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.

The goal of this course is to provide an original, unknown outcome research experience in developmental biology. After training in basic methods and descriptions of selected research problems, students form teams and investigate a problem of their choosing. Team members work together in the lab, but each writes an independent research proposal, a notebook, and a final project report on which they are graded. Prerequisite: BIOL 3000 or 3010.

Practical usage of various microscopy imaging methodologies to study the morphology and cellular function in various biological systems from single cell to single molecule in cells and tissues. Topics include basics theory of microscopy, imaging and image analysis to solve various biological questions, fluorophore labeling, technical and hands on training on various microscopy techniques applied in different biological and biomedical investigations. Lectures, discussion, student presentations and laboratory.

This is an introductory course that takes a multidisciplinary approach to studying the relationship between plants and people. The course focuses on providing students foundational information on the growth, development, physiology and genetics of plants and explores the connection between plants and people by looking at the use of plants as sources of food, shelter, medicinals and manufactured goods.

One of the most important characteristics of life is the ability to reproduce. In order to produce new life, multicellular organisms evolved specialized cells whose only purpose is reproduction ¿ the germ cells. Germ cells are the only cells that persist from one generation to the next and are often called immortal. We will decipher how these totipotent stem cells function in order to faithfully create the next generation of organisms.

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.

How has a bioluminescent jellyfish saved lives? What does a Himalayan pond fish have to do with research into the origins of psychiatric disorders? Innovative methods in biomedical research have played a significant part in the development of revolutionary disease cures, treatments and diagnostics. This course will examine many of these technical approaches and how they have led to such significant discoveries in basic biomedical research.Prerequisite: BIOL 3010

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 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.

New course in the subject of biology.