An alternative way of writing the Michaelis–Menten

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An alternative way of writing the Michaelis–Menten

equation: v=kcatkAe0akcat+kAe0awas introduced, selleckchem with Km replaced by kcat/kA. The symbol kA has achieved almost no currency, but the name specificity constant suggested for it has become widely accepted. This was a new term at the time, but it followed in a natural way from the realisation ( Fersht, 1977) that it was the natural parameter for quantifying the ability of an enzyme to discriminate between two or more alternative substrates that are simultaneously available. The section dealing with reactions that do not obey Michaelis–Menten kinetics was essentially confined to a brief mention of an equation for inhibition by excess substrate: v=V′aKmA′+a+a2/KiaIt was noted that the parameters V′V′ and KmA′ are not parameters of the Michaelis–Menten equation because this is not the Michaelis–Menten equation, so a symbol such as a  0.5 is appropriate to represent the substrate concentration at which v  =0.5V′V′, and definitely not KmA′, which is not equal to that concentration. For more elaborate kinds of departures from Michaelis–Menten kinetics (cooperativity and so on) the document referred to a later section with the same name. Regardless of the number of substrates, a reaction is said to obey Michaelis–Menten kinetics if the rate equation can be expressed in the following form: equation(4) v=e0(1/kcat)+(1/kAa)+(1/kBb)+…+(1/kABab)+…+(p/kAPa)which

can be regarded as a generalization

of the TSA HDAC manufacturer Michaelis–Menten equation for one substrate, and in which p   represents the concentration of a product. Each term in the denominator of the rate expression Diflunisal contains unity or any number of product concentrations in its numerator, and a coefficient k   and any number of substrate concentrations raised to no higher than the first power in its denominator. Thus a  , b  , ab  , etc., are all acceptable concentrations in the denominator of any individual denominator term, but a  2, for example, would not be; p  , q  , pq  , p  2, etc., are all acceptable concentration factors in the numerator of any denominator term. The constant k  cat corresponds to k  cat in Eq. (3); each other coefficient is assigned a subscript for each substrate concentration in the denominator of the term concerned and a superscript for each product concentration in its numerator. The constant term 1/k  cat must be present (because otherwise the rate would increase without limit with increasing concentrations of all substrate concentrations), together with one term for each substrate of the form 1/k  Aa  , but the terms in products of concentrations, such as those shown in Eq. (4) with coefficients k  AB and kAP, may or may not be present. The paragraph concluded by mentioning Dalziel coefficients, which use ϕA, for example, as the symbol corresponding to 1/kA.

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