Biochemical analysis of genetic recombination in eukaryotes

A model for effective pairing and recombination at meiosis based on early replicating sites (R-bands) along chromosomes

A model for meiotic pairing is proposed in which early replicating sites (R-band equivalent) along chromosomes are envisaged as sites for synaptic initiation. Only within such sites will "effective" pairing for recombination be established. Pairing in later replicating (G- and C-band equivalent) regions will be "ineffective" and will not provide for the stringent requirements of the crossover process. Exchange events might be predetermined at S-phase, and possibly at junctions between early and later replicating sequences, these being seen as vulnerable sites for breakage. Temporal shifts in replication from early to late S, are postulated to produce localized pairing disruption and lowering of crossover values as regions of chromatin shift from being effectively to ineffectively paired.

DNA polymerases, deoxyribonucleases, and recombination during meiosis in Saccharomyces cerevisiae

We utilized strains of Saccharomyces cerevisiae that exhibit high efficiency of synchrony of meiosis to examine several aspects of meiosis including sporulation, recombination, DNA synthesis, DNA polymerase I and II, and Mg2+-dependent alkaline DNases. The kinetics of commitment to intragenic recombination and sporulation are similar. The synthesis of DNA, as measured directly with diphenylamine, appears to precede the commitment to recombination. Both DNA polymerase I and II activities and total DNA-synthesizing activity in crude extracts increase two- to threefold before the beginning of meiotic DNA synthesis. Increases of 10- to 20-fold over mitotic levels are found for Mg2+-dependent alkaline DNase activity in crude extracts before and during the commitment to meiotic intragenic recombination. Of particular interest is the comparable increase in a nuclease under the control of the RAD52 gene; this enzyme has been identified by the use of antibody raised against a similar enzyme from Neurospora crassa. Since the RAD52 gene is essential for meiotic recombination, the nuclease is implicated in the high levels of recombination observed during meiosis. The effects observed in this report are meiosis specific since they are not observed in an alpha alpha strain.

DNA polymerases, deoxyribonucleases, and recombination during meiosis in Saccharomyces cerevisiae

We utilized strains of Saccharomyces cerevisiae that exhibit high efficiency of synchrony of meiosis to examine several aspects of meiosis including sporulation, recombination, DNA synthesis, DNA polymerase I and II, and Mg2+-dependent alkaline DNases. The kinetics of commitment to intragenic recombination and sporulation are similar. The synthesis of DNA, as measured directly with diphenylamine, appears to precede the commitment to recombination. Both DNA polymerase I and II activities and total DNA-synthesizing activity in crude extracts increase two- to threefold before the beginning of meiotic DNA synthesis. Increases of 10- to 20-fold over mitotic levels are found for Mg2+-dependent alkaline DNase activity in crude extracts before and during the commitment to meiotic intragenic recombination. Of particular interest is the comparable increase in a nuclease under the control of the RAD52 gene; this enzyme has been identified by the use of antibody raised against a similar enzyme from Neurospora crassa. Since the RAD52 gene is essential for meiotic recombination, the nuclease is implicated in the high levels of recombination observed during meiosis. The effects observed in this report are meiosis specific since they are not observed in an alpha alpha strain.

Aberrant segregation patterns and gene mappability inAscobolus immersus

Crosses between various types of mutant giving specific patterns of aberrant segregation were performed in theb2spore colour locus ofAscobolus immersus. The map of 41 mutations showing various patterns of aberrant segregation was established. The frequency of wild-type recombinants and the map additivity, map expansion and map contraction characteristics were shown to be strongly dependent upon the pattern of aberrant segregation of the mutations used. Mutations giving no postmeiotic segregation and an excess of conversion to wild type over conversion to mutant exhibit map expansion in small intervals and a strong map contraction in large intervals. Mutations giving postmeiotic segregations also exhibit map contraction in large intervals. Mutations giving no postmeiotic segregations and an excess of conversion to mutant over conversion to wild type show map additivity and thus provide a simple way for devising gene maps. The relationship between the mapping properties and the pattern of aberrant segregations is accounted for when considering parameters of gene conversion: frequency and distribution of hybrid DNA, frequency and direction of mismatch correction.

Meiosis in Schizophyllum commune: The effect of hydroxyurea on the frequency of recombination and mutations

The effect of exposure of nuclei at different stages of meiosis to hydroxyurea (HU) was tested by examination of its effect on the frequency of auxotrophic mutations and on intergenic recombination. The results indicate that recombination is increased most significantly if the nuclei are exposed to the drug during the premeiotic-S phase and to a lesser extent if exposed during prophase. Similarly, nuclei exposed to HU during premeiotic-S phase and prophase mutate at a frequency 10 to 50 times higher than untreated meiotic nuclei. The degree of response of the mutagenic events and recombination events is not similar and it is suggested that the mutagenic events occur at stages prior to recombination. The temporal relations of the two events in response to HU suggest that the mutagenic events precede recombination and the results obtained with HU only amplify the mutagenic events that normally occur in meiotic nuclei and are related to the meiotic effect.