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.

New course in the subject of biology.

Examines the fundamental principles of eukaryotic cell biology at the molecular level. Topics include: structure and function of the plasma membrane, transport of small molecules, ions and macromolecular complexes across membranes, protein trafficking, the cytoskeleton, signal transduction pathways, and the control of cell division and cellular proliferation. Prerequisites: completion of BIOL 2100 or BME 2104 and either CHEM 1410,1420, or CHEM 1810,1820. NOT repeatable if passing grade received.

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.

Imagine a world where your DNA is sequenced for free and any human gene can be altered at will. The goal of this course is to address the question: can our society be better prepared for this transformation in science? Is genetic privacy achievable or genetic discrimination avoidable? Who owns your genes? Do your genes drive your medical future? Classes involve student perspectives and discussions with experts in science, policy, ethics and law.

BIOL 2100 is one of two semester courses that together provide an intensive introduction to biology for prospective Biology majors and pre-health (med, vet, dental) students. This course focuses on the fundamentals of cell biology and genetics with an emphasis on classical and modern experimental approaches. Lecture topics and concepts are reinforced and extended during once-weekly laboratory/small group discussions.

Are developmental biology and regenerative biology one and the same? Throughout this course, we will emphasize both classical and modern experimental approaches that have been used to unravel the genetic, molecular and celluar mechanisms of development. Additionally, the practical value of understanding development is enormous, and the relationship between embryology and clinical applications will be a theme that runs throughout the course.

Animals are incredibly diverse, but they all evolved from the same single-celled ancestor that lived hundreds of millions of years ago. This course takes a cell-biological approach to explore key questions in animal evolution such as the origins of multicellularity and differentiation. Students will gain a cutting-edge perspective on current research that integrates cell, developmental, and evolutionary biology to explore animal origins.

By applying the principles of engineering to biology, students will design molecules, viruses, and cells to solve global problems in public health, food security, manufacturing, information processing, and the environment, changing the traditional question of 'How do cells work?' to 'How can I get a cell to work for me?' Students will gain experience in writing internationally competitive research project proposals. Prerequisite: Instructor Permission

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.