The electrophoretic polymorphism of bacterial esterases

Abstract

Abstract The specific activities of esterases and certain other molecular properties including immunospecificity indicate that the electrophoretic variations of these enzymes in bacterial populations are the result of allelic variations at specific gene loci. The esterase polymorphism of Enterobacteriaceae and some other species isolated from man or animals demonstrates that esterases can distinguish between bacteria at the species or subspecies level, both by their biochemical properties and by their electrophoretic differences. The esterase data complement DNA hybridization studies and agree with ribosomal DNA polymorphism, especially for delineating a phylogenetically distinct group of highly pathogenic strains in Escherichia coli. A two-dimensional electrophoretic profile obtained by establishing a direct correspondence between homologous esterase bands resolved by independent runs of isoelectric focusing and standard electrophoresis considerably improves the detection of allelic variations, whereas protein titration curves (electrophoresis in pH gradient) can be used to demonstrate the real electrophoretic homogeneity of allozymes or evalue their molecular relationship in terms of apparent amino acid substitutions. This overview establishes that esterases, by their significant electrophoretic polymorphism, are reliable molecular markers for systematics and epidemiology, and are suitable enzyme systems for studying population genetics and phylogeny.