protein with similar properties has been discovered in the yeast Saccharomyces cerevisiae. Unexpectedly, this RecA-like protein has additional biochemical activities, and its function may not be restricted to recombination.     

Meiotic recombination: too much of a good thing?

Proper chromosome segregation in meiosis requires the right number and distribution of crossovers. Recent work in budding yeast has revealed a meiosis-specific role for RecQ helicase in limiting crossovers, distinct from its known somatic role in maintaining genome stability.     

Recombination or mutational hot spots in human mtDNA?

Awadalla, Eyre-Walker, and Maynard Smith (1999) recently argued that there might be recombination in human mitochondrial DNA (mtDNA). Their claim was based on their observation of decaying linkage disequilibrium (LD) as a function of physical distance. Their study was much criticized, and follow-up studies have failed to find any evidence for recombination. We argue that the criticisms levied, even if correct, could not possibly explain the findings of Awadalla, Eyre-Walker, and Maynard Smith (1999). Nonetheless, the test proposed by Awadalla, Eyre-Walker, and Maynard Smith (1999 ) is not robust because recombination is not the only explanation for decay of LD. We show that such a pattern can be caused by mutational hot spots as well. However, a closer look at the data suggests that the pattern observed was not caused by mutational hot spots but rather by chance. Thus, there appears to be no evidence for recombination in the mtDNA polymorphism data. In conclusion, we discuss the possibility of detecting recombination in mtDNA and the implications of its existence.     

Directionality and Nonreciprocality of Chi-Stimulated Recombination in Phage λ

Chi's are genetic elements that stimulate generalized recombination in their locale in phage λ. All Chi's, wherever located on λ's chromosome, act asymmetrically in crosses blocked in DNA replication: (1) They stimulate exchange primarily to their left on the conventional λ map, and (2) the stimulated exchange is frequently nonreciprocal, the recombinant carrying the Chi element being produced less often than the complementary product.     

Chromosomally-Induced Meiotic Drive in Drosophila Males: Checkpoint or Fallout?

In male Drosophila melanogaster, anomalies in sex chromosome pairing at meiosis often lead to complete or partial sperm dysfunction. This observation has led to the suggestion that defects in either the efficiency or configuration of chromosome pairing at metaphase trigger a checkpoint mechanism that leads to the elimination of meiotic products. Here, we discuss this model in consideration of recent observations on the conservation of metaphase checkpoint components in male meiosis, and on the phenotype of new alleles of the male-specific meiotic mutant teflon. Based on these observations, we propose an alternative hypothesis for the cause of sperm dysfunction in cases of chromosomal sterility and drive. We suggest that disruption of the prophase compartmentalization of sex chromatin, rather than abnormal pairing at metaphase, may be the causative defect. Such disruption may occur as a result of perturbations in sex chromosome pairing, or by translocations involving autosomal and sex chromatin. We discuss how this hypothesis may account for previously described examples chromosomal causes of meiotic drive and sterility in Drosophila. This revised version was published online in July 2006 with corrections to the Cover Date.     

Meiotic Studies of Diploid Perennial Teosinte and Its Hybrids with Maize

1. Open-pollinated diploid perennial teosinte Microsporocytes at pachytene stage from six different diploid perennial teosinte plants were investigated. It was found that they all had 10 pairs of chromosomes (2n = 20). All of the knobs and large chromomere were terminal (Plate Ⅰ,). The size of the knobs varied from medium to small. The short arms of chromosomes 1 and 2 and the long arms of chromosomes 2 and 3 had a small knob. A large chromomere     

Shugoshin Is Essential for Meiotic Prophase Checkpoints in C. elegans

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