Reproduction at the Extremes: Pseudovivipary, Hybridization and Genetic Mosaicism in Posidonia Australis (Posidoniaceae)

Overview

Journal Ann Bot

Publisher Oxford University Press

Specialty Biology

Date 2015 Nov 19

PMID 26578720

Citations 8

Authors

Elizabeth A Sinclair

John Statton

Renae Hovey

Janet M Anthony

Kingsley W Dixon

Gary A Kendrick

Affiliations

Soon will be listed here.

Abstract

Background And Aims: Organisms occupying the edges of natural geographical ranges usually survive at the extreme limits of their innate physiological tolerances. Extreme and prolonged fluctuations in environmental conditions, often associated with climate change and exacerbated at species' geographical range edges, are known to trigger alternative responses in reproduction. This study reports the first observations of adventitious inflorescence-derived plantlet formation in the marine angiosperm Posidonia australis, growing at the northern range edge (upper thermal and salinity tolerance) in Shark Bay, Western Australia. These novel plantlets are described and a combination of microsatellite DNA markers and flow cytometry is used to determine their origin.

Methods: Polymorphic microsatellite DNA markers were used to generate multilocus genotypes to determine the origin of the adventitious inflorescence-derived plantlets. Ploidy and genome size were estimated using flow cytometry.

Key Results: All adventitious plantlets were genetically identical to the maternal plant and were therefore the product of a novel pseudoviviparous reproductive event. It was found that 87 % of the multilocus genotypes contained three alleles in at least one locus. Ploidy was identical in all sampled plants. The genome size (2 C value) for samples from Shark Bay and from a separate site much further south was not significantly different, implying they are the same ploidy level and ruling out a complete genome duplication (polyploidy).

Conclusions: Survival at range edges often sees the development of novel responses in the struggle for survival and reproduction. This study documents a physiological response at the trailing edge, whereby reproductive strategy can adapt to fluctuating conditions and suggests that the lower-than-usual water temperature triggered unfertilized inflorescences to 'switch' to growing plantlets that were adventitious clones of their maternal parent. This may have important long-term implications as both genetic and ecological constraints may limit the ability to adapt or range-shift; this seagrass meadow in Shark Bay already has low genetic diversity, no sexual reproduction and no seedling recruitment.

Citing Articles

The cycle of seagrass life: From flowers to new meadows.

Kendrick G, Cambridge M, Orth R, Fraser M, Hovey R, Statton J Ecol Evol. 2023; 13(9):e10456.

PMID: 37664509 PMC: 10469021. DOI: 10.1002/ece3.10456.

Concluding Embryogenesis After Diaspora: Seed Germination in Illicium Parviflorum.

Losada J Integr Comp Biol. 2023; 63(6):1352-1363.

PMID: 37349968 PMC: 10755177. DOI: 10.1093/icb/icad078.

Extensive polyploid clonality was a successful strategy for seagrass to expand into a newly submerged environment.

Edgeloe J, Severn-Ellis A, Bayer P, Mehravi S, Breed M, Krauss S Proc Biol Sci. 2022; 289(1976):20220538.

PMID: 35642363 PMC: 9156900. DOI: 10.1098/rspb.2022.0538.

Variation in reproductive effort, genetic diversity and mating systems across seagrass meadows in Western Australia.

Sinclair E, Edgeloe J, Anthony J, Statton J, Breed M, Kendrick G AoB Plants. 2020; 12(4):plaa038.

PMID: 32904346 PMC: 7454027. DOI: 10.1093/aobpla/plaa038.

A novel adaptation facilitates seed establishment under marine turbulent flows.

Kendrick G, Pomeroy A, Orth R, Cambridge M, Shaw J, Kotula L Sci Rep. 2019; 9(1):19693.

PMID: 31873181 PMC: 6928165. DOI: 10.1038/s41598-019-56202-7.

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