The properties of meiotic gene conversion important in its effects on evolution

Lamb, Bernard Charles

doi:10.1038/hdy.1984.68

Cited by 51 publications

(43 citation statements)

References 42 publications

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“…Two other models predict that variations in GC content are due to bias in fixation of AT toward GC mutations because of selection for GC (Bernardi and Bernardi 1986;Charlesworth 1994;Eyre-Walker 1999;Bernardi 2000) or a neutral process called GC-biased gene conversion (GC-BGC) (for review see Eyre-Walker 1993;Galtier et al 2001;Smith et al, 2002;Webster et al, 2003;Galtier 2003;Marais 2003). In meiotic recombination, parental chromosomes form heteroduplexes (DNA with one strand from the male and one strand from the female) in which there can be AT/GC heteromismatches (Lamb 1984). If subjected to the effect of GC-BGC, these mismatches are preferentially repaired in GC in mammalian genomes (Brown and Jiricny 1998;Bill et al 1998;Kudla et al 2004).…”

Section: Introductionmentioning

confidence: 99%

GC Content Evolution of the Human and Mouse Genomes: Insights from the Study of Processed Pseudogenes in Regions of Different Recombination Rates

et al. 2006

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Abstract. Processed pseudogenes are generated by reverse transcription of a functional gene. They are generally nonfunctional after their insertion and, as a consequence, are no longer subjected to the selective constraints associated with functional genes. Because of this property they can be used as neutral markers in molecular evolution. In this work, we investigated the relationship between the evolution of GC content in recently inserted processed pseudogenes and the local recombination pattern in two mammalian genomes (human and mouse). We confirmed, using original markers, that recombination drives GC content in the human genome and we demonstrated that this is also true for the mouse genome despite lower recombination rates. Finally, we discussed the consequences on isochores evolution and the contrast between the human and the mouse pattern.

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Section: Introductionmentioning

confidence: 99%

GC Content Evolution of the Human and Mouse Genomes: Insights from the Study of Processed Pseudogenes in Regions of Different Recombination Rates

et al. 2006

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“…Lamb (1984Lamb ( , 1986 having analysed several sets of data, concluded that significant disparity is not uncommon in yeast for base substitutions or for large deletions, and that the amount of disparity in yeast was very similar to that in Ascobolus and Sordaria when comparable types of mutations were studied. Some of the yeast data of Fogel et al (1979) underestimate the disparity which would be found in + x m crosses as the data for arg4 mutations came wholly or largely from heteroallelic crosses, sometimes from pooled data from heteroallelic crosses of reversed phase (e.g., arg4 16, +/ +, 17 and 16, 17/ + ,+) where co-correction could greatly reduce observed disparities.…”

Section: General Conversion Propertiesmentioning

confidence: 99%

“…Criteria 6 and 7, table 1, relate to the presence of parity or disparity in conversion direction, with very frequent and often extreme disparity in Ascobolus and Sordaria (details given by Lamb, 1984Lamb, , 1986. Szostak et a!.…”

Section: General Conversion Propertiesmentioning

confidence: 99%

Tests of double-strand gap repair as a major source of meiotic gene conversion in fungi

Lamb

1987

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In current recombination theory, meiotic gene conversions may arise from hybrid-DNA (hDNA), often with correction of mispaired or unpaired bases, or from repair of double-strand gaps. The two types of model have quite different predictions for:-the occurrence and proportions of different classes of aberrant segregations; relationships between conversion properties and the molecular origin of a mutation; the extent of disparity in conversion direction; and whether a heterozygous mutation can affect the conversion properties of other nearby heterozygous mutations. These criteria are used to study the origin of meiotic gene conversions in the fungi Ascobolus, Sordaria and Saccharomyces. Novel tests are described, one based on comparisons of observed conversion frequencies for very close sites within a locus, and one based on possible correlations of 6:2/2:6 disparity with the proportion of aberrant segregations having postmeiotic segregation. From Ascobolus, Sordaria and yeast, most data are consistent with most or all meiotic conversions coming from hDNA; they are not consistent with all or most conversions arising directly from doublestrand gap repair. Differences in frequencies of postmeiotic segregation between fungi with four-spored asci and ones with eight-spored asci may reflect a shorter period for hDNA correction in the latter type.

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“…In a heteroallelic cross, conversions at any site are usually a mixture of conversions involving only that site, with its own conversion properties, and of co-conversions in which correction could be triggered by the other nearby heterozygous site, possibly reducing overall disparity for that site: in Table 2, arg4-16 in a monohybrid cross had ǹ40% 6:2/2:6 disparity, but this was reduced in heteroallelic crosses with either or both arg4-17 and arg4-19 to ǹ12, ǹ17 or ǹ25%. Data from filamentous fungi were nearly all from monohybrid crosses (Lamb, 1984).…”

Section: Monohybrid or Dihybrid (Heteroallelic) Crosses Coupling Or mentioning

confidence: 99%

“…The earlier yeast data were analysed for c, d and y by Lamb (1984Lamb ( , 1985Lamb ( , 1986, so only newer data are covered in Table 6, using only cases with 20 or more conversion asci. Conversion frequencies were high, with c of 0.156-0.548, for bik1 and the nearby his4, and for MAT, but lower for ARG4 RV with different homozygous deletions, 0.036-0.091.…”

Section: Conversion As a Force Changing Allele Frequenciesmentioning

confidence: 99%

Gene conversion disparity in yeast:its extent, multiple origins, and effects onallele frequencies

Lamb

1998

Heredity

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The properties of meiotic gene conversion important in its effects on evolution

Cited by 51 publications

References 42 publications

GC Content Evolution of the Human and Mouse Genomes: Insights from the Study of Processed Pseudogenes in Regions of Different Recombination Rates

GC Content Evolution of the Human and Mouse Genomes: Insights from the Study of Processed Pseudogenes in Regions of Different Recombination Rates

Tests of double-strand gap repair as a major source of meiotic gene conversion in fungi

Gene conversion disparity in yeast:its extent, multiple origins, and effects onallele frequencies

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