Emphasis on the functions and integration of human nervous, cardiovascular, respiratory, digestive, and renal systems in maintaining homeostasis, and by extension, health. Normal function, from cells to organs, of each system provides a foundation for study of mechanisms that lead to dysfunction and the identification of potential therapeutic targets and strategies.

Independent study under the direction of a Biology faculty member for students to read and critically assess primary research papers and current reviews in a focused area of the life sciences. Directed readings and discussions can be used to explore how contemporary topics and research areas can be incorporated into other formal courses. Students will have the opportunity to develop both scientific writing and oral presentation skills.

This course uses a case study approach to examine cellular processes that underlie diverse diseases and to identify the relevant molecular components that have been validated or that may serve as new therapeutic targets. We will discuss both established, transformative drugs as well as novel, emerging therapies under development. We will consider socio-economic and demographic issues that impact the accessibility and affordability of new drugs.

Independent wet-lab or dry-lab research for Biology majors, under the supervision of a University of Virginia faculty member in the Department of Biology, with emphasis on experimental design, data acquisition, and data interpretation. Instructor permission required; prior completion of any one of BIOL 3000, BIOL 3010, or BIOL 3020 strongly recommended.

In this course, we'll dive into our current understanding of the evolution and ecology of parasitic interactions through primary literature, modeling, and experimental design. Throughout, we will focus on generating and testing hypotheses, evaluating theoretical models with evidence, drawing parallels between diverse domains of life, and connecting evolutionary and ecological ideas to today's past, present, and future epidemics.

This intensive, graduate-level course is designed to provide a foundational understanding of the principles underlying the development, genetics, and molecular-cellular biology of the nervous system. Over the span of the semester, students will engage with three core areas of neuroscience: Genetics in Neuroscience, Neurodevelopment, Molecular and Cellular Biology (MCB) of Neurons.

Developing skill in communicating scientific principles and writing compelling research proposals is essential for successful graduate training in the biological sciences. This seminar and workshop course will focus on how to create effective grant and research proposals in preparation for thesis research. Students will be actively involved by presenting their research progress and plans, and critiquing each other's written proposals.

Periodic seminar offerings to provide intensive study of the scientific literature in focused areas of Biology.

The evolutionary history of a population can be studied by examining patterns of genetic variation among individuals. Using information about genetic variation, we can infer historical evolutionary events like migration and adaptation. In this lab course, you will learn to utilize genomic data to conduct evolutionary inference. We will learn fundamentals of population genetics, bioinformatic skills, and research methods applied to real short-read sequencing data.

Microbes rule. This course will teach microbial genomics using the cutting edge next-generation DNA sequencing technology and its applications to study microbes around us. Topics covered include microbial genomics, DNA sequencing and sequence analysis.