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Transcript
Ch. 5 • Reversible interactions • Simple binding (myoglobin) – Constant affinity (Kd) • Cooperative binding – Allostery Ch. 5 • Cooperativity – Multiple binding sites – Two states: high affinity (R for Hb) & low (T) – Different factors influence the R↔T equil • Oxygen: allosteric activator (positive) • BPG, H+, etc.: allosteric inhibitors Chapter 6 3/16, 19, 21, 26, 27, 28 • Catalysis in general – Activation energy (EA or DG‡ ) is a kinetic barrier to reaction – Enzymes lower this barrier (don’t change DG or the equilibrium constant) • Create a new reaction pathway with better DH or (and) better DS Chapter 6 • General types of catalysis (how do enzymes change the reaction pathway?) – General acid/base • Donate/accept protons from a substrate (substrates) – Many times water (activation of water) – Covalent catalysis – Metal ion catalysis • Stabilize (slightly) negatively charged intermediates (ie. lower H of transition state) • Oxidation/reduction Chapter 6 • Quantification of catalysis – Km – Vmax/kcat – kcat/Vmax – Ki • Michaelis-Menten kinetics • Lineweaver-Burk plots Chapter 6 • Enzyme regulation – Why? – How? Ch.7 4/13, 16 • Carbohydrates (sugars) – Polyhydroxy + ketone OR aldehyde – Named –ose – Typically a ring structure • -OH attack on carbonyl carbon creates a hemiacetal or hemiketal • Makes an anomeric carbon: new stereocenter – Capable of mutarotation Ch.7 • Cyclic sugars: chair form, not flat • Hemiacetal/ketal can be attacked by another hydroxyl group: full ace-/ke-tal Often another sugar: glycosidic bond/polymerization Disaccharide/polysaccharides Ch.7 • Sugars as energy sources – Highly polymerized, starch/glycogen • Structural sugars – Cellulose, chitin • Sugar/peptide conjugates – Peptido/proteoglycans • Mainly sugar: biological activity modified by protein attachment – Glycoproteins • Mainly proteins: bio activity modified by sugars Ch.8 4/17, 18 • Nucleotides/nucleic acids – Different functions • • • • • ATP, etc Signal transduction (cAMP, etc) Coenzymes (NADH, etc) Information transfer, storage Components of proteins (RNA-containing proteins) • Structure of nucleotides • Structure of nuc acids – Base pairing: weak interactions Hbonding/stacking (vdW) – Antiparallel – “Melting point”: determined by? – RNA: ss, but still base pairs • Secondary structure Ch.8 • Consequences of covalent modification of DNA (RNA?): mutation – Base deamination – Depurination (removal of the base) – Dimerization of pyrimidines – Oxidative damage • Other functions of nucleotides Ch.10 & 11 4/23, 24, 25, 30 • Fatty acids – Melting points? – Modification of the carboxylic acid • Lipid structure, esp glycophospholipids • Fluid mosaic model • Roles of lipids (why different types/dynamics?) • • • • Membrane fluidity Activity of integral membrane proteins Attraction of peripheral memb proteins Precursors to other molecules: vitamins, signaling molecules, hormones Ch. 10&11 • Cholesterol – Membrane component, precursor to steroids • Fat-soluble vitamins – D (derived from cholesterol: regulates Ca2+ uptake, etc) – A (retinol; visual pigment, regulates gene expression (skin plasticity)) – E (antioxidant, protects membrane lipids from free radical damage) – K (coenzyme, processing of blood clotting proteins) Ch. 10&11 • Membranes – Lipid bilayer: fluid mosaic – Lateral diffusion is easy (in general) – Transverse diffusion (flip-flop) is slow (sans catalysis) – Integral/peripheral membrane proteins – Membrane asymmetry/modification of fluidity • Inner/outer leaflets different lipids • Lipid rafts: keep multiprotein complexes together • Intracellular ‘anchoring’ of memb proteins Ch.10&11 • Concept of hydropathy plots to predict integral membrane proteins • Membrane fusion – Regulated exocytosis • Problems? • Solute movement through membranes – Diffusion • Simple vs. facilitated – Active transport Ch.13 • Bioenergetics – DG stuff – ATP as a good energy storage molecule • Other energy storage molecules • Creation of ATP – Slow (ie. respiration) – Fast (eg. creatine kinase) • Use of ATP (not just ‘parallel’ hydrolysis) – Redox • Terminology (oxidation/reduction/oxidizing agt/etc) • Pos DE ~ neg DG Aerobic respiration of glucose • Glycolysis: – Start with glucose (6 carbon) – Generate some ATP, some NADH, pyruvate (2 x 3 carbon) – Regeneration of NAD+ in absence of O2 (fermentation) • TCA cycle – Start with pyruvate – Generate acetate (acetyl CoA) – Generate CO2 and reduced NADH and FADH2 • Electron transport – Start with NADH/FADH2 – Generate electrochemical H+ gradient • Oxidative phosphorylation – Start with H+ gradient and O2 (and ADP + Pi) – Generate ATP and H2O
