Faculty by Research Area

Chemical Ecology

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Ambrose Ambrose,  Stanley

ambrose@illinois.edu
217-244-3504

Professor
PEEC

Maybe Berenbaum,  May

maybe@illinois.edu
216A Morrill Hall / 318B Morrill Hall
217-333-2910 / 217-333-7784

Professor & Head, Swanlund Chair
Entomology, PEEC

Delucia DeLucia,  Evan

delucia@illinois.edu

G. William Arends Professor of Integrative Biology; Professor; Director, Institute for Sustainability, Energy, and Environment
Plant Biology, PEEC

My laboratory is studying the physiological ecology of vascular plants with an emphasis on the environmental limitations to photosynthesis and resource allocation. I am particularly interested in developing integrated models of light utilization by plants in different habitats, with an emphasis on woody plants. Other research projects include investigations of the effects of UV-B irradiation on growth and photosynthesis, and the impact of elevated CO2 on nutrient acquisition of trees. Currently we are using growth analysis, leaf and plant gas exchange, water relations, tissue chemistry, carbon isotope discrimination, and foliar optical properties, among other methods, in these studies. Research sites include grasslands, old fields, and deciduous forests in Illinois; subalpine and alpine habitats in Wyoming; and shrub steppe in Nevada.
No photo Hanks,  Lawrence

hanks@illinois.edu

Professor
Entomology, PEEC

Hughrobe Robertson,  Hugh

hughrobe@illinois.edu
417 Morrill Hall
217-333-0489

Professor
Entomology, PEEC

Generobi Robinson,  Gene

generobi@illinois.edu
1608 IGB / 449 Morrill Hall
217-265-0309

Swanlund Chair and Director, Institute for Genomic Biology;
Entomology, PEEC

Seigler Seigler,  David

daveseig@illinois.edu
217-333-7577

Professor Emeritus & Curator of Herbarium
Plant Biology, PEEC

Secondary metabolites of many structural types form the basis of many biological interactions in which plants are involved. Study of secondary metabolism, the interactions in which secondary metabolites serve as mediators or messages, and the evolutionary relationships of organisms in which these interactions occur is the central focus of research in my laboratory. We are presently developing and evaluating the activity of mixtures of soy oil products and plant secondary metabolites as insecticides for mosquitoes. This work is in collaboration with Dr. Robert Novak, Center for Economic Entomology, Illinois State Natural History Survey, and Dr. Robert Metcalf, Professor Emeritus, Department of Entomology, University of Illinois. We have presently developed mosquitocidal mixtures and have identified fractions from several plants that also possess mosquitocidal activity. By combining the two, we hope to reduce the amount of oil mixtures needed to control mosquitoes effectively. In collaborative work with Dr. Mary Ann Lila Smith of NRES, we are extracting, fractionating and purifying bioactive compounds from several berries that have powerful antioxidant activity. Extracts of these fruits give positive results in antioxidant, cancer preventive and cardioprotective bioassays. We are presently attempting to identify and characterize the compounds responsible. As a part of this work, we are modifying and improving chromatographic techniques needed to fractionate the mixtures. We have examined systematic and phylogenetic problems in the genus Acacia for several years and have published revisions of several portions of this large genus (about 250 neotropical species). Initial phases of this work, involving analysis using morphological features of two series of the genus, Acacia series Gummiferae and Vulgares are in progress. However, use of DNA sequencing of both chloroplast and nuclear encoded characters is essential to establish phylogenies of these taxa solidly. We are presently isolating DNA and carrying out amplification of the ITS regions. In the coming year, I plan to obtain sequences of several key taxa of each group within the genus and to apply for NSF funding for this project. Past research has focused on compounds capable of liberating HCN upon hydrolysis - both cyanogenic glycosides and lipids. Although studies have involved a number of plant groups, recent investigations have centered on the genus Acacia (Fabaceae) of the southwestern U.S. and Mexico, and the Passifloraceae and related families, providing a base for resolution of systematic and evolutionary problems as well as biological interactions within the groups. In related work, we are exploring cyanogenesis in the genus Tiquilia (Boraginaceae) of the southwestern U.S. and Mexico. Some species contain the cyanogenic glucoside dhurrin, whereas, in others, a non-cyanogenic nitrile glucoside, menisdaurin, is found. The two glucosides have been considered to arise from distinct pathways, but our results suggest strongly that their biosynthesis is linked. Menisdaurin itself may be formed as an artifact from another cyanogenic compound that can only be isolated from the plant under conditions that avoid heating. This heat-labile cyanogen has not been characterized.
Suarez2 Suarez,  Andrew

suarez2@illinois.edu
515 Morrill Hall
217-244-6631

I. C. Gunsalus Scholar, Professor and Head of Animal Biology
Animal Biology, Entomology, PEEC