(Offered as BIOL 391, BCBP 391, and NEUR-391) Fluorescence imaging offers a window to understanding the structure and function of living cells at sub-cellular resolution. This laboratory and lecture course will focus on advanced quantitative fluorescence microscopy techniques used for imaging a range of biological model systems and functions ranging from single molecules to cells to tissues.
(Offered as BIOL 391, BCBP 391, and NEUR-391) Fluorescence imaging offers a window to understanding the structure and function of living cells at sub-cellular resolution. This laboratory and lecture course will focus on advanced quantitative fluorescence microscopy techniques used for imaging a range of biological model systems and functions ranging from single molecules to cells to tissues.
Independent reading or research course. A half course. Does not normally count toward the major.
Fall and spring semesters. The Department.
How to handle overenrollment: null
Students who enroll in this course will likely encounter and be expected to engage in the following intellectual skills, modes of learning, and assessment: Varies by course but includes independent research, independent writing, reading and evaluating primary literature, data analysis, and quantitative reasoning.
Independent reading or research course. A full course. Does not normally count toward the major.
Fall and spring semesters. The Department.
How to handle overenrollment: null
Students who enroll in this course will likely encounter and be expected to engage in the following intellectual skills, modes of learning, and assessment: Varies by course but includes independent research, independent writing, reading and evaluating primary literature, data analysis, and quantitative reasoning.
A study of the architecture and interactions of genetic systems. Advances in genomics are providing insights into a variety of important issues, from the structural limits of DNA-based inheritance to the discovery of novel infectious and genetic diseases. We will address how heritable information is organized in different groups of organisms. We will also cover a major challenge of this emerging field—the application of vast amounts of genetic data to understanding genomic integrity and regulation.
(Offered as BIOL 371 and BCBP 371) A study of the molecular mechanisms underlying the transmission and expression of genes. DNA replication and recombination, RNA synthesis and processing, and protein synthesis and modification will be examined. Both prokaryotic and eukaryotic systems will be analyzed, with an emphasis upon the regulation of gene expression. Application of modern molecular methods to biomedical and agricultural problems will also be considered. The laboratory component will focus upon recombinant DNA methodology.
(Offered as BIOL 371 and BCBP 371) A study of the molecular mechanisms underlying the transmission and expression of genes. DNA replication and recombination, RNA synthesis and processing, and protein synthesis and modification will be examined. Both prokaryotic and eukaryotic systems will be analyzed, with an emphasis upon the regulation of gene expression. Application of modern molecular methods to biomedical and agricultural problems will also be considered. The laboratory component will focus upon recombinant DNA methodology.
(Offered as BIOL 371 and BCBP 371) A study of the molecular mechanisms underlying the transmission and expression of genes. DNA replication and recombination, RNA synthesis and processing, and protein synthesis and modification will be examined. Both prokaryotic and eukaryotic systems will be analyzed, with an emphasis upon the regulation of gene expression. Application of modern molecular methods to biomedical and agricultural problems will also be considered. The laboratory component will focus upon recombinant DNA methodology.
Evolution is a powerful and central theme that unifies the life sciences. In this course, emphasis is placed on microevolutionary mechanisms of change, and their connection to large-scale macroevolutionary patterns and diversity. Through lectures and readings from the primary literature, we will study genetic drift and gene flow, natural selection and adaptation, molecular evolution, speciation, the evolution of sex and sexual selection, life history evolution, and inference and interpretation of evolutionary relationships.
Evolution is a powerful and central theme that unifies the life sciences. In this course, emphasis is placed on microevolutionary mechanisms of change, and their connection to large-scale macroevolutionary patterns and diversity. Through lectures and readings from the primary literature, we will study genetic drift and gene flow, natural selection and adaptation, molecular evolution, speciation, the evolution of sex and sexual selection, life history evolution, and inference and interpretation of evolutionary relationships.
