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Transcript
Advanced Cell Biology BI735 Syllabus Fall 2008 Overview Complex organisms are comprised of hundreds of distinct cell types that carry out different functions required to keep the organism alive. To investigate and understand these functions, cell biologists have developed fascinating experimental approaches, often combining microscopic, biochemical and molecular techniques. As graduate students interested in Cell and Molecular Biology, it is imperative that you have a fundamental understanding of these experimental approaches and their limitations. In this course, you will read original research papers that have led to our current understanding of the cytoskeleton, nuclear import/export, protein quality control, membrane trafficking and more. In addition, you will read current research papers that describe the latest innovations in microscopic and molecular analysis of cellular function. As a final project, you will work in a small group (~3 students) to cover an aspect of Cell Biology that was not covered extensively by either of the professors' lectures. These groups will give the last three lectures of the course and the material from these presentations will be included on the final exam. This should be a fun experience for those interested in research, and it should be viewed as an opportunity to develop the communication skills required for expressing your own scientific ideas in the future. Professors Sid Tamm Jim Deshler Rm 116, 2 Cummington (BSC) (Office Hours-Any Time); email [email protected] Rm 603, 24 Cummington, (Office Hour-By Appointment); email [email protected] Prerequisites BI203 (Cell Biology), BI552 (Molecular Biology I) and BI721 (Graduate Biochemistry). BI735 Web Page Much of the course information, including the syllabus, descriptions of assignments, reading lists, and reading material are in the form of .PDF files will be available on the web site. The easiest way to access the web site is to go to http://courseinfo.bu.edu and type BI735 (no spaces) in the search box. You will need your BU login name and kerberos password to login. Click on the "Course Information" and "Course Document" buttons to find general and lecture related information, respectively. Time and Place Lectures are held Tuesdays and Thursdays 11:00 am - 12:30 pm in SCI 111. Grading 30% Midterm; 30% Final; 20% Paper; 10% Oral Presentation; 10% Class Participation. Readings Materials Text: Molecular Cell Biology, Alberts et al., 2007, the Fifth Edition, Garland Science, is required. Primary Literature: In addition to a text, reading lists will be handed out containing various journal articles pertinent to lecture material. These articles will be accessible either via the course web site as a PDF file, or in the Sci/Eng Library on reserve. Lecture 1--ST 2--ST 3--ST 4--ST 5--ST 6--ST 7--ST 8--ST 9--ST September 2 Organization and Evolution of Eukaryotic Cells 4 Optical Microscopy and Video-enhancement 9 Fluorescence Microscopy: Types and Modes 11 Luminescent and Fluorescent Probes 16 Electron Microscopy 18 Calcium signaling 23 Cytoskeleton Dynamics and Interactions 25 Motor Proteins 30 Microtubule and Centrin-based Motile Systems October 10--ST 2 Cell Adhesion and Migration 11--ST 7 Regulation of Actin Assembly and Disassembly 9 MIDTERM EXAM 14 Holiday (Columbus Day; Substitute Monday 10/13 classes) 12--JD 16 Sub-cellular Fractionation and Characterization of Organelles 13--JD 21 Nuclear Structure and Dynamics 14--JD 23 Nuclear Import/Export 15--JD 28 Secretory Pathway 16--JD 30 Protein Translocation November 17-4 Guest Lecture 18--JD 6 Vesicle Trafficking 11 Holiday (Veteran’s Day) 19--JD 13 Vesicle Budding 20--JD 18 SNARE Hypothesis 21--JD 20 Protein Quality Control 22--JD 25 Regulation by Proteolysis and Nerve Cells 27 Thanksgiving Holiday Note: Deshler’s lectures will be December consolidated into four 3-hour lectures on the following Fridays from 9:00am-12:00pm: 23--JD 2 Protein Targeting to Mitochondria Oct. 24, Oct. 31, Nov. 7, Nov 14. 23 4 Student Seminar 24 9 Student Seminar 25 11 Student Seminar 19 FINAL EXAM 9:00-11:00—Friday