Up to all Biochemistry & Molecular Biophysics Courses for 2021-22 Show Filters

Biochemistry & Molecular Biophysics (BMB) Undergraduate Courses (2021-22)

Bi/BE/BMB 115. Viruses and Applications to Biological Systems. 9 units (3-2-4): third term. Learn about viruses as fascinating biological machines, focusing on naturally-occurring and evolved variants, in silico viral vector engineering, and computational methods that include structure visualization and machine learning. This course will introduce the fundamentals in the chemistry and biology of viruses, emphasizing their engineerable properties for use in basic research and translational applications. Topics include: viruses by the numbers, mammalian and non-mammalian (plant, bacteria) viruses, enveloped vs. non-enveloped viruses, host-virus interactions, viral life cycles (replication vs. dormancy), immune responses to viruses, zoonosis, diverse mechanisms of entry and replication, the application of viruses as gene-delivery vehicles (with a focus on adeno-associated viruses or AAVs, lentiviruses, and rabies), and how to engineer viral properties for applications in basic research and gene therapy. The lectures will be complemented by short lab exercises in AAV preparation, bioinformatics and machine learning, and structure visualization. Given in alternate years; offered 2021-22. Instructors: Bjorkman, Gradinaru, Van Valen.
Ch/BMB 129. Introduction to Biophotonics. 9 units (3-0-6): first term. Prerequisites: Ch 21 abc and Ch 125 recommended. This course will cover basic optics and introduce modern optical spectroscopy principles and microscopy techniques. Topics include molecular spectroscopy, linear and nonlinear florescence microscopy, Raman spectroscopy, coherent microscopy, single-molecule spectroscopy, and super-resolution imaging. Instructor: Wei.
BMB/Bi/Ch 170. Biochemistry and Biophysics of Macromolecules and Molecular Assemblies. 9 units (3- 0-6): first term. Prerequisites: Ch/Bi 110. Detailed analysis of the structures of the four classes of biological molecules and the forces that shape them. Introduction to molecular biological and visualization techniques. Not offered 2021-2022.
BMB/Bi/Ch 173. Biophysical/Structural Methods. 9 units (3-0-6): second term. Basic principles of modern biophysical and structural methods used to interrogate macromolecules from the atomic to cellular levels, including light and electron microscopy, X-ray crystallography, NMR spectroscopy, single molecule techniques, circular dichroism, surface plasmon resonance, mass spectrometry, and molecular dynamics and systems biological simulations. Not offered 2020-21. Instructors: Jensen, and other guest lecturers.
BMB/Bi/Ch 174. Advanced Topics in Biochemistry and Molecular Biophysics. 6 units (3-0-3): first term. Prerequisites: Ch/Bi 110 or equivalent. Discussion of research fields in biochemistry and molecular biophysics at Caltech. Development of skills in literature analysis and information synthesis. Instructors: Chong, Semlow, and guest lecturers.
BMB/Ch 178. Macromolecular Function: kinetics, energetics, and mechanisms. 9 units (3-0-6): first term. Prerequisites: Ch/Bi 110 or equivalent. Discussion of the energetic principles and molecular mechanisms that underlie enzyme's catalytic proficiency and exquisite specificity. Principles of allostery, selectivity, and enzyme evolution. Practical kinetics and their application to more complex biological systems, including steady-state and pre-steadystate kinetics, kinetic simulations, and kinetics at single molecule resolution. Instructor: Shan.
Bi/BMB 189. The Cell Cycle. 6 units (2-0-4): third term. Prerequisites: Bi 8 and Bi 9. The course covers the mechanisms by which eukaryotic cells control their duplication in a properly regulated manner. A large emphasis will be placed on the controls that cells employ to replicate and segregate their chromosomes with the necessary precision. In addition, the course will examine the mechanisms by which cells detect and rectify damaged DNA throughout the cell cycle. These various processes, collectively known as checkpoint-regulatory mechanisms, lie at the heart of how organisms maintain genomic integrity throughout their lifetimes. These pathways are essential for the prevention of cancer, birth defects, and other maladies. As part of the course, students will give presentations on key publications in the field, including both classic papers and newer papers that employ cutting-edge technologies. Instructor: Dunphy.

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