1 Enzymes – Part II Biochemistry I Lecture 2 2008 (J.S.) 2 Induced-fit model of enzyme-substrate binding: The enzyme changes shape on substrate binding. The active site forms a shape complementary to the substrate only after the substrate has been bound. The formation of an enzyme-substrate complex is the first step in enzymatic catalysis: 3 Catalytic mechanisms depend on the number of substrates. Monosubstrate (monomolecular) reactions are not very frequent: S P S + E ES•••transition state•••EP P + E Bisubstrate (bimolecular) reactions: SA + SB + E ESAB•••transition state•••EPAB PA + PB + E Multiple substrate reaction can be divided into two classes: Sequential displacement – in the mechanism, all substrates must bind to the enzyme before any product is released (ternary complex of the enzyme and both substrates forms). Double-displacement (ping-pong) reactions – one or more products are released before all substrates bind the enzyme (existence of a substituted enzyme intermediate, in which the enzyme is temporarily modified). 4 In the Cleland notation: Sequential reaction - type ordered - the substrates bind the enzyme in a defined sequence: - type random – the order of addition of substrates and release of products is random: Ping-pong reaction: + + + 5 The details of the catalytic mechanisms of enzymes will not be discussed in the lectures. A brief general comment: Decrease of the reaction free energy of activation ΔG‡ is caused by facilitating the formation of the transition state of the reactive intermediates in the active site of enzymes and specific preferential binding (stabilization) of it. Examples of different types of catalytic mechanisms: - Catalysis through proximity and orientation effects (strained reactants) - Covalent catalysis – formation of transitory covalent bonds between E and S - Acid-base catalysis – protonization of substrates or catalytic groups of E - Metal ion catalysis mediating redox reactions or shielding negative el. charges - Electrostatic catalysis (after excluding water from the active site by binding of substrate) The great catalytic efficiency arises from the simultaneous use of several of these catalytic mechanisms. 6 = ]S[ ∆ ∆ t –=v 1 ν ]P[ ∆ ∆ t 1 ν v = c – t Because , velocity is expressed in mol × l–1 × s–1 The fundamental terms in general reaction kinetics Kinetics studies the rates of chemical reactions. The term velocity (symbol v) is the reaction rate expressed in terms of change in the concentrations of reactants: For the simple reaction S → P, the velocity is defined as S – substrate, P – product, ν – reaction stoichiometric coefficients (if there are any) Factors affecting velocities of reactions: temperature, concentrations of reactants, catalysts or inhibitors. 7 Velocity depends on the concentrations of reactants This dependence is described in the velocity equation: For the reaction mA + nB → xC, v = k [A]m [B]n where k is the kinetic constant that includes the specific reaction features as well as the temperature term ( k = A × e–Ea I RT ). Due to decreasing concentrations of reactants, there must be always a gradual decrease of reaction velocity in closed systems till the reaction reaches the equilibrium. The sum of all exponents in velocity equations (m + n + ….) indicates the reaction order. The equation mentioned above is a (m+n)th -order reaction. 8 Progress curves (kinetic curves) The progress - the time course of a reaction is shown by a plot of the concentration of any of the substrates or products against time. The instantaneous velocity vx at any particular time tx is then given by the slope of the tangent to the curve at that time. For the first-order reactions [S]t = [S]0 e– k t or vt = v0 e– k t [S]0 – initial concentration of S, v0 – initial velocity, in the first moments of the reaction Example: Both curves hold for the reaction S → P. It is a first-order reaction according to the velocity equation v = k [S] . [S] t x tg α = d[S] / dt = vx α tx [P] t [S] t (equilibrium) At equilibrium the net reaction velocity is zero. 9 Kinetics of enzyme-catalysed reactions Let us consider an enzyme-catalysed transformation of substrate S to the product P: E + S ES E + P The overall velocity of the reaction depends on the substrate concentration [S] as well as on the enzyme concentration [E] Initial reaction velocities Initial velocities v0 measured in the short time period after the reaction has started are used preferentially in kinetics studies considering that – they are the highest under the given conditions (then they decrease), – they are not influenced by the small decrease of the substrate concentration, – the product concentration can be neglected (it is very low), and that is why – there is no need to think of the reverse reaction (it is insignificant). 10 [P] t [S1] [S2] [S3] [S4] v0 1 v0 2v0 3v0 4 From the obtained progress curves, the values of v0 should be estimated and plotted against the corresponding [S] to gain a part of an rectangular hyperbolic curve: At a constant enzyme concentration, the velocity v0 rises linearly as substrate concentration increases, and then begins to level till it reaches a limit value at high substrate concentrations. Dependence of initial velocity on substrate concentration [E] = const. A series of measurements of initial reaction velocity must be arranged at a constant enzyme concentration [E] and different substrate concentrations [S] (in the range of 2 - 3 orders of magnitude). 11 A plot of v0 against [S] is called a saturation curve or a Michaelis plot . The hyperbole is asymptotic to certain limit value on the v0 axis called maximal velocity Vmax for the given concentration [E]. The concentration of substrate which gives half the maximum velocity is the Michaelis constant Km (of the enzyme half-saturation). Realize the distinction between progress curves and saturation curves: A progress (kinetic) curve shows the time-progress of only one experiment, [S] = f(t). A saturation curve (Michaelis plot) is derived from the multiple experiments, v0 = f([S]). [S] V0 Vmax Vmax 2 v0 = Km 12 [S] + Km v0 = Vmax [S] The Michaelis- Menten equation describes the dependence of v0 on [S] and [E] in monosubstrate reactions. E + S ES E + P 1 2 (–2) –1 At initial velocity v0 in the reaction initial period, the net reaction does not depend on product concentration [P] and the reaction (–2) can be neglected. If the kinetic constant k1 > k2, the reaction 2 is decisive for the net reaction and the overall velocity of P appearance is v0 = k2 [ES] . When the enzyme is fully saturated by the substrate, then v0 = Vmax = k2 [E]tot . Leonar Michaelis and Maud Menten, 1913 Sometimes the reaction is cited in the form v0 = Vmax 1 + Km [S] [S] ( - 1 )Km = v0 Vmax By separating of Km from the equation we obtain the definition 13 E + S ES E + P 1 2 (–2) –1 Deduction of the Michaelis-Menten equation At initial velocity v0 in the reaction initial period, the net reaction does not depend on product concentration [P] and the reaction (–2) can be neglected. The Michaelis-Menten equation (simply Michaelis kinetics) is based on assumptions that - [S] » [E]tot and so the difference between [S] and ([S]tot - [S]ES) can be neglected, - the kinetic constant k1 > k2 (reaction 2 is decisive for the net reaction S → P i.e. the overall velocity of P formation is v0 = k2 [ES] ), - the reaction passes through a state with a steady concentration [ES]. Then velocity of ES formation v1 = k1 [S] ([E]tot - [ES]), velocity of ES breakdown (v2 + v–1) = (k2 + k–1) [ES]. These two velocities are equal in the supposed steady state, from that ([S] ([E]tot - [ES]) / [ES] = (k2 + k–1) / k1 = Km . After separation of [ES], multiplication of the obtained equation by k2 and by substitution v0 for k2[ES]tot and Vmax for k2[E]tot (because v0 shall reach up to Vmax if enzyme is completely saturated by the substrate) we get the Michaelis-Menten equation.. 14 At very low concentrations of the substrate there is the 1st order kinetics. If [S] « Km, then v0 = Vmax [S] + Km [S] ≈ [S] = k [S]1 Km Vmax If [S] = Km, then that defines the Michaelis constant Km If [S] » Km, then At [S] much higher than the value of Km it is the 0th order kinetics (e.g. at [S] = 10 Km velocity v0 equals 0.91 × Vmax). = Vmax [S] 2 [S] Vmax= 1 2 v0 = Vmax [S] +[S] [S] [S] [S] + Km ≈ [S] [S] = k [S]0 Vmax v0 = Vmax [S] V 0 Vmax Km The zero-order kinetics The 1st order kinetics In zero-order kinetics the velocity does not depend on substrate concentration [S], v = k [S]0 = k . At very high substrate concentrations, the enzyme is fully saturated by an substrate and in addition, there is a surplus of substrate. Then the reaction is of 0th order kinetics until the decrease of [S] is not sufficient to saturate all enzyme molecules fully. After that. the 0th kinetics transforms in the 1st order (or a higher order) kinetics. 15 Determination of Km and Vmax [S] V0 Vmax ? Vmax 2 v0 = Km × × × × × × × × point of intersection [S] V0 Vmax – Km × × × × × × × × Rough visual estimate of Vmax The plot of Eisenthal and Cornish-Bowden Michaelis equation v0 = Vmax [S] [S] + Km The reciprocal form of Michaelis equation (The equation of a line y = a x + b) 1 Km 1 1 [S]Vmax Vmaxv0 = + ×× × × ×× × × ×α tg α = Km Vmax –1/Km 1/Vmax The linear double reciprocal plot of Lineweaver-Burk 16 Significance of Km and Vmax The Michaelis constant Km ("the constant of half-saturation") is the concentration of substrate [S] which gives half the maximum velocity Vmax. The value of Km is independent of enzyme concentration and defines the substrate concentration range that an enzyme requires in order to work efficiently. Km is inversely related to the affinity of the enzyme for its substrate. If more substrates with similar structure exist, then the best natural substrate is one with the least value of Km. If there is a need to measure the catalytic activity of an enzyme in zeroorder kinetics reaction, the substrate concentration has to be at least several times higher than the Km value. 17 Km / μmol l–1 *) Take notice that there are different values of the Km for particular substrates! *) *) 18 Km [S] / mol l–1 v0 [E] Vmax [E]/2 [E]/4 Vmax is directly proportional to the enzyme concentration [E]. Km does not change at various concentrations [E]. The Michaelis plots at different enzyme concentrations: Dependence of initial velocity on enzyme concentration 19 Enzymes differ in efficiency to catalyze. Two quantities exist for comparing of the ability: Catalytic constant kcat The overall velocity of substrate conversion into products in a given reaction when the enzyme is completely saturated by the substrate is Vmax = kcat [E] ; then It denotes either the number of substrate molecules transformed in the reaction by one enzyme molecule per second – the turnover number, or the catalytic activity (moles of substrate transformed per second) of one mole of the enzyme – the molar activity (kat / mol). The numerical values of both quantities are the same. Catalytic efficiency kcat / Km takes into consideration Km that is inversely related to the enzyme affinity for its substrate. Vmax [E]kcat = 20 Examples of the turnover numbers of some enzymes Turnover number Enzyme ( s–1 ) 21 kcat / Km 22 kcat / Km 23 Assays of enzymes Assays of enzymes in a tissue or a body fluid by measuring the mass (mass concentrations in μg/l, μg/g tissue) or amount of substance (nmol/l, nmol/g) are rather exceptional. For that purpose, immunochemical methods are the most convenient.. Assays of enzyme catalytic activities The amount of an enzyme in a complex mixture is usually determined by measuring the velocity of the reaction catalysed by a given amount of the sample, making the assumption that this velocity is proportional to the amount of enzyme present. 24 1 μkat = 60 IU 1 IU = 16.6 nkat Catalytic activity of an enzyme simply "enzyme activity" means the velocity of the reaction which can be ascribed to the catalytic action of the enzyme. The SI unit of catalytic activity is katal – the activity that catalyses transformation of one mole of the substrate per one second 1 kat = 1 mol / s The older unit is still in use in certain countries, so-called international unit – the activity catalysing transformation of one micromole of the substrate per one minute. 1 IU = 1 μmol / min . Catalytic concentration is the catalytic activity estimated in certain volume of a liquid sample (usual units μkat / l, nkat / l). Specific activity informs of the activity of usually 1 mg of proteins present in solid samples. 25 Methods for estimation of enzyme catalytic activities The common prerequisites: nearly optimal temperature and pH value, presence of necessary cofactors, absence of inhibitory factors. The zero-order kinetics is preferred (high substrate concentrations).. 1 The constant time method Reactions proceed for a fixed time, then are stopped by inactivating the enzyme, and the concentration of a substrate (or product) are measured. The average velocity is calculated. 2 The kinetic method Changes in substrate (or product) concentrations are measured continually in the course of the reaction, e.g. by spectrophotometers. If only the 1st order reaction can be arranged, kinetic methods are preferred. It is necessary to calculate the value of the kinetic constant k, from which the initial velocity v0 (that is directly proportional to [E]) can be derived: k = ln ([S]t1/ [S]t2) / (t2 – t1) 26 Irreversible inhibition Irreversible inhibitors are usually compounds not of biological origin, which bind onto an enzyme mostly covalently and make substrate binding impossible. Some of them called "active-site directed inhibitors" are used in experimental studies of enzymes because they permit to map the active sites (affinity labels structurally similar to the substrate, other group-specific reagents). Heavy metal ions bind and inhibit irreversibly enzymes during isolation. Mechanism-based inhibitors (suicide inhibitors) are recognized as substrates, initially processed, but catalysis generates a reactive intermediate that inactivates the enzyme (e.g. α1-antitrypsin, penicillin, aspirin). Inhibitors of enzyme activity Inhibitors are substances which reduce enzyme activities. There are two major classes – irreversible and reversible inhibitors. 27 Irreversible inhibition – examples: Iodoacetamide (specific reaction with –SH groups) can be used to map the active sites. Diisopropyl fluorophosphate (and similar pesticides and nerve gases) inhibits acetylcholine esterase by phosphorylation of a crucial serine residue. 28 Reversible inhibition In contrast with irreversible inhibitors, reversible inhibitors bind to the enzyme loosely and can rapidly dissociate from the enzyme-inhibitor complex. These inhibitors are classified as competitive, non-competitive and uncompetitive. Competitive inhibitors resemble the substrates and bind to the active sites, but the complex is non-reactive. They compete with normal substrates for the active sites. 29 Competitive inhibitors increase the value of Km without any change in Vmax The Vmax can be reached even in the presence of inhibitor, but at much higher concentrations of [S] that have to overcome the competing inhibitor concentration. 30 Malonate competitively inhibit succinate dehydrogenase Examples: Methotrexate Tetrahydrofolate Methotrexate competitively inhibits active sites for tetrahydrofolate of the dihydrofolate reductase in the synthesis of purine and pyrimidine bases of nucleic acids. It is used to treat cancer. Malonate Succinate COO– CH2 CH2 COO– COO– CH2 COO– 31 Non-competitive inhibition Non-competitive inhibitors bind to both free enzyme and enzymesubstrate complex, but in contrast to competitive inhibitors, not in the active site (the structures of inhibitors is distinct from the substrates. Uncompetitive inhibitors bind only to the enzyme-substrate complex decrease both Km and Vmax. Non-competitive inhibition cannot be overcome by increasing the substrate concentration. The non-inhibited remaining molecules of the enzyme behave like a more diluted solution of the enzyme. 32 Non-competitive inhibitors decrease Vmax without any change in Km 33 Cooperative effect, allosteric enzymes, allosteric effectors Not all enzymes obey the Michaelis kinetics (M.-M. equation). Regulatory enzymes are frequently oligomers that consist of several subunits (protomers). Those enzymes show saturation curves which deviate from Michaelis (hyperbolic) behaviour – saturation curves exhibit a sigmoid dependence of v0 on [S]. [S] v0 Vmax 34 Cooperative effect In these allosteric enzymes (and also in some not catalysing proteins, e.g. haemoglobin) the binding of substrate (oxygen to haemoglobin, resp.) to one active site can affect the properties of other active sites in the same oligomeric molecule. The binding of substrate becomes positively cooperative, when the binding of substrate to one active site facilitates substrate binding to the other sites on other subunits due to induced changes in conformation. Allosteric effectors In addition, the activity of such enzymes may be altered by regulatory molecules that are allosteric to the substrate (having their structure distinct from the substrate) and bind reversibly to specific sites other than the active sites – to the allosteric sites. 35 Allosteric inhibition Allosteric activation, steep increase in affinity for substrate [S] v0 The binding of an allosteric effector may either stimulate or inhibit the enzyme activity.