Enzymes popular literature

AP is the second most popular choice for antibody-enzyme conjugation, being used in almost 20 percent of all commercial enzyme-linked assays. Although P-gal and GO are used frequendy in research and cited numerous times in the literature, their utilization for commercial ELISA applications represents less than 1 percent of the total assays available. 

The two-step nature of SPDP crosslinking provides control over the conjugation process. Complexes of defined composition can be constructed by adjusting the ratio of enzyme to secondary molecule in the reaction as well as the amount of SPDP used in the initial activation. The use of SPDP in conjugation applications is extensively cited in the literature, perhaps making it one of the more popular crosslinkers available. It is commonly used to form immunoto-xins, antibody-enzyme conjugates, and enzyme-labeled DNA probes. A standard activation and coupling procedure can be found in Chapter 5, Section 1.1. 

In addition there is at least one area where enzyme-catalysed reactions have established themselves as the first line of attack for solving synthetic problems that area involves the transformations of carbohydrates. Indeed, biocatalysed transformations of saccharides is becoming increasingly popular and roughly 10% of the recent literature (Year 2000) on biotransformations involves the preparation and modification of carbohydrates. Early literature on chemoenzy-matic approaches for the synthesis of saccharides and mimetics has been reviewed by a pioneer in the field, C.-H. Wong[158]. For one of the most popular areas, enzyme-catalysed glycosylation reactions, a useful survey is also available, penned by the same senior author[159]. 

Although many methods for the quantitation of uric acid are described in the literature, the most popular methods today employ the uricase-mediated reaction however, the specificity of this reaction may be compromised by the choice of detector reaction, owing to either an interfering enzyme or a molecule that competes in the final color generation step. Today reactions that generate a visible end product are preferred because of the higher color yield however, care should be taken that interference caused by ascorbate, bilirubin, and unspecified interferants in plasma from patients with kidney failure is minimized. 

Use of a high field to activate a membrane enzyme was first reported by Witt et al. (25) in 1976. They used dc pulses of approximately 1 kV/cm and of 1-ms duration to induce ATP synthesis by the chloroplast ATPase. Following this initial work, there have been many reports on 1-kV/ cm dc field-induced ATP synthesis in different ATP synthetic systems (see the literature cited in references 13 and 14). The main conclusion from these studies is that an applied field-induced transmembrane potential can facilitate ATP release from the enzyme whether a PEF can affect enzyme turnover is not clear. Because 1-kV/ cm dc fields also cause severe Joule heating of a sample suspension, thermal effects cannot be easily avoided except when very short electric pulses (microseconds) are used. Thus, the method has limited utility for electroactivation experiments. The PEF method is, however, quite popular for the study of electroporation and electrofusion of cell membranes (see the chapter by J. Weaver in this volume), electroinsertion of membrane proteins (26), and electrotransfection of cells (27). 

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