Binding Energy and Enzymatic Catalysis

Binding Energy and Enzymatic Catalysis David E. Hansen Amherst College. Amherst. MA 01002 Ronald T. Raines University of Wisconsin, Madison. WI 53706 ...
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Binding Energy and Enzymatic Catalysis David E. Hansen Amherst College. Amherst. MA 01002 Ronald T. Raines University of Wisconsin, Madison. WI 53706

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For nearlv 100 vears..the extraordinarv catalvtic . Dower . of enzymes has fascinated b~ochemlsts(I). In a recent article in t h ~Journal. s 12) analvzed several of the factors .Solittzerber . by which enzymes are thought to kffect catalysis, including nroximitv and orientation effects, substrate strain, acidbase catilysis, and nucleophilic cablysis. Here we will discuss the fundamental role that the favorable free energy of binding of the rate-determining transition state plays in catalysisand will review the principle that all of the catalytic factors mentioned above, askell as numerous others (3);are realized by the use of this binding energy. At the most basic level, enthalpically favorable binding interactions between an enzyme and the transition state of the reaction being catalvzed-reeardless of the nature of these interactions&;the freeenergy ofactivationand thus lead to catalysis. Indeed. as Jencks has recentlv reiterated (4). transition state stabilization "is required by the definitiohsof catalysis and of the transition state." As early as 1930, Haldane (5)recognized the importance of bindine enerrr in catalvsis when be suggested that an enzyme a& bydistortinithe structures o f t h e substrates toward those of the products. Eighteen years later, Pauling, in a seminal statement ( 6 ) ,modified Haldane's suggestion and postulated that "enzymes are molecules that are complementary in structure to the [transition states] of the reactions that they catalyze." In 1975, Jencks (7),concisely defined binding energy, calling it the currency to pay for substrate destabilization through distortion, electrostatic interactions, and desolvation, for bringing about the necessary iws of entropy by freezing the substrates in the proper position for reaction, and for binding to the transition state. The maximum binding energy is then not realized directly in the bindingof thesubstrate, but ismore eompletelyrealizedin the transition state (italica added). Jencks continued, stating that the importance of binding energy in enzymatic catalysis

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immediatelv orovides a oualitative rationale for the laree size of . enzymes, coenzymes, and some substrates. Energy from the specific binding interactions hetween an enzyme and a subsrratr or roewyme is required in order lo bring about the (highly impnlbable) positioning of reacting groups in the optimum manner [to react] and such hinding requires. ..a large interaction area. ~

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~ossible.Furthermore, even for those reactions that do go at

a measurable rate, the chemical participation of active-site

amino acids usually makes the choice of appropriate reaction conditions for the uncatalyzed process unclear. Competing side reactions can also complicate the kinetic analysis. Nevertheless. a few rate constants for uncatal~zedreactions have been measured and compared with theanalogous enzvmic rate constants (9). (In addition, see Schowen (101 for an incisive comment on the comparison of enzymic and nonenzymic rate constants.) For example, the k,,,.t for the deamination of adenosine has been calculated to be 1.8 X 10-'0 s-' a t 310 K and pH 7, while kcat for the adenosine deaminase catalyzed reaction is 3.75 X loPs-'. The ratio of kcat to kUncatis thus 2 X loL2,requiring that the rate-determining transition state be stabilized upon binding to the enzyme by at least 17.5 kcallmol a t 310 K-17.5 kcal/mol is the minimum value as the enzymic and nonenzymic reactions may proceed by different mechanisms. As the firstorder rate constant k,., is ameasure of the free energydifference between the eG-ymesuhstrate complex a n d t h e enzyme-bound transition state, this value of 17.5 kcallmol does not include the energy required simply to hold the substrate in the active site, and thus the total binding energy of adenosine deaminase for the transition state is even greater. Wolfenden's group has calculated i t to be at least 22.8 kcallmol (9),which corresponds to an association constant of 1.25 X 10'"-' a t 310 K. Of course, this number cannot be directly measured, but we may ask whether there exists independent evidence for association constants of such enormous magnitude. Unfortunately, the calculation of an enzyme-transition state association constant in terms of the specific thermodynamic forces important in ligand binding&lectrostatic i d van der Wads attractions, hydrogen . . bonding, and hydrophobic interactions (11,12j-is problematic. i a r g e free ene r w changes in solvent water often obscure those due to the bkding OF the ligand itself. In addition, the dielectric constant of a protein is anisotropic, thus complicating calculations of electrostatic interactions between proteins and ligands (13). (Fersht and co-workers ( 1 4 ~however, , have made progress in determining experimentally the net free energy change for the formation of a hydrogen bond between a and Kati and Wolfenden (1.5) have re-lieand - - ~ and ~ ~nrotein. ~ cently reported additional data.) Finally, even i'f such analyses were straightforward, uncertainties about the precise structures of transition states would render the results suspect. Given these difficulties, we may ask how tightly can a protein bind a ligand in a system for which maximal binding of the mound state is nresumed to be advantageous. For examPC, antigens and antibodies combine with &)ciation constants of up to 10" M-' (16). but this value is far lower than that discussed above. It is not believed, however, that antibodies have evolved to bind specific antigens ax tightly as possible. In contrast, the egg white protein avidin apparently hasevolvedspecifically to bind thecofactor biotin (17). Here, the association constant is 10': !v-I, slightly lower ~

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Similarly, Warshel(8) has suggested that enzymes are large so that sufficient folding energy is available to hold adivesite residues in a relatively high-energy conformation. These active-site residues can then act t o stabilize the transition state maximally. However, before fully assessing the amount of binding energy required to achieve the enormous catalytic accelerations observed for many enzymes, we must first discuss the magnitude of these rate accelerations. Catalvtlc Enhancements Since many enzymes catalyze reactions that do not proceed a t a measurable rate in the absence of a catalmt, the quantification of catalytic rate enhancements is often im-

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Volume 67 Number 6 June 1990

483

than that reouired for transition state bindine in the adenosine deaminase catalyzed reaction. (~ecentl; the structure of biotin bound to streptavidin, which is homologous to avidin, was determined, and the molecular basis for this extraordinarily tight binding was analyzed (18).)Obviously, the binding energy of a protein for a given molecule will depend on the size and structure of the molecule, but interestingly, the binding energy observed for the association of biotin with avidin approaches that required for the largest of .. enzymatic accelerations. Energetics 01 Catalysis

The catalysis that results from the use of binding energy can he divided into two Darts. as is shown in Fieure 1. The first part is that gained'from the equal stabilization of all enzyme-hound species, including the rate-determining transition state. Albery and Knowles (19) have termed this use of binding energy "uniform binding". The second part, which Albery and Knowles have termed "catalysis of an elementarv step", is tbat zained from the stabilization of the ratedetermining enzyme-hound transition state relative to all other hound species. (See below for a discussion of the origi1 illusnal analvsis.). The nrofiles in Fieure - - ~Alhew-Knowles -- - - ~" trate the reaction of a substrate with a nonenzymic chemical catalvst that cannot bind to the substrate. as comnared with the ilkeractiou of a substrate with an enzymic cataiyst that is able to utilize binding energy. Profile 1illustrates the reaction of the substrate with the nonenzymic catalyst. (The local free enerw minimum shown in ~ r o f i l e1for the nonenzymic catalystand substrate entering the same solvent cage is rhosen arbitrarily to simplify the discussion below; Jenrks (20) has discussed reactions for which evidence for the formation of such "preassociative complexes" exists.) Profile 2 illustrates the reaction of a substrate with an enzyme tbat effects only uniform binding, and profile 3 illustrates the reaction with an enzvme that also selectivelv stabilizes the rate-determining transition state. We will now discuss evidence for both types of transition state stabilization in turn. A

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Unlform Blndlng Uniform binding was first analyzed theoretically by Westbeimbr (Zl), who in 1962 proposed that enzymes can act as "entropv traps". Westheimer stated that "an enzyme catalyzes a-reaciion in part by overcoming the unfavorable entropy of activation usually inherent in a chemical reaction." That is.. uoon substrate hindine. a reaction of hieh kineticbrder (especially when consider& the chemical p&ticipation of enzyme artive-site acids and bases) is converted

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Figure 1. 1. Free energy proflle for the reaction of a substrate A with nonenzymic ~aralystC. 2. Free energy profile for the reacUon of a substrate A with an enzyme E that enects uniform binding. 3. Free energy profile for the reaction 01 a subslrate A with an enzyme E that also effects Me selective stabilization of Me transitton state. 484

Journal of Chemical Education

into a first-order process. Westheimer continued, "In order t o constrain a molecule onto an enzyme surface, some strong forces must be involved; van der Wads and electrostatic attractions must produce free-enerev chanees to comoensate for the transltkional entropy losiin form& a compiex." Catalvsis results because bindine enerw is utilized to overcometbe unfavorable entropic requirements of bringing the catalvst and reactants toeether in the DroDer orientation to rear; Thus, as is indicated in profile 2;the eneyme-suhstrate complex A . E and the transition state are stabilized with respect to their counterpans in profile 1. Experimental evidence that overcoming the entropy of activation results in catalysis comes primarily from the comparison uf intermolecular reactions with their intramolecular counterparts. As Kirby (221 stated in 1980: [Intramolecular reactions1 are generally faster than the currespunding intermulecular processes, and are frequently so much faster that it isporsible toobserve those typesofreaction involved in enzyme catalysis.. . Bimolecular reactions in water ... are frequently t w slow to detect even under vigorous conditions.But when the catalytic and substrate m OUD . .S are browht together in the same mol&le such otherwise unreactive compounds may [react]under quite mild conditions. Although the meaningful comparison of a first order rate constant (in units of s-l) with its second order counterpart (in units of M-1 s-1) is impossible, the "effective molarity", which is defined as the rate constant for the unimolecular reaction divided by the rate constant for the bimolecular reaction (and thus has units of M), is a useful parameter. Effective molarities may be interpreted as "the eoncentration of the catalytic moup required t o make the intermolecular reaction &at the observed rate of the intramolecular process" (22).Effective molarities of lo5 M a r e not atypical as in, for example, the unimolecular carboxylate ion catalyzed hydrolysis of a succinate ester as compared with the bimolecular acetate ion catalyzed counterpart (Fig. 2). Thus, an (unattainable!) concentration of acetate ion of lo5 M would be required t o yield the hydrolysis products from the bimolecular reaction a t a rate equal to that for the unimolecular reaction; alternatively, a t 1 M s t a n d a d s t a t e the unimolecular reaction would proceed 105 times faster than the bimolecular reaction, a t 1mM standard state lo8 times faster, etc. The unimolecular reaction is, of course, analogous to the enzyme-catalyzed process and proceeds faster than the bimolecular reaction because unfavorable entropic constraints have been removed by the covalent linking of the two reactants. Amazingly, effective molarities as high as loL6 M have been measured, but their precise interpretation can

Intel~rnoicculal~ reaction

Figure 2. Intramolecular verses lntemlecular catalysis of ester hydrolysis.

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(33); indeed, the design of these analogues has become increasingly important in the pharmaceutical industry (3436). Given the buee rate accelerations effected bv enzvmes. one might e x p c t transition state analogues ti bind with ereater affinities than are actnallv observed. For exam~le. proline racemase (37) and triosephosphate isomerase i19; 38) are far more efficient catalysts than is suggested by the 160- and 250-fold differences in binding discussed ahove. Of course, transition state analogues are only analogues, and the true transition states presumably bind more tightly. Furthermore, as Schray and Klinman have discussed (39), if, for a given enzyme, uniform hinding contributes greatly to catalysis, then large association constants for transition state analogues and that enzyme will not he observed. If, at the extreme, catalysis is due exclusively to uniform binding, then the association constants for the substrate and for the transition state will he equal. (See helow for a discussion of the relative contributions of uniform binding and of selective stabilization of the transition state in the triosephosphate isomerase catalyzed readion.) To address the question of whether a transition state analogue is in f a d being recognized by an enzyme as such, one may, as was first suggested by Thompson (40) and hy Westerik and Wolfenden (41), study a series of related inhibitors. An excellent example of this approach is that of Bartlett and Marlowe (42), who synthesized six inhibitors of the protease thermolysin. The inhibitors each contain a negatively charged, tetrahedral phosphonamidate functionality that mimics the presumed transition state in apeptide bond hydrolysis reaction, but each has a different C-terminal residue (Fig. 5). (Note that these phosphonamidate inhibitors are formally analogous to the high-energy, tetrahedral intermediates involved in Deotide bond hvdrolvsis; hv the Hammond postulate (43),hiwever, the siruct&e of the highest enerev transition state will closely resemble that of these inte%ediaces.) Bartlett and %larl&ve ohserved a linear corof relation between the measured dissociation constants (K,) these phosphonamidates and the second-order rate constants (k,.JK,) of the corresponding peptide suhstrates (Fig. 5); they found no correlation, however, between the dissociation constants of the inhibitors and the Micbaelis constants (K-) of the substrates. Since the rate constant k,JK, isa'm&sure of anenzyme's affinityfor the transition state. these data sueeest that the tetrahedral ~hosohonamidate 'inhibitors arelndeed recognized by