Application of separator isoelectric focusing within the pH range 4-6

Steady state electrolysis and isoelectric focusing

The properties of pH gradients formed by stationary electrolysis of weak mobile or fixed electrolytes are analyzed. The model uses the appropriate balance equations and those of chemical equilibria. It is shown how the equation of the current density has to be modified for considering that fraction of current that is associated with the diffusion of neutral buffer molecules within a pH gradient. Furthermore it is shown that the pH gradients themselves give rise to water production within the gradient and that essential properties of the steady state are related to chemical reactions between the electrolyte constituents. The differential equations describing the gradients of the concentration of a given component, the pH, conductivity and potential are explicitly formulated in relation to those reactions. The equations are solved numerically and the significance of the results for isoelectric focusing is discussed. The experimental conditions to reach shallow and smooth pH gradients exhibiting sufficient ionic strength are formulated.

Selection of chemical spacers to improve isoelectric focusing resolving power: implications for use in two-dimensional electrophoresis

Presented here is a straightforward and inexpensive method for expanding isoelectric focusing pH gradients relative to the gradients that are formed by commercially available narrow range ampholytes. This method requires no special equipment or techniques and is applicable to isoelectric focusing in acrylamide gels, in Sephadex, and in agarose. The utility of separators in improving the resolving power of two-dimensional polyacrylamide gel electrophoresis is demonstrated using proteins from the exocytotic trichocyst organelle of Paramecium tetraurelia. The mode of action of separators is briefly described.

Group-specific component: a review of the isoelectric focusing methods and auxiliary methods available for the separation of its phenotypes

This review compares the major isoelectric focusing methods that have been published for the separation of group-specific component (Gc) phenotypes since 1978. The various parameters of gel composition, size, electrical and running conditions and sample application points are listed. More current auxiliary methods are also listed. These relate to the extraction of Gc from bloodstains and its identification after isoelectric focusing. Protocols are then recommended for the forensic analysis of Gc phenotypes.