A laboratory designed to complement the lecture material in 230. Laboratory and computer projects investigate methods in molecular biology including recombinant DNA, gene cloning and DNA sequencing as well as contemporary bioinformatics, data mining and the display and analysis of complex genome databases. Prerequisite: BIO 230 (should be taken concurrently).

A laboratory designed to complement the lecture material in 230. Laboratory and computer projects investigate methods in molecular biology including recombinant DNA, gene cloning and DNA sequencing as well as contemporary bioinformatics, data mining and the display and analysis of complex genome databases. Prerequisite: BIO 230 (should be taken concurrently).

A laboratory designed to complement the lecture material in 230. Laboratory and computer projects investigate methods in molecular biology including recombinant DNA, gene cloning and DNA sequencing as well as contemporary bioinformatics, data mining and the display and analysis of complex genome databases. Prerequisite: BIO 230 (should be taken concurrently).

An exploration of genes and genomes that highlights the connections between molecular biology, genetics, cell biology and evolution. Topics include DNA and RNA, protein structure and function, gene organization, mechanisms and control of gene expression, origins and evolution of molecular mechanisms, and gene networks. The course also deals with the principal experimental and computational tools that have advanced relevant fields, and introduces students to the rapidly expanding databases at the core of contemporary biology.

An exploration of genes and genomes that highlights the connections between molecular biology, genetics, cell biology and evolution. Topics include DNA and RNA, protein structure and function, gene organization, mechanisms and control of gene expression, origins and evolution of molecular mechanisms, and gene networks. The course also deals with the principal experimental and computational tools that have advanced relevant fields, and introduces students to the rapidly expanding databases at the core of contemporary biology.

An exploration of genes and genomes that highlights the connections between molecular biology, genetics, cell biology and evolution. Topics include DNA and RNA, protein structure and function, gene organization, mechanisms and control of gene expression, origins and evolution of molecular mechanisms, and gene networks. The course also deals with the principal experimental and computational tools that have advanced relevant fields, and introduces students to the rapidly expanding databases at the core of contemporary biology.

An exploration of genes and genomes that highlights the connections between molecular biology, genetics, cell biology and evolution. Topics include DNA and RNA, protein structure and function, gene organization, mechanisms and control of gene expression, origins and evolution of molecular mechanisms, and gene networks. The course also deals with the principal experimental and computational tools that have advanced relevant fields, and introduces students to the rapidly expanding databases at the core of contemporary biology.

The laboratory is a course-based research experience addressing how plant physiology responds to climate change. The Lyman Plant House provides the ideal setting for growing plants under real life climate change scenarios. Students gain hands-on experience with sophisticated instrumentation and techniques used to measure micro-climate, plant-water relations, gas exchange (photosynthetic rate and respiration), nutrient allocation and stable isotope variation. Additionally, students will use RStudio for data visualization, data exploration and data analysis. 

This course provides a broad understanding of key concepts in plant physiology and how the environment affects plant function. Key concepts include water and nutrient uptake, growth and allocation, plant-soil interactions and gas exchange from the leaves to ecosystems. General principles in these topics are used to develop an understanding of how interactions between plants, as well as plant and animals, impact plant communities and ecosystem processes. Prerequisites: A course in ecology, organismal biology, or environmental science. 

Experiments in this course explore the morphology, physiology, biochemistry and genetics of bacteria using a variety of bacterial genera. Methods of aseptic technique; isolation, identification and growth of bacteria are learned. An individual project is completed at the end of the term. BIO 204 must be taken concurrently.