Elena Litchman

Last updated
Elena Litchman
Alma mater Moscow State University, University of Minnesota
Scientific career
Thesis Competition and coexistence of phytoplankton under fluctuating light  (1997)
Doctoral advisor Robert W. Sterner and David Tilman

Elena Litchman is a professor of aquatic ecology at Michigan State University known for her research on the consequences of global environmental change on phytoplankton.

Contents

Education and career

Litchman received an Honors Diploma in biology from Moscow State University, Russia, [1] and a Ph.D. in ecology from the University of Minnesota in 1997. [2] Following graduate work, Litchman held postdoctoral positions at the Smithsonian Environmental Research Center, the Swiss Federal Institute for Aquatic Science and Technology, and Rutgers University. [3] [4] From 2003 to 2005, Litchman was a research scientist at Georgia Institute of Technology. [1] [4] In 2005, Litchman took a position in the Zoology Department of Michigan State University and the W.K. Kellogg Biological Station. [1] She has been named a MSU Foundation Professor at Michigan State University where she works in the Department of Integrative Biology. [5]

Research

Litchman's Ph.D. research [2] examined the impact of changing light levels on competition in phytoplankton. [6] She introduced the use of trait-based ecology for phytoplankton in papers published in 2007 [7] and 2008. [8] Prior to these publications, trait-based ecology had been implemented in terrestrial science and Litchman was the first to apply these ideas to marine research. Key traits in phytoplankton include light, nutrient use, morphology, predation, and temperature, and Litchman has combined these traits to mathematically define phytoplankton community structure. [7] [8] Litchman's research has examined the connection between the size of phytoplankton over evolutionary time and nutrient limitation [9] which, in turn, impacts marine food webs under changing climates. [10] Through eco-evolutionary modeling, Litchman's research has shown that in the future warmer oceans will cause phytoplankton to shift towards polar regions. [11] [12]

Selected publications

Awards

Related Research Articles

<span class="mw-page-title-main">Annual plant</span> Plant which completes its life cycle within one growing season and then dies

An annual plant is a plant that completes its life cycle, from germination to the production of seeds, within one growing season, and then dies. Globally, only 6% of all plant species and 15% of herbaceous plants are annuals. The annual life cycle has independently emerged in over 120 different plant families throughout the entire angiosperm phylogeny.

In biology, weapons are traits that are used most often by males to fight one another off for access to mates. A mate is won in battle either by a male chasing off a fellow competitor or killing it off, usually leaving the victor as the only option for the female to reproduce with. However, because stronger organisms, whether mentally or physically, are usually favored in combat, this also leads to the evolution of stronger organisms in species that use combat as a way to secure mates, via intrasexual selection. Examples of weapons include: antlers, horns, and ossicones.

<span class="mw-page-title-main">Phytoplankton</span> Autotrophic members of the plankton ecosystem

Phytoplankton are the autotrophic (self-feeding) components of the plankton community and a key part of ocean and freshwater ecosystems. The name comes from the Greek words φυτόν, meaning 'plant', and, meaning 'wanderer' or 'drifter'.

<span class="mw-page-title-main">Redfield ratio</span>

The Redfield ratio or Redfield stoichiometry is the consistent atomic ratio of carbon, nitrogen and phosphorus found in marine phytoplankton and throughout the deep oceans.

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.

In ecology, a priority effect refers to the impact that a particular species can have on community development as a result of its prior arrival at a site. There are two basic types of priority effects: inhibitory and facilitative. An inhibitory priority effect occurs when a species that arrives first at a site negatively affects a species that arrives later by reducing the availability of space or resources. In contrast, a facilitative priority effect occurs when a species that arrives first at a site alters abiotic or biotic conditions in ways that positively affect a species that arrives later. Inhibitory priority effects have been documented more frequently than facilitative priority effects. Studies indicate that both abiotic and biotic factors can affect the strength of priority effects. Priority effects are a central and pervasive element of ecological community development that have significant implications for natural systems and ecological restoration efforts.

The term phylogenetic niche conservatism has seen increasing use in recent years in the scientific literature, though the exact definition has been a matter of some contention. Fundamentally, phylogenetic niche conservatism refers to the tendency of species to retain their ancestral traits. When defined as such, phylogenetic niche conservatism is therefore nearly synonymous with phylogenetic signal. The point of contention is whether or not "conservatism" refers simply to the tendency of species to resemble their ancestors, or implies that "closely related species are more similar than expected based on phylogenetic relationships". If the latter interpretation is employed, then phylogenetic niche conservatism can be seen as an extreme case of phylogenetic signal, and implies that the processes which prevent divergence are in operation in the lineage under consideration. Despite efforts by Jonathan Losos to end this habit, however, the former interpretation appears to frequently motivate scientific research. In this case, phylogenetic niche conservatism might best be considered a form of phylogenetic signal reserved for traits with broad-scale ecological ramifications. Thus, phylogenetic niche conservatism is usually invoked with regards to closely related species occurring in similar environments.

Evolutionary rescue is a process by which a population—that would have gone extinct in the absence of evolution—persists due to natural selection acting on heritable variation. Coined by Gomulkiewicz & Holt in 1995, evolutionary rescue was described as a continuously changing environment predicted to appear as a stable lag of the mean trait value behind a moving environmental optimum, where the rate of evolution and change in the environment are equal. Evolutionary rescue is often confused with two other commonplace forms of rescue: genetic rescue and demographic rescue-in nature due to overlapping similarities. Figure 1 highlights the different pathways that result in their respective rescue.

Freshwater phytoplankton is the phytoplankton occurring in freshwater ecosystems. It can be distinguished between limnoplankton, heleoplankton, and potamoplankton. They differ in size as the environment around them changes. They are affected negatively by the change in salinity in the water.

<span class="mw-page-title-main">Pedro Jordano</span>

Pedro Diego Jordano Barbudo is an ecologist, conservationist, researcher, focused on evolutionary ecology and ecological interactions. He is an honorary professor and associate professor at University of Sevilla, Spain. Most of his fieldwork is done in Parque Natural de las Sierras de Cazorla, Segura y Las Villas, in the eastern side of Andalucia, and in Doñana National Park, where he holds the title of Research Professor for the Estación Biológica Doñana, Spanish Council for Scientific Research (CSIC). Since 2000 he has been actively doing research in Brazil, with fieldwork in the SE Atlantic rainforest.

Terence Vincent Callaghan is a British biologist specialized in the ecology of the Arctic. Much of his work on arctic plants has taken place in Abisko in northernmost Sweden, based at the Abisko Scientific Research Station where he served as director. He was a lead author of the IPCC Fourth Assessment Reports chapter on polar regions.

Maria R. Servedio is a Canadian-American professor at the University of North Carolina at Chapel Hill. Her research spans a wide range of topics in evolutionary biology from sexual selection to evolution of behavior. She largely approaches these topics using mathematical models. Her current research interests include speciation and reinforcement, mate choice, and learning with a particular focus on evolutionary mechanisms that promote premating (prezygotic) isolation. Through integrative approaches and collaborations, she uses mathematical models along with experimental, genetic, and comparative techniques to draw conclusions on how evolution occurs. She has published extensively on these topics and has more than 50 peer-reviewed articles. She served as Vice President in 2018 of the American Society of Naturalists, and has been elected to serve as President in 2023.

Jeannine Cavender-Bares is a Distinguished McKnight University Professor at the University of Minnesota in the Department of Ecology, Evolution & Behavior. Her research integrates evolutionary biology, ecology, and physiology by studying the functional traits of plants, with a particular focus on oaks.

The enemy release hypothesis is among the most widely proposed explanations for the dominance of exotic invasive species. In its native range, a species has co-evolved with pathogens, parasites and predators that limit its population. When it arrives in a new territory, it leaves these old enemies behind, while those in its introduced range are less effective at constraining them. The result is sometimes rampant growth that threatens native species and ecosystems.

Stephanie M. Carlson is the A.S. Leopold Chair in Wildlife Biology at the University of California Berkeley. Her research considers fish ecology, freshwater ecology, and evolutionary ecology.

Nancy Collins Johnson is an American earth scientist who is the Regents’ Professor and Director of the School of Earth Sciences & Environmental Sustainability at Northern Arizona University. Her work considers soil microbial ecology and the study of mycorrhizal fungi. She was elected a Fellow of the American Association for the Advancement of Science in 2020.

Priyanga Amarasekare is a Professor of Ecology and Evolutionary Biology at the University of California, Los Angeles (UCLA) and distinguished Fellow of the Ecological Society of America (ESA). Her research is in the fields of mathematical biology and trophic ecology, with a focus on understanding patterns of biodiversity, species dispersal and the impacts of climate change. She received a 2021 Guggenheim Fellowship and received ESA's Robert H. MacArthur Award in 2022.

Tadashi Fukami is an associate Professor of Biology and community ecologist at Stanford University. He is currently the head of Fukami Lab which is a community ecology research group that focuses on "historical contingency in the assembly of ecological communities." Fukami is an elected Fellow of the Ecological Society of America.

Eco-evolutionary dynamics refers to the reciprocal effects that ecology and evolution have on each other. The effects of ecology on evolutionary processes are commonly observed in studies, but the realization that evolutionary changes can be rapid led to the emergence of eco-evolutionary dynamics. The idea that evolutionary processes can occur quickly and on one timescale with ecological processes led scientists to begin studying the influence evolution has on ecology along with the affects ecology has on evolution. Recent studies have documented eco-evolutionary dynamics and feedback, which is the cyclic interaction between evolution and ecology, in natural and laboratory systems at different levels of biological organization, such as populations, communities, and ecosystems.

Douglas Schemske is an evolutionary ecologist who made major contributions to research on pollination, the latitudinal gradient in species diversity, the evolution of polyploidy, and plant mating systems.

References

  1. 1 2 3 "Elena Litchman | Honored Faculty | Michigan State University". msu.edu. Retrieved 2021-05-15.
  2. 1 2 Litchman, Elena Gennady (1997). Competition and coexistence of phytoplankton under fluctuating light. ISBN   9780591661460 . Retrieved 2021-05-15.{{cite book}}: |website= ignored (help)
  3. "Seminar: Elena Litchman | Carnegie's Department of Global Ecology". dge.carnegiescience.edu. Retrieved 2021-05-15.
  4. 1 2 "Litchman CV" (PDF). Archived (PDF) from the original on 2021-06-14.
  5. "Biologist Litchman Named MSU Foundation Professor | Research at Michigan State University" . Retrieved 2021-06-14.
  6. Litchman, Elena (1998-11-01). "Population and community responses of phytoplankton to fluctuating light". Oecologia. 117 (1): 247–257. Bibcode:1998Oecol.117..247L. doi:10.1007/s004420050655. ISSN   1432-1939. PMID   28308494. S2CID   17099101.
  7. 1 2 Litchman, Elena; Klausmeier, Christopher A.; Schofield, Oscar M.; Falkowski, Paul G. (2007). "The role of functional traits and trade-offs in structuring phytoplankton communities: scaling from cellular to ecosystem level". Ecology Letters. 10 (12): 1170–1181. doi:10.1111/j.1461-0248.2007.01117.x. ISSN   1461-0248. PMID   17927770.
  8. 1 2 Litchman, Elena; Klausmeier, Christopher A. (2008). "Trait-Based Community Ecology of Phytoplankton". Annual Review of Ecology, Evolution, and Systematics. 39 (1): 615–639. doi:10.1146/annurev.ecolsys.39.110707.173549. ISSN   1543-592X.
  9. Litchman, E.; Klausmeier, C. A.; Yoshiyama, K. (2009-02-24). "Contrasting size evolution in marine and freshwater diatoms". Proceedings of the National Academy of Sciences. 106 (8): 2665–2670. Bibcode:2009PNAS..106.2665L. doi: 10.1073/pnas.0810891106 . ISSN   0027-8424. PMC   2650323 . PMID   19202058.
  10. "Mighty Diatoms: Global Climate Feedback From Microscopic Algae". ScienceDaily. Retrieved 2021-05-15.
  11. Thomas, M. K.; Kremer, C. T.; Klausmeier, C. A.; Litchman, E. (2012-11-23). "A Global Pattern of Thermal Adaptation in Marine Phytoplankton". Science. 338 (6110): 1085–1088. Bibcode:2012Sci...338.1085T. doi: 10.1126/science.1224836 . ISSN   0036-8075. PMID   23112294. S2CID   14178409.
  12. "Warmer future oceans could cause phytoplankton to thrive near poles, shrink in tropics". ScienceDaily. Retrieved 2021-05-15.
  13. "President Obama Names Top U.S. Early Career Scientists and Engineers". www.nsf.gov. Retrieved 2021-05-15.
  14. "Litchman lands prestigious award for excellence in aquatic ecology". MSUToday | Michigan State University. Retrieved 2021-05-15.
  15. "2021 Hutchinson Award Recipient". ASLO. Retrieved 2021-05-15.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.