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Transcript
Review For Final I Should I take the final? • Can’t hurt you • Calculate your average and determine what you need to change your grade Calculating what you need • multiply each exam score by 0.4 • add the three numbers together • subtract this sum from the average you want to get • divide the difference by 40 for the percent score you need example • • • • test scores: 35, 29, 38 0.4 * (35+29+38) = 40.8 average right now = 40.8/60 = 68%=D this person wants to get a C or 70% in the class so 70 – 40.8 = 29.2 • 29.2/40 = 0.73 • this person need a 73 % on the final How should you study for the final? • Study the old study guides • Study the three exams • Study the 2 review lectures 3-dimensional model of plasma membrane Phosphatidylcholine Non-polar molecule dissolved in water Arrangement of water molecules strongly disturbed Effect of cis double bonds on membranes Cholesterol Cholesterol in lipid bilayer Lipid raft with specific membrane proteins Distribution of phospholipids and glycolipids in the lipid bilayer of human red blood cells Some glycolipid molecules Hydrophobic amino acids in green and yellow Membrane Proteins in Human Red Blood Cells Most Membrane Proteins have Structural Functions Molecule movement across lipid bilayer without proteins Passive vs. Active Transport Three Ways of Driving Active Transport Electrochemical gradient vs. membrane potential Can work additively or against each other Mechanism of Na+ - glucose carrier Binding of Na+ and glucose is cooperative Selectivity of a K+ channel Gating of Ion Channels Transcellular transport of glucose The Na+ - K+ pump is an ATPase Resting Chemical Synapse Active Chemical Synapse Ion Channels at Neuromuscular Junction Topological relationships between compartments of a eukaryotic cell Roadmap of protein traffic inside cell Two ways in which a sorting signal can be built into a protein Nuclear pore complexes Protein import by mitochondria Signal Peptide is cleaved and the protein folds inside the ER lumen Protein glycosylation in the rough ER Phospholipid synthesis occurs in the cytosolic leaflet of ER membrane Scramblase, a phospholipid translocator equilibrates phospholipids between the two leaflets Flippases maintain highly asymmetric composition of the plasma membrane Endocytic and secretory pathways red = secretory green = endocytic blue = recycling Different coats are used for different transport steps in the cell Assembly and disassembly of clathrin coat SNARE proteins guide vesicular transport Vesicular tubular clusters move along microtubules to carry proteins from ER to Golgi apparatus 3-dimensional model of the Golgi Apparatus Oligosaccharide chains are processed in the Golgi complex common core high-mannose Lysosome interior is different from cytosol
