Jarett Wilcoxen
- Assistant Professor, Chemistry & Biochemistry
Education
- Post-Doctoral research associate, University of California-Davis (R. David Britt)
- Ph.D. in Biochemistry and Molecular Biology, University of California, Riverside (Russ Hille)
- B.S. in Biochemistry, University of California, Santa Barbara
Teaching Schedule
| Course Num | Title | Meets |
|---|---|---|
| CHEM 612-001 | Transition Metal and Organometallic Chemistry | MW 3:30pm-4:45pm |
| CHEM 612G-001 | Transition Metal and Organometallic Chemistry | MW 3:30pm-4:45pm |
| CHEM 711-001 | Topics in Inorganic Chemistry: Bio-inorganic Chemistry | TR 3:30pm-4:45pm |
| CHEM 933-002 | Advanced Seminar in Inorganic Chemistry | No Meeting Pattern |
Research Interests
Research in the Wilcoxen lab will examine the structure-function relationship of metalloenzymes using biochemical and biophysical tools. We will explore, on a molecular level, how metalloenzymes generate highly reactive species, direct the reaction coordinate, and prevent unwanted side reactions. Researchers will develop skills in protein expression and purification, air free techniques with biological samples, and spectroscopic techniques such as UV-vis and electron paramagnetic resonance spectroscopy.
Radical SAM Enzymes:
Radical SAM enzymes are a going superfamily of enzymes with over 100k members, making it the largest superfamily of enzymes. Despite the abundance of sequence information little is known of the chemistry these enzymes catalyze. With only ~80 reactions identified, there is much more chemistry to be discovered and reaction mechanisms elucidated. We are particularly interested in radical SAM enzymes with auxiliary domains containing additional co-factors and co-substrates. Our primary goal is to understand how the protein environment guides the reaction path, from generating a primary carbon radical to subsequent substrate radical intermediates and product while preventing unwanted side reactions and dangerous side products.
Molybdenum Enzymes:
Molybdenum enzymes are present in all kingdoms of life catalyzing oxygen atom transfers between substrate and water. We are interested in how the protein environment tunes the molybdenum center through direct ligation to the molybdenum or through non-covalent interactions with the organic cofactor that coordinates molybdenum in the protein active site. We approach this project in two ways, the first is to understand the structure and function of the enzymes as present in biology by studying highly purified enzyme. We examine the kinetics and electronic structure to gain insight into the mechanism of the enzyme, utilizing the differences observed in variants of the enzyme to guide out hypotheses. A second approach is to generate tools to study the enzyme that can help guide our understanding of the biological proteins.