Whole‐landscape modelling of compositional turnover in aquatic invertebrates informs conservation gap analysis: An example from south‐western Australia

Pennifold, Melita G.; Williams, Kristen J.; Pinder, Adrian; Harwood, Thomas D.; Manion, Glenn; Ferrier, Simon

doi:10.1111/fwb.12949

Cited by 11 publications

(6 citation statements)

References 95 publications

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“…Recent predictions of warming of up to 3–4°C by 2090 (IPCC, 2014) mean that these trends will continue to accelerate until at least the end of the century. Few invertebrates appear on conservation listings in SWA (a common problem worldwide; Chichorro et al, 2019); however, recently some SWA stream fauna have been identified as candidates for conservation listing (Pennifold, 2018; Pennifold et al, 2017). But we contend that the numbers of SWA stream‐dwelling species under threat of range contraction and eventual extinction due to climate drying will be far greater than identified under current predictions because many, perhaps most, common species will be affected.…”

Section: Discussionmentioning

confidence: 99%

Life‐history traits are poor predictors of species responses to flow regime change in headwater streams

Carey

Chester

Robson

2021

Global Change Biology

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Recent climate change is altering the timing, duration and volume of river and stream flows globally, and in many regions, perennially flowing rivers and streams are drying and switching to intermittent flows. Profound impacts on aquatic biota are becoming apparent, due in part to the strong influence of flow regime on the evolution of life history. We made predictions of life‐history responses for 13 common aquatic invertebrate species (four caddisflies, five mayflies, two stoneflies, a dragonfly and an amphipod), to recent flow regime change in Australian mediterranean climate streams, based on historic studies in the same streams. Size distributions, phenology, voltinism and synchrony were compared, revealing five main responses. More than half of the species were restricted to perennially flowing streams and were absent from those that had switched to intermittent flows (including all four caddisfly species). These formerly common species are at risk of extinction as climate change progresses. Two mayfly species had divergent responses in voltinism and synchrony, and one relied on drought micro‐refuges to persist. One stonefly species changed development timing to suit the new flow regime, and the amphipod species retreated to subterranean refuges. Two formerly common species were not detected at all during 2016–2017. In addition, a new mayfly species and a caddisfly species proliferated under new flow regimes, because they had life histories suited to brief hydroperiods. Importantly, previous life history rarely predicted species’ actual responses to climate‐driven flow regime change, raising doubts about the veracity of predictions based on species traits. This is because a species’ potential for flexible phenology or growth rate is not necessarily indicated by life‐history traits.

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Section: Discussionmentioning

confidence: 99%

Life‐history traits are poor predictors of species responses to flow regime change in headwater streams

Carey

Chester

Robson

2021

Global Change Biology

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“…For example, finite budgets mean that the acquisition of incompletely surveyed land parcels to complement reserve systems must be prioritised. Indeed, much of the literature concerning spatial representation deals with conservation planning (Arponen et al., 2008; Ferrier, 2002; Pennifold et al., 2017; Williams et al., 2006), and, in particular, reserve selection (Araújo et al., 2001; Engelbrecht et al., 2016; Faith & Walker, 1996).…”

Section: Introductionmentioning

confidence: 99%

Using generalised dissimilarity modelling and targeted field surveys to gap‐fill an ecosystem surveillance network

Guerin

Williams

Leitch

et al. 2020

Journal of Applied Ecology

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Effective ecosystem management requires spatially distributed measurements that are representative of ecological diversity. When considering which sites complement existing conservation or monitoring networks, there are many strategies for optimising ecological coverage in the absence of ground observations. However, such optimisation is often implemented theoretically in conservation prioritisation frameworks and real‐world implementation is rarely assessed, particularly for monitoring networks. We assessed the performance of adding new survey sites informed by predictive modelling in gap‐filling the ecological coverage of the Terrestrial Ecosystem Research Network's (TERN) continental network of ecosystem surveillance plots, Ausplots. We constructed a generalised dissimilarity model (GDM) in which plant species composition in 531 sites was fitted to environmental parameters. We combined predicted nearest‐neighbour ecological distances for locations across Australia with practical considerations to select regions for gap‐filling surveys of 181 new plots across 18 expeditions. We iteratively tracked the reduction in mean nearest‐neighbour distances in GDM space, and increases in the actual sampling of ecological space, using cumulative multivariate dispersion. The generalised dissimilarity model explained 34% of deviance in species compositional turnover as a function of geographic distance, soil P, aridity, actual evapotranspiration and rainfall seasonality, among 17 significant predictors. We targeted identified gap regions in the Australian jurisdictions of Queensland, New South Wales and Western Australia for surveys in addition to opportunistic or project‐based gap‐filling over 2 years. Approximately 20% of the land area of Australia received increased servicing of biological representation, corresponding to a reduction in mean nearest‐neighbour ecological distances from 0.38 to 0.33 in units of compositional dissimilarity. The corresponding increase in sampled ecological space was 172% more than that achieved from the previous 181 plots. Synthesis and applications. Increases in the representation of ecosystems included in surveillance networks can be achieved efficiently using objective methods for site selection and appraisal. Scaling of environmental variables through ecological models supports practical sampling decisions, while optimising putative survey locations via their ecological distance to a nearest neighbour is useful when the aim is to increase inclusion of habitats. Iterations between modelled gaps and field campaigns provide a pragmatic compromise between theoretical optima and real‐world decision‐making.

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“…Output of the GDM model was used to predict compositional turnover across South Africa. The proportional representation of ecological environment (scaled using spider data) in conservation areas and the sample coverage of these environments by the database were quantified as a continuous fraction of the entirety of South Africa (Pennifold et al 2017). Lesotho and Swaziland were excluded from this analysis as layers for conserved areas in these countries were not available.…”

Section: Methodsmentioning

confidence: 99%

The South African National Red List of spiders: patterns, threats, and conservation

Foord

Dippenaar-Schoeman

Haddad

et al. 2020

The Journal of Arachnology

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Triage in conservation biology necessitates the prioritization of species and ecosystems for conservation. Although highly diverse, ecologically important, and charismatic, spiders are rarely considered. With 2,253 known species, South Africa's spider diversity is among the highest in the world. A 22-year initiative culminating in a national assessment of all the South African species saw a 33% increase in described species and a 350% rise in specimen accessions of the national collection annually. Endemism is high, at 60% of all South African species. Levels of endemicity are particularly high in Fynbos, Succulent Karroo and Forests. Relative to its area, Forests have three times more endemics than any of the other biomes, followed by the Indian Ocean Coastal Belt. A total of 127 species (5.7%) are either rare or endangered. Threats to these species are largely linked to habitat destruction in the form of urbanization and agriculture. The bulk (62.8%) of taxa are of least concern, but many species are data deficient (27%). Predicted large-scale diversity patterns are confounded by the localised nature of distribution records. Best estimates of compositional turnover point to an east-west bias in our understanding and conservation of spiders in the country, a bias that is most acute in the north-western parts of the country because this region has seen less collecting and has fewer conservation estates. In general, rare and threatened species are mainly ground-dwelling taxa that are either relictual or have poor dispersal abilities. Complemented with longterm surveys that will provide insights into population dynamics of spiders, exploring the use of species traits in predicting extinction probability could provide additional criteria for conservation prioritization. Based on these assessments, targeted species-level interventions might provide a platform for more public awareness and institutional involvement.

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Whole‐landscape modelling of compositional turnover in aquatic invertebrates informs conservation gap analysis: An example from south‐western Australia

Cited by 11 publications

References 95 publications

Life‐history traits are poor predictors of species responses to flow regime change in headwater streams

Life‐history traits are poor predictors of species responses to flow regime change in headwater streams

Using generalised dissimilarity modelling and targeted field surveys to gap‐fill an ecosystem surveillance network

The South African National Red List of spiders: patterns, threats, and conservation

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