Your search keyword '"Linda J. Beaumont"' showing total 63 results

1. Climate change increases global risk to urban forests

Author

Manuel Esperon-Rodriguez, Mark G. Tjoelker, Jonathan Lenoir, John B. Baumgartner, Linda J. Beaumont, David A. Nipperess, Sally A. Power, Benoît Richard, Paul D. Rymer, and Rachael V. Gallagher

Subjects

Environmental Science (miscellaneous), Social Sciences (miscellaneous)

Published

2022

2. An integrated approach to assessing abiotic and biotic threats to post‐fire plant species recovery: Lessons from the 2019–2020 Australian fire season

Author

Rachael V. Gallagher, Stuart P. Allen, Berin D. E. Mackenzie, David A. Keith, Rachael H. Nolan, Libby Rumpff, Carl R. Gosper, Geoffrey Pegg, Stephen van Leeuwen, Mark K. J. Ooi, Colin J. Yates, Cory Merow, Richard J. Williams, Efthymios I. Nikolopoulos, Linda J. Beaumont, Tony D. Auld, and Morgan Varner

Subjects

Global and Planetary Change, Ecology, Ecology, Evolution, Behavior and Systematics

Published

2022

3. Climate and land-use changes reduce the benefits of terrestrial protected areas

Author

Linda J. Beaumont, Ernest Frimpong Asamoah, and Joseph Maina

Subjects

Sustainable development, Land use, business.industry, Environmental resource management, Biodiversity, Climate change, Environmental Science (miscellaneous), Geography, Habitat destruction, Natural resource management, business, Protected area, Social Sciences (miscellaneous), Global biodiversity

Abstract

Expanding and enhancing protected area networks (PAs) is at the forefront of efforts to conserve and restore global biodiversity but climate change and habitat loss can interact synergistically to undermine the potential benefits of PAs. Targeting conservation, adaptation and mitigation efforts requires understanding climate and land-use patterns within PAs, both currently and under future scenarios. Here, projecting rates of temporal and spatial displacement of climate and land-use revealed that more than one-quarter of the world’s PAs (~27%) are located in regions that will experience both high rates of climate change and land-use change by 2050. Substantial changes are expected to occur more often within PAs distributed across tropical moist and grassland biomes, which currently host diverse tetrapods and vascular plants, and fall into less-stringent management categories. Taken together, our findings can inform spatially adaptive natural resource management and actions to achieve sustainable development and biodiversity goals. The authors project future rates of temporal and spatial displacement of climate and land-use in protected areas (PAs), and show that more than one-quarter of the world’s PAs are highly threatened, with particular risk to PAs across tropical moist and grassland biomes.

Published

2021

4. National assessments of species vulnerability to climate change strongly depend on selected data sources

Author

Linda J. Beaumont, Daniel Scherrer, Antoine Guisan, Manuel Esperón-Rodríguez, and Víctor L. Barradas

Subjects

Geography, business.industry, Ecology, Environmental resource management, Vulnerability, Climate change, business, Ecology, Evolution, Behavior and Systematics

Published

2021

5. Hydraulic failure and tree size linked with canopy die‐back in eucalypt forest during extreme drought

Author

Shubham S. Chhajed, Belinda E. Medlyn, Alice Gauthey, Brendan Choat, Adriano Losso, Xine Li, Kathryn J. Fuller, Linda J. Beaumont, Rachael H. Nolan, Rhiannon Smith, Matthias M. Boer, Magnolia Song, and Ian J. Wright

Subjects

0106 biological sciences, 0301 basic medicine, Canopy, Physiology, Plant Science, Forests, Biology, 01 natural sciences, Trees, Eucalypt forest, 03 medical and health sciences, Hydraulic conductivity, Xylem, Australia, Water, Die back, 15. Life on land, Eucalyptus, Droughts, Plant Leaves, 030104 developmental biology, Agronomy, Tree (set theory), Tree health, 010606 plant biology & botany

Abstract

Eastern Australia was subject to its hottest and driest year on record in 2019. This extreme drought resulted in massive canopy die-back in eucalypt forests. The role of hydraulic failure and tree size on canopy die-back in three eucalypt tree species during this drought was examined. We measured pre-dawn and midday leaf water potential (Ψleaf ), per cent loss of stem hydraulic conductivity and quantified hydraulic vulnerability to drought-induced xylem embolism. Tree size and tree health was also surveyed. Trees with most, or all, of their foliage dead exhibited high rates of native embolism (78-100%). This is in contrast to trees with partial canopy die-back (30-70% canopy die-back: 72-78% native embolism), or relatively healthy trees (little evidence of canopy die-back: 25-31% native embolism). Midday Ψleaf was significantly more negative in trees exhibiting partial canopy die-back (-2.7 to -6.3 MPa), compared with relatively healthy trees (-2.1 to -4.5 MPa). In two of the species the majority of individuals showing complete canopy die-back were in the small size classes. Our results indicate that hydraulic failure is strongly associated with canopy die-back during drought in eucalypt forests. Our study provides valuable field data to help constrain models predicting mortality risk.

Published

2021

6. Land-use and climate risk assessment for Earth's remaining wilderness

Author

Ernest F. Asamoah, Moreno Di Marco, James E.M. Watson, Linda J. Beaumont, Oscar Venter, and Joseph M. Maina

Subjects

velocity of climate change, Conservation of Natural Resources, climate mitigation, wilderness areas, Climate Change, climate adaptation, Biodiversity, Risk Assessment, General Biochemistry, Genetics and Molecular Biology, land-use change, Wilderness, post-2020 global biodiversity framework, tracking climate change, protected areas, General Agricultural and Biological Sciences, climate change, climate refugia, Ecosystem

Abstract

Earth's wilderness areas are reservoirs of genetic information and carbon storage systems, and are vital to reducing extinction risks. Retaining the conservation value of these areas is fundamental to achieving global biodiversity conservation goals; however, climate and land-use risk can undermine their ability to provide these functions. The extent to which wilderness areas are likely to be impacted by these drivers has not previously been quantified. Using climate and land-use change during baseline (1971-2005) and future (2016-2050) periods, we estimate that these stressors within wilderness areas will increase by ca. 60% and 39%, respectively, under a scenario of high emission and land-use change (SSP5-RCP8.5). Nearly half (49%) of all wilderness areas could experience substantial climate change by 2050 under this scenario, potentially limiting their capacity to shelter biodiversity. Notable climate (5 km year

Published

2022

7. The Global Urban Tree Inventory: A database of the diverse tree flora that inhabits the world’s cities

Author

Hugh M. Burley, Rachael V. Gallagher, Malin J. Hoeppner, Linda J. Beaumont, Alessandro Ossola, and Michelle R. Leishman

Subjects

Global and Planetary Change, Tree (data structure), Flora, Geography, Ecology, Urban tree, Urbanization, Biodiversity, Species richness, Ecology, Evolution, Behavior and Systematics

Published

2020

8. How exposure to land use impacts and climate change may prune the tetrapod tree of life

Author

Linda J Beaumont, David A Nipperess, Peter D Wilson, John B Baumgartner, and Manuel Esperon-Rodriguez

Abstract

Human domination of landscapes is a key driver of biodiversity loss, with the fingerprint of climate change becoming increasingly pronounced. Frameworks and tools for identifying threats to biodiversity are required to meet Post-2020 Global Biodiversity Framework targets for 2030 that call for, among other things, reducing or halting species extinction rates (1). Hence, we compiled a phylogenetic tree for terrestrial tetrapods, mapped hotspots of geographically restricted and evolutionarily distinct lineages, and identified which hotspots may simultaneously face the highest magnitudes of land use impacts and climate change. Across a quarter of Earth’s surface, hotspots contain the entire ranges of 45% of tetrapods, representing 39% of terrestrial tetrapod evolutionary heritage. By 2070, we estimate 8–13% of this heritage to occur entirely within hotspots highly exposed to climate change, with 13–29% of hotspots projected to experience high exposure to both stressors simultaneously. Most hotspots at highest risk occur in countries least able to take action. Our analysis highlights the need for global ambition and coordination to avoid catastrophic loss of tetrapod evolutionary heritage.

Published

2022

9. Tracking habitat or testing its suitability? Similar distributional patterns can hide very different histories of persistence versus nonequilibrium dynamics

Author

Jia‐Yee Samantha Yap, Maurizio Rossetto, Sourav Das, Peter D. Wilson, Linda J. Beaumont, and Robert J. Henry

Subjects

Geography, Climate Change, Genetics, Australia, Genetic Variation, General Agricultural and Biological Sciences, Biological Evolution, Ecology, Evolution, Behavior and Systematics, Ecosystem

Abstract

The expansions and contractions of a species' range in response to temporal changes in selective filters leave genetic signatures that can inform a more accurate reconstruction of their evolutionary history across the landscape. After a long period of continental decline, Australian rainforests settled into localized patterns of contraction or expansion during the climatic fluctuations of the Quaternary. The environmental impacts of recurring glacial and interglacial periods also intensified the arrival of new lineages from the Sunda shelf, and it can be expected that immigrant versus locally persistent taxa responded to environmental challenges in quantifiably different manner. To investigate how such differences impact on species' distribution, we contrast landscape genomic patterns and changes in habitat availability between a species with a long continental history on Doryphora sassafras and a Sunda-derived species (Toona ciliata), across a distributional overlap. Extensive landscape-level homogeneity across chloroplast and nuclear genomes for the Sunda-derived T. ciliata, characterize the genetic signature of a very recent invasion and a rapid southern "exploratory" expansion that had not been previously recorded in the Australian flora (i.e., of Gondwanan origin or Sahul-derived). In contrast, D. sassafras is consistent with other Sahul-derived species characterized by strong geographical divergence and regional differentiation. Interestingly, our findings suggest that admixture between genetically divergent populations during expansion events might be a contributing factor to the successful colonization of novel habitats. Overall, this study identifies some of the mechanisms regulating the rearrangements in species distributions and assemblage composition that follow major environmental shifts, and reminds us how a species' current range might not necessarily define species' habitat preference, with the consequence that estimates of past or future range might not always be reliable.

Published

2021

10. The Effect of Co-occurring Heat and Water Stress on Reproductive Traits and Yield of Tomato (Solanum lycopersicum)

Author

Linda J. Beaumont, Brian J. Atwell, and Chinedu Felix Amuji

Subjects

Plant growth, Horticulture, Yield (engineering), Co occurring, biology, Water stress, Plant Science, Solanum, biology.organism_classification, Plant reproduction

Published

2020

11. Simulating streamflow in the Upper Halda Basin of southeastern Bangladesh using SWAT model

Author

Akm Saiful Islam, Linda J. Beaumont, Joseph Maina, Sandy P. Harrison, and Farzana Raihan

Subjects

Data deficient, Hydrology, Hydrology (agriculture), Streamflow, 0208 environmental biotechnology, Environmental science, Tropics, 02 engineering and technology, SWAT model, Structural basin, 020801 environmental engineering, Water Science and Technology

Abstract

Most catchments in tropical regions are ungauged and data deficient, complicating the simulation of water quantity and quality. Yet, developing and testing hydrological models in data-poor regions ...

Published

2019

12. Identifying climate refugia for 30 Australian rainforest plant species, from the last glacial maximum to 2070

Author

John B. Baumgartner, Linda J. Beaumont, Maurizio Rossetto, Manuel Esperón-Rodríguez, Jia-Yee S. Yap, Peter R. Wilson, and Sourav Das

Subjects

0106 biological sciences, Flora, Ecology, 010604 marine biology & hydrobiology, Geography, Planning and Development, Climate change, Last Glacial Maximum, Rainforest, 010603 evolutionary biology, 01 natural sciences, Geography, Habitat, Plant species, Biological dispersal, Landscape ecology, Nature and Landscape Conservation

Abstract

Climate refugia—areas that remain suitable for species during periods of climate disruption—have played an important role in species persistence over time. Identifying and protecting these refugia is a key climate change adaptation approach for conservation planning. To identify climate refugia for Australian tropical/sub-tropical rainforest flora, from the Last Glacial Maximum to 2070. Habitat suitability models were calibrated for 30 species using Maxent, and projected onto climate data for: Last Glacial Maximum (LGM, ~ 22,000 ybp); mid-Holocene (MH, ~ 6000 ybp); current period; and 2070. The intersection of suitable habitat over consecutive periods was assessed, identifying: current refugia (LGM–MH–Current); future refugia (Current–Future); and High Value Refugia (HVR, suitable over all four periods). Refugial hotspots (regions suitable for at least 15 species) were also identified. Suitable habitat was generally projected to span the greatest area in the current period. Four current refugial hotspots were identified: Wet Tropics, Central Mackay Coast, South Eastern Queensland, and North Coast (New South Wales). While suitable habitat for most species may decline in the future, HVRs will likely be retained for all species to at least 2070, although restricted in size. Future refugia was also projected in areas beyond species’ dispersal ranges. HVRs are highly important for the conservation of these rainforest species, given their generation times, limited dispersal capabilities and additional anthropogenic barriers to movement. This study assists in understanding long-term spatial shifts in rainforest flora in response to climate change and in designing future conservation strategies.

Published

2019

13. Using a species distribution model to guide NSW surveys of the long-footed potoroo (Potorous longipes)

Author

Linda J. Beaumont, Joss Bentley, John B. Baumgartner, David A. Nipperess, and Mareshell Wauchope-Drumm

Subjects

Ecology, biology, Range (biology), Ecology (disciplines), Species distribution, biology.organism_classification, Potorous longipes, Geography, Habitat, Threatened species, Potoroo, Conservation biology, Ecology, Evolution, Behavior and Systematics

Published

2019

14. Taxonomic shortfalls in digitised collections of Australia’s flora

Author

Linda J. Beaumont, Md. Mohasinul Haque, and David A. Nipperess

Subjects

0106 biological sciences, Flora, Ecology, business.industry, 010604 marine biology & hydrobiology, Biodiversity, Distribution (economics), Megadiverse countries, Native plant, 010603 evolutionary biology, 01 natural sciences, Representativeness heuristic, Herbarium, Geography, Species richness, business, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Rapid growth in the digitisation of the world’s natural history collections substantially simplifies scientific access to taxonomic and biogeographic information. Despite recent efforts to collate more than two centuries of biodiversity inventories into comprehensive databases, these collections suffer limitations across spatial, temporal and taxonomic dimensions. We assessed taxonomic shortfalls in preserved specimens from 296 plant families native to Australia, for which records have been collated into the Australasian Virtual Herbarium (AVH), specifically addressing the following questions: (1) Based on the number of specimen records per species, which Australian native plant families are under- or over-represented in the collection of preserved specimens digitised in the AVH? (2) To what extent does the distribution of collectors among plant families, or the area occupied by plant families, explain patterns of taxonomic representativeness? We found that the number of preserved specimens per family is not proportional to the family’s known species richness. For 29% of Australia’s plant families (i.e. 86), the number of digitised records constitutes

Published

2019

15. Incorporating future climate uncertainty into the identification of climate change refugia for threatened species

Author

Mareshell Wauchope-Drumm, Manuel Esperón-Rodríguez, John B. Baumgartner, Linda J. Beaumont, and David A. Nipperess

Subjects

0106 biological sciences, Ecology, Range (biology), 010604 marine biology & hydrobiology, Climate change, Future climate, 010603 evolutionary biology, 01 natural sciences, Geography, Threatened species, Biological dispersal, Identification (biology), Precipitation, Adaptation, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Climate change presents a substantial threat to species unable to keep pace via migration or adaptation. In-situ climate refugia, areas currently occupied by a species and that remain suitable in the future, will be vital for species with dispersal limitations. Ex-situ refugia, areas beyond species' current ranges that remain suitable, may facilitate range shifts or provide options for translocation. Assessing both refugia is a conservation priority. Here, we identify refugia for 319 species threatened in New South Wales, using four plausible scenarios describing futures that are Warmer/Wetter, Warmer/Drier, Hotter/Wetter and Hotter/Little Precipitation change, relative to the present. Using Maxent, we identify (a) in-situ refugia for each species under each scenario; (b) regions of consensus – areas projected as in-situ refugia across all scenarios; (c) hotspots of in-situ refugia (regions suitable for >1 species); and (d) regions of consensus for ex-situ refugia. Species were categorised based on the extent of in- and ex-situ refugia. By 2070, refugia will likely be broadest, and narrowest, under the Warmer/Wetter and Hotter/Wetter scenarios, respectively. East coast regions currently suitable for multiple species are unlikely to remain as hotspots. Most species (65%) are projected to have limited regions of consensus for either refugia. Translocation should be explored for species with little-to-no in-situ refugia, but for which ex-situ refugia exist. Management of existing populations will be critical for species with in-situ refugia but limited ex-situ. We highlight how management decisions based on agreement across climate scenarios can be made, irrespective of uncertainty about the magnitude of climate change.

Published

2019

16. Assessing the vulnerability of Australia’s urban forests to climate extremes

Author

Hugh M. Burley, Mark G. Tjoelker, Dayenari Caballero-Rodríguez, Manuel Esperón-Rodríguez, Paul D. Rymer, Sally A. Power, and Linda J. Beaumont

Subjects

lcsh:GE1-350, landscape planting, Species selection, species selection, business.industry, Tree inventory, species composition, Environmental resource management, Species distribution, Vulnerability, Climate change, Forestry, Plant Science, Horticulture, lcsh:QK1-989, climate change, Geography, Urban planning, climate niche, lcsh:Botany, species distribution, business, Climate extremes, lcsh:Environmental sciences, Ecology, Evolution, Behavior and Systematics

Abstract

Societal Impact Statement Urban forests are recognized for the multiple benefits they provide to city‐dwellers. However, climate change will affect tree species survival and persistence in urban ecosystems. Tree failures will cause economic losses and jeopardize the delivery of societal benefits. The impacts of climate change will depend on the species’ resilience and adaptive capacity, as well as management actions which may ameliorate some of the negative impacts. Here, we assessed the potential vulnerability of Australia's urban forests to climate extremes. Our results can be used for future urban planning aiming to incorporate species that are well‐adapted to the hotter, drier climates expected with climate change. Summary Urban forests (UFs) are recognized for the multiple benefits they provide to city‐dwellers. However, global climate change—particularly predicted increases in the frequency and intensity of heatwaves and drought—will affect tree species’ performance and survival in urban ecosystems. Here, we assessed species composition and potential vulnerability of UFs in 22 Australian significant urban areas (SUAs) to heat and/or moisture stress. We quantified species’ realized climatic niches across their known distribution, and assessed the extent to which baseline climate in the SUAs where a particular species is planted fell within its niche. We used three environmental variables to group species based on their potential climate vulnerability. UFs varied in species composition and climate vulnerability across the continent. In general, neither climate similarity nor geographical proximity were good predictors of species composition among UFs. Of 1,342 tree species assessed (68.4% natives), 53% were considered potentially vulnerable to heat and/or moisture stress in at least one city where they are currently planted. Our results highlight the climate vulnerability of current plantings across Australian SUAs and can be used to direct future species selection that considers the species’ climate of origin and climatic niche. UF planning can incorporate species from SUAs with similar climates and with low vulnerability to contemporary, as well as future climate conditions. Species with high climate vulnerability, in contrast, may require more intensive management to avoid failure under future hotter, drier climate conditions.

Published

2019

17. Prioritizing the protection of climate refugia: designing a climate-ready protected area network

Author

John B. Baumgartner, Linda J. Beaumont, Manuel Esperón-Rodríguez, Alana Grech, and Victoria Graham

Subjects

Fluid Flow and Transfer Processes, Convention on Biological Diversity, business.industry, National park, Geography, Planning and Development, Environmental resource management, 0211 other engineering and technologies, Biodiversity, Climate change, 021107 urban & regional planning, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, 01 natural sciences, Geography, Bioregion, Reserve design, Marxan, business, Protected area, 0105 earth and related environmental sciences, General Environmental Science, Water Science and Technology

Abstract

Protected areas are the primary strategy for maintaining natural landscapes and separating biodiversity features from preventable anthropogenic threats. The Convention on Biological Diversity calls for the coverage of at least 17% of land by protected areas, and the strategic prioritization of important biodiversity areas. Using the spatially explicit reserve design software, Marxan, this study combines climate refugia modelled under future climates in the year 2070 and bioregions to identify priority sites for protected area expansion under climate change in the state of New South Wales (NSW), Australia. Priority sites for new protected areas that meet bioregion and climate refugia targets were identified in central-western, northeast and patches of southeast NSW. Seven existing parks, including Kosciuszko National Park, overlapped with regions identified repeatedly as climate refugia under 12 future climate scenarios. The recommendations from this study support policy-makers in prioritizing the protection of biodiversity under a changing and uncertain climate.

Published

2019

18. Tracing climate and land-use instability reveals new insights into the future of Earth’s remaining wilderness

Author

Joseph Maina, James E. M. Watson, Moreno Di Marco, Ernest Frimpong Asamoah, Linda J. Beaumont, and Oscar Venter

Subjects

Geography, Land use, Earth science, media_common.quotation_subject, Earth (chemistry), Tracing, Wilderness, Instability, media_common

Abstract

Accelerated loss of Earth’s wilderness over the last five decades underscores the urgency for efforts to retain the conservation value of these areas. Assessing how wilderness areas are likely to be impacted by the future environmental change is fundamental to achieving global biodiversity conservation goals. Using scenarios of climate and land-use change during baseline (1970–2005) and future (2015–2050) epochs, we found that climate change within wilderness areas is predicted to increase by ~ 47%, compared to a 19% increase in land-use change. Half (52%) of all wilderness areas may undergo climate change by 2050, limiting their capacity to shelter biodiversity. More significant changes are especially predicted to occur in the unprotected wilderness that supports unique assemblages of species and are therefore more important for biodiversity persistence. Countries with smaller and disconnected wilderness areas are disproportionately at risk from the combined impacts of climate and land-use change. Mitigating greenhouse gas emissions and preserving remaining intact natural ecosystems can help fortify these frontiers of biodiversity.

Published

2021

19. Embedding biodiversity research into climate adaptation policy and practice

Author

Tony D. Auld, Lesley Hughes, Nola Hancock, Linda J. Beaumont, Victoria Graham, Michelle R. Leishman, Linda Bell, Polly Mitchell, Rachael V. Gallagher, Suzanne Dunford, and Leigh Staas

Subjects

Global and Planetary Change, Government, Conservation of Natural Resources, Process management, Ecology, Process (engineering), Climate Change, Climate change, Biodiversity, Natural resource, Policy, Natural Resources, Agency (sociology), Environmental Chemistry, Business, Adaptation (computer science), Working group, Knowledge transfer, General Environmental Science

Abstract

Addressing climate change risks requires collaboration and engagement across all sectors of society. In particular, effective partnerships are needed between research scientists producing new knowledge, policy-makers and practitioners who apply conservation actions on the ground. We describe the implementation of a model for increasing the application and useability of biodiversity research in climate adaptation policy and practice. The focus of the program was to increase the ability of a state government agency and natural resource practitioners in Australia to manage and protect biodiversity in a changing climate. The model comprised a five-stage process for enhancing impact (i) initiation of research projects that addressed priority conservation policy and management issues; (ii) co-design of the research using a collaborative approach involving multiple stakeholders; (iii) implementation of the research and design of decision tools and web-based resources; (iv) collaborative dissemination of the tools and resources via government and community working groups; and (v) evaluation of research impact. We report on the model development and implementation, and critically reflect on the model's impact. We share the lessons learnt from the challenges of operating within a stakeholder group with diverse objectives and criteria for success, and provide a template for creating an environmental research program with real world impact.

Published

2021

20. Climate-change risk analysis for global urban forests

Author

Rachael V. Gallagher, Jonathan Lenoir, John B. Baumgartner, Sally A. Power, Linda J. Beaumont, Mark G. Tjoelker, Manuel Esperón-Rodríguez, Paul D. Rymer, Richard B, and David A. Nipperess

Subjects

Risk analysis, Geography, Agroforestry, Plant species, Vulnerability, Climate change, Precipitation, Vegetation, Socioeconomic status, Latitude

Abstract

Urban forests (i.e. all vegetation present in urban areas), provide environmental and socio-economic benefits to more than half of the global population. Projected climate change threatens these benefits to society. Here, we assess vulnerability to climate change of 16,006 plant species present in the urban forests of 1,010 cities within 93 countries, using three vulnerability metrics: exposure, safety margin and risk. Exposure expresses the magnitude of projected changes in climate in a given area, safety margin measures species' sensitivity to climate change, and risk is the difference between exposure and safety margin. We identified 9,676 (60.5%) and 8,344 (52.1%) species exceeding their current climatic tolerance (i.e. safety margin) for mean annual temperature (MAT) and annual precipitation (AP), respectively. By 2050, 13,479 (84.2%) and 9,960 (62.2%) species are predicted to be at risk from projected changes in MAT and AP, respectively, with risk increasing in cities at lower latitudes. Our results can aid evaluation of the impacts of climate change on urban forests and identify the species most at risk. Considering future climates when selecting species for urban plantings will enhance the long-term societal benefits provided by urban forests, including their contribution to mitigating the magnitude and impacts of climate change.

Published

2021

21. Future climate and land use instability can negate the benefits of protected areas

Author

Linda J. Beaumont, Joesph M Maina, and Ernest Frimpong Asamoah

Subjects

Land use, Business, Future climate, Environmental planning

Abstract

Expanding protected area networks and enhancing their capacities is currently one avenue at the forefront of efforts to conserve and restore global biodiversity. Climate and habitat loss resulting from land use interact synergistically to undermine the potential benefits of protected areas (PAs). Targeting conservation, adaptation and mitigation efforts requires an understanding of patterns of climate and land-use change within the current arrangement of PAs, and how these might change in the future. In this paper, we provide this understanding using predicted rates of temporal and spatial displacement of future climate and land use globally and within PAs. We show that ~ 47% of the world’s PAs—10.6% of which are under restrictive management—are located in regions that will likely experience both climate stress and land-use instability by 2050. The vast majority of these PAs are also distributed across moist biomes and in high conservation value regions, and fall into less-restrictive management categories. The differential impacts of combined land use and climate velocity across protected biomes indicate that climate and land-use change may have fundamentally different ecological and management consequences at multiple scales. Taken together, our findings can inform spatially adaptive natural resource management and actions to achieve sustainable development and biodiversity goals.

Published

2021

22. Land use planning to support climate change adaptation in threatened plant communities

Author

Joseph Maina, Anu Vijayan, Linda J. Beaumont, Peter J. Davies, Hsing-Chung Chang, and Rochelle Lawson

Subjects

Conservation of Natural Resources, Environmental Engineering, Biodiversity offsetting, business.industry, Climate Change, Environmental resource management, Land management, Climate change, Land-use planning, General Medicine, Biodiversity, Management, Monitoring, Policy and Law, Forests, Habitat destruction, Geography, Urban planning, Urbanization, Land use, land-use change and forestry, business, Waste Management and Disposal, Ecosystem

Abstract

Among the many causes of habitat loss, urbanization coupled with climate change has produced some of the greatest local extinction rates and has led to the loss of many native species. Managing native vegetation in a rapidly expanding urban setting requires land management strategies that are cognizant of these impacts and how species and communities may adapt to a future climate. Here, we demonstrate how identifying climate refugia for threatened vegetation communities in an urban matrix can be used to support management decisions by local government authorities under the dual pressures of urban expansion and climate change. This research was focused on a local government area in New South Wales, Australia, that is undergoing significant residential, commercial and agricultural expansion resulting in the transition of native forest to other more intensive land-uses. Our results indicate that the key drivers of change from native vegetation to urban and agriculture classes were population density and the proximity to urban areas. We found two of the most cleared vegetation community types are physically restricted to land owned or managed by council, suggesting their long-term ecological viability is uncertain under a warming climate. We propose that land use planning decisions must recognize the compounding spatial and temporal pressures of urban development, land clearing and climate change, and how current policy responses, such as biodiversity offsetting, can respond positively to habitat shifts in order to secure the longevity of important ecological communities.

Published

2020

23. Conservation prioritization can resolve the flagship species conundrum

Author

John B. Baumgartner, Jennifer McGowan, Adam J. Stow, Linda J. Beaumont, Scott C. Atkinson, Andrew J. Beattie, Hugh P. Possingham, Rachael Y. Dudaniec, Richard Grenyer, Alienor L. M. Chauvenet, David A. Nipperess, Robert J. Smith, Robert Harcourt, Manuel Esperón-Rodríguez, and John C. Mittermeier

Subjects

Lions, 0106 biological sciences, 0301 basic medicine, Prioritization, Conservation of Natural Resources, Science, Cost-Benefit Analysis, Elephants, Biodiversity, General Physics and Astronomy, QH75, Fund Raising, 010603 evolutionary biology, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Representation (politics), 03 medical and health sciences, Animals, Flagship species, Tigers, lcsh:Science, Environmental planning, Multidisciplinary, Conservation biology, General Chemistry, 030104 developmental biology, lcsh:Q, Global biodiversity

Abstract

Conservation strategies based on charismatic flagship species, such as tigers, lions, and elephants, successfully attract funding from individuals and corporate donors. However, critics of this species-focused approach argue it wastes resources and often does not benefit broader biodiversity. If true, then the best way of raising conservation funds excludes the best way of spending it. Here we show that this conundrum can be resolved, and that the flagship species approach does not impede cost-effective conservation. Through a tailored prioritization approach, we identify places containing flagship species while also maximizing global biodiversity representation (based on 19,616 terrestrial and freshwater species). We then compare these results to scenarios that only maximized biodiversity representation, and demonstrate that our flagship-based approach achieves 79−89% of our objective. This provides strong evidence that prudently selected flagships can both raise funds for conservation and help target where these resources are best spent to conserve biodiversity., Conservation actions focused on flagship species are effective at raising funds and awareness. Here, McGowan et al. show that prioritizing areas for conservation based on the presence of flagship species results in the selection of areas with ~ 79-89% of the total species that would be selected by maximizing biodiversity representation only.

Published

2020

24. Author Correction: Climate and land-use changes reduce the benefits of terrestrial protected areas

Author

Ernest F. Asamoah, Linda J. Beaumont, and Joseph M. Maina

Subjects

Environmental Science (miscellaneous), Social Sciences (miscellaneous)

Published

2022

25. Identifying in situ climate refugia for plant species

Author

John B. Baumgartner, Linda J. Beaumont, and Manuel Esperón-Rodríguez

Subjects

0106 biological sciences, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Climate change, Tropical and subtropical grasslands, savannas, and shrublands, Woodland, 010603 evolutionary biology, 01 natural sciences, Arid, Shrubland, Spatial variability, Precipitation, Species richness, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Published

2018

26. Assessment and prioritisation of plant species at risk from myrtle rust (Austropuccinia psidii) under current and future climates in Australia

Author

Manuel Esperón-Rodríguez, Linda J. Beaumont, K. Berthon, Angus J. Carnegie, and Michelle R. Leishman

Subjects

0106 biological sciences, biology, Range (biology), Ecology, Host (biology), business.industry, Myrtaceae, Distribution (economics), biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Rust, Invasive species, Plant disease, Geography, Habitat, business, Ecology, Evolution, Behavior and Systematics, 010606 plant biology & botany, Nature and Landscape Conservation

Abstract

Myrtle rust (Austropuccinia psidii) is an invasive rust fungus that attacks species of the Myrtaceae family, one of the most dominant plant families in Australia. The potential extent of myrtle rust affected areas and the high number of potential host species make a species prioritisation scheme essential to direct conservation and management efforts. This study builds on previous work by: compiling an up-to-date list of myrtle rust occurrences and host species; mapping current and future climate suitability for myrtle rust; and identifying host species at risk based on range overlaps and susceptibility data. Suitable habitat for myrtle rust is restricted to eastern and southern coastal areas of Australia, with minor areas in the Northern Territory and Western Australia. This coastal distribution remains present under future climates, with some extension in inland New South Wales and Tasmania, and a reduction of suitable habitat in northern Queensland and Western Australia. Contrary to previous studies, our results indicate that south-west Western Australia has low climatic suitability for myrtle rust. Under current climate, 1285 Myrtaceae species are at risk of exposure to myrtle rust. This number decreases to 1224 species under future climate. We divide species exposed to myrtle rust into three priority categories, giving highest priority to species with at least 70% of their range overlapping regions climatically suitable for myrtle rust under current or future climates. We find 23 species are of high priority for conservation action. Finally, we provide a series of recommendations for management of species within each priority category.

Published

2018

27. How well documented is Australia's flora? Understanding spatial bias in vouchered plant specimens

Author

Rachael V. Gallagher, Md. Mohasinul Haque, Linda J. Beaumont, and David A. Nipperess

Subjects

0106 biological sciences, Ecology, Range (biology), 010604 marine biology & hydrobiology, Biodiversity, Sampling (statistics), Biology, Native plant, 010603 evolutionary biology, 01 natural sciences, Herbarium, Bioregion, Spatial ecology, Species richness, Ecology, Evolution, Behavior and Systematics

Abstract

Massive digitization of natural history collections (NHC) has opened the door for researchers to conduct inferential studies on the collection of biological diversity across space and time. The widespread use of NHCs in scientific research makes it essential to characterize potential sources of spatial bias. In this study, we assessed spatial patterns in records from the Australian Virtual Herbarium (AVH), based on >3 000 000 vouchered specimens of around 21 000 native plant species. The AVH is the main database for describing Australia's flora, and identifying its limitations is of paramount interest for the validity of conservation and environmental studies. We characterized how sampling effort is distributed across each Interim Bioregion of Australia (IBRA), then asked: (i) How complete are species inventories for each bioregion? We define completeness (C) as the ratio of observed to estimated species richness, using the Chao 1 estimator, (ii) How is sampling effort related to a commonly used Human Influence Index (HII)? and (iii) What is the probability that additional collections would result in the identification of previously unrecorded species in each bioregion? Sampling effort across bioregions is unequal, which partially reflects the collecting behaviour of naturalists in relation to species richness patterns. The density of records in bioregions ranges from 0.02–8.37 km−2. At the bioregional scale, completeness is generally high with 79% of bioregions estimated to have records for at least 80% of their species. Completeness is partly explained by sampling effort (r = 0.43, p = 0.01), although some bioregions (e.g. Northern Kimberley and Burt Plain) have high completeness yet relatively low sampling effort. The inventory of Hampton, however, is substantially less complete than other bioregions (C = 0.66). Bioregions with high HII consistently have high completeness, while regions with low HII span the full range of completeness values. We calculated that an additional specimen collected from a bioregion has a 0.33% (Wet Tropics) to 11.7% (Arnhem Coast) probability of representing a new species for that region. Our assessment can assist with directing future systematic survey efforts by identifying bioregions where additional surveying may result in the greatest return, in terms of increasing knowledge of species richness and diversity.

Published

2017

28. New methods for measuring ENM breadth and overlap in environmental space

Author

John B. Baumgartner, Russell Dinnage, Linda J. Beaumont, and Dan L. Warren

Subjects

0106 biological sciences, Environmental space, business.industry, Ecology, 010604 marine biology & hydrobiology, Environmental resource management, Biology, business, 010603 evolutionary biology, 01 natural sciences, Ecology, Evolution, Behavior and Systematics

Published

2018

29. Peer reviewers need a code of conduct too

Author

Linda J. Beaumont

Subjects

Research ethics, Medical education, Multidisciplinary, Formative Feedback, business.industry, MEDLINE, Bullying, Mental health, Research Personnel, Formative assessment, Mental Health, Publishing, Codes of Ethics, Humans, business, Psychology, Ethical code

Published

2019

30. Substantial declines in urban tree habitat predicted under climate change

Author

Linda J. Beaumont, Manuel Esperón-Rodríguez, Shawn W. Laffan, Hugh M. Burley, Michelle R. Leishman, Anthony Manea, Rachael V. Gallagher, John B. Baumgartner, and Alessandro Ossola

Subjects

Environmental Engineering, 010504 meteorology & atmospheric sciences, Climate Change, Climate change, Distribution (economics), 010501 environmental sciences, 01 natural sciences, Trees, Environmental monitoring, Environmental Chemistry, Ecosystem, Cities, Baseline (configuration management), Waste Management and Disposal, 0105 earth and related environmental sciences, Horticulture industry, business.industry, Ecology, Australia, Models, Theoretical, Pollution, Herbarium, Geography, Habitat, business, Environmental Monitoring, Forecasting

Abstract

Globally, local governments are increasing investment in urban greening projects. However, there is little consideration of whether the species being planted will be resilient to climate change. We assessed the distribution of climatically suitable habitat, now and in the future, for 176 tree species native to Australia, commonly planted across Australia's Significant Urban Areas (SUAs) and currently grown by commercial nurseries. Species' occurrence records were obtained from inventories and herbaria, globally and across Australia, and combined with baseline climate data (WorldClim, 1960-1990) and six climate scenarios for 2030 and 2070 using climatic suitability models (CSMs). CSMs for each species were calibrated and projected onto baseline and future scenarios. We calculated changes in the size of climatically suitable habitat for each species across each SUA, and identified urban areas that are likely to have suitable climate for either fewer or more of our study species under future climate. By 2070, climatically suitable habitat in SUAs is predicted to decline for 73% of species assessed. For 18% of these species, climatically suitable area is predicted to be more than halved, relative to their baseline extent. Generally, for urban areas in cooler regions, climatically suitable habitat is predicted to increase. By contrast, for urban areas in warmer regions, a greater proportion of tree species may lose climatically suitable habitat. Our results highlight changing patterns of urban climatic space for commonly planted species, suggesting that local governments and the horticultural industry should take a proactive approach to identify new climate-ready species for urban plantings.

Published

2019

31. Which species distribution models are more (or less) likely to project broad-scale, climate-induced shifts in species ranges?

Author

Erin Graham, Daisy Englert Duursma, Peter R. Wilson, Linda J. Beaumont, Manuel Esperón-Rodríguez, Shawn W. Laffan, Abigail L. Cabrelli, Willow Hallgren, Dan L. Warren, David A. Nipperess, John B. Baumgartner, and Jeremy VanDerWal

Subjects

0106 biological sciences, Extinction, 010504 meteorology & atmospheric sciences, Range (biology), Ecology, Ecological Modeling, Species distribution, Linear model, Climate change, 15. Life on land, Biology, 010603 evolutionary biology, 01 natural sciences, Stability (probability), Habitat, 13. Climate action, Scale (map), 0105 earth and related environmental sciences

Abstract

Species distribution models (SDMs) frequently project substantial declines in the spatial extent of climatically suitable habitat in response to scenarios of future climate change. Such projections are highly disconcerting. Yet, considerable variation can occur in the direction and magnitude of range changes projected by different SDM methods, even when predictive performance is similar. In this study, we assessed whether particular methods have a tendency to predict substantial loss or gain of suitable habitat. In particular, we asked, “are 14 SDM methods equally likely to predict extreme changes to the future extent of suitable habitat for 220 Australian mammal species?”. We defined five non-mutually exclusive categories of ‘extreme’ change, based on stability or loss of current habitat, or the dislocation of current and future habitat: a) no future habitat (range extinction); b) low stability of current habitat (≤10% remains); c) no gain of habitat in new locations; d) all future habitat is in new locations (i.e. completely displaced from current habitat); and e) substantial increase in size of habitat (future habitat is ≥100% larger than current). We found that some SDM methods were significantly more likely than others to predict extreme changes. In particular, distance-based models were significantly less likely than other methods to predict substantial increases in habitat size; Random Forest models and Surface Range Envelopes were significantly more likely to predict a complete loss of current habitat, and future range extinction. Generalised Additive Models and Generalised Linear Models rarely predicted range extinction; future habitat completely disjunct from current habitat was predicted more frequently than expected by Classification Tree Analysis and less frequently by Maxent. Random Forest generally predicted extreme range changes more frequently than other SDM methods. Our results identify trends among different methods with respect to tendency to predict extreme range changes. These are of significance for climate-impact assessments, with implications for transferability of models to novel environments. Our findings emphasise the need to explore and justify the use of different models and their parameterisations, and to develop approaches to assist with optimisation of models.

Published

2016

32. Cunningham's skinks show low genetic connectivity and signatures of divergent selection across its distribution

Author

Linda J. Beaumont, Adam J. Stow, and Benjamin Y. Ofori

Subjects

0106 biological sciences, 0301 basic medicine, Conservation genetics, Range (biology), Outbreeding depression, Egernia cunninghami, next‐generation sequencing, Biology, 010603 evolutionary biology, 01 natural sciences, single nucleotide polymorphisms, 03 medical and health sciences, Genetic variation, Ecology, Evolution, Behavior and Systematics, Original Research, Nature and Landscape Conservation, Local adaptation, Ecology, adaptive genetic variation, 030104 developmental biology, conservation genetics, Genetic structure, Spatial ecology, Adaptation, local adaptation

Abstract

Establishing corridors of connecting habitat has become a mainstay conservation strategy to maintain gene flow and facilitate climate‐driven range shifts. Yet, little attention has been given to ascertaining the extent to which corridors will benefit philopatric species, which might exhibit localized adaptation. Measures of genetic connectivity and adaptive genetic variation across species’ ranges can help fill this knowledge gap. Here, we characterized the spatial genetic structure of Cunningham's skink (Egernia cunninghami), a philopatric species distributed along Australia's Great Dividing Range, and assessed evidence of localized adaptation. Analysis of 4,274 SNPs from 94 individuals sampled at four localities spanning 500 km and 4° of latitude revealed strong genetic structuring at neutral loci (mean F ST ± SD = 0.603 ± 0.237) among the localities. Putatively neutral SNPs and those under divergent selection yielded contrasting spatial patterns, with the latter identifying two genetically distinct clusters. Given low genetic connectivity of the four localities, we suggest that the natural movement rate of this species is insufficient to keep pace with spatial shifts to its climate envelope, irrespective of habitat availability. In addition, our finding of localized adaptation highlights the risk of outbreeding depression should the translocation of individuals be adopted as a conservation management strategy.

Published

2016

33. Potential impacts of a future persistent El Niño or La Niña on three subspecies of Australian butterflies

Author

Daisy Englert Duursma, Jason P. Evans, Linda J. Beaumont, Darrell J. Kemp, and Peter R. Wilson

Subjects

0106 biological sciences, education.field_of_study, 010504 meteorology & atmospheric sciences, biology, Ecology, Population, Climate change, Subspecies, Hypolimnas alimena, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, La Niña, Geography, Habitat, Butterfly, Ecosystem, education, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences

Abstract

One of the major uncertainties of 21st century climate change is the potential for shifts to the intensity and frequency of the El Nino Southern Oscillation (ENSO) cycle. Although this phenomenon is known to have dramatic impacts on ecosystems regionally and globally, the biological consequences of climate change-driven shifts in future ENSO events have been unexplored. Here, we investigate the potential impacts that a persistent El Nino, La Nina, or ‘Neutral' phase may have on species distributions. Using MaxEnt, we model the distribution of climatically suitable habitat for three northeast Australian butterfly subspecies (Doleschallia bisaltide australis, Hypolimnas alimena lamina, and Mycalesis terminus terminus) across the three ENSO phases. We find that the spatial extent and quality of habitat are lowest under conditions that would characterize a persistent El Nino (hot/dry). In contrast, suitable habitat is broadest under the warm/wet conditions associated with La Nina. Statistical analyses of the difference between pair-wise combinations of suitability maps using Hellinger distance showed that projections for each subspecies and ENSO phase combination were significantly different from other combinations. The resilience of these, and other, butterfly (sub)species to changes in ENSO will be influenced by fluctuations in the strength of these events, availability of refugia, and life-history characteristics. However, the population dynamics of wet- and dry-season phenotypes of M. t. terminus and physiological limitations to high temperatures suggest that this subspecies, in particular, may have limited resilience should the strength and frequency of El Nino events increase.

Published

2016

34. Environmental tolerance governs the presence of reef corals at latitudes beyond reef growth

Author

Andrew H. Baird, Linda J. Beaumont, Toni Mizerek, and Joshua S. Madin

Subjects

0106 biological sciences, Global and Planetary Change, geography, geography.geographical_feature_category, Ecology, Environmental change, Resilience of coral reefs, Range (biology), 010604 marine biology & hydrobiology, Coral, fungi, technology, industry, and agriculture, Coral reef, biochemical phenomena, metabolism, and nutrition, Biology, 010603 evolutionary biology, 01 natural sciences, population characteristics, Biological dispersal, Species richness, Reef, geographic locations, Ecology, Evolution, Behavior and Systematics

Abstract

Aim: Understanding mechanisms that enhance survival outside the usual range of a taxonomic group is key to understanding diversity gradients, how range boundaries operate and how environmental change might influence geographical distributions. Our aims were: (1) to identify species-level traits associated with reef-building coral species whose ranges extend into high-latitude, non-reefal habitats (i.e. 'beyond reef'), (2) determine if these patterns were consistent in different global regions, and (3) determine if traits associated with living beyond reef were related to enhanced dispersal or tolerance to harsher environmental conditions. Location: Three regions of the Central Indo-Pacific with tropical-temperate gradients from 35 degrees N to 36 degrees S. Methods: Scleractinian coral richness was collated and analysed as a function of latitude, region and whether or not reef accretion occurred. Species traits that are hypothesized to contribute to living beyond the environmental limits of carbonate reef accretion were compiled; these included traits associated with dispersal potential and environmental tolerance. The contribution of species traits to presence beyond reefs was then quantified using a binomial generalized linear mixed effects model. Results: In each region, coral species richness dropped by up to 73% where reef accretion ceased. Compared with corals restricted to coral reefs, the subset of species extending beyond reefs shared common traits related to environmental tolerance (larger depth ranges, more robust morphologies and tolerance of turbid water), but not to dispersal potential. Patterns were mostly consistent among regions. Main conclusions: We show for the first time that coral species living successfully in beyond-reef habitats share common characteristics that are consistent in three global regions. Environmental tolerance appears to play the dominant role in determining which species successfully establish beyond reefs. Our trait-based approach sheds light on how species assemblages and ranges might be altered by environmental change or loss of reef habitats.

Published

2016

35. The Biodiversity and Climate Change Virtual Laboratory: Where ecology meets big data

Author

Hamish Holewa, Lynda E. Chambers, Rachel Warren, Shawn W. Laffan, Gerhard Weis, Jeff Price, Erin Graham, Henry A. Nix, Willow Hallgren, Brendan Mackey, Jeremy VanDerWal, Linda J. Beaumont, and Andrew Bowness

Subjects

0106 biological sciences, Engineering, Environmental Engineering, 010504 meteorology & atmospheric sciences, Climate change, Cloud computing, 010603 evolutionary biology, 01 natural sciences, Upload, Environmental Science(all), Species distribution modelling, Virtual Laboratory, 0105 earth and related environmental sciences, Data collection, business.industry, Ecological Modeling, Environmental resource management, Biodiversity, Variety (cybernetics), Environmental niche modelling, Ecological Modelling, Transparency (graphic), business, Software

Abstract

Advances in computing power and infrastructure, increases in the number and size of ecological and environmental datasets, and the number and type of data collection methods, are revolutionizing the field of Ecology. To integrate these advances, virtual laboratories offer a unique tool to facilitate, expedite, and accelerate research into the impacts of climate change on biodiversity. We introduce the uniquely cloud-based Biodiversity and Climate Change Virtual Laboratory (BCCVL), which provides access to numerous species distribution modelling tools; a large and growing collection of biological, climate, and other environmental datasets; and a variety of experiment types to conduct research into the impact of climate change on biodiversity.Users can upload and share datasets, potentially increasing collaboration, cross-fertilisation of ideas, and innovation among the user community. Feedback confirms that the BCCVL's goals of lowering the technical requirements for species distribution modelling, and reducing time spent on such research, are being met. BCCVL facilitates and expedites modelling of climate change's impact on biodiversity.BCCVL integrates numerous species distribution modelling tools and myriad datasets.BCCVL negates the need for advanced programming and modelling expertise.BCCVL allows for increases in productivity and complexity of experimental design.BCCVL facilitates the sharing of data promoting transparency in the research process.

Published

2016

36. Author Correction: Potential impacts of climate change on habitat suitability for the Queensland fruit fly

Author

Bernard C. Dominiak, Linda J. Beaumont, Sabira Sultana, John B. Baumgartner, and Jane E. Royer

Subjects

Habitat suitability, Entomology, Multidisciplinary, Geography, business.industry, lcsh:R, Environmental resource management, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, lcsh:Medicine, Climate change, lcsh:Q, lcsh:Science, business

Abstract

A correction to this article has been published and is linked from the HTML and PDF versions of this paper. The error has been fixed in the paper.

Published

2018

37. MOLECULAR DETECTION OF ANTIBIOTIC-RESISTANCE DETERMINANTS INESCHERICHIA COLIISOLATED FROM THE ENDANGERED AUSTRALIAN SEA LION (NEOPHOCA CINEREA)

Author

Robert Harcourt, Linda J. Beaumont, Koa N. Webster, Michelle L. Power, and Tiffany C. Delport

Subjects

DNA, Bacterial, Molecular Sequence Data, Endangered species, medicine.disease_cause, Microbiology, Antibiotic resistance, Drug Resistance, Bacterial, Escherichia coli, medicine, Animals, Escherichia coli Infections, Phylogeny, Ecology, Evolution, Behavior and Systematics, Oligonucleotide Array Sequence Analysis, Phylotype, Base Sequence, Ecology, biology, Endangered Species, Australia, Neophoca cinerea, biology.organism_classification, Anti-Bacterial Agents, Sea Lions, Fecal coliform, Gene cassette, Mobile genetic elements

Abstract

Greater interaction between humans and wildlife populations poses significant risks of anthropogenic impact to natural ecosystems, especially in the marine environment. Understanding the spread of microorganisms at the marine interface is therefore important if we are to mitigate adverse effects on marine wildlife. We investigated the establishment of Escherichia coli in the endangered Australian sea lion (Neophoca cinerea) by comparing fecal isolation from wild and captive sea lion populations. Fecal samples were collected from wild colonies March 2009-September 2010 and from captive individuals March 2011-May 2013. Using molecular screening, we assigned a phylotype to E. coli isolates and determined the presence of integrons, mobile genetic elements that capture gene cassettes conferring resistance to antimicrobial agents common in fecal coliforms. Group B2 was the most abundant phylotype in all E. coli isolates (n = 37), with groups A, B1, and D also identified. Integrons were not observed in E. coli (n = 21) isolated from wild sea lions, but were identified in E. coli from captive animals (n = 16), from which class I integrases were detected in eight isolates. Sequencing of gene cassette arrays identified genes conferring resistance to streptomycin-spectinomycin (aadA1) and trimethoprim (dfrA17, dfrB4). Class II integrases were not detected in the E. coli isolates. The frequent detection in captive sea lions of E. coli with resistance genes commonly identified in human clinical cases suggests that conditions experienced in captivity may contribute to establishment. Identification of antibiotic resistance in the microbiota of Australian sea lions provides crucial information for disease management. Our data will inform conservation management strategies and provide a mechanism to monitor microorganism dissemination to sensitive pinniped populations.

Published

2015

38. Shifting time: recent changes to the phenology of Australian species

Author

Linda J. Beaumont, Teagan Hartenthaler, Marie R. Keatley, and Lynda E. Chambers

Subjects

Atmospheric Science, Geography, Ecology, Agriculture, business.industry, Phenology, Citizen science, Environmental Chemistry, Climate change, business, General Environmental Science

Published

2015

39. A journey through time: exploring temporal patterns amongst digitized plant specimens from Australia

Author

Md. Mohasinul Haque, David A. Nipperess, Linda J. Beaumont, and John B. Baumgartner

Subjects

0106 biological sciences, 0301 basic medicine, 03 medical and health sciences, Temporal consistency, 030104 developmental biology, Data quality, Biodiversity, Plant Science, Biology, 010603 evolutionary biology, 01 natural sciences, Cartography, Ecology, Evolution, Behavior and Systematics

Abstract

Online access to species occurrence records has opened new windows into investigating biodiversity patterns across multiple scales. The value of these records for research depends on their spatial, temporal, and taxonomic quality. We assessed temporal patterns in records from the Australasian Virtual Herbarium, asking: (1) How temporally consistent has collecting been across Australia? (2) Which areas of Australia have the most reliable records, in terms of temporal consistency and inventory completeness? (3) Are there temporal trends in the completeness of attribute information associated with records? We undertook a multi-step filtering procedure, then estimated temporal consistency and inventory completeness for sampling units (SUs) of 50 km × 50 km. We found temporal bias in collecting, with 80% of records collected over the period 1970–1999. South-eastern Australia, the Wet Tropics in north-east Queensland, and parts of Western Australia have received the most consistent sampling effort over time, whereas much of central Australia has had low temporal consistency. Of the SUs, 18% have relatively complete inventories with high temporal consistency in sampling. We also determined that 25% of digitized records had missing attribute information. By identifying areas with low reliability, we can limit erroneous inferences about distribution patterns and identify priority areas for future sampling.

Published

2018

40. Influence of adaptive capacity on the outcome of climate change vulnerability assessment

Author

Benjamin Y. Ofori, John B. Baumgartner, Linda J. Beaumont, and Adam J. Stow

Subjects

0106 biological sciences, Decision support system, 010504 meteorology & atmospheric sciences, Climate Change, Science, Vulnerability, 010603 evolutionary biology, 01 natural sciences, Outcome (game theory), Article, Climate change vulnerability, Species Specificity, Animals, Vulnerable species, 0105 earth and related environmental sciences, Adaptive capacity, Multidisciplinary, business.industry, Environmental resource management, Lizards, Adaptation, Physiological, Geography, Habitat, Medicine, Identification (biology), business

Abstract

Climate change vulnerability assessment (CCVA) has become a mainstay conservation decision support tool. CCVAs are recommended to incorporate three elements of vulnerability – exposure, sensitivity and adaptive capacity – yet, lack of data frequently leads to the latter being excluded. Further, weighted or unweighted scoring schemes, based on expert opinion, may be applied. Comparisons of these approaches are rare. In a CCVA for 17 Australian lizard species, we show that membership within three vulnerability categories (low, medium and high) generally remained similar regardless of the framework or scoring scheme. There was one exception however, where, under the warm/dry scenario for 2070, including adaptive capacity lead to five fewer species being classified as highly vulnerable. Two species, Eulamprus leuraensis and E. kosciuskoi, were consistently ranked the most vulnerable, primarily due to projected losses in climatically suitable habitat, narrow thermal tolerance and specialist habitat requirements. Our findings provide relevant information for prioritizing target species for conservation and choosing appropriate conservation actions. We conclude that for the species included in this study, the framework and scoring scheme used had little impact on the identification of the most vulnerable species. We caution, however, that this outcome may not apply to other taxa or regions.

Published

2017

41. Generalized 'avatar' niche shifts improve distribution models for invasive species

Author

Eric Larson, Rachael V. Gallagher, Linda J. Beaumont, and Julian D. Olden

Subjects

Mahalanobis distance, Range (biology), Ecology, business.industry, Species distribution, Niche, Distribution (economics), Biology, business, Ecology, Evolution, Behavior and Systematics, Invasive species, Environmental niche modelling, Avatar

Abstract

Aim Species distribution models are an invaluable tool for anticipating the potential range of invasive species. These models often improve when both native and non-native occurrences are available for model development and validation. Therefore, how might ecologists anticipate the potential distributions for emerging invasive species that lack any or abundant non-native range occurrences? Here, we evaluate the recent suggestion of transferring niche shifts from well-established ‘avatar’ invaders to emerging invaders by testing if ensemble niche shifts from a group of globally invasive plants improve model predictions when each of these species is iteratively treated as an ‘emerging’ invader. Location Global. Methods We built species distribution models using Mahalanobis distance and four climatic predictors (maximum and minimum temperature and precipitation) for 26 invasive terrestrial plants from an Australian priority list of weeds. Models using only native range occurrences for each species were modified with avatar niche shifts from the remaining ensemble of 25 species based on both a typical (median) niche shift and a large (extreme) niche shift (or niche expansion). Native range and both median and extreme avatar models were then compared with total range models (developed with both native and non-native occurrences) for performance by measures of discrimination and an approximation of calibration. Results Avatar niche shifts reduced errors of omission for known non-native occurrences relative to native range models, with a trade-off of increased errors of commission of lesser magnitude. Further, our approximation of model calibration measured relative to total range models improved with avatar niche shifts. Differences between native range and avatar models were most pronounced for the larger ‘extreme’ avatar niche shifts (or expansion) based on increased niche size and decreased (towards 0) covariance among climatic axes. Main conclusions We suggest that researchers and managers evaluating risk of invasion of their jurisdiction by emerging data-poor invaders modify native range models with observed avatar niche shifts from ensembles of well-studied invaders. Alternative implementations of the avatar invader concept are discussed and research needs for methodological improvements proposed. Despite these opportunities for improved implementation of avatar niche shifts, ample evidence now supports that researchers should expect models based on only native ranges to underestimate or misrepresent the total range for data-poor emerging invaders. Avatar niche shifts (and specifically expansion) from well-studied species offer a precautionary means to anticipate the extent to which native range models may underestimate total ranges.

Published

2014

42. How can knowledge of the climate niche inform the weed risk assessment process? A case study ofChrysanthemoides moniliferain Australia

Author

Linda J. Beaumont, Paul O. Downey, Rachael V. Gallagher, Lesley Hughes, and Michelle R. Leishman

Subjects

Ecological niche, Habitat, biology, Range (biology), Ecology, Niche, Introduced species, Chrysanthemoides monilifera, Subspecies, biology.organism_classification, Ecology, Evolution, Behavior and Systematics, Invasive species

Abstract

Aim Climate change and the ability of alien populations to realize different climatic niches compared to native populations pose challenges for pre-empting invasion risk. These issues are not addressed in Weed Risk Assessments (WRAs), which have been developed to identify potentially invasive species and prevent their importation. Chrysanthemoides monilifera, native to Southern Africa, has two subspecies invasive in Australia, which has led to an importation ban on all six subspecies. We assess whether the two invasive subspecies occupy different realized climatic niches, compared with native populations, and the climatic suitability of Australia for all subspecies under current and future climate scenarios. Location Southern Africa and Australia Methods Realized climatic niches of native and alien populations of two invasive subspecies (Bitou Bush and Boneseed) were compared using niche identity tests. The distribution of climatically suitable habitat within Australia for all subspecies was modelled using MaxEnt, under current and future climate scenarios. For invasive subspecies, models were calibrated using (1) native or (2) alien range data. Results Realized climatic niches of native and alien populations are not identical, with some alien populations of Boneseed occupying climatic niches absent from Southern Africa. As such, MaxEnt models for Boneseed based on native range data failed to classify one-third of Australian populations as inhabiting suitable climate. Main Conclusions We validate the Australian decision to ban all subspecies by showing that climatically suitable habitat in Australia for non-introduced subspecies exceeds that of introduced subspecies, under current and future climates. Niche shifts and climate change alter estimates of invasion risks, and this may reduce efficacy of current WRAs. We call for greater dialogue to identify and standardize a comprehensive system for incorporating these challenging issues into WRA systems to ensure that they remain effective in reducing the weed risk into the future.

Published

2014

43. Climate, soil or both? Which variables are better predictors of the distributions of Australian shrub species?

Author

John B. Baumgartner, Linda J. Beaumont, Yasmin Hageer, and Manuel Esperón-Rodríguez

Subjects

0106 biological sciences, Biogeochemical cycle, 010504 meteorology & atmospheric sciences, Climate, Species distribution, ved/biology.organism_classification_rank.species, lcsh:Medicine, Forage, Plant Science, 010603 evolutionary biology, 01 natural sciences, Shrub, General Biochemistry, Genetics and Molecular Biology, Shrubland, Soil, Predictor choice, Species distribution modelling, Growth form, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Ecology, ved/biology, General Neuroscience, lcsh:R, Australia, General Medicine, Biodiversity, Environmental niche modelling, Habitat, Biogeography, Habitat suitability, Environmental science, Species richness, Shrubs, Maxent, General Agricultural and Biological Sciences, Environmental Sciences

Abstract

BackgroundShrubs play a key role in biogeochemical cycles, prevent soil and water erosion, provide forage for livestock, and are a source of food, wood and non-wood products. However, despite their ecological and societal importance, the influence of different environmental variables on shrub distributions remains unclear. We evaluated the influence of climate and soil characteristics, and whether including soil variables improved the performance of a species distribution model (SDM), Maxent.MethodsThis study assessed variation in predictions of environmental suitability for 29 Australian shrub species (representing dominant members of six shrubland classes) due to the use of alternative sets of predictor variables. Models were calibrated with (1) climate variables only, (2) climate and soil variables, and (3) soil variables only.ResultsThe predictive power of SDMs differed substantially across species, but generally models calibrated with both climate and soil data performed better than those calibrated only with climate variables. Models calibrated solely with soil variables were the least accurate. We found regional differences in potential shrub species richness across Australia due to the use of different sets of variables.ConclusionsOur study provides evidence that predicted patterns of species richness may be sensitive to the choice of predictor set when multiple, plausible alternatives exist, and demonstrates the importance of considering soil properties when modeling availability of habitat for plants.

Published

2017

44. Impacts of Climate Change on the Distributions of Allergenic Species

Author

Daisy Englert Duursma and Linda J. Beaumont

Subjects

Geography, Ecology, Climate change

Published

2016

45. Impacts of climate change on the world's most exceptional ecoregions

Author

Niklaus E. Zimmermann, Andrew J. Pitman, Nigel G. Yoccoz, Linda J. Beaumont, Wilfried Thuiller, and Sarah E. Perkins

Subjects

Greenhouse Effect, Multidisciplinary, Ecology, Biome, Global warming, Climate change, Subtropics, Biological Sciences, Models, Biological, Tundra, Greenhouse gas, Humans, Environmental science, Climate model, Physical geography, Greenhouse effect, Ecosystem

Abstract

The current rate of warming due to increases in greenhouse gas (GHG) emissions is very likely unprecedented over the last 10,000 y. Although the majority of countries have adopted the view that global warming must be limited to Ann Mo Bot Gard 89:199–224]. We assess the likelihood that, by 2070, these iconic ecoregions will regularly experience monthly climatic conditions that were extreme in 1961–1990. Using >600 realizations from climate model ensembles, we show that up to 86% of terrestrial and 83% of freshwater ecoregions will be exposed to average monthly temperature patterns >2 SDs (2σ) of the 1961–1990 baseline, including 82% of critically endangered ecoregions. The entire range of 89 ecoregions will experience extreme monthly temperatures with a local warming of

Published

2011

46. Does the choice of climate baseline matter in ecological niche modelling?

Author

Jeremy VanDerWal, Andrew J. Pitman, A.J. Roubicek, Peter R. Wilson, Linda J. Beaumont, and Lesley Hughes

Subjects

Ecological niche, Range (biology), business.industry, Ecology, Ecological Modeling, Ecology (disciplines), Climate change, Distribution (economics), Habitat, Environmental science, Physical geography, Hellinger distance, Baseline (configuration management), business

Abstract

Ecological niche models (ENMs) have multiple applications in ecology, evolution and conservation planning. They relate the known locations of a species to characteristics of its environment (usually climate) over its geographical range. Most ENMs are trained using standard 30-year (1961–1990) or 50-year (1951–2000) baselines to represent current climate conditions. Species occurrence records used as input to the models, however, are frequently collected from time periods that differ from those from which the climate is derived. Since climate variability can be significant within and outside baselines, and the distributions of some plants and animals (e.g., annual plants, insects) can adjust to environmental conditions on much shorter time scales, this mismatch between collection records and climatic baselines may affect the utility and accuracy of model outputs. We investigated how the choice of baseline periods influenced modelling efforts, anticipating that climate baselines derived from the same temporal period as the species records would yield improved ENMs. Ten simulated species’ distributions were modelled using an ENM (Maxent) for (a) occurrences and climates within the same temporal period, based on eighteen 10-year baselines within the 20th century and (b) all available samples and climate baselines from 1951–2000 and 1961–1990. Each model was projected onto all the available 10-year climate scenarios and compared to the models trained on the corresponding scenario. We show that temporal mismatches of species occurrences and climate baselines can result in significantly poorer distribution models. Such temporal mismatch may be unavoidable for many studies, but we emphasize here the need to match the time range of samples and climate data whenever possible.

Published

2010

47. Author Correction: Biological responses to the press and pulse of climate trends and extreme events

Author

Tessa Vance, David M. J. S. Bowman, Mike Letnic, C. A. Woodward, Marie R. Keatley, Nigel R. Andrew, Lynda E. Chambers, Michael R. Kearney, Michael-Shawn Fletcher, Rebecca M. B. Harris, Grant J. Williamson, Carly R. Tozer, Shayne McGregor, Patrick J. Mitchell, Lindsay B. Hutley, Adrienne B. Nicotra, Thomas Wernberg, Tomas A. Remenyi, Norman C. Duke, Sarah E. Perkins-Kirkpatrick, and Linda J. Beaumont

Subjects

0106 biological sciences, History, business.industry, 010604 marine biology & hydrobiology, Perspective (graphical), Environmental resource management, Extreme events, Biodiversity, Climate change, 010501 environmental sciences, Environmental Science (miscellaneous), 01 natural sciences, Pulse (physics), Ecosystem, Conservation biology, business, Social Sciences (miscellaneous), 0105 earth and related environmental sciences

Abstract

In the version of this Perspective originally published, affiliations 1 and 4 ware incorrect, and should have read: “1Antarctic Climate & Ecosystems CRC, University of Tasmania, Hobart, Tasmania, Australia” and “4Centre for Water, Climate and Land (CWCL), University of Newcastle, Callaghan, NSW, Australia”. These have been corrected in the online versions of this Perspective.

Published

2018

48. Evidence for climatic niche and biome shifts between native and novel ranges in plant species introduced to Australia

Author

Michelle R. Leishman, Lesley Hughes, Linda J. Beaumont, and Rachael V. Gallagher

Subjects

Ecological niche, Ecology, Range (biology), Biome, Niche, Introduced species, Plant Science, Realized niche width, Biology, Ecology, Evolution, Behavior and Systematics, Invasive species, Environmental niche modelling

Abstract

1. The potential invasive success of exotic plant species is thought to be associated with similarity in climate and biome between the original and novel range. We tested this assumption by quantifying the match between the realized climatic niches and biomes occupied in the exotic and native range of 26 plant species introduced to Australia. We then explored correlations between the propensity to shift climatic niche with residence time, invasion status, geographic range size, and species traits. 2. Occurrence data from the native and exotic range of 26 species introduced to Australia were obtained, and the overlap between native and exotic climate niches was calculated using between-class analysis. Shifts into novel biomes were assessed using a Geographic Information System (GIS). Correlations between introduction, distribution and species traits and the degree of climate matching were examined using nonparametric statistical tests. 3. Exotic species frequently occurred in climatic conditions outside those occupied in their native range (20 of 26 species). Nineteen species inhabited biomes in Australia not occupied in the native range and in some instances this shift represented the establishment of populations in novel biomes not present in the native range. No single-species trait, introduction or distributional characteristic was significantly associated with the degree of climatic niche shift. 4. Synthesis. Exotic species are able to occupy climate niches in the new range that differ substantially from those of the native range, and generally do not show biome conservatism between their native and introduced ranges. This implies that novel climatic conditions are not a major obstacle for exotic species establishing populations outside their native range. These results have important implications for the use and interpretation of ecological niche models used to predict the distribution of species in novel climates in time or space. The results also highlight the importance of alternate mechanisms, such as enemy release, phenotypic plasticity or rapid evolution, in the establishment of naturalized and invasive populations.

Published

2010

49. The risk to Myrtaceae ofAustropuccinia psidii,myrtle rust, in Mexico

Author

Manuel Esperón-Rodríguez, Víctor L. Barradas, Michelle R. Leishman, M. A. Alfonzetti, Linda J. Beaumont, Angus J. Carnegie, K. Berthon, and John B. Baumgartner

Subjects

0106 biological sciences, Habitat suitability, Ecology, biology, Myrtaceae, Botany, Forestry, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Rust, Invasive species, 010606 plant biology & botany

Published

2018

50. Modelling the impact ofHieraciumspp. on protected areas in Australia under future climates

Author

Michelle R. Leishman, Wilfried Thuiller, Paul O. Downey, Lesley Hughes, Rachael V. Gallagher, and Linda J. Beaumont

Subjects

Ecological niche, Hieracium, Geography, biology, Ecology, Tussock, Biodiversity, Climate change, Introduced species, Protected area, biology.organism_classification, Ecology, Evolution, Behavior and Systematics, Invasive species

Abstract

Anthropogenically-induced climate change is one of the most important global threats to biodiversity. Understanding its impact on the distribution of exotic plant species is critical for developing effective adaptation and management strategies. However, there is insufficient information currently available on the biodiversity at risk from 1) exotic plant invasions, 2) climate change, and 3) the interaction between these two major threats, to develop such strategies. We use ecological niche models as a first step to identify zones inside and outside Australian protected areas that may be most at risk from invasions of three species of Hieracium (hawkweeds) under current and future (2030 and 2070) climate scenarios, should current control and eradication methods fail. These perennial herbs are native to Europe and invasive to New Zealand and North America. Naturalised in Australia, hawkweeds threaten native tussock grasslands and the grazing industry, and have been placed on the National Alert List. Using eight ecological niche models currently available in the software package BIOMOD, we found that these species have yet to realize the extent of their climatic distribution under present day climate in Australia. As climate change accelerates, the climatic range of hawkweeds was projected to contract overall. However, much of the Australian Alps, which contain large contiguous tracts of reserves and many endemic species, will continue to retain climatically suitable areas for hawkweeds through to 2070. These results emphasise the need for ongoing monitoring as well as focused control to minimize the likelihood of hawkweeds realizing their invasive potential in protected areas and beyond.

Published

2009