The Evaluation of the Enzyme-Inhibitor Dissociation Constant of α

1/ [S]o plot, suggests that the affinity of the enzyme for this competitive inhibitor is of such a magnitude as to in- validate the usual assumption t...
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3228 [CONTRIDUTION No. 1516

H. T. HUANG A N D CARLNIEMANN FROM TIIE

Vol. 73

GATESAND CRELLINLABORATORIES OF CHEMISTRY,CALIFORNIA INSTITUTE OF TECHNOLOGY ]

The Evaluation of the Enzyme-Inhibitor Dissociation Constant of a-Chymotrypsin and Acetyl-D-tryptophan Methyl Ester B Y H. T. HUANG AND C.4R1, NIEhIANN'' The value of the apparent dissociation constant of a-chyomotrypsin and acetyl-D-tryptophanmethyl ester, at 25' and PH 7.9, determined by the competitive inhibition of the a-chymotrypsin-catalyzed hydrolysis of nicotinyl-L-tryptophanamide by acetyl-D-tryptophan methyl ester at an enzyme concentration of 0.208 mg. protein nitrogen per ml. and the customary l / v ~versus 1/ [SI0 plot, suggests that the affinity of the enzyme for this competitive inhibitor is of such a magnitude as to invalidate the usual assumption that the molar concentration of the inhibitor is very much greater than the molar concentration of the enzyme-inhibitor complex. An attempt has been made to determine the true value of the above enzyme-inhibitor dissociation constant, and to evaluate the equivalent weight of the enzyme, by a more detailed analysis of the kinetic data.

The simplifying zone A assumptions employed in the derivation of rate equations to describe the course of the a-chymotrypsin-catalyzed hydrolysis of specific substrates in the, presence of competitive inhibitors were briefly discussed in a previous comm~nication.~Specifically, these assumptions refer to the experimental conditions under which >> [ES] and [I] = the approximation that [SI = [Sf] [If]>> [EI] may be considered as being valid in the quantitative formulation of the reactions

I t has been observed3 that in general the upper limits for zone A behavior recommended by Straus ie., E's = [E]/& and E'I = and Gold~tein,',~ [E]/Kr > 0.1, can serve as a convenient guide to determine if a given system is in zone A. Thus in those cases where the highest enzyme concentration is of the order of 5 X M3sSdeviations from zone A conditions would not be expected unless the system contained a specific substrate or competititive inhibitor with a Ks or K I value of less than 0.5 X M . I t will be noted that to date no specific substrate of a-chymotrypsin has been found to have a K s value of less than 1 X 11P,788 and in view of the enzyme concentrations that have been employed for the evaluation of this constant it is not surprising that no deviations from zone A relations have been reported for specific substrates. However, in a systematic study of the affinity of a-chymotrypsin for a series of competitive inhibitors derived from D-tryptophan several coinpounds were found to have an apparent K I value ( K ' I )of less than 0.5 X .Id when nicotinyl-~-tryptophanamidewas used as the specific substrate.' I t is evident from the low K ' I values ( 1 ) Supported in part by a grant from Eli Lilly and Co.

(2) 'To whom inquiries regarding this article should be .sent. (3) II. T. Iiuang and C.Niemann, THISJOURNAL, 73, 1541 (1051). ( 4 ) 0 H. Straus and A. Goldstein, J . Gen. P h y s i d . , 96, 559 fI!M3) (a) A. Goldstein, i b i d . , 17, 529 (1044). (6) Computed for an enzyme concentration of 0.208 mg. protein nitrogen per ml. on the basis of one reactive site per enzyme molecule and B molecular weight of 27,000. Cf, E. F. Jansen. IvI. D. FellowsNutting, R. Jang and A. K . Balls, J . B i d . Chcm.. 186, 209 (1950). ( 7 ) H. Neurath and C.. W. Schwert, Chrm. Reus., 46, 69 (1950). (&) D. Thomas, R. V. SlacAllister and C. Niemann, TIIISJ O U R N A L , 73, 1548 (1051). (9) H . T.Huang, uuyublished observations

and the enzyme concentrations employed in these experiments that for these systems the assumption that [I] A [If]>> [EL] may not be valid. In other words, while these systems are in zone A with respect to the specific substrate they appear to be in zone B with respect to the competitive inhibitor. The fact that, in all cases, the customary 1/00 versus l/[S]o plot of the datal0 showed a satisfactory linear relationship within the limits of experimental error clearly suggested the need of a more rigorous analysis of the data to disclose deviations from zone A behavior and to provide reliable information as to the extent to which the K ' I values evaluated by the Lineweaver and Burk zone A equation for competitive inhibition, l o ie., equation (3), may differ from the corresponding values of KI. For this

study acetyl-D-tryptophan methyl ester was chosen since i t is an effective competitive inhibitor in systems containing a-chymotrypsin and a hydrolyzable specific substrate and is sufficiently soluble in aqueous media to permit its use a t concentrations from 0.05 to 1.00 X lo-* M. All experiments were conducted at 25' and pH 7.9 in the presence of a tris-(hydroxymethy1)aminomethane-hydrochloric acid buffer 0.02 AI with respect to the amine component. The main series of experiments were performed with nicotinylL-tryptophanamide as the specific substrate and a t an enzyme concentration corresponding to 0.208 mg. protein nitrogen per ml. The supplementary experiments were conducted with nicotinyl-Ltyrosinamide as the specific substrate a t an enzyme concentration of 0.047 mg. protein nitrogen per ml Since the extent of hydrolysis of the above specific substrates in all experiments was less than 30% the inhibition of the hydrolytic reaction by the corresponding liberated acylamino acid+ may be ignored, and equations (1) and (2) can be taken as an accurate representation of the system under discussion. By definition & =([El - IEsl

-

WII)([Sl - P S I ) [ESI

( [ E l - [ESI

-

and Kl

=

[EIl)([Il P II

-

Ell)

(4)

(5)

(10) €I. Lineweaver and D. Burk, THISJOURNAL. 66, 058 (1934).

July, 1951 DISSOCIATION CONSTANT OF CY-CHYMOTRYPSIN AND ACETYL-D-TRYPTOPHAN METHYLESTER 3229

It follows that and KE[ESI =

Since the system is in zone A with respect to substrate, i.e., [SI >> [ E S ] equation , (7) can be reduced to which on rearrangement gives a quadratic equation in [ES], ;.e.

+ [SI(KSKI+ Kr[SI + KEPI -

Ks(Ks[Sl)[ESlz

[ElKs)[ESl

-

[EIKr[Sl2 = 0 (9)

It will be noted that equation (9) can be obtained by the expansion and suitable rearrangement of equation GBIAs of Goldstein,s which refers specifically to a system in zone A with respect to substrate but in zone B with respect to inhibitor. The most important difference between equation (9) and pure zone A type expressions is that i t is not possible to find a solution for [ES] in which [E] can be conveniently eliminated such as in equation (3). Therefore, with equation (9) KI cannot be evaluated without a previous or simultaneous evaluation of [E]. While a knowledge of [E] can be derived from existing data on the molecular weight of a-chymotrypsin and the number of reactive sites per molecule,6 i t is of interest to see if an independent evaluation of [E], based entirely upon kinetic data, is possible with our present analytical methods. In order to effect a solution of equation (9) i t has been found desirable to resort to the practice of Straus and Goldstein4J' and to use the term "fractional activity" which is defined as 'y = v / V = [ES]/[E]. Substituting the quantity a [ E ] for [ES] in equation (9) and rearranging one obtains the relation

2

4

6

8

10

iOO*

12

14

IC

I8

20

22

24

26

e.

Fig. 1.-Inhibition of the hydrolysis of nicotinyl-Ltryptophanamide by acetyl-D-tryptophan methyl ester; plot of Q uersus aKs/ [SI; [E] = 0.208 mg. protein nitrogen M,K E = 2.7 X M. per ml., [SI and [I] in units of 0 , [I] = 1.0 x io-* M; A, [I] = 0.40 x 10-3 M ; D, [I] = 0.20 X M ; 0, [I] = 0.10 X M . The points for experiments a t [I] = 0.05 X M are not included because the error is too large to be of value in the plot. Each point represents the mean of the values obtained in two separate experiments.

magnified in the function (a-l - 1). Furthermore, considering the large error in Q for each measurement, the range in a K s / [ S ]is too small to allow a good estimation of a difference in Q to be made. It is evident that while the data do indicate a significant slope, i.e., [E] is finite and the system is in zone B with respect to the inhibitor, the plot given in Fig. 1 cannot be expected to yield a value of [E]with a precision of better than 50%, Thus forced to an alternative procedure the best lines have been drawn to fit [E], on the basis of 27,000 as the molecular weight of a-chymotrypsin6 for different values of n, where n = the number of reactive sites per molecule. It will be noted that only when n = 1 does the corresponding line touch all of the points on the plot within the indicated limits of experimental error. Therefore, it may be concluded that n = 1, and K I = 8.9 * 0.4 X Malthough n = 2 is not clearly excluded. In spite of the extreme sensitivity of the function Q to errors in a, the present results indicate that this approach has definite possibilities as a method for the estimation of [E] and hence to provide an independent check on the equivalent weight or the number of reactive sites per molecule of enzyme. Equation (lo), while identical in content with It is clear that the precision of the evaluation of Goldstein's equation BBrAs, is in a more convenient [E] can be improved by a substantial increase in form for the evaluation of KI and [E]. Thus a the precision of present experimental methods, - 11 versus and by the use of higher enzyme concentrations. plot of Q = [ I ] / [ ( a - ' - l)[S]/Ks aKs/[S] should give K I as the intercept and [E] An increase in the enzyme concentration will have as the slope. The results of competition experi- the effect of increasing both the value of the slope ments a t different inhibitor concentrations with of the Q versus a K s / [ S ]plot and the range of the nicotinyl-L-tryptophanamideas the specific sub- aKs/[S] values. A further advantage of working strate, and with [E] invariant, are summarized in a t higher enzyme concentrations is that i t should the plot given in Fig. 1. An attempt has been be possible to obtain more reliable values of the made to indicate the range in which Q must lie initial velocities vo a t lower values of [SI. The value of Kr = 8.9 * 0.4 X M for the for each individual experiment, based on the possible variations in a, as calculated from the probable system a-chymotrypsinacetyl-D-tryptophanmethyl limits of error in the determination of the experi- ester, a t 25' and PH 7.9, is significantly smaller mental values of v . It should be pointed out that than the corresponding K'I values calculated if the system is entirely in zone A, i.e., [E] -+ 0, from the same experimental data with the aid of then Q = K I and a line parallel to the abscissa equation (3) by the customary l/vo versus ~ / [ S ] O is obtained. Q, however, is extremely sensitive to plot, cf., Fig. 2 and Table I. The fact that the errors in a , since a small deviation in a is grossly values for K'I decrease as [I] is increased is con-

3230

H. T. HUANG AND CARLNIEMANN

VOl. 73

K I has been evaluated from a series of experiments with nicotinyl-L-tyrosinamideas the specific substrate and where [E] = 1.08 X &I, i.e., 0.047 mg. protein nitrogen per ml. The value obtained for K’r in this instance was 8.8 X M , cf. Fig. 3, which is in excellent agreement with the previously estimated value of K I of 8.9 X 10-j M. It should be noted that in the experiments where [E] = 1.08 X M the value of E’r was 0.13.

I/

I/

I

I

I

0 .I

0.2

1I

I/ (SI,.

Fig. 2.-Inhibition of the hydrolysis of nicotiny1-Ltryptophanamide by acetyl-D-tryptophan methyl ester; plot of 1/00 versus 1/ [SI,; [E] = 0.208 mg. protein nitrogen M , K E = 2.7 X M. per ml., [SI and [I]in units of Each point represents the mean of the values obtained in two separate experiments.

sistent with the expectation that as [I] is increased the approximation that [I]>> [EI] assumes a greater degree of validity. If i t is assumed, with some justification, that the value of [E] which was used for the evaluation of K I is correct then E’I = 0.54 and the system appears to be close to the lower boundary of zone B, ;.e., E‘I = 0.1. When i t is recalled that the effect of the presence of substantial amounts of the specific substrate is to shift the system as a whole toward zone AJ3the actual deviations from zone A behavior will be even smaller than those expected from a consideration of the value of 23’1 alone, Le,, the systems are closer to zone A than the value of E’I would indicate. Therefore, with a lower enzyme concentration it should be possible to evaluate K I under essentially zone A conditions. For this reason

0

0 os

0 10

I/ISI,.

Fig. 3.-Inhibition of the hydrolysis of nicotinyl-Ltyrosinamide by acetyl-D-tryptophan methyl ester; plot of = 0.047 mg. protein nitrogen per 1 / v 0 versus ~ / [ S ] O [E] ; ml., [SIand [I] in units of M,K E = 15.0 X M: 0,mean of three experiments; 0 , mean of two experiments; 0, single experiment.

From a priori considerations i t may be expected that for larger concentrations of the enzyme a plot of 1/vo versus 1/[S]o may give rise to a curve with decreasing slope as the value of l/[S]o is increased. However, in the present series of experiments, no such deviation was observed even for M. measurements with [I] as low as 0.05 X No unambiguous relation could be obtained from approximate solutions of equation (9) for [ES] which would justify a linear relationship between l/vo and l/[SJo. For the condition that Ks(Ks [SI)[ESI/[SI(Ks~1 KI[Sl KsDI - Ks[EI) is less than 0.1, a perturbation solution of equation (9) gives the relation

+

+

+

+

where 6 = & ( [ I ] - [E])/KI(Ks [SI). Thus for each series of experiments a t a given value of [I] and [E], 6 decreases as [SI is increased. However, it can be seen that the variation in 6 is small TABLE I within the range of [SI ordinarily encountered and APPARENTENZYME-INHIBITOR DISSOCIATION CONSTANTS OF considering the change a variation in 6 causes in a-CHYMOTRYPSIN AND ACETYL-D-TRYPTOPHAN METHYL the terms [I]/K1 - [EI/KI [ E I / K I ( ~ 4) ESTER^ as a whole i t would not be expected, in our experiSubstrate PI* [ElC K‘rd ments, that the plot of l/vo versus ~ / [ S ] would O be Nicotinyl-L-tryptophanamide’ 0.05 0.208 0.11 Nicotinyl-L-tryp tophanamide’ .10 .208 .10 other than linear. It is obvious that the observed linear relationship between I / V O and ~ / [ S ]isOmore h’icotinyl-L-tryptophanamidee .20 .208 .10 h’icotinyl-L-tryptophanamide’ .40 .208 ,097 apparent than real. It will be appreciated that Xcotinyl-L-tryptophanamidee 1.00 208 09 1 under favorable conditions equation (11) can be Kicotinyl-L-tyrosinamide’ 0 10 047 088 used to give a corrected value of K’I by making a A t 25’ and pH 7.9. * I n units of Jf. [ E ] in use of the value of K’I derived from equation (3). In units of M. ‘ K s In general, once the correct slope is determined, mg. protein nitrogen per ml. an evaluation of Kl from a plot based on equation = 2.7 X 10-3M. K B = 15.0 X 111.

+

f

+

July, 1951

a-CHYMOTRYPSIN CATALYZED HYDROLYSIS OF NXCOTINYL-L-TYROSINAMIDE 3231

(10) is less ambiguous. ADDlications of eauation (10) will be i1lust;ated by tfii evaluation of ;he K I values of various competitive inhibitors in a subsequent communication. We wish to express our thanks to Dr. Verner Schomaker for valuable suggestions and discussions in relation to this work. Experimental The preparation of acetyl-D-tryptophan methyl ester,a

[CONTRIBUTION K O .

1520 FROM

THE

GATESAND

- -

nicotinyl L tryptophanamidea and nicotinyl-r. -tyrosinamide11 has been -described previously. All enzymatic experiments are conducted at 25' and PH 7.9 * 0.02 in aqueous solution 0.02 M with respect to the amine component of a tris-(hydroxymethyl) -amhomethane-hydrochloric acid buffer. The methods used are identical with those described previously.* The a-chymotrypsin was an Armour preparation lot no. 90402 of bovine origin. (11) B. M. Iselin, H. T.Huang, R. V. MacAllister and C. Niemann, THISJOURNAL, 71, 1729 (1950).

PASADENA 4, CALIF.

RECEIVED JANUARY 16, 1951

CRELLIN LABORATORIES OF CHEMISTRY, CALIFORNIA INSTITUTE OF TECHNOLOGY]

The Kinetics of the a-Chymotrypsin Catalyzed Hydrolysis of Nicotinyl-L-tyrosinamide in Aqueous Solutions at 25' and pH 7.9' BY H. T. HUANG,R. V. M A ~ L L I S T E D. R , W. THOMAS AND CARLNIEMANN~ The kinetics of the a-chymotrypsin-catalyzed hydrolysis of nicotinyl-L-tyrosinamide in aqueous solutions at 25' and PH 7.9 have been found to be similar to those reported previously for this enzyme and other specific substrates of the acylated a-amino acid amide type. For the system a-chymotrypsin-nicotinyl-L-tyrosinamideat 25' and PH 7.9 KSwas found to have a value of 15.0 * 1.0 X 10-8 M and k3 a value of 6.2 X 10-3 M/mg. protein nitrogen/ml./min.

It has been noted previously that whereas the pH-activity curves for a-chymotrypsin and acetyland nicotinyl-L-tryptophanamide are practically k4 identical3 there is a significant difference between Er Pif EPi (2) the above curves and that observed for a-chymok; trypsin and acetyl-~-tyrosinamide.~From the data given in Fig. 1 i t will be seen that the pH- and, when E's < 0.1, by the rate equation (3) activity curve for a-chymotrypsin and nicotinyl-Ltyrosinamide is identical, within the limits of experimental error, with that observed for this enzyme and acetyl-L-tyrosinamide. The fact that substantially different pH-activity relationships have now been observed for a-chymotrypsin and However, with the system a-chymotrypsin-nicoacetyl- and nicotinyl-L-tryptophanamide on one tinyl-L-tyrosinamide a t 25' and p H 7.9, the relahand, and a-chymotrypsin and acetyl- and nico- tion between the values of Ks, Kp, and ks is such tinyl-L-tyrosinamide on the other, clearly indicates that the experimental data can also be described, that for this enzyme and specific substrates of the within the limits of experimental error, by rate general formula RCONHCHRlCONH2, the nature equation (4) of the amino acid side chain, Le., R1, may have a k s [ E ] t 2.3Ks log- [Slo -I- (IS], - [SI) (4) profound influence upon the pH-activity relation[SI ship. I n contrast, it appears, from the two cases a t hand, that the role of the acyl group, ;.e., of R, wherein inhibition of the hydrolytic reaction by the in the above process is relatively ~ n i m p o r t a n t . ~liberated nicotinyi-L-tyrosine is ignored. ThereExperiments designed to provide data relative to fore, in this instance, and when E's