Margaret A. Daugherty Fall 2003

Enzymes & Kinetics IV Regulation and Allostery ENZYME-SUBSTRATE INTERACTIONS THE LOCK & KEY MODEL Margaret A. Daugherty Fall 2003 A perfect match between enzyme and substrate can explain enzyme specificity does not explain enzymatic catalysis ENZYME-SUBSTRATE INTERACTIONS THE INDUCED FIT MODEL GENERAL THOUGHTS ON REGULATION KEY FEATURES: ENZYME STRUCTURE CHANGES IN PRESENCE OF SUBSTRATE --- BRINGS CATALYTIC GROUPS INTO CORRECT POSITION TO DO CHEMISTRY ---SUBSTRATE IS FORCED INTO TRANSITION STATE CONFORMATION 1). Enzymes slow down as product accumulates 2). Availability of substrates (and cofactors) determines reaction rate 3). Enzymes are controlled at the level of DNA 4). Many enzymes are regulated via reversible covalent modification 5). Many enzymes regulated via non-covalent interactions with small molecules

REGULATION OF ENZYME ACTIVITY? How does the cell know when enough is enough? First step in glycolysis: hexokinase REGULATION OF ENZYME ACTIVITY? Problem: Most metabolic pathways involve many enzymes that act sequentially E1 E2 E3 E4 E5 A B C D threonine dehydratase hexokinase threonine leucine Substrate-level control Feedback inhibition: the end product of the pathway binds to, and inhibits a regulatory enzyme on the pathway. FEEDBACK CONTROL: INHIBITION & ACTIVATION The same substrate can act as an inhibitor of one pathway, and an activator of a second pathway. + Increase in G can inhibit formation of D, activate formation of K. Similarly N can inhibit formation of K and activate formation of D. REGULATORY ENZYMES: THREE GENERAL CLASSES Regulatory enzymes: enzymes that control key metabolic points in a pathway. Usually located at the first committed step to a pathway. 1). Enzymes regulated via reversible covalent modification; 2). Enzymes regulated via proteolytic cleavage. 3). Other types: isozymes, modulator proteins 4). Allosteric enzymes

ENZYMES REGULATED VIA COVALENT MODIFICATION 30-50% Modification AA residue ENZYMES REGULATED VIA COVALENT MODIFICATION Glycogen synthase: multiple phosphorylation sites, that can act independently, or in concert. (p) of any or all of these sites moderately affects activity (p) of all sites dramatically affects activity (p) of site 5 does not affect activity ENZYMES REGULATED VIA PROTEOLYSIS: Proteases in protein digestion ACTIVATION OF INTESTINAL PROTEASES Secretions from exocrine pancreas play role HCO 3- : Neutralizes stomach acidity Zymogens of proteases: Proteases secreted in inactive form Trypsinogen Chymotrypsinogen Prolelastase Procarboxypeptidases Cleaved to active form NOTE: These all work on one another, so they all must be activated in a short time span! Regulation is key in everything!

ENZYMES REGULATED VIA PROTEOLYSIS: THE BLOOD CLOTTING CASCADE ISOZYMES: LACTATE DEHYDROGENASE Isomer: one or more quaternary forms; differ in ratios of catalytic subunits that make up the quaternary structure. MODULATOR PROTEINS: Influence activity of an enzyme camp regulatory protein: dimer of C (catalytic subunit) and R (regulatory subunit). Dissociation of R allows activation of C ALLOSTERIC ENZYMES: KEY FACTS Multi-subunit proteins that can have different quaternary structures (T - low affinity; R - high affinity) Situated at key steps in metabolic pathways (1rst step) Enzymes that are regulated by the binding of an effector molecule, i.e., a signal molecule that can influence the action of the enzyme. Effectors bind at an allosteric site. (Site that is not the active site) Modulator proteins interact directly with an enzyme Can either upregulate or downregulate activity Allosteric effectors can be; Postive effectors - increase enzyme rate Negative effectors - decrease enzyme rate Enzymes can posses both positive and negative regulatory sites

Allosteric Enzymes: Substrate Binding Symmetry Model: MWC Monod - Wyman - Changeux Model State 1: unligated state In R: All subunits have R conformation In T: All subunits have T conformation Sigmoidal curve - homo-allostery (cooperative binding) R: conformation is high-affinity; favors binding Lineweaver-Burke plot is non-linear T: conformation is low-affinity; disfavors binding Symmetry Model: MWC Monod - Wyman - Changeux Model Two types of equilibrium constants: L and K T /K R R <--> T ES <--> E + S State 1: unligated state c = K R /K T equilibrium constant for 4 o switch K T and K R : substrate dissociation constants K T = [E][S]/[ES] Model assumes K T >> K R ;This means R has greater affinity for substrate - doesn t disociate as easily Increasing L favors T; Harder to switch; More sigmoidal A larger c means that substrate dissociates less from R than T (R has higher affinity); more hyperbolic

Symmetry Model: MWC Monod - Wyman - Changeux Model Symmetry Model: MWC Monod - Wyman - Changeux Model State 2: Ligated state S= substrate binding site F = effector binding site Heterotropic effectors: small molecules that influence the binding of substrate; work by binding at a site other than the substrate binding site; Binding of one substrate: 4 o shifts to favor R R is the high affinity structure All binding sites now high affinity Makes binding of next ligand easier POSITIVE COOPERATIVITY! Homotropic: that like molecules influence binding of like molecules Effector binding site Positive effectors: molecules that favor the high affinity R conformation Negative effectors: molecules that favor the low affinity T conformation Effect of positive & negative effectors on binding curves K vs. V Systems V system: Vmax changes +/- allosteric effectors K 0.5 is unchanged K system: The K 0.5 changes +/- allosteric effectors; Vmax is unchanged T and R have same affinity for substrate; Differ in catalytic ability Differ in affinities for activator and inhibitor T and R have different affinities for substrate, activator and inhibitor

An example: Glycogen phosphorylase Role: breaks glycogen down to glucose Where: liver and muscle When: Times of energy need (mild starvation, exercise) 2 3 1 4 Dimer: 2 copies of each site 1). Active site (PLP); Pi 2). Glycogen storage site 3). Allosteric effector site 4). Regulatory site Control of GP v vs. S curves for glycogen phosphorylase 1). Response to fuel needs: High fuel state: Enzyme off high ATP high Glucose high G6P Low fuel state: Enzyme on high AMP low ATP 2). Covalent modification Stress situation! Molecule on! Binding of substrate, Pi, shows positive homotropic cooperativity Binding of activator favors high affinity R quaternary structure without altering Vmax Binding of inhibitor, ATP, favors low affinity T quaternary structure, but doesn t affect Vmax.

HORMONAL ACTIVATION OF GLYCOGEN PHOSPHORYLASE GP needs to be phosphorylated (Ser 14) to activate it adrenaline The difference between phosphorylase b and phosphorylase a is a dramatic rearrangement of the N-terminal domain. Change from intrasubunit contacts to intersubunit contacts. flight or fight response Structure of AMP-activated phosphorylase b is almost identical to phosphorylationactivated phosphorylase a. Review 1). The induced fit model accounts for enzymatic catalysis better than the lock and key model. 2). Regulation of enzymes occurs on many levels: Level of DNA synthesis: enzyme is made according to need substrate level control: product directly inhibits enzyme Feedback inhibition: endproduct of pathway inhibits enzyme Reversible covalent modification Cleavage of zymogens Isozymes, modulator proteins Allosteric proteins 3). Allosteric enzymes have two quaternary forms: A low affinity T form with it s own substrate binding constant, K T A high affinity R form with its own substrate binding constant, K R 4). Allosteric enzymes are regulated by effector molecules, either positively or negatively. 5). Velocity vs. Substrate binding curves are sigmoidal. Negative effectors favor more sigmoidicity; positive effectors favor more hyperbolic curves.

Review 6). Substrate binding to allosteric enzymes is cooperative; binding of one molecule enhances the binding of subsequent molecules. This is a consequence of the T to R quaternary transition. 7). Allosteric systems can be classified as V systems or K systems 8). Glycogen phosphorylase is a paradigm for understanding allosteric enzymes. 9). Glycogen phosphorylase has two forms: phosphorylase b: mostly inactive due to high concentrations of glucose and ATP (negative heterotropic effectors). Activated when the cell is in a state of energy need (low ATP, hence high AMP). AMP is a positive heterotropic effector phosphorylase a: active form. Covalent phosphorylation due to stress or exercise. In response to an enzyme cascade initiated by an extracellular hormone signal. --The structural basis for activation of both phosphorylase b and phosphorylase a appears to be the same!