Enzyme kinetics

The reaction catalysed by an enzyme uses exactly the same reactants and produces exactly the same products as the uncatalysed reaction. Like othercatalysts,enzymes do not alter the position ofequilibriumbetween substrates and products.^[1]However, unlike uncatalysed chemical reactions, enzyme-catalysed reactions display saturation kinetics. For a given enzyme concentration and for relatively low substrate concentrations, the reaction rate increases linearly with substrate concentration; the enzyme molecules are largely free to catalyse the reaction, and increasing substrate concentration means an increasing rate at which the enzyme and substrate molecules encounter one another. However, at relatively high substrate concentrations, the reaction rateasymptoticallyapproaches the theoretical maximum; the enzyme active sites are almost all occupied by substrates resulting in saturation, and the reaction rate is determined by the intrinsic turnover rate of the enzyme.^[2]The substrate concentration midway between these two limiting cases is denoted byK_M.Thus,K_Mis the substrate concentration at which the reaction velocity is half of the maximum velocity.^[2]

The two important properties of enzyme kinetics are how easily the enzyme can be saturated with a substrate, and the maximum rate it can achieve. Knowing these properties suggests what an enzyme might do in the cell and can show how the enzyme will respond to changes in these conditions.

Enzyme assaysare laboratory procedures that measure the rate of enzyme reactions. Since enzymes are not consumed by the reactions they catalyse, enzyme assays usually follow changes in the concentration of either substrates or products to measure the rate of reaction. There are many methods of measurement.Spectrophotometricassays observe the change in theabsorbanceof light between products and reactants; radiometric assays involve the incorporation or release ofradioactivityto measure the amount of product made over time. Spectrophotometric assays are most convenient since they allow the rate of the reaction to be measured continuously. Although radiometric assays require the removal and counting of samples (i.e., they are discontinuous assays) they are usually extremely sensitive and can measure very low levels of enzyme activity.^[3]An analogous approach is to usemass spectrometryto monitor the incorporation or release ofstable isotopesas the substrate is converted into product. Occasionally, an assay fails and approaches are essential to resurrect a failed assay.

The most sensitive enzyme assays uselasersfocused through amicroscopeto observe changes in single enzyme molecules as they catalyse their reactions. These measurements either use changes in thefluorescenceofcofactorsduring an enzyme's reaction mechanism, or offluorescent dyesadded onto specific sites of theproteinto report movements that occur during catalysis.^[4]These studies provide a new view of the kinetics and dynamics of single enzymes, as opposed to traditional enzyme kinetics, which observes the average behaviour of populations of millions of enzyme molecules.^[5][6]

An example progress curve for an enzyme assay is shown above. The enzyme produces product at an initial rate that is approximately linear for a short period after the start of the reaction. As the reaction proceeds and substrate is consumed, the rate continuously slows (so long as the substrate is not still at saturating levels). To measure the initial (and maximal) rate, enzyme assays are typically carried out while the reaction has progressed only a few percent towards total completion. The length of the initial rate period depends on the assay conditions and can range from milliseconds to hours. However, equipment for rapidly mixing liquids allows fast kinetic measurements at initial rates of less than one second.^[7]These very rapid assays are essential for measuring pre-steady-state kinetics, which are discussed below.

Most enzyme kinetics studies concentrate on this initial, approximately linear part of enzyme reactions. However, it is also possible to measure the complete reaction curve and fit this data to a non-linearrate equation.This way of measuring enzyme reactions is called progress-curve analysis.^[8]This approach is useful as an alternative torapid kineticswhen the initial rate is too fast to measure accurately.

TheStandards for Reporting Enzymology DataGuidelines provide minimum information required to comprehensively report kinetic and equilibrium data from investigations of enzyme activities including corresponding experimental conditions. The guidelines have been developed to report functional enzyme data with rigor and robustness.

Enzymes with single-substrate mechanisms includeisomerasessuch astriosephosphateisomeraseorbisphosphoglycerate mutase,intramolecularlyasessuch asadenylate cyclaseand thehammerhead ribozyme,an RNA lyase.^[9]However, some enzymes that only have a single substrate do not fall into this category of mechanisms.Catalaseis an example of this, as the enzyme reacts with a first molecule ofhydrogen peroxidesubstrate, becomes oxidised and is then reduced by a second molecule of substrate. Although a single substrate is involved, the existence of a modified enzyme intermediate means that the mechanism of catalase is actually a ping–pong mechanism, a type of mechanism that is discussed in theMulti-substrate reactionssection below.

As enzyme-catalysed reactions are saturable, their rate of catalysis does not show a linear response to increasing substrate. If the initial rate of the reaction is measured over a range of substrate concentrations (denoted as [S]), the initial reaction rate (${\displaystyle v_{0}}$) increases as [S] increases, as shown on the right. However, as [S] gets higher, the enzyme becomes saturated with substrate and the initial rate reachesV_max,the enzyme's maximum rate.

TheMichaelis–Menten kinetic model of a single-substrate reactionis shown on the right. There is an initialbimolecular reactionbetween the enzyme E and substrate S to form the enzyme–substrate complex ES. The rate of enzymatic reaction increases with the increase of the substrate concentration up to a certain level called V_max;at V_max,increase in substrate concentration does not cause any increase in reaction rate as there is no more enzyme (E) available for reacting with substrate (S). Here, the rate of reaction becomes dependent on the ES complex and the reaction becomes aunimolecular reactionwith an order of zero. Though the enzymatic mechanism for theunimolecular reaction${\displaystyle {\ce {ES ->[k_{cat}] E + P}}}$can be quite complex, there is typically one rate-determining enzymatic step that allows this reaction to be modelled as a single catalytic step with an apparent unimolecular rate constantk_cat. If the reaction path proceeds over one or several intermediates,k_catwill be a function of several elementary rate constants, whereas in the simplest case of a single elementary reaction (e.g. no intermediates) it will be identical to the elementary unimolecular rate constantk₂.The apparent unimolecular rate constantk_catis also calledturnover number,and denotes the maximum number of enzymatic reactions catalysed per second.

TheMichaelis–Menten equation^[10]describes how the (initial) reaction ratev₀depends on the position of the substrate-bindingequilibriumand the rate constantk₂.

${\displaystyle v_{0}={\frac {V_{\max }[{\ce {S}}]}{K_{M}+[{\ce {S}}]}}}$(Michaelis–Menten equation)

with the constants

${\displaystyle {\begin{aligned}K_{M}\ &{\stackrel {\mathrm {def} }{=}}\ {\frac {k_{2}+k_{-1}}{k_{1}}}\approx K_{D}\\V_{\max }\ &{\stackrel {\mathrm {def} }{=}}\ k_{cat}{\ce {[E]}}_{tot}\end{aligned}}}$

This Michaelis–Menten equation is the basis for most single-substrate enzyme kinetics. Two crucial assumptions underlie this equation (apart from the general assumption about the mechanism only involving no intermediate or product inhibition, and there is noallostericityorcooperativity). The first assumption is the so-called quasi-steady-state assumption(or pseudo-steady-state hypothesis), namely that the concentration of the substrate-bound enzyme (and hence also the unbound enzyme) changes much more slowly than those of the product and substrate and thus the change over time of the complex can be set to zero ${\displaystyle d{\ce {[ES]}}/{dt}\;{\overset {!}{=}}\;0}$.The second assumption is that the total enzyme concentration does not change over time, thus${\displaystyle {\ce {[E]}}_{\text{tot}}={\ce {[E]}}+{\ce {[ES]}}\;{\overset {!}{=}}\;{\text{const}}}$.

The Michaelis constantK_Mis experimentally defined as the concentration at which the rate of the enzyme reaction is halfV_max,which can be verified by substituting [S] =K_Minto the Michaelis–Menten equation and can also be seen graphically. If the rate-determining enzymatic step is slow compared to substrate dissociation (${\displaystyle k_{2}\ll k_{-1}}$), the Michaelis constantK_Mis roughly thedissociation constantK_Dof the ES complex.

If${\displaystyle {\ce {[S]}}}$is small compared to${\displaystyle K_{M}}$then the term${\displaystyle [{\ce {S}}]/(K_{M}+[{\ce {S}}])\approx [{\ce {S}}]/K_{M}}$and also very little ES complex is formed, thus${\displaystyle {\ce {[E]_{\rm {tot}}\approx [E]}}}$.Therefore, the rate of product formation is

${\displaystyle v_{0}\approx {\frac {k_{cat}}{K_{M}}}{\ce {[E][S]}}\qquad \qquad {\text{if }}[{\ce {S}}]\ll K_{M}}$

Thus the product formation rate depends on the enzyme concentration as well as on the substrate concentration, the equation resembles a bimolecular reaction with a corresponding pseudo-second order rate constant${\displaystyle k_{2}/K_{M}}$.This constant is a measure ofcatalytic efficiency.The most efficient enzymes reach a${\displaystyle k_{2}/K_{M}}$in the range of10⁸– 10¹⁰M⁻¹s⁻¹.These enzymes are so efficient they effectively catalyse a reaction each time they encounter a substrate molecule and have thus reached an upper theoretical limit for efficiency (diffusion limit); and are sometimes referred to askinetically perfect enzymes.^[11]But most enzymes are far from perfect: the average values of${\displaystyle k_{2}/K_{\rm {M}}}$and${\displaystyle k_{2}}$are about${\displaystyle 10^{5}{\rm {s}}^{-1}{\rm {M}}^{-1}}$and${\displaystyle 10{\rm {s}}^{-1}}$,respectively.^[12]

The observed velocities predicted by the Michaelis–Menten equation can be used to directly model thetime course disappearance of substrateand the production of product through incorporation of the Michaelis–Menten equation into the equation for first order chemical kinetics. This can only be achieved however if one recognises the problem associated with the use ofEuler's numberin the description of first order chemical kinetics. i.e.e^−kis a split constant that introduces a systematic error into calculations and can be rewritten as a single constant which represents the remaining substrate after each time period.^[13]

${\displaystyle [S]=[S]_{0}(1-k)^{t}\,}$

${\displaystyle [S]=[S]_{0}(1-v/[S]_{0})^{t}\,}$

${\displaystyle [S]=[S]_{0}(1-(V_{\max }[S]_{0}/(K_{M}+[S]_{0})/[S]_{0}))^{t}\,}$

In 1983 Stuart Beal (and also independentlySantiago Schnelland Claudio Mendoza in 1997) derived a closed form solution for the time course kinetics analysis of the Michaelis-Menten mechanism.^[14][15]The solution,known as the Schnell-Mendoza equation^{[failed verification]},has the form:

${\displaystyle {\frac {[S]}{K_{M}}}=W\left[F(t)\right]\,}$

where W[ ] is theLambert-W function.^[16][17]and where F(t) is

${\displaystyle F(t)={\frac {[S]_{0}}{K_{M}}}\exp \!\left({\frac {[S]_{0}}{K_{M}}}-{\frac {V_{\max }}{K_{M}}}\,t\right)\,}$

This equation is encompassed by the equation below, obtained by Berberan-Santos,^[18]which is also valid when the initial substrate concentration is close to that of enzyme,

${\displaystyle {\frac {[S]}{K_{M}}}=W\left[F(t)\right]-{\frac {V_{\max }}{k_{cat}K_{M}}}\ {\frac {W\left[F(t)\right]}{1+W\left[F(t)\right]}}\,}$

where W[ ] is again theLambert-W function.

The plot ofvversus [S] above is not linear; although initially linear at low [S], it bends over to saturate at high [S]. Before the modern era ofnonlinear curve-fittingon computers, this nonlinearity could make it difficult to estimateK_MandV_maxaccurately. Therefore, several researchers developed linearisations of the Michaelis–Menten equation, such as theLineweaver–Burk plot,theEadie–Hofstee diagramand theHanes–Woolf plot.All of these linear representations can be useful for visualising data, but none should be used to determine kinetic parameters, as computer software is readily available that allows for more accurate determination bynonlinear regressionmethods.^[19]

TheLineweaver–Burk plotor double reciprocal plot is a common way of illustrating kinetic data. This is produced by taking thereciprocalof both sides of the Michaelis–Menten equation. As shown on the right, this is a linear form of the Michaelis–Menten equation and produces a straight line with the equationy= mx+ c with ay-intercept equivalent to 1/V_maxand anx-intercept of the graph representing −1/K_M.

${\displaystyle {\frac {1}{v}}={\frac {K_{M}}{V_{\max }[{\mbox{S}}]}}+{\frac {1}{V_{\max }}}}$

Naturally, no experimental values can be taken at negative 1/[S]; the lower limiting value 1/[S] = 0 (they-intercept) corresponds to an infinite substrate concentration, where1/v=1/V_maxas shown at the right; thus, thex-intercept is anextrapolationof the experimental data taken at positive concentrations. More generally, the Lineweaver–Burk plot skews the importance of measurements taken at low substrate concentrations and, thus, can yield inaccurate estimates ofV_maxandK_M.^[20]A more accurate linear plotting method is theEadie–Hofstee plot.In this case,vis plotted againstv/[S]. In the third common linear representation, theHanes–Woolf plot,[S]/vis plotted against [S]. In general, data normalisation can help diminish the amount of experimental work and can increase the reliability of the output, and is suitable for both graphical and numerical analysis.^[21]

The study of enzyme kinetics is important for two basic reasons. Firstly, it helps explain how enzymes work, and secondly, it helps predict how enzymes behave in living organisms. The kinetic constants defined above,K_MandV_max,are critical to attempts to understand how enzymes work together to controlmetabolism.

Making these predictions is not trivial, even for simple systems. For example,oxaloacetateis formed bymalate dehydrogenasewithin themitochondrion.Oxaloacetate can then be consumed bycitrate synthase,phosphoenolpyruvate carboxykinaseoraspartate aminotransferase,feeding into thecitric acid cycle,gluconeogenesisoraspartic acidbiosynthesis, respectively. Being able to predict how much oxaloacetate goes into which pathway requires knowledge of the concentration of oxaloacetate as well as the concentration and kinetics of each of these enzymes. This aim of predicting the behaviour of metabolic pathways reaches its most complex expression in the synthesis of huge amounts of kinetic andgene expressiondata into mathematical models of entire organisms. Alternatively, one useful simplification of the metabolic modelling problem is to ignore the underlying enzyme kinetics and only rely on information about the reaction network's stoichiometry, a technique calledflux balance analysis.^[22][23]

One could also consider the less simple case

${\displaystyle {\ce {{E}+S<=>[k_{1}][k_{-1}]ES->[k_{2}]EI->[k_{3}]{E}+P}}}$

where a complex with the enzyme and an intermediate exists and the intermediate is converted into product in a second step. In this case we have a very similar equation^[24]

${\displaystyle v_{0}=k_{cat}{\frac {{\ce {[S] [E]_0}}}{K_{M}^{\prime }+{\ce {[S]}}}}}$

but the constants are different

${\displaystyle {\begin{aligned}K_{M}^{\prime }\ &{\stackrel {\mathrm {def} }{=}}\ {\frac {k_{3}}{k_{2}+k_{3}}}K_{M}={\frac {k_{3}}{k_{2}+k_{3}}}\cdot {\frac {k_{2}+k_{-1}}{k_{1}}}\\k_{cat}\ &{\stackrel {\mathrm {def} }{=}}\ {\dfrac {k_{3}k_{2}}{k_{2}+k_{3}}}\end{aligned}}}$

We see that for the limiting case${\displaystyle k_{3}\gg k_{2}}$,thus when the last step from${\displaystyle {\ce {EI -> E + P}}}$is much faster than the previous step, we get again the original equation. Mathematically we have then${\displaystyle K_{M}^{\prime }\approx K_{M}}$and${\displaystyle k_{cat}\approx k_{2}}$.

Multi-substrate reactions follow complex rate equations that describe how the substrates bind and in what sequence. The analysis of these reactions is much simpler if the concentration of substrate A is kept constant and substrate B varied. Under these conditions, the enzyme behaves just like a single-substrate enzyme and a plot ofvby [S] gives apparentK_MandV_maxconstants for substrate B. If a set of these measurements is performed at different fixed concentrations of A, these data can be used to work out what the mechanism of the reaction is. For an enzyme that takes two substrates A and B and turns them into two products P and Q, there are two types of mechanism: ternary complex and ping–pong.

In these enzymes, both substrates bind to the enzyme at the same time to produce an EAB ternary complex. The order of binding can either be random (in a random mechanism) or substrates have to bind in a particular sequence (in an ordered mechanism). When a set ofvby [S] curves (fixed A, varying B) from an enzyme with a ternary-complex mechanism are plotted in aLineweaver–Burk plot,the set of lines produced will intersect.

Enzymes with ternary-complex mechanisms includeglutathioneS-transferase,^[25]dihydrofolate reductase^[26]andDNA polymerase.^[27]The following links show short animations of the ternary-complex mechanisms of the enzymes dihydrofolate reductase^[β]and DNA polymerase^[γ].

As shown on the right, enzymes with a ping-pong mechanism can exist in two states, E and a chemically modified form of the enzyme E*; this modified enzyme is known as anintermediate.In such mechanisms, substrate A binds, changes the enzyme to E* by, for example, transferring a chemical group to the active site, and is then released. Only after the first substrate is released can substrate B bind and react with the modified enzyme, regenerating the unmodified E form. When a set ofvby [S] curves (fixed A, varying B) from an enzyme with a ping–pong mechanism are plotted in a Lineweaver–Burk plot, a set of parallel lines will be produced. This is called asecondary plot.

Enzymes with ping–pong mechanisms include someoxidoreductasessuch asthioredoxin peroxidase,^[28]transferasessuch as acylneuraminate cytidylyltransferase^[29]andserine proteasessuch astrypsinandchymotrypsin.^[30]Serine proteases are a very common and diverse family of enzymes, includingdigestiveenzymes (trypsin, chymotrypsin, and elastase), several enzymes of theblood clotting cascadeand many others. In these serine proteases, the E* intermediate is an acyl-enzyme species formed by the attack of an active siteserineresidue on apeptide bondin a protein substrate. A short animation showing the mechanism of chymotrypsin is linked here.^[δ]

External factors may limit the ability of an enzyme to catalyse a reaction in both directions (whereas the nature of a catalyst in itself means that it cannot catalyse just one direction, according to the principle ofmicroscopic reversibility). We consider the case of an enzyme that catalyses the reaction in both directions:

${\displaystyle {\ce {{E}+{S}<=>[k_{1}][k_{-1}]ES<=>[k_{2}][k_{-2}]{E}+{P}}}}$

The steady-state, initial rate of the reaction is${\displaystyle v_{0}={\frac {d\,[{\rm {P}}]}{dt}}={\frac {(k_{1}k_{2}\,[{\rm {S}}]-k_{-1}k_{-2}[{\rm {P}}])[{\rm {E}}]_{0}}{k_{-1}+k_{2}+k_{1}\,[{\rm {S}}]+k_{-2}\,[{\rm {P}}]}}}$

${\displaystyle v_{0}}$is positive if the reaction proceed in the forward direction (${\displaystyle S\rightarrow P}$) and negative otherwise.

Equilibriumrequires that${\displaystyle v=0}$,which occurs when${\displaystyle {\frac {[{\rm {P}}]_{\rm {eq}}}{[{\rm {S}}]_{\rm {eq}}}}={\frac {k_{1}k_{2}}{k_{-1}k_{-2}}}=K_{\rm {eq}}}$.This shows thatthermodynamicsforces a relation between the values of the 4 rate constants.

The values of the forward and backwardmaximalrates, obtained for${\displaystyle [{\rm {S}}]\rightarrow \infty }$,${\displaystyle [{\rm {P}}]=0}$,and${\displaystyle [{\rm {S}}]=0}$,${\displaystyle [{\rm {P}}]\rightarrow \infty }$,respectively, are${\displaystyle V_{\rm {max}}^{f}=k_{2}{\rm {[E]}}_{tot}}$and${\displaystyle V_{\rm {max}}^{b}=-k_{-1}{\rm {[E]}}_{tot}}$,respectively. Their ratio is not equal to the equilibrium constant, which implies thatthermodynamicsdoes not constrain the ratio of the maximal rates. This explains that enzymes can be much "better catalysts" (in terms of maximal rates) in one particular direction of the reaction.^[31]

On can also derive the two Michaelis constants${\displaystyle K_{M}^{S}=(k_{-1}+k_{2})/k_{1}}$and${\displaystyle K_{M}^{P}=(k_{-1}+k_{2})/k_{-2}}$.The Haldane equation is the relation${\displaystyle K_{\rm {eq}}={\frac {[{\rm {P}}]_{\rm {eq}}}{[{\rm {S}}]_{\rm {eq}}}}={\frac {V_{\rm {max}}^{f}/K_{M}^{S}}{V_{\rm {max}}^{b}/K_{M}^{P}}}}$.

Therefore,thermodynamicsconstrains the ratio between the forward and backward${\displaystyle V_{\rm {max}}/K_{M}}$values, not the ratio of${\displaystyle V_{\rm {max}}}$values.

Many different enzyme systems follow non Michaelis-Menten behavior. A select few examples include kinetics of self-catalytic enzymes, cooperative and allosteric enzymes, interfacial and intracellular enzymes, processive enzymes and so forth. Some enzymes produce asigmoidvby [S] plot, which often indicatescooperative bindingof substrate to the active site. This means that the binding of one substrate molecule affects the binding of subsequent substrate molecules. This behavior is most common inmultimericenzymes with several interacting active sites.^[32]Here, the mechanism of cooperation is similar to that ofhemoglobin,with binding of substrate to one active site altering the affinity of the other active sites for substrate molecules. Positive cooperativity occurs when binding of the first substrate moleculeincreasesthe affinity of the other active sites for substrate. Negative cooperativity occurs when binding of the first substratedecreasesthe affinity of the enzyme for other substrate molecules.

Allosteric enzymes include mammalian tyrosyl tRNA-synthetase, which shows negative cooperativity,^[33]and bacterialaspartate transcarbamoylase^[34]andphosphofructokinase,^[35]which show positive cooperativity.

Cooperativity is surprisingly common and can help regulate the responses of enzymes to changes in the concentrations of their substrates. Positive cooperativity makes enzymes much more sensitive to [S] and their activities can show large changes over a narrow range of substrate concentration. Conversely, negative cooperativity makes enzymes insensitive to small changes in [S].

TheHill equation^[36]is often used to describe the degree of cooperativity quantitatively in non-Michaelis–Menten kinetics. The derived Hill coefficientnmeasures how much the binding of substrate to one active site affects the binding of substrate to the other active sites. A Hill coefficient of <1 indicates negative cooperativity and a coefficient of >1 indicates positivecooperativity.

In the first moment after an enzyme is mixed with substrate, no product has been formed and nointermediatesexist. The study of the next few milliseconds of the reaction is called pre-steady-state kinetics. Pre-steady-state kinetics is therefore concerned with the formation and consumption of enzyme–substrate intermediates (such as ES or E*) until theirsteady-state concentrationsare reached.

This approach was first applied to the hydrolysis reaction catalysed bychymotrypsin.^[37]Often, the detection of an intermediate is a vital piece of evidence in investigations of what mechanism an enzyme follows. For example, in the ping–pong mechanisms that are shown above, rapid kinetic measurements can follow the release of product P and measure the formation of the modified enzyme intermediate E*.^[38]In the case of chymotrypsin, this intermediate is formed by an attack on the substrate by thenucleophilicserine in the active site and the formation of the acyl-enzyme intermediate.

In the figure to the right, the enzyme produces E* rapidly in the first few seconds of the reaction. The rate then slows as steady state is reached. This rapid burst phase of the reaction measures a single turnover of the enzyme. Consequently, the amount of product released in this burst, shown as the intercept on they-axis of the graph, also gives the amount of functional enzyme which is present in the assay.^[39]

An important goal of measuring enzyme kinetics is to determine the chemical mechanism of an enzyme reaction, i.e., the sequence of chemical steps that transform substrate into product. The kinetic approaches discussed above will show at what ratesintermediatesare formed and inter-converted, but they cannot identify exactly what these intermediates are.

Kinetic measurements taken under various solution conditions or on slightly modified enzymes or substrates often shed light on this chemical mechanism, as they reveal the rate-determining step or intermediates in the reaction. For example, the breaking of acovalent bondto ahydrogenatomis a common rate-determining step. Which of the possible hydrogen transfers is rate determining can be shown by measuring the kinetic effects of substituting each hydrogen bydeuterium,its stableisotope.The rate will change when the critical hydrogen is replaced, due to a primarykinetic isotope effect,which occurs because bonds to deuterium are harder to break than bonds to hydrogen.^[40]It is also possible to measure similar effects with other isotope substitutions, such as¹³C/¹²C and¹⁸O/¹⁶O, but these effects are more subtle.^[41]

Isotopes can also be used to reveal the fate of various parts of the substrate molecules in the final products. For example, it is sometimes difficult to discern the origin of anoxygenatom in the final product; since it may have come from water or from part of the substrate. This may be determined by systematically substituting oxygen's stable isotope¹⁸O into the various molecules that participate in the reaction and checking for the isotope in the product.^[42]The chemical mechanism can also be elucidated by examining the kinetics and isotope effects under different pH conditions,^[43]by altering the metal ions or other boundcofactors,^[44]bysite-directed mutagenesisof conserved amino acid residues, or by studying the behaviour of the enzyme in the presence of analogues of the substrate(s).^[45]

Enzyme inhibitors are molecules that reduce or abolish enzyme activity, while enzyme activators are molecules that increase the catalytic rate of enzymes. These interactions can be eitherreversible(i.e., removal of the inhibitor restores enzyme activity) orirreversible(i.e., the inhibitor permanently inactivates the enzyme).

Traditionally reversible enzyme inhibitors have been classified ascompetitive,uncompetitive,ornon-competitive,according to their effects onK_MandV_max.These different effects result from the inhibitor binding to the enzyme E, to the enzyme–substrate complex ES, or to both, respectively. The division of these classes arises from a problem in their derivation and results in the need to use two different binding constants for one binding event. The binding of an inhibitor and its effect on the enzymatic activity are two distinctly different things, another problem the traditional equations fail to acknowledge. In noncompetitive inhibition the binding of the inhibitor results in 100% inhibition of the enzyme only, and fails to consider the possibility of anything in between.^[46]In noncompetitive inhibition, the inhibitor will bind to an enzyme at its allosteric site; therefore, the binding affinity, or inverse ofK_M,of the substrate with the enzyme will remain the same. On the other hand, the V_maxwill decrease relative to an uninhibited enzyme. On a Lineweaver-Burk plot, the presence of a noncompetitive inhibitor is illustrated by a change in the y-intercept, defined as 1/V_max.The x-intercept, defined as −1/K_M,will remain the same. In competitive inhibition, the inhibitor will bind to an enzyme at the active site, competing with the substrate. As a result, theK_Mwill increase and the V_maxwill remain the same.^[47]The common form of the inhibitory term also obscures the relationship between the inhibitor binding to the enzyme and its relationship to any other binding term be it the Michaelis–Menten equation or a dose response curve associated with ligand receptor binding. To demonstrate the relationship the following rearrangement can be made:

${\displaystyle {\cfrac {V_{\max }}{1+{\cfrac {[I]}{K_{i}}}}}={\cfrac {V_{\max }}{\cfrac {[I]+K_{i}}{K_{i}}}}}$

Adding zero to the bottom ([I]-[I])

${\displaystyle {\cfrac {V_{\max }}{\cfrac {[I]+K_{i}}{[I]+K_{i}-[I]}}}}$

Dividing by [I]+K_i

${\displaystyle {\cfrac {V_{\max }}{\cfrac {1}{1-{\cfrac {[I]}{[I]+K_{i}}}}}}=V_{\max }-V_{\max }{\cfrac {[I]}{[I]+K_{i}}}}$

This notation demonstrates that similar to the Michaelis–Menten equation, where the rate of reaction depends on the percent of the enzyme population interacting with substrate, the effect of the inhibitor is a result of the percent of the enzyme population interacting with inhibitor. The only problem with this equation in its present form is that it assumes absolute inhibition of the enzyme with inhibitor binding, when in fact there can be a wide range of effects anywhere from 100% inhibition of substrate turn over to just >0%. To account for this the equation can be easily modified to allow for different degrees of inhibition by including a deltaV_maxterm.

${\displaystyle V_{\max }-\Delta V_{\max }{\cfrac {[I]}{[I]+K_{i}}}}$

or

${\displaystyle V_{\max 1}-(V_{\max 1}-V_{\max 2}){\cfrac {[I]}{[I]+K_{i}}}}$

This term can then define the residual enzymatic activity present when the inhibitor is interacting with individual enzymes in the population. However the inclusion of this term has the added value of allowing for the possibility of activation if the secondaryV_maxterm turns out to be higher than the initial term. To account for the possibly of activation as well the notation can then be rewritten replacing the inhibitor "I" with a modifier term denoted here as "X".

${\displaystyle V_{\max 1}-(V_{\max 1}-V_{\max 2}){\cfrac {[X]}{[X]+K_{x}}}}$

While this terminology results in a simplified way of dealing with kinetic effects relating to the maximum velocity of the Michaelis–Menten equation, it highlights potential problems with the term used to describe effects relating to theK_M.TheK_Mrelating to the affinity of the enzyme for the substrate should in most cases relate to potential changes in the binding site of the enzyme which would directly result from enzyme inhibitor interactions. As such a term similar to the one proposed above to modulateV_maxshould be appropriate in most situations:^[48]

${\displaystyle K_{m1}-(K_{m1}-K_{m2}){\cfrac {[X]}{[X]+K_{x}}}}$

Enzyme inhibitors can also irreversibly inactivate enzymes, usually by covalently modifying active site residues. These reactions, which may be called suicide substrates, followexponential decayfunctions and are usually saturable. Below saturation, they followfirst orderkinetics with respect to inhibitor. Irreversible inhibition could be classified into two distinct types. Affinity labelling is a type of irreversible inhibition where a functional group that is highly reactive modifies a catalytically critical residue on the protein of interest to bring about inhibition. Mechanism-based inhibition, on the other hand, involves binding of the inhibitor followed by enzyme mediated alterations that transform the latter into a reactive group that irreversibly modifies the enzyme.

Having discussed reversible inhibition and irreversible inhibition in the above two headings, it would have to be pointed out that the concept of reversibility (or irreversibility) is a purely theoretical construct exclusively dependent on the time-frame of the assay, i.e., a reversible assay involving association and dissociation of the inhibitor molecule in the minute timescales would seem irreversible if an assay assess the outcome in the seconds and vice versa. There is a continuum of inhibitor behaviors spanning reversibility and irreversibility at a given non-arbitrary assay time frame. There are inhibitors that show slow-onset behavior and most of these inhibitors, invariably, also show tight-binding to the protein target of interest.

The favoured model for the enzyme–substrate interaction is the induced fit model.^[49]This model proposes that the initial interaction between enzyme and substrate is relatively weak, but that these weak interactions rapidly induceconformational changesin the enzyme that strengthen binding. Theseconformationalchanges also bring catalytic residues in the active site close to the chemical bonds in the substrate that will be altered in the reaction.^[50]Conformational changes can be measured usingcircular dichroismordual polarisation interferometry.After binding takes place, one or more mechanisms of catalysis lower the energy of the reaction'stransition stateby providing an alternative chemical pathway for the reaction. Mechanisms of catalysis include catalysis by bond strain; by proximity and orientation; by active-site proton donors or acceptors; covalent catalysis andquantum tunnelling.^[38][51]

Enzyme kinetics cannot prove which modes of catalysis are used by an enzyme. However, some kinetic data can suggest possibilities to be examined by other techniques. For example, a ping–pong mechanism with burst-phase pre-steady-state kinetics would suggest covalent catalysis might be important in this enzyme's mechanism. Alternatively, the observation of a strong pH effect onV_maxbut notK_Mmight indicate that a residue in the active site needs to be in a particularionisationstate for catalysis to occur.

In 1902Victor Henriproposed a quantitative theory of enzyme kinetics,^[52]but at the time the experimental significance of thehydrogen ion concentrationwas not yet recognized. AfterPeter Lauritz Sørensenhad defined the logarithmic pH-scale and introduced the concept ofbufferingin 1909^[53]the German chemistLeonor Michaelisand Dr.Maud Leonora Menten(a postdoctoral researcher in Michaelis's lab at the time) repeated Henri's experiments and confirmed his equation, which is now generally referred to asMichaelis-Menten kinetics(sometimes alsoHenri-Michaelis-Menten kinetics).^[54]Their work was further developed byG. E. BriggsandJ. B. S. Haldane,who derived kinetic equations that are still widely considered today a starting point in modeling enzymatic activity.^[55]

The major contribution of the Henri-Michaelis-Menten approach was to think of enzyme reactions in two stages. In the first, the substrate binds reversibly to the enzyme, forming the enzyme-substrate complex. This is sometimes called the Michaelis complex. The enzyme then catalyzes the chemical step in the reaction and releases the product. The kinetics of many enzymes is adequately described by the simple Michaelis-Menten model, but all enzymes haveinternal motionsthat are not accounted for in the model and can have significant contributions to the overall reaction kinetics. This can be modeled by introducing several Michaelis-Menten pathways that are connected with fluctuating rates,^[56][57][58]which is a mathematical extension of the basic Michaelis Menten mechanism.^[59]

ENZO(Enzyme Kinetics) is a graphical interface tool for building kinetic models of enzyme catalyzed reactions. ENZO automatically generates the corresponding differential equations from a stipulated enzyme reaction scheme. These differential equations are processed by a numerical solver and a regression algorithm which fits the coefficients of differential equations to experimentally observed time course curves. ENZO allows rapid evaluation of rival reaction schemes and can be used for routine tests in enzyme kinetics.^[60]

• Protein dynamics
• Diffusion limited enzyme
• Langmuir adsorption model

α.^{^}Link: Interactive Michaelis–Menten kinetics tutorial (Java required)

β.^{^}Link: dihydrofolate reductase mechanism (Gif)

γ.^{^}Link: DNA polymerase mechanism (Gif)

δ.^{^}Link: Chymotrypsin mechanism (Flash required)

Introductory

• Cornish-Bowden A (2012).Fundamentals of enzyme kinetics(4th ed.). Weinheim: Wiley-Blackwell.ISBN978-3-527-33074-4.
• Stevens L, Price NC (1999).Fundamentals of enzymology: the cell and molecular biology of catalytic proteins.Oxford [Oxfordshire]: Oxford University Press.ISBN978-0-19-850229-6.
• Bugg T (2004).Introduction to Enzyme and Coenzyme Chemistry.Cambridge, MA: Blackwell Publishers.ISBN978-1-4051-1452-3.
• Segel IH (1993).Enzyme kinetics: behavior and analysis of rapid equilibrium and steady state enzyme systems.New York: Wiley.ISBN978-0-471-30309-1.

Advanced

• Fersht A (1999).Structure and mechanism in protein science: a guide to enzyme catalysis and protein folding.San Francisco: W.H. Freeman.ISBN978-0-7167-3268-6.
• Schnell S, Maini PK (2004). "A century of enzyme kinetics: Reliability of the K_Mand v_maxestimates ".Comments on Theoretical Biology.8(2–3): 169–87.CiteSeerX10.1.1.493.7178.doi:10.1080/08948550302453.
• Walsh C (1979).Enzymatic reaction mechanisms.San Francisco: W. H. Freeman.ISBN978-0-7167-0070-8.
• Cleland WW, Cook P (2007).Enzyme kinetics and mechanism.New York: Garland Science.ISBN978-0-8153-4140-6.

• Animation of an enzyme assay— Shows effects of manipulating assay conditions
• MACiE— A database of enzyme reaction mechanisms
• ENZYME— Expasy enzyme nomenclature database
• ENZO— Web application for easy construction and quick testing of kinetic models of enzyme catalyzed reactions.
• ExCatDB— A database of enzyme catalytic mechanisms
• BRENDA— Comprehensive enzyme database, giving substrates, inhibitors and reaction diagrams
• SABIO-RK— A database of reaction kinetics
• Joseph Kraut's Research Group, University of California San Diego— Animations of several enzyme reaction mechanisms
• Symbolism and Terminology in Enzyme Kinetics— A comprehensive explanation of concepts and terminology in enzyme kinetics
• An introduction to enzyme kinetics— An accessible set of on-line tutorials on enzyme kinetics
• Enzyme kinetics animated tutorial— An animated tutorial with audio