17 People Results for the Tag: Cell Growth
Associate Professor of Chemical Engineering; Associate Professor of Agricultural and Biological Engineering
Engineering microorganisms for applications in synthetic biology and metabolic engineering.
Eberly Chair and Professor of Biology
Mechanism of plant growth. Function and evolution of expansins. Biochemistry and rheology of plant cell walls. Growth responses to light, hormones, and water stress and other stimuli.
Professor of Biochemistry & Molecular Biology
Characterization and biochemical analysis of cellulose synthesis in a variety of organisms. Mechanism and regulation of fungal degradation of lignin. Dissimilatory Iron reduction.
J. Franklin Styer Professor of Horticultural Botany; Professor of Plant Molecular Biology; Director, Endowed Program in the Molecular Biology of Cocoa
Plant functional genomics, metabolomics and biotechnology. Identification of key genes for disease resistance and important traits in the tree crop Theoboma cacao, the Chocolate tree.
Research Professor of Plant Biotechnology Co-Director, Endowed Program in the Molecular Biology of Cocoa
Molecular basis of plant-pathogen and plant-endophyte interactions. Biotechnology of tree crops. Development of sustainable energy crops.
Professor of Agricultural and Biological Engineering
Cellulose synthesis and organization, cellulosic composites and coatings, microbial cellulose production, and chemically powered microfluidic and biological devices and sensors.
Associate Professor of Biology
Plant cell signaling. Hormonal and mechanical signal transduction in plant growth regulation. Live cell imaging of subcellular microdomains of ionic signaling.
Co-Director, Center for Biorenewables; Associate Professor of Biology
In vivo imaging of plant cell wall dynamics. Molecular genetic analysis of genes involved in cell growth. Cell wall biosynthesis in dividing cells. Cell wall engineering for sustainable bioenergy production.
Associate Professor of Bioengineering
Understanding the fundamental mechanisms by which biomaterial interfaces alter the proliferation, migration and differentiation of mesenchymal stem cells, and application of these principles in the intelligent design of biomaterial scaffolds that facilitate generation or regeneration of musculoskeletal tissues