Expansion of the Rare Eucalyptus Risdonii Under Climate Change Through Hybridization with a Closely Related Species Despite Hybrid Inferiority

Overview

Journal Ann Bot

Publisher Oxford University Press

Specialty Biology

Date 2021 Aug 5

PMID 34351372

Citations 4

Authors

T R Pfeilsticker

R C Jones

D A Steane

P A Harrison

R E Vaillancourt

B M Potts

Affiliations

Soon will be listed here.

Abstract

Background And Aims: Hybridization is increasingly recognized as an integral part of the dynamics of species range expansion and contraction. Thus, it is important to understand the reproductive barriers between co-occurring species. Extending previous studies that argued that the rare Eucalyptus risdonii was expanding into the range of the surrounding E. amygdalina by both seed and pollen dispersal, we here investigate the long-term fitness of both species and their hybrids and whether expansion is continuing.

Methods: We assessed the survival of phenotypes representing a continuum between the two pure species in a natural hybrid swarm after 29 years, along with seedling recruitment. The performance of pure species as well as of artificial and natural hybrids was also assessed over 28 years in a common garden trial.

Key Results: In the hybrid zone, E. amygdalina adults showed greater mortality than E. risdonii, and the current seedling cohort is still dominated by E. risdonii phenotypes. Morphologically intermediate individuals appeared to be the least fit. Similar results were observed after growing artificial first-generation and natural hybrids alongside pure species families in a common garden trial. Here, the survival, reproduction, health and growth of the intermediate hybrids were significantly less than those of either pure species, consistent with hybrid inferiority, although this did not manifest until later reproductive ages. Among the variable progeny of natural intermediate hybrids, the most E. risdonii-like phenotypes were the most fit.

Conclusions: This study contributes to the increasing number of reports of hybrid inferiority in Eucalyptus, suggesting that post-zygotic barriers contribute to the maintenance of species integrity even between closely related species. However, with fitness rapidly recovered following backcrossing, it is argued that hybridization can still be an important evolutionary process, in the present case appearing to contribute to the range expansion of the rare E. risdonii in response to climate change.

Citing Articles

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Distinct hybridization modes in wide- and narrow-ranged lineages of Causonis (Vitaceae).

Yu J, Zhao H, Niu Y, You Y, Barrett R, Ranaivoson R BMC Biol. 2023; 21(1):209.

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Long-term research reveals potential role of hybrids in climate-change adaptation. A commentary on 'Expansion of the rare Eucalyptus risdonii under climate change through hybridisation with a closely related species despite hybrid inferiority'.

Bush D Ann Bot. 2021; 129(1):i-iii.

PMID: 34289013 PMC: 8829906. DOI: 10.1093/aob/mcab085.

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