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Rebecca Drenovsky

Professor - Biology

Associate Vice President for Academic Affairs - Provost and Academic Vice President's Office

Rebecca Drenovsky Profile Picture

eMail

rdrenovsky@jcu.edu

Phone Number - Biology

216-397-4451

Phone Number - Provost and Academic Vice President's Office

216-397-4451

Location - Biology

Saint Ignatius Hall 133e

Location - Provost and Academic Vice President's Office

Saint Ignatius Hall 133e

Personal Websites

Rebecca Drenovsky Profile Picture

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Degrees:ÌýB.S. in Biology, Aquinas College, Grand Rapids, MI Ph.D. in Plant Biology, University of California, Davis, CA Post-doctoral research in Soil Microbial Ecology, University of California, Davis, CA

Expertise:ÌýPlant physiology and ecology, with an emphasis on plant-soil interactions

Research Interests

My overall research objective is to understand how resource availability influences plant physiological function and how these changes at the whole-plant level drive ecological processes.ÌýSuch research is critical to understanding how species and communities will respond to modifications in environmental factors due to global climate change, N deposition, and anthropogenic disturbance.ÌýCurrently, my research program at ÌÇÐÄlogoÔÚÏßÈë¿Ú has the following foci:Ìý1) plant adaptation to soil types; 2) ecology of arid land species; 3) environmental and evolutionary constraints on plant nutrient conservations; 4) functional traits associated with plant invasiveness. My research at the plant-soil interface is highly relevant given current pressures on native environments.ÌýBy understanding plant physiological responses to these changes, we can better predict feedbacks on community dynamics and ecosystem processes.

Recent Courses

BL 156 – Principles of Biology II lecture BL 159/160 – Principles of Biology III lecture and laboratory BL 420/520 – Plant Physiology BL 435/535 – Plant Ecology lecture and laboratory BL 454/554 – Desert Biology BL 454L/554L – Desert Field Biology BL 560 Experimental Design & Analysis

Selected Publications

B.J. Grewell, C.J. Futrell, M. Iannucci†, R.E. Drenovsky. 2019. Resprouting potential of rhizome fragments from invasive macrophytes reveals superior colonization ability of the diploid congener. AoB Plants. In press.

B. Gallego-Tévar, B.J. Grewell, C.J. Futrell, R.E. Drenovsky, J.M. Castillo. 2019. Interactive effects of salinity and inundation on native Spartina foliosa, invasive S. densiflora, and their hybrid from San Francisco Estuary, California. Annals of Botany. In press.

R.E. Drenovsky, N. Pietrasiak, T.H. Short. 2019. Global temporal patterns in nutrient resorption plasticity. 28:728-743.

R.L. Nielsen†, J.J. James, R.E. Drenovsky. 2019. Functional traits explain variation in chaparral shrub sensitivity to altered water and nutrient availability. Frontiers in Plant Science-Plant Nutrition.Ìý 10:505 (online only)

C.T. Muller†‡, M.J. Moore, Z. Feder‡, H. Tiley‡, R.E. Drenovsky. 2017. Phylogenetic patterns of foliar mineral nutrition accumulation among gypsophiles and their relatives in the Chihuahuan Desert. American Journal of Botany 104:1442-1450. Highlighted article.

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EXTERNAL COLLABORATIONS & RELATIONSHIPS:

GYPWORLD—a global consortium of researchers studying plants growing on gypsum soil

USDA-ARS Aquatic Weeds Research Unit

UNIVERSITY OF CALIFORNIAÌý Sierra Foothills Research and Extension Center David M. and Sylvia McLaughlin Reserve Ìý

TheÌý4Ìýmain areas of my research program:

1.Ìý Morphological and physiological traits associated with plant invasiveness. Exotic plant invasions pose a serious global ecological and conservation threat to native plant communities and can induce serious economic costs. Given their potential negative impacts, it is of interest to ecologists and invasion biologists to understand which traits makes some species more invasive than others. We know that some non-native species, following their arrival to a new area, simply naturalize and become part of the resident plant community. In contrast, other species experience rapid range expansion and are considered invasive. Determining which traits contribute most strongly to non-native organisms’ competitive ability is an essential first step in improving prediction and management of invasive species spread. Previous research has focused on species diversity or functional group diversity as a mechanism of invasion resistance. However, coarse functional or taxonomic groupings may not capture traits enabling invasive plants to outperform native ones. Our research focuses on key morphological and physiological functional traits involved in resource acquisition and use, particularly in resource poor environments.

2.Ìý Environmental and evolutionary constraints on plant nutrient resorption.Ìý I seek to understand the physiological, environmental, and evolutionary controls on internal plant nutrient recycling.Ìý Nutrient resorption and storage in perennial species conserves plant nutrient pools, decreasing plant reliance on current external nutrient supply and buffering the impact of annual variation in nutrient availability.Ìý At the whole-plant level, more complete nutrient resorption can increase plant fitness, a major driver of population dynamics.Ìý In contrast, complete resorption can negatively impact ecosystem processes.Ìý Since more complete resorption leads to nutrient-poor litter, decomposition processes are slowed, influencing site fertility and ultimately plant community composition.Ìý Despite the major role that nutrient resorption and storage may play in population, community, and ecosystem processes, there are significant gaps in our knowledge, such as:Ìý What is the relative importance of phylogeny versus environment on nutrient resorption?Ìý How do environmental factors influence realized resorption?Ìý Do other nutrient conservation or allocation mechanisms compensate in years of poor resorption?Ìý Using multi-year field sampling, manipulative experiments, and meta-analysis of published works, my ultimate goal is to gain a better understanding of how environmental variation, storage, and recycling drives community and ecosystem processes.Ìý By understanding plant physiological responses to these changes, we can predict feedbacks on community dynamics and ecosystem processes.Ìý

3.Ìý Plant adaptation to unique soil types.Ìý Unique soils, such as serpentine or gypsum, are hotspots of biological diversity.Ìý As such, they are excellent locations for asking questions related to adaptation and acclimation, as well as being areas of conservation concern.Ìý In addition to projects related to nutrient resorption and storage at the UC McLaughlin Reserve, I am investigating questions related to seed and seedling ecology of serpentine and non-serpentine shrubs, as well as plant-soil relations on gypsum outcrops in the Chihuahuan Desert.Ìý This work seeds to understand the physiological mechanisms promoting adaptation to these unique soils and how they relate to species evolution in these habitats.Ìý

4.Ìý Ecology of aridland communities.Ìý A common theme among my research program is studying aridland communities.Ìý Some of this work has focused on targeting species for restoration following invasive species management, particularly perennial bunchgrass systems.Ìý Other foci include the ecology of soil microbial crust communities and ecophysiological comparisons of common shrub and forb species.

Sigma Xi Scientific Research Society