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1 - 5 of 5 results for: BIO42

BIO 42: Cell Biology and Animal Physiology

Cell structure and function; principles of animal physiology (immunology, renal, cardiovascular, sensory, motor physiology, and endocrinology); neurobiology from cellular basis to neural regulation of physiology. Prerequisites: CHEM 31X (or 31A,B), 33. Recommended: BIO 41; CHEM 35; MATH 19, 20, 21 or 41, 42.
Terms: Win | Units: 5 | UG Reqs: GER: DB-NatSci, WAY-SMA

BIO 42A: Bio Solve-It

Students enrolled in Bio42 lecture and regular discussion sections attend two additional 80 min sections per week. The objective of the course is to help students to solidify basic concepts, identify areas to work on, and apply core concepts learned that week in Bio42 lecture and section. Space is limited, by application only. Co-Requisite: Bio 42.
Terms: Win | Units: 1

BIO 156: Epigenetics (BIO 256)

Epigenetics is the process by which phenotypes not determined by the DNA sequence are stably inherited in successive cell divisions. Course will cover the molecular mechanisms governing epigenetics, ranging from the discovery of epigenetic phenomena to present-day studies on the role of chromatin, DNA methylation, and RNA in regulating epigenetics processes. Topics include: position effect gene expression, genome regulation, gene silencing & heterochromatin, histone code, DNA methylation & imprinting, epigenetics & disease, and epigenetic-based therapeutics. Prerequisite: BIO41 and BIO42 or consent of instructor, advanced biology course such as Bio104
Last offered: Spring 2015

BIO 256: Epigenetics (BIO 156)

Epigenetics is the process by which phenotypes not determined by the DNA sequence are stably inherited in successive cell divisions. Course will cover the molecular mechanisms governing epigenetics, ranging from the discovery of epigenetic phenomena to present-day studies on the role of chromatin, DNA methylation, and RNA in regulating epigenetics processes. Topics include: position effect gene expression, genome regulation, gene silencing & heterochromatin, histone code, DNA methylation & imprinting, epigenetics & disease, and epigenetic-based therapeutics. Prerequisite: BIO41 and BIO42 or consent of instructor, advanced biology course such as Bio104
Last offered: Spring 2015

BIOE 244: Advanced Frameworks and Approaches for Engineering Integrated Genetic Systems

Concepts and techniques for the design and implementation of engineered genetic systems. Topics covered include the quantitative exploration of tools that support (a) molecular component engineering, (b) abstraction and composition of functional genetic devices, (c) use of control and dynamical systems theory in device and systems design, (d) treatment of molecular "noise", (e) integration of DNA-encoded programs within cellular chassis, (f) designing for evolution, and (g) the use of standards in measurement, genetic layout architecture, and data exchange. Prerequisites: CME104, CME106, CHEM 33, BIO41, BIO42, BIOE41, BIOE42, and BIOE44 (or equivalents), or permission of the instructors.
Terms: Spr | Units: 4
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