A Low-altitude Mountain Range As an Important Refugium for Two Narrow Endemics in the Southwest Australian Floristic Region Biodiversity Hotspot

Overview

Journal Ann Bot

Publisher Oxford University Press

Specialty Biology

Date 2016 Sep 17

PMID 27634576

Citations 10

Authors

Gunnar Keppel

Todd P Robinson

Grant W Wardell-Johnson

Colin J Yates

Kimberly P Van Niel

Margaret Byrne

Antonius G T Schut

Affiliations

Soon will be listed here.

Abstract

Background And Aims: Low-altitude mountains constitute important centres of diversity in landscapes with little topographic variation, such as the Southwest Australian Floristic Region (SWAFR). They also provide unique climatic and edaphic conditions that may allow them to function as refugia. We investigate whether the Porongurups (altitude 655 m) in the SWAFR will provide a refugium for the endemic Ornduffia calthifolia and O. marchantii under forecast climate change.

Methods: We used species distribution modelling based on WorldClim climatic data, 30-m elevation data and a 2-m-resolution LiDAR-derived digital elevation model (DEM) to predict current and future distributions of the Ornduffia species at local and regional scales based on 605 field-based abundance estimates. Future distributions were forecast using RCP2.6 and RCP4.5 projections. To determine whether local edaphic and biotic factors impact these forecasts, we tested whether soil depth and vegetation height were significant predictors of abundance using generalized additive models (GAMs).

Key Results: Species distribution modelling revealed the importance of elevation and topographic variables at the local scale for determining distributions of both species, which also preferred shadier locations and higher slopes. However, O. calthifolia occurred at higher (cooler) elevations with rugged, concave topography, while O. marchantii occurred in disturbed sites at lower locations with less rugged, convex topography. Under future climates both species are likely to severely contract under the milder RCP2.6 projection (approx. 2 °C of global warming), but are unlikely to persist if warming is more severe (RCP4.5). GAMs showed that soil depth and vegetation height are important predictors of O. calthifolia and O. marchantii distributions, respectively.

Conclusions: The Porongurups constitute an important refugium for O. calthifolia and O. marchantii, but limits to this capacity may be reached if global warming exceeds 2 °C. This capacity is moderated at local scales by biotic and edaphic factors.

Citing Articles

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Response of distribution patterns of two closely related species in genus to climate change since last inter-glacial.

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High species diversity and turnover in granite inselberg floras highlight the need for a conservation strategy protecting many outcrops.

Yates C, Robinson T, Wardell-Johnson G, Keppel G, Hopper S, Schut A Ecol Evol. 2019; 9(13):7660-7675.

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