Enzymes with single-substrate mechanisms include
isomerases such as
triosephosphateisomerase or
bisphosphoglycerate mutase, intramolecular
lyases such as
adenylate cyclase, and the
hammerhead ribozyme, an RNA lyase. However, some enzymes that only have a single substrate do not fall into this category of mechanisms.
Catalase is an example of this, as the enzyme reacts with a first molecule of
hydrogen peroxide substrate, 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 the
Multi-substrate reactions section below.
Michaelis–Menten kinetics 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 (v_0) increases as [S] increases. However, as [S] gets higher, the enzyme becomes saturated with substrate and the initial rate reaches
Vmax, the enzyme's maximum rate. In the Michaelis–Menten kinetic model of a single-substrate reaction there is an initial
bimolecular reaction between 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 Vmax; at Vmax, 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 a unimolecular reaction with an order of zero. Though the enzymatic mechanism for the unimolecular reaction 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 constant kcat. If the reaction path proceeds over one or several intermediates,
kcat will 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 constant
k2. The apparent unimolecular rate constant
kcat is also called
turnover number, and denotes the maximum number of enzymatic reactions catalysed per second. The Michaelis–Menten equation describes how the (initial) reaction rate
v0 depends on the position of the substrate-binding
equilibrium and the rate constant
k2. : v_0 = \frac{V_{\max}[\ce{S}]}{K_M + [\ce{S}]}
(Michaelis–Menten equation) with the constants : \begin{align} 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{align} 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 no
allostericity or
cooperativity). 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. d\ce{[ES]}/{dt} \; \overset{!} = \;0 . The second assumption is that the total enzyme concentration does not change over time, thus \ce{[E]}_\text{tot} = \ce{[E]} + \ce{[ES]} \; \overset{!} = \; \text{const} . The Michaelis constant
KM is experimentally defined as the concentration at which the rate of the enzyme reaction is half
Vmax, which can be verified by substituting [S] =
KM into the Michaelis–Menten equation and can also be seen graphically. If the rate-determining enzymatic step is slow compared to substrate dissociation (k_2 \ll k_{-1} ), the Michaelis constant
KM is roughly the
dissociation constant KD of the ES complex. If [S] is small compared to K_M then the term [\ce S] / (K_M + [\ce S]) \approx [\ce S] / K_M and also very little ES complex is formed, thus [E]_{\rm tot} \approx [E]. Therefore, the rate of product formation is :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 k_2 / K_M. This constant is a measure of
catalytic efficiency. The most efficient enzymes reach a k_2 / K_M in the range of . 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 as kinetically perfect enzymes. But most enzymes are far from perfect: the average values of k_{2}/K_{\rm M} and k_{2} are about 10^5 {\rm s}^{-1}{\rm M}^{-1} and 10 {\rm s}^{-1}, respectively.
Direct use of the Michaelis–Menten equation for time course kinetic analysis The observed velocities predicted by the Michaelis–Menten equation can be used to directly model the
time course disappearance of substrate and 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 of
Euler's number in the description of first order chemical kinetics. i.e.
e−
k is 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. :[S]=[S]_0(1-k)^{t}\, :[S]=[S]_0(1-v/[S]_0)^{t}\, :[S]=[S]_0(1-(V_{\max} [S]_0 / (K_M + [S]_0)/[S]_0))^{t}\, In 1983 Stuart Beal (and also independently
Santiago Schnell and Claudio Mendoza in 1997) derived a closed form solution for the time course kinetics analysis of the Michaelis-Menten mechanism. The solution, known as the Schnell-Mendoza equation, has the form: :\frac{[S]}{K_M} = W \left[ F(t) \right]\, where W[ ] is the
Lambert-W function and where F(t) is :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, which is also valid when the initial substrate concentration is close to that of enzyme, :\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 the
Lambert-W function.
Linear plots of the Michaelis–Menten equation The plot of
v versus [S] above is not linear; although initially linear at low [S], it bends over to saturate at high [S]. Before the modern era of
nonlinear curve-fitting on computers, this nonlinearity could make it difficult to estimate
KM and
Vmax accurately. Therefore, several researchers developed linearisations of the Michaelis–Menten equation, such as the Lineweaver–Burk plot, the Eadie–Hofstee diagram and the Hanes–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 by nonlinear regression methods. The Lineweaver–Burk plot or double reciprocal plot is a common way of illustrating kinetic data. This is produced by taking the
reciprocal of both sides of the Michaelis–Menten equation. This is a linear form of the Michaelis–Menten equation and produces a straight line with the equation
y = m
x + c with a
y-intercept equivalent to 1/
Vmax and an
x-intercept of the graph representing −1/
KM. :\frac{1}{v} = \frac{K_{M}}{V_{\max} [\mbox{S}]} + \frac{1}{V_\max} No experimental values can be taken at negative 1/[S]; the lower limiting value 1/[S] = 0 (the
y-intercept) corresponds to an infinite substrate concentration, where
1/v=1/Vmax thus, the
x-intercept is an
extrapolation of 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 of
Vmax and
KM. A more accurate linear plotting method is the
Eadie–Hofstee plot. In this case,
v is plotted against
v/[S]. In the third common linear representation, the
Hanes–Woolf plot, [S]/
v is 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.
Practical significance of kinetic constants 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,
KM and
Vmax, are critical to attempts to understand how enzymes work together to control
metabolism. Making these predictions is not trivial, even for simple systems. For example,
oxaloacetate is formed by
malate dehydrogenase within the
mitochondrion. Oxaloacetate can then be consumed by
citrate synthase,
phosphoenolpyruvate carboxykinase or
aspartate aminotransferase, feeding into the
citric acid cycle,
gluconeogenesis or
aspartic acid biosynthesis, 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 and
gene expression data 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 called
flux balance analysis.
Michaelis–Menten kinetics with intermediate One could also consider the less simple case : {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 : v_0 = k_{cat}\frac\ce{[S] [E]_0}{K_M^{\prime}+ \ce{[S]}} but the constants are different : \begin{align} 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{align} We see that for the limiting case k_3 \gg k_2, thus when the last step from EI -> E + P is much faster than the previous step, we get again the original equation. Mathematically we have then K_M^{\prime} \approx K_M and k_{cat} \approx k_2. ==Multi-substrate reactions==