Studies the genetics and cell biology of the vertebrate immune system, with a focus on adaptive immunity. Classic and current experimental systems are emphasized. Prerequisite: Must have completed or be currently taking BIOL 2010 or BIOL 2100 or BME 2104

Genome databases contain a wealth of information that enable us to answer myriad questions in biology. Working with genome data requires foundational knowledge in molecular genetic concepts, as well as technical knowledge of how to read and analyze sequence data. This class will provide students with the skills to understand genomic data and its applications in biology and medicine.

Microbes rule. In this course, we will explore how microbes rule the world and how genomics has revolutionized the way we study them. Fundamental principles of microbiology will be introduced. Topics include microbial cell structure, metabolism, genetics, diversity, evolution and infectious disease. Laboratory work will complement lecture topics and cover the core themes & concepts, as recommended by the American Society of Microbiology.

This course, the first in a two-course sequence, is an introduction to the structure and function of the human body. Review of the structure and physiology of cells and tissues leads to in-depth study of the musculoskeletal and nervous systems. Control mechanisms and the contributions of each system to overall homeostasis are emphasized.

This course, the second in a two-course sequence, examines structures and functions of the endocrine, cardiovascular, urogenital, respiratory, renal, gastrointestinal and reproductive systems. Control mechanisms and functional integration of these systems in overall homeostasis is emphasized.

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.

Introduction to the fundamental principles of conservation biology (e.g., global species numbers, value of biodiversity, causes of extinction, genetic diversity, island biogeography, priority setting) and current topics of debate (including zoo versus field conservation, effects of global change on species extinction). Conservation case studies will allow students to judge the relevance of biological theory to practical problems in conservation.

In this course, new transfer students will get to know the scientists and research going on in the Biology Department. We'll read scientific papers and participate in weekly departmental seminars. Together, we'll identify the many ways in which new transfer students can be part of the scientific community at UVA. We will engage with resources that will promote your success as a student of biology and help you navigate the paths to turn your degree into a meaningful career.

New course in the subject of biology.

Independent wet-lab or dry-lab research, under the supervision of a University of Virginia faculty member who does not have primary affiliation with the Biology Department, with emphasis on learning basic experimental approaches and techniques. See Biology Department website for application instructions. Instructor permission required; prior completion of BIOL 2100 or BIOL 2200 strongly recommended.