In industrial enzymology, sometimes one has to deal with multi-substrate enzyme-catalyzed reactions. In such cases, the initial rate measurements depend upon whether the random or ordered mechanisms are involved. An excellent and comprehensive treatment for various possibilities is available at many places (Dixon et al., 1979, Eisenthal and Danson, 2002 and Purich,
2010). While the initial rate is a useful parameter for practical applications, a complete progress curve of the bioconversion or biotransformation is A-1210477 mw desirable, particularly in industrial enzymology. To be practically useful, a high conversion is desirable, often greater than 90%. An enzyme and reaction mixture that proceeds rapidly to 5% conversion, but then slows selleck chemical dramatically, will be less favoured than one that proceeds more slowly initially, but remains close to linear
to high conversion. The velocity of the reaction falls with time due to various reasons. These include (a) product inhibition (b) fall in substrate concentration to the extent that % saturation of the enzyme with the substrate changes significantly, (c) the product concentration increases and the substrate becomes depleted and the reaction velocity in the reverse direction may become significant, and (d) the operational stability of the enzyme may become a factor and enzyme may start getting inactivated. The presence of known or unknown reactive compounds present in the industrial grade substrates may contribute to this factor. Hence, if the enzyme is being used for a bioconversion or biotransformation for an industrial application, knowledge of just initial rates is not sufficient. In fact, it can be misleading. So, it is very necessary that complete progress curve of the reaction is drawn under intended process conditions. This can be done at the laboratory scale. Even this picture PD184352 (CI-1040) may change when the process is scaled up to the pilot plant or industrial level. But that is a different issue. It is the characteristic of enzymes as biocatalysts that they perform best at a particular temperature and pH and thermal inactivation begins in
a significant way beyond a certain temperature. Hence, information about these three characteristics is routinely expected in any research article describing a new enzyme. These issues are equally important in industrial enzymology as well. All three are discussed in most textbooks of biochemistry. However, each one requires a more careful consideration than frequently given. The activity vs. reaction temperature typically forms a bell shaped curve. Initial increase is due to increase in reaction rates with increase in temperature. Beyond the optimum value, the activity declines as protein chain unfolds, the thermal inactivation sets in (Gupta, 1993). However, it is important to distinguish between two very different patterns of behavior.