Differentiation of haploid and diploid fertilities in Gracilaria chilensis affect ploidy ratio

dc.contributor.authorHuanel, Oscar R.
dc.contributor.authorVieira, Vasco M. N. C. S.
dc.contributor.authorEngelen, Aschwin H.
dc.contributor.authorGuillemin, Marie-Laure.
dc.date.accessioned2019-10-17T15:41:41Z
dc.date.available2019-10-17T15:41:41Z
dc.date.issued2018
dc.date.updated2019-10-14T18:30:32Z
dc.description.abstractAbstract Background Algal isomorphic biphasic life cycles alternate between free-living diploid (tetrasporophytes) and haploid (dioicious gametophytes) phases and the hypotheses explaining their maintenance are still debated. Classic models state that conditional differentiation between phases is required for the evolutionary stability of biphasic life cycles while other authors proposed that the uneven ploidy abundances observed in the field are explained by their cytological differences in spore production. Results We monitored the state and fate of individuals of the red seaweed Gracilaria chilensis periodically for 3 years in five intertidal pools from two sites with distinct conditions. We tested for differentiation in fecundity and spore survival among the gametophyte males and females (haploids) and the tetrasporophytes (diploids). We tested for the influence of fecundity and spore survival on the observed uneven ploidy abundances in recruits. The probability of a frond becoming fecund was size-dependent, highest for the haploid males and lowest for the haploid females, with the diploids displaying intermediate probabilities. Fecund diploids released more tetraspores than carpospores released by the haploid females. Spore survival depended on ploidy and on the local density of co-habiting adult fronds. An advantage of diploid over haploid germlings was observed at very low and very high adult fronds densities. Conclusions Neither spore production nor spore survival determined the highly variable ploidy ratio within G. chilensis recruits. This result invalidates the hypothesis of natural cytological differences in spore production as the only driver of uneven field ploidy abundances in this species. Diploid spores (carpospores) survived better than haploid spores (tetraspores), especially in locations and time periods that were associated with the occurrence of strong biotic and abiotic stressors. We hypothesise that carpospore survival is higher due to support by their haploid female progenitors passing-on nutrients and chemical compounds improving survival under stressful conditions.Abstract Background Algal isomorphic biphasic life cycles alternate between free-living diploid (tetrasporophytes) and haploid (dioicious gametophytes) phases and the hypotheses explaining their maintenance are still debated. Classic models state that conditional differentiation between phases is required for the evolutionary stability of biphasic life cycles while other authors proposed that the uneven ploidy abundances observed in the field are explained by their cytological differences in spore production. Results We monitored the state and fate of individuals of the red seaweed Gracilaria chilensis periodically for 3 years in five intertidal pools from two sites with distinct conditions. We tested for differentiation in fecundity and spore survival among the gametophyte males and females (haploids) and the tetrasporophytes (diploids). We tested for the influence of fecundity and spore survival on the observed uneven ploidy abundances in recruits. The probability of a frond becoming fecund was size-dependent, highest for the haploid males and lowest for the haploid females, with the diploids displaying intermediate probabilities. Fecund diploids released more tetraspores than carpospores released by the haploid females. Spore survival depended on ploidy and on the local density of co-habiting adult fronds. An advantage of diploid over haploid germlings was observed at very low and very high adult fronds densities. Conclusions Neither spore production nor spore survival determined the highly variable ploidy ratio within G. chilensis recruits. This result invalidates the hypothesis of natural cytological differences in spore production as the only driver of uneven field ploidy abundances in this species. Diploid spores (carpospores) survived better than haploid spores (tetraspores), especially in locations and time periods that were associated with the occurrence of strong biotic and abiotic stressors. We hypothesise that carpospore survival is higher due to support by their haploid female progenitors passing-on nutrients and chemical compounds improving survival under stressful conditions.
dc.fuente.origenBiomed Central
dc.identifier.citationBMC Evolutionary Biology. 2018 Dec 05;18(1):183
dc.identifier.doi10.1186/s12862-018-1287-x
dc.identifier.urihttps://repositorio.uc.cl/handle/11534/26785
dc.issue.numeroNo. 183
dc.language.isoen
dc.nota.accesoContenido completo
dc.pagina.final11
dc.pagina.inicio1
dc.revistaBMC Evolutionary Biologyes_ES
dc.rightsacceso abierto
dc.rights.holderThe Author(s).
dc.subject.ddc570
dc.subject.deweyBiologíaes_ES
dc.subject.otherPlantas - evoluciones_ES
dc.subject.otherAlgas rojas -Reproducciónes_ES
dc.subject.otherCromosomas - Análisises_ES
dc.titleDifferentiation of haploid and diploid fertilities in Gracilaria chilensis affect ploidy ratioes_ES
dc.typeartículo
dc.volumenVol. 18
sipa.codpersvinculados1050531
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