Continued support is requested for an ongoing program of graduate research training in molecular biology and biophysics at the University of Oregon. This training activity is centered in the Institute of Molecular Biology, and also involves additional groups with related scientific interests. Funds are requested for 12 predoctoral positions, within a program that includes approximately 59 graduate students, 47 postdoctoral trainees, and 22 training faculty. The program places special emphasis on the control of gene expression and nucleic acid structure/function, molecular basis of signaling and cell function, protein structure and dynamics, and molecular approaches to development and differentiation. The basic aspect of the training is laboratory research carried out under the direction of a facult member in the molecular biology and biophysics training program. Through this experience, the trainee becomes skilled at posing questions about fundamental biological processes and designing experiments to answer those questions. The training is augmented by formal courses offered by the Biology, Chemistry, and Physics Departments, by seminar programs that highlight current research in molecular biology, biophysics, and related disciplines, by the close involvement of a Thesis Advisory Committee, and by research seminar and journal club presentations by trainees. The training facilities include the laboratories of the faculty and support services such as the structural biology biophysical facility, the state-of-the-art genomics and imaging facilities, and a large number of other modern facilities. Major equipment is shared and housed in common space. The laboratories of most of the faculty are contiguous and in interconnected buildings. This arrangement fosters strong interdisciplinary interactions and collaborations among faculty and students.
This proposal is to provide support for graduate training leading to the Ph.D. degree in molecular biology and biophysics. Our goal is to produce creative, intellectually critical, and experimentally skilled bioscientists. We believe that trainig towards this end is first and foremost accomplished at the laboratory bench, and training is focused on learning to find a rigorous experimental answer to a significant scientific question. The training program actively promotes strongly interdisciplinary and collaborative science. We want our students to develop into imaginative and capable research scientists, equipped with the knowledge to lead research programs of their own, thereby strengthening the national resource in this area.
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|Sackman, Andrew M; McGee, Lindsey W; Morrison, Anneliese J et al. (2017) Mutation-Driven Parallel Evolution during Viral Adaptation. Mol Biol Evol 34:3243-3253|
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|Wheeler, Lucas C; Harms, Michael J (2017) Human S100A5 binds Ca2+ and Cu2+ independently. BMC Biophys 10:8|
|Plakos, Kory; DeRose, Victoria J (2017) Mapping platinum adducts on yeast ribosomal RNA using high-throughput sequencing. Chem Commun (Camb) 53:12746-12749|
|Wheeler, Lucas C; Donor, Micah T; Prell, James S et al. (2016) Multiple Evolutionary Origins of Ubiquitous Cu2+ and Zn2+ Binding in the S100 Protein Family. PLoS One 11:e0164740|
|Wheeler, Lucas C; Lim, Shion A; Marqusee, Susan et al. (2016) The thermostability and specificity of ancient proteins. Curr Opin Struct Biol 38:37-43|
|Lee, Wonbae; Gillies, John P; Jose, Davis et al. (2016) Single-molecule FRET studies of the cooperative and non-cooperative binding kinetics of the bacteriophage T4 single-stranded DNA binding protein (gp32) to ssDNA lattices at replication fork junctions. Nucleic Acids Res 44:10691-10710|
|McGee, Lindsey W; Sackman, Andrew M; Morrison, Anneliese J et al. (2016) Synergistic Pleiotropy Overrides the Costs of Complexity in Viral Adaptation. Genetics 202:285-95|
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