Gametophytic apomixis: elements and genetic regulation

Asker, Sven

doi:10.1111/j.1601-5223.1980.tb01367.x

Cited by 71 publications

(26 citation statements)

References 59 publications

(16 reference statements)

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“…The production of healthy seeds (germination rates did not decrease with Δ p : Appendix ) derived from cross‐fertilization suggests that apomicts potentially usurp progeny of sexuals. Cross‐fertilization may lead to the reproductive transformation of sexuals by apomicts as apomixis is known to be transmitted by pollen (Asker, ; Grimanelli, Leblanc, Perotti, & Grossniklaus, ; Ozias‐Akins & Van Dijk, ). In case that such intercytotype offspring is vital and fertile, reproductive (and cytological) transformation can speed up replacement of sexuals by apomicts, although the actual outcome of competition among reproductive modes depends on a series of factors as rates of penetrance of apomixis, the male and female fitness of cytotypes, pollen and seed dispersal abilities, existence of crossing barriers, or starting frequencies of cytotypes in the population (Britton & Mogie, ; Joshi & Moddy, ; Mogie, ), conditions which need to be established simultaneously for a concrete situation.…”

Section: Discussionmentioning

confidence: 99%

Asymmetric reproductive interference: The consequences of cross‐pollination on reproductive success in sexual–apomictic populations of Potentilla puberula (Rosaceae)

Dobeš

Scheffknecht

Fenko

et al. 2017

Ecology and Evolution

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Apomixis evolves from a sexual background and usually is linked to polyploidization. Pseudogamous gametophytic apomicts, which require a fertilization to initiate seed development, of various ploidy levels frequently co‐occur with their lower‐ploid sexual ancestors, but the stability of such mixed populations is affected by reproductive interferences mediated by cross‐pollination. Thereby, reproductive success of crosses depends on the difference in ploidy levels of mating partners, that is, on tolerance of deviation from the balanced ratio of maternal versus paternal genomes. Quality of pollen can further affect reproductive success in intercytotype pollinations. Cross‐fertilization, however, can be avoided by selfing which may be induced upon pollination with mixtures of self‐ and cross‐pollen (i.e., mentor effects). We tested for reproductive compatibility of naturally co‐occurring tetraploid sexuals and penta‐ to octoploid apomicts in the rosaceous species Potentilla puberula by means of controlled crosses. We estimated the role of selfing as a crossing barrier and effects of self‐ and cross‐pollen quality as well as maternal: paternal genomic ratios in the endosperm on reproductive success. Cross‐fertilization of sexuals by apomicts was not blocked by selfing, and seed set was reduced in hetero‐ compared to homoploid crosses. Thereby, seed set was negatively related to deviations from balanced parental genomic ratios in the endosperm. In contrast, seed set in the apomictic cytotypes was not reduced in hetero‐ compared to homoploid crosses. Thus, apomictic cytotypes either avoided intercytotype cross‐fertilization through selfing, tolerated intercytotype cross‐fertilizations without negative effects on reproductive success, or even benefitted from higher pollen quality in intercytotype pollinations. Our experiment provides evidence for asymmetric reproductive interference, in favor of the apomicts, with significantly reduced seed set of sexuals in cytologically mixed populations, whereas seed set in apomicts was not affected. Incompleteness of crossing barriers further indicated at least partial losses of a parental genomic endosperm balance requirement.

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Section: Discussionmentioning

confidence: 99%

Asymmetric reproductive interference: The consequences of cross‐pollination on reproductive success in sexual–apomictic populations of Potentilla puberula (Rosaceae)

Dobeš

Scheffknecht

Fenko

et al. 2017

Ecology and Evolution

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“…This is best illustrated in the Rosaceae, where apospory and diplospory have been described in the same individuals (Muniyamma and Phipps 1984a). This intriguing observation may arise from the difficulty of distinguishing somatic and generative cells in the multicellular female archesporium (the part of the nucellus that gives rise to the megaspore mother cell) of many Rosaceae (Asker 1980). However, there are several species in which both diplospory and apospory occur, leading some workers to speculate that these two modes of megagametophyte formation share a common genetic basis (Mogie 1992).…”

Section: Aposporymentioning

confidence: 94%

“…A puzzle about the genetics of apomixis raised by Asker (1980) and others is the requirement for nearly simultaneous transitions in the formation of megagametophytes and in embryo development. The chance that two mutations causing these two shifts would occur soon after each other within a small nascent apomictic population seems prohibitive; yet, without the simultaneous emergence of the two traits, apomixis seems unlikely.…”

Section: Taxonomic Occurrence Of Apomixismentioning

confidence: 99%

The Dynamic Nature of Apomixis in the Angiosperms

Whitton¹,

Sears²,

Baack³

et al. 2008

International Journal of Plant Sciences

184

169

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Apomixis, the asexual production of seed, is a trait estimated to occur in fewer than 1% of flowering plant species, with an uneven distribution among lineages. In the past decade, targeted research efforts have aimed at clarifying the genetic basis of apomixis, with the goal of engineering or breeding apomictic crops. Recent work suggests a simple genetic basis for apomixis, but it also indicates that natural populations of apomicts are much more complex than is often assumed. For example, in nature, nearly all apomicts that go through a megagametophyte stage (gametophytic apomicts) are polyploid, while their sexual relatives are typically diploid. Although populations have been characterized as obligately sexual or apomictic, it is increasingly clear that many plant populations exhibit some variation in reproductive mode. Many apomicts retain residual sexual function as pollen donors and thus have the potential to spread apomixis via male gametes, thereby increasing the genetic diversity observed within apomictic populations. Here, we summarize our current understanding of the genetic basis and transmission of apomixis. We use insights from previous case studies and models for the spread of asexuality to explore the potential for establishment and spread of apomixis in nature.

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“…Apomixis is mostly facultative, with both sexual and apomictic processes occurring within the same flower and the progeny containing a variable proportion of apomicts and sexual plants (Asker 1980).…”

Section: Introductionmentioning

confidence: 99%

No evidence of apomixis in matroclinal progeny from experimental crosses in the genus Fragaria (strawberry) based on RAPDs

2009

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Crossing experiments in Fragaria have frequently resulted in some matroclinal progeny. These have been attributed to either accidental selfing and/or pollen contamination, or apomixis. In this study 202 carefully controlled intra and interspecific crosses in Fragaria were made. No progeny were produced from 164 interploid crosses made between diploids, hexaploids and octoploids but 38 intraploid crosses resulted in 904 F 1 plants, of which 42 (4.6%) were found to be morphologically matroclinal. All matroclinal progeny subsequently studied by RAPDs were found to be hybrids and not apomicts. The absence of apomixis among matroclinal progeny in this study casts doubt on previous reports of apomixis in Fragaria. Our results showed that the complete morphological similarity of progeny to the seed parent, even in recessive characteristics, cannot therefore be taken as evidence of apomixis, and may rather indicate the heterozygosity of the pollen parent, emphasising the need to use DNA markers for confirmation of apomixis.

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Gametophytic apomixis: elements and genetic regulation

Cited by 71 publications

References 59 publications

Asymmetric reproductive interference: The consequences of cross‐pollination on reproductive success in sexual–apomictic populations of Potentilla puberula (Rosaceae)

Asymmetric reproductive interference: The consequences of cross‐pollination on reproductive success in sexual–apomictic populations of Potentilla puberula (Rosaceae)

The Dynamic Nature of Apomixis in the Angiosperms

No evidence of apomixis in matroclinal progeny from experimental crosses in the genus Fragaria (strawberry) based on RAPDs

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