Lauren B. Buckley

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Lauren B. Buckley
LaurenBuckley.jpg
Alma mater Williams College (BA)
Stanford University (PhD)
Scientific career
FieldsEvolutionary ecology
Climate change
InstitutionsSanta Fe Institute
National Center for Ecological Analysis and Synthesis (NCEAS)
University of North Carolina Chapel Hill
University of Washington
Website www.biology.washington.edu/people/profile/lauren-buckley/

Lauren B. Buckley is an evolutionary ecologist and professor of biology at the University of Washington. She researches the relationship between organismal physiological and life history features and response to global climate change. [1]

Contents

Early life and education

Lauren Buckley grew up on Conanicut Island, Rhode Island. She developed an early interest in biology while exploring her home island with her parents, both marine biologists. [2]

Buckley earned her Bachelor of Arts in biology and mathematics (honors) at Williams College in 2000. She conducted research as a graduate student at Stanford University, where she earned her PhD in 2005. Following her time at Stanford, Buckley pursued postdoctoral fellowships at the National Center for Ecological Analysis and Synthesis (NCEAS) and the Santa Fe Institute. [3] [4] Buckley became an assistant professor at the University of North Carolina Chapel Hill, a position she held from 2009 to 2013. In 2013, she joined the faculty at the University of Washington Department of Biology, and has been a professor from 2019 onward. Her lab, Buckley Lab, is affiliated with the University of Washington, and conducts research on the adaptive and ecological responses of organisms to global climate change. [5]

Research

Climate change modeling

Buckley's work has focused on improving the modeling and forecasting of organismal responses to climate change by integrating field and experimental data. She has demonstrated that the most commonly used models in climate change research are insufficient predictors of species and population behavior, as they neglect essential features such as thermal physiology, behavior, size, and abiotic constraints, all of which factor into species fitness and performance. The mechanistic species distribution models she has developed incorporate essential aspects of species biology to improve predictions and assess the generalizability of certain phenotypes to other systems. [6] Another central concern these modeling improvements seek to address is a how much organisms will be able to move to adapt to changing climate patterns, and how this ability changes given an array of biotic and abiotic variables. [7]

Ectotherm studies

Buckley has utilized a variety of systems to study the responses of ectotherms to climate and weather patterns. Beginning with her dissertation, Buckley’s early research focused heavily on insular lizard population dynamics. Through the study of island lizard populations, she has documented the impact of energy constraints as key limiting factors to the density, abundance, and community structure of ectotherm populations. She has also studied and described the importance of incorporating physiological and life history features into models when predicting the range constraints and shifts of species. [8]

Museum specimens of Colias meadii reveal the effects of climate change through changes in pigmentation Colias.png
Museum specimens of Colias meadii reveal the effects of climate change through changes in pigmentation

Her more recent research has focused insect systems where historical data can be used to test predictions of responses to climate change. In particular, she focuses on the fitness implications of climate change for a species, given its biological and ecological features, which are often-overlooked components of climate change research. Her work has been instrumental in clarifying the performance and fitness consequences of thermal stress for ectotherm species, and brought attention to the particular vulnerability of mid-latitude species to climate change. [9] Buckley has also analyzed the influence of a number of variables on a given species' ability to respond to climate change, especially thermal developmental plasticity. Further, she has drawn important connections between developmental plasticity and maladaptive phenological shifts that may reduce fitness and disrupt ecological interactions, as well as the role of plasticity in attenuating climate change impacts. [10] [11] Her primary insect study systems are Colias butterflies and grasshopper communities in Colorado. [1]

Teaching

Buckley teaches undergraduate biology courses at the University of Washington, including BIOL 315: Biological Impacts of Climate Change and BIOL 421: Ecological and Evolutionary Physiology of Animals. Her classes align with her research, emphasizing the interactions between biology and climate change. [12]

Public outreach and TrEnCh Project

IR imaging is one of the tools used by the TrEnCh project IR image.png
IR imaging is one of the tools used by the TrEnCh project

Buckley received an NSF CAREER grant to pursue the development of the Translating Environmental Change (TrEnCh) project. [13] The goal of the TrEnCh project is to develop tools for visualizing the impact and response of environmental and climate change on organisms. It offers open-source, high-resolution data for sophisticated modeling and forecasting with greater detail and accuracy than traditional models that use general parameters. The project integrates a variety of open-source historical and observational data to promote dissemination of the material, and to connect the public to accessible means of understanding climate effects. One of the tools available through the project is TrenchR, a package for organismal energy modeling using the R programming language. [14] The TrEnCh project also uses infrared imaging to better collect data on the thermal conditions of ectotherms, and elucidate the possible resulting climate change impacts on thermally-sensitive processes.

The TrEnCh-ed portion of the project is designed to allow students to interact with data and observe climate-related correlations in organismal responses. [14]

Honors and awards

YearAward Title
2021The Reuters Hot List (top 1000 most influential climate scientists) [15]
2021Expertscape World Expert in Climatic Processes [16]
2021Clarivate Highly Cited Researcher in Environment and Ecology [17]
2014–2019NSF CAREER awardee [13]
2015Future leader, Science and Technology in Society (STS) Forum [18]
2011, 2013National Academy of Sciences Kavli Frontiers of Science Fellow [4]
2005–2007Santa Fe Institute Omidyar Postdoctoral Fellowship [3] [19]

Select publications

Related Research Articles

<span class="mw-page-title-main">Ecology</span> Study of organisms and their environment

Ecology is the study of the relationships among living organisms, including humans, and their physical environment. Ecology considers organisms at the individual, population, community, ecosystem, and biosphere level. Ecology overlaps with the closely related sciences of biogeography, evolutionary biology, genetics, ethology, and natural history.

This glossary of ecology is a list of definitions of terms and concepts in ecology and related fields. For more specific definitions from other glossaries related to ecology, see Glossary of biology, Glossary of evolutionary biology, and Glossary of environmental science.

Acclimatization or acclimatisation is the process in which an individual organism adjusts to a change in its environment, allowing it to maintain fitness across a range of environmental conditions. Acclimatization occurs in a short period of time, and within the organism's lifetime. This may be a discrete occurrence or may instead represent part of a periodic cycle, such as a mammal shedding heavy winter fur in favor of a lighter summer coat. Organisms can adjust their morphological, behavioral, physical, and/or biochemical traits in response to changes in their environment. While the capacity to acclimate to novel environments has been well documented in thousands of species, researchers still know very little about how and why organisms acclimate the way that they do.

The oxygen minimum zone (OMZ), sometimes referred to as the shadow zone, is the zone in which oxygen saturation in seawater in the ocean is at its lowest. This zone occurs at depths of about 200 to 1,500 m (700–4,900 ft), depending on local circumstances. OMZs are found worldwide, typically along the western coast of continents, in areas where an interplay of physical and biological processes concurrently lower the oxygen concentration and restrict the water from mixing with surrounding waters, creating a "pool" of water where oxygen concentrations fall from the normal range of 4–6 mg/L to below 2 mg/L.

<span class="mw-page-title-main">Evolutionary ecology</span> Interaction of biology and evolution

Evolutionary ecology lies at the intersection of ecology and evolutionary biology. It approaches the study of ecology in a way that explicitly considers the evolutionary histories of species and the interactions between them. Conversely, it can be seen as an approach to the study of evolution that incorporates an understanding of the interactions between the species under consideration. The main subfields of evolutionary ecology are life history evolution, sociobiology, the evolution of interspecific interactions and the evolution of biodiversity and of ecological communities.

<span class="mw-page-title-main">Phenotypic plasticity</span> Trait change of an organism in response to environmental variation

Phenotypic plasticity refers to some of the changes in an organism's behavior, morphology and physiology in response to a unique environment. Fundamental to the way in which organisms cope with environmental variation, phenotypic plasticity encompasses all types of environmentally induced changes that may or may not be permanent throughout an individual's lifespan.

The following outline is provided as an overview of and topical guide to ecology:

<span class="mw-page-title-main">Evolutionary physiology</span> Study of changes in physiological characteristics

Evolutionary physiology is the study of the biological evolution of physiological structures and processes; that is, the manner in which the functional characteristics of individuals in a population of organisms have responded to natural selection across multiple generations during the history of the population. It is a sub-discipline of both physiology and evolutionary biology. Practitioners in the field come from a variety of backgrounds, including physiology, evolutionary biology, ecology, and genetics.

Gretchen Hofmann is professor of ecological physiology of marine organisms at the University of California, Santa Barbara. She holds a B.S. from the University of Wyoming, and an M.S. and Ph.D. from the University of Colorado at Boulder in Environmental, Population and Organismal Biology.

Ecological forecasting uses knowledge of physics, ecology and physiology to predict how ecological populations, communities, or ecosystems will change in the future in response to environmental factors such as climate change. The goal of the approach is to provide natural resource managers with information to anticipate and respond to short and long-term climate conditions.

<span class="mw-page-title-main">Effects of climate change on plant biodiversity</span>

The history of life on Earth is closely associated with environmental change on multiple spatial and temporal scales. Climate change is a long-term change in the average weather patterns that have come to define Earth’s local, regional and global climates. These changes have a broad range of observed effects that are synonymous with the term. Climate change is any significant long term change in the expected pattern, whether due to natural variability or as a result of human activity. Predicting the effects that climate change will have on plant biodiversity can be achieved using various models, however bioclimatic models are most commonly used.

<span class="mw-page-title-main">Ecological fitting</span> Biological process

Ecological fitting is "the process whereby organisms colonize and persist in novel environments, use novel resources or form novel associations with other species as a result of the suites of traits that they carry at the time they encounter the novel condition". It can be understood as a situation in which a species' interactions with its biotic and abiotic environment seem to indicate a history of coevolution, when in actuality the relevant traits evolved in response to a different set of biotic and abiotic conditions.

Johanna Schmitt is an evolutionary ecologist and plant geneticist. Her research is notable for its focus on the genetic basis of traits in ecologically valuable plants and on predicting how such plants will respond and adapt to environmental change such as climate warming. She has authored over 100 articles and her works have been cited over 7900 citations. She is honored with being the first female scientist at Brown University to be elected to the National Academy of Sciences.

Ruth Geyer Shaw is a professor and principal investigator in the Department of Ecology, Evolution and Behavior at the University of Minnesota. She studies the processes involved in genetic variation, specializing in plant population biology and evolutionary quantitative genetics. Her work is particularly relevant in studying the effects of stressors such as climate instability and population fragmentation on evolutionary change in populations. She has developed and applied new statistical methods for her field and is considered a leading population geneticist.

Sarah E. Diamond is an American ecologist and biologist who is currently the George B. Mayer Chair in Urban and Environmental Studies at Case Western Reserve University in Cleveland, Ohio. A climate scientist, Diamond's research focuses on predicting how ecological and biological systems will respond and adapt to the changing climate.

The temperature-size rule denotes the plastic response of organismal body size to environmental temperature variation. Organisms exhibiting a plastic response are capable of allowing their body size to fluctuate with environmental temperature. First coined by David Atkinson in 1996, it is considered to be a unique case of Bergmann's rule that has been observed in plants, animals, birds, and a wide variety of ectotherms. Although exceptions to the temperature-size rule exist, recognition of this widespread "rule" has amassed efforts to understand the physiological mechanisms underlying growth and body size variation in differing environmental temperatures.

Thermal ecology is the study of the interactions between temperature and organisms. Such interactions include the effects of temperature on an organism's physiology, behavioral patterns, and relationship with its environment. While being warmer is usually associated with greater fitness, maintaining this level of heat costs a significant amount of energy. Organisms will make various trade-offs so that they can continue to operate at their preferred temperatures and optimize metabolic functions. With the emergence of climate change scientists are investigating how species will be affected and what changes they will undergo in response.

Aimée Classen is an American ecologist who studies the impact of global changes on a diverse array of terrestrial ecosystems. Her work is notable for its span across ecological scales and concepts, and the diversity of terrestrial ecosystems that it encompasses, including forests, meadows, bogs, and tropics in temperate and boreal climates.

<span class="mw-page-title-main">Jessica Hua</span> Herpetologist

Jessica Hua is an associate professor in the Department of Biological Sciences at Binghamton University, NY. In addition Hua is the Director for the Center for Integrated Watershed Studies at Binghamton University which focuses on understanding watersheds and the human influences on them through research. She is a herpetologist and oversees her own lab, The Hua Lab, where they focus on ecological interactions, evolutionary processes and ecological-evolutionary feedbacks. Hua's background has led to her appreciation of education with coming from a refugee family who "epitomizes the concept of the American Dream". Her research aims to help others gain opportunities while also establishing a lab that is inclusive and diverse. Hua also enjoys a variety of sports and plays disc golf professionally since 2016.

Warren P. Porter is a biophysical ecologist, environmental toxicologist, and an academic. He is an emeritus Professor in the Department of Integrative Biology at the University of Wisconsin, Madison.

References

  1. 1 2 "Lauren-Buckley | UW Biology". University of Washington. Retrieved 2022-04-30.
  2. "lbuckley - Overview" . Retrieved 2022-05-18 via GitHub.
  3. 1 2 "Omidyar". Santa Fe Institute. Retrieved 2022-04-26.
  4. 1 2 "Lauren Buckley". National Academy of Sciences. Retrieved 2022-04-25.
  5. "People". University of Washington. Retrieved 2022-04-25.
  6. "Mechanistic distribution models: Energetics, fitness, and population dynamics". National Center for Ecological Analysis and Synthesis. Retrieved 2022-05-16.
  7. Buckley, Lauren B.; Tewksbury, Joshua J.; Deutsch, Curtis A. (2013-08-22). "Can terrestrial ectotherms escape the heat of climate change by moving?". Proceedings of the Royal Society B: Biological Sciences. 280 (1765). doi:10.1098/rspb.2013.1149. PMC   3712453 . PMID   23825212.
  8. Buckley, Lauren B. (2010-05-01). "The range implications of lizard traits in changing environments". Global Ecology and Biogeography. doi:10.1111/j.1466-8238.2010.00538.x.
  9. Kingsolver, Joel G.; Diamond, Sarah E.; Buckley, Lauren B. (2013-12-01). Grindstaff, Jennifer (ed.). "Heat stress and the fitness consequences of climate change for terrestrial ectotherms". Functional Ecology. 27 (6): 1415–1423. doi: 10.1111/1365-2435.12145 .
  10. Buckley, Lauren B; Arakaki, Andrew J; Cannistra, Anthony F; Kharouba, Heather M; Kingsolver, Joel G (2017-11-01). "Insect Development, Thermal Plasticity and Fitness Implications in Changing, Seasonal Environments". Integrative and Comparative Biology. 57 (5): 988–998. doi: 10.1093/icb/icx032 . ISSN   1540-7063. PMID   28662575.
  11. Buckley, Lauren B.; Kingsolver, Joel G. (2019-10-01). Hampe, Arndt (ed.). "Environmental variability shapes evolution, plasticity and biogeographic responses to climate change". Global Ecology and Biogeography. 28 (10): 1456–1468. doi: 10.1111/geb.12953 . ISSN   1466-822X. S2CID   196659494.
  12. "Biology". University of Washington. Retrieved 2022-05-16.
  13. 1 2 "NSF Award Search: Award # 1951356 - Collaborative Research: RoL: Detecting and predicting the relative contributions of fecundity and survival to fitness in changing environments". National Science Foundation. Retrieved 2022-04-25.
  14. 1 2 "Tools". TrEnCh Project. Retrieved 2022-05-04.
  15. "Explore the @Reuters Hot List of 1,000 top climate scientists". Reuters. Retrieved 2022-04-25.
  16. "Climatic Processes: Buckley, Lauren - Expertscape.com". expertscape.com. Retrieved 2022-04-25.
  17. "Lauren Buckley's Publons profile". publons.com. Retrieved 2022-04-25.
  18. "Archive|NPO STS forum". Science and Technology in Society Forum. Retrieved 2022-04-27.
  19. "Postdoc Buckley and co-researcher Jetz study species and environmental turnover | Santa Fe Institute". Santa Fe Institute. Retrieved 2022-04-26.
  20. Buckley, Lauren B; Cannistra, Anthony F; John, Aji (2018-07-01). "Leveraging Organismal Biology to Forecast the Effects of Climate Change". Integrative and Comparative Biology. 58 (1): 38–51. doi: 10.1093/icb/icy018 . ISSN   1540-7063. PMID   29701771.
  21. "Functional and phylogenetic approaches to forecasting species' responses to climate change". scholar.google.com. Retrieved 2022-04-30.
  22. Burrows, Michael T.; Schoeman, David S.; Buckley, Lauren B.; Moore, Pippa; Poloczanska, Elvira S.; Brander, Keith M.; Brown, Chris; Bruno, John F.; Duarte, Carlos M.; Halpern, Benjamin S.; Holding, Johnna (2011-11-04). "The Pace of Shifting Climate in Marine and Terrestrial Ecosystems". Science. 334 (6056): 652–655. doi:10.1126/science.1210288. ISSN   0036-8075. PMID   22053045. S2CID   37662584.
  23. Buckley, Lauren B.; Urban, Mark C.; Angilletta, Michael J.; Crozier, Lisa G.; Rissler, Leslie J.; Sears, Michael W. (2010-04-01). "Can mechanism inform species' distribution models?". Ecology Letters. 13 (8): 1041–1054. doi:10.1111/j.1461-0248.2010.01479.x. ISSN   1461-023X. PMID   20482574.
  24. Buckley, Lauren B.; Jetz, Walter (2008-11-18). "Linking global turnover of species and environments". Proceedings of the National Academy of Sciences. 105 (46): 17836–17841. doi: 10.1073/pnas.0803524105 . ISSN   0027-8424. PMC   2584760 . PMID   19001274.
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