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Welcome to BISC 220 Cell Physiology Lab. Lab Instructor: Jennifer Hood-DeGrenier Office: SC 376A, x3313 Research Lab: SC 311, x3387 Email : jhooddeg@wellesley.edu Office Hours: Tues. 1:30-2:30 pm Thurs. 9:30-10:30 am Or e-mail to schedule an appointment.
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Welcome toBISC 220 Cell Physiology Lab Lab Instructor: Jennifer Hood-DeGrenier Office: SC 376A, x3313 Research Lab: SC 311, x3387 Email: jhooddeg@wellesley.edu Office Hours: Tues. 1:30-2:30 pm Thurs. 9:30-10:30 am Or e-mail to schedule an appointment
The Four Strands of Modern Cell Biology • Cytology: observation of cells by microscopy • Biochemistry: reductionist approach; in vitro study of biological molecules • Genetics: study of the effect of heritable information (DNA) on cell behavior/attributes; use of mutants to study cellular processes • Bioinformatics: application of computer algorithms to the analysis of large databases of biological information (genomics/proteomics)
BISC 220 Lab Overview • Series1 (Biochemistry) • Protein purification & enzyme kinetics using the enzyme b-galactosidase • Molecular modeling & database search • Recombinant protein induction & purification by affinity chromatography • Quantitative & qualitative assessment of purification success (gel electrophoresis) • Quantitative enzyme kinetics assays, including determination of the effect of an inhibitor • Series 2 (Genetics) • Analysis of the secretory pathway in budding yeast • Genetic assay to identify/characterize mutants defective in secretion • Western Blot to assess location of secretion defect • Series 3 (Cytology) • Tissue culture & the cytoskeleton • Learning cell culture techniques • Determining the effect of varying concentrations of a drug on the actin cytoskeleton & cell viability by fluorescence microscopy & flow cytometry
Lab Grading • Series 1 • Homework assignments (3) 35 • Lab report 40 • Series 2 • Homework assignment (1) 15 • Lab report 45 • Series 3 • Group Presentation 25 • Partial Lab report 35 • “P” points—Participation & Preparation 5 TOTAL: 200
Lab 1 • Induction of b-galactosidase (b- gal) expression in E. coli • RasMol • Investigation of the structure of -gal • ClustalW • Identification of amino acid residues conserved among b-gal proteins from different species Next week: purification of b-gal for study of its enzymatic properties
b-galactosidase: our enzyme of choice • Our b-gal is the Escherichia coli (E. coli) version Lactose Glucose+ Galactose Beta-galactosidase
How is b-gal expression normally regulated? lac operon
lac promoter T7 polymerase lacO lac repressor IPTG (resembles natural inducer of lac operon) Our system: how to make lots of b-gal! I. E. coli BL21(DE3): genetically engineered to express T7 RNA polymerase in the presence of IPTG A two-part process: IPTG binds lac repressor, prevents it from interfering with the lac promoter and turns on T7 Pol expression
II. pET-14 = plasmid in this E. coli strain T7 promoter lacZ encodes -gal with 6 histidines (His) added as a tail (affinity tag) 6xHis Expression of T7 polymerase causes expression of large amounts of 6xHis-b-gal. (The 6xHis tag will be used in the purification process.)
Protocol:Things to Remember • Think about aseptic technique (avoid contaminating your culture!) • Make flow chart of procedure and record all results in lab notebook • Do not discard anything contaminated with bacteria in sink—put growth medium in waste container or back in flask (must be treated with bleach) • Give labeled cell pellets to instructor for freezing: • Pre-IPTG induction (small aliquot in tube) • After IPTG induction (small aliquot in tube) • After IPTG (remainder in centrifuge bottle)
While your bacteria are making lots of 6xHis--gal… • Calibrate micropipets • Look at CD animation of pdb file • Follow RasMol tutorial in Appendix 1 Lab 1 (groups of 2) • Follow ClustalW instructions in Appendix 2 Lab 1 (same groups as RasMol)
A quick review of protein structure • Levels of structure: primary, secondary, tertiary & quaternary • Secondary structure elements: a-helices & b-sheets • R-group interactions • Salt bridges (ionic interactions), Hydrogen bonds, van der Waals forces, hydrophobic interactions, disulfide bonds • Use of X-ray crystallography to “solve” protein structures (important for determining enzyme mechanisms, designing drugs, engineering mutations that alter protein function)
Interactions that contribute to tertiary & quaternary structure
X-ray crystallography as a means for determining a protein’s structure at the atomic level
Homework • Do individually • Due next lab; 10 points • Create a figure with a correctly formatted legend from your saved RasMol picture of the active site of b-gal. • Include a paragraph (up to 1 page) describing what you learned about the active site. Try to relate the ClustalW analysis to the structural analysis. • May consult references listed at end of HW assignment in lab manual.