Correction: Coupling environment and physiology to predict effects of climate change on the taxonomic and functional diversity of fish assemblages in the Murray-Darling Basin, Australia

AbstractHigh-altitude-adapted ectotherms can escape competition from dominant species by tolerating low temperatures at cooler elevations, but climate change is eroding such advantages. Studies evaluating broad-scale impacts of global change for high-altitude organisms often overlook the mitigating role of biotic factors. Yet, at fine spatial-scales, vegetation-associated microclimates provide refuges from climatic extremes. Using one of the largest standardised data sets collected to date, we tested how ant species composition and functional diversity (i.e., the range and value of species traits found within assemblages) respond to large-scale abiotic factors (altitude, aspect), and fine-scale factors (vegetation, soil structure) along an elevational gradient in tropical Africa. Altitude emerged as the principal factor explaining species composition. Analysis of nestedness and turnover components of beta diversity indicated that ant assemblages are specific to each elevation, so species are not filtered out but replaced with new species as elevation increases. Similarity of assemblages over time (assessed using beta decay) did not change significantly at low and mid elevations but declined at the highest elevations. Assemblages also differed between northern and southern mountain aspects, although at highest elevations, composition was restricted to a set of species found on both aspects. Functional diversity was not explained by large scale variables like elevation, but by factors associated with elevation that operate at fine scales (i.e., temperature and habitat structure). Our findings highlight the significance of fine-scale variables in predicting organisms’ responses to changing temperature, offering management possibilities that might dilute climate change impacts, and caution when predicting assemblage responses using climate models, alone.

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Functional diversity in European estuaries: Relating the composition of fish assemblages to the abiotic environment

Estuarine Coastal and Shelf Science ◽

10.1016/j.ecss.2010.04.010 ◽

2010 ◽

Vol 88 (3) ◽

pp. 329-338 ◽

Cited By ~ 53

Author(s):

D. Nicolas ◽

J. Lobry ◽

O. Le Pape ◽

P. Boët

Keyword(s):

Functional Diversity ◽

Fish Assemblages ◽

Abiotic Environment ◽

European Estuaries

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Temporal variation of larval fish assemblages of the Murray Mouth in prolonged drought conditions

Marine and Freshwater Research ◽

10.1071/mf12278 ◽

2013 ◽

Vol 64 (10) ◽

pp. 932 ◽

Cited By ~ 6

Author(s):

L. B. Bucater ◽

J. P. Livore ◽

C. J. Noell ◽

Q. Ye

Keyword(s):

Fish Assemblages ◽

Larval Fish ◽

River System ◽

Sampling Period ◽

Marine Species ◽

Flow Regulation ◽

Nursery Areas ◽

Transition Zones ◽

Murray Darling Basin ◽

Drought Conditions

Estuaries are transition zones that link freshwater and marine ecosystems and are often used as nursery areas by fish. The Murray–Darling Basin, which is heavily affected by flow regulation and water extraction, is the largest river system in Australia and terminates at the Murray Mouth estuary. Protracted drought conditions resulted in extremely low flows to the Murray Mouth that affected water condition, fish abundance, community structure and fish use of the estuary (e.g. nursery areas). The aims of the present study were to examine temporal changes in larval fish assemblages in this estuary. The assemblages were dominated by two gobiid species, Arenigobius bifrenatus and Tasmanogobius lasti. There was a noticeable absence or low abundance of freshwater, diadramous and large-bodied marine species that use this estuary for reproductive functions. Monthly differences in larval fish assemblages, between August–September and October–November, were attributed to increases in the abundances of A. bifrenatus in October and November and oscillation in T. lasti during the entire sampling period. The outcomes of the present study suggested that larval fish assemblages in drought conditions are limited to small-bodied species tolerant of high salinities and that freshwater flows are needed for the estuary to function as a nursery for other species.

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Temporal changes in taxonomic and functional diversity of fish assemblages downstream from mountaintop mining

Freshwater Science ◽

10.1086/676997 ◽

2014 ◽

Vol 33 (3) ◽

pp. 915-926 ◽

Cited By ~ 29

Author(s):

Nathaniel P. Hitt ◽

Douglas B. Chambers

Keyword(s):

Functional Diversity ◽

Fish Assemblages ◽

Temporal Changes ◽

Mountaintop Mining

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Riparian vegetation structure and seasonality influence functional diversity more than taxonomic diversity of stream fish assemblages in the Colombian Amazon

Aquatic Ecology ◽

10.1007/s10452-021-09904-y ◽

2021 ◽

Author(s):

Angélica M. Torres-Bejarano ◽

S. Mažeika Patricio Sulliván ◽

William González-Daza ◽

Carlos Cáceres ◽

Gabriel J. Colorado Z.

Keyword(s):

Functional Diversity ◽

Vegetation Structure ◽

Riparian Vegetation ◽

Fish Assemblages ◽

Taxonomic Diversity ◽

Stream Fish ◽

Influence Functional ◽

Colombian Amazon ◽

Stream Fish Assemblages

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Risks, Uncertainty and Climate Confusion in the Murray–Darling Basin Reforms

Water Economics and Policy ◽

10.1142/s2382624x16500387 ◽

2016 ◽

Vol 03 (03) ◽

pp. 1650038 ◽

Cited By ~ 16

Author(s):

Jason Alexandra

Keyword(s):

Climate Change ◽

Water Policy ◽

Water Governance ◽

Climate Science ◽

Cultural Construction ◽

Policy Integration ◽

Institutional Settings ◽

Murray Darling Basin ◽

Financial Consequences ◽

Key Dimensions

Risks and uncertainties arising from climate change are increasingly recognized as significant challenges for water governance. To support adaptive approaches, critical examinations of water policy practices and rationalities are needed. This paper focuses on the treatment of climate change in Australia’s Murray–Darling Basin (MDB) reforms over the past decade. While the MDB faces potentially significant drying trends due to climate change no reductions in future water availability due to climate change were formalized in the 2012 Basin Plan — a regulatory instrument agreed to by Australia’s National Parliament. The background, key dimensions and possible reasons for this decision are examined. Possible reasons for not formally reducing water deemed available in the future include the complexity and uncertainty of climate science, the cultural construction of “climate normal” based on long-term averages, and institutional settings that reinforce dominant “hydro-logical” approaches and rationalities. Minimizing the political, legal and financial consequences of attributing reductions in water allocations to climate change are also potential reasons. The case of the MDB, as outlined in this paper, demonstrates some of the ways climate change is causing systemic challenges for adaptive water governance, and that innovative approaches need to be embraced, including better processes for institutionalizing science/policy integration.

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Avian Response to Wildfire Severity in a Northern Boreal Region

Forests ◽

10.3390/f11121330 ◽

2020 ◽

Vol 11 (12) ◽

pp. 1330

Author(s):

Michelle Knaggs ◽

Samuel Haché ◽

Scott E. Nielsen ◽

Rhiannon F. Pankratz ◽

Erin Bayne

Keyword(s):

Climate Change ◽

Species Richness ◽

Functional Diversity ◽

Vegetation Type ◽

Fire Severity ◽

Natural Disturbance ◽

Burn Severity ◽

Vegetation Types ◽

Generalist Species ◽

High Severity

Research Highlights: The effects of fire on birds in the most northern parts of the boreal forest are understudied. We found distinct differences in bird communities with increasing fire severity in two vegetation types with naturally different burn severity. The highest severity burns tended to have communities dominated by generalist species, regardless of the original vegetation type. Background and Objectives: Wildfire is the primary natural disturbance in the boreal ecosystems of northwestern Canada. Increased wildfire frequency, extent, and severity are expected with climate change in this region. In particular, the proportion of burns that are high severity and the area of peatlands burned are increasing, and how this influences birds is poorly understood. Materials and Methods: We quantified the effects of burn severity (low, moderate, and high severity) in uplands and peatlands on occupancy, density, richness, community composition, and functional diversity using point counts (n = 1158) from the first two years post-fire for two large fires in the Northwest Territories, Canada. Results: Burn severity had a significant effect on the occupancy and density of 86% of our focal species (n = 20). Responses to burn severity depended on vegetation type for four of the 18 species using occupancy and seven of the 18 using density, but were typically in a similar direction. Species richness and functional diversity were lower in areas of high severity burns than unburned areas and low severity burns in peatlands. Richness was not related to severity in uplands, but functional diversity was. Peatlands had higher species richness than uplands in all burn severities, but as burn severity increased the upland and peatland communities became more similar. Conclusions: Our results suggest that high severity burns in both vegetation types support five generalist species and two fire specialists that may benefit from alterations in vegetation structure as a result of climate induced changes to fire regimes. However, eight species avoided burns, particularly birds preferring peatlands, and are likely to be more susceptible to fire-driven changes to their habitat caused by climate change. Understanding the long-term risks to these species from climate change requires additional efforts that link fire to bird populations.

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