Abstract

The human genome contains an estimated 3 billion bases of DNA making up some 100000 genes, and the variation within this genome accounts for human diversity and, in many cases, disease. Defining and understanding the expression profile of given genotypes is essential to understanding adverse effects from acute or chronic exposure to environmental toxicants or other stimuli. DNA array technology could help researchers understand how organisms function in response to exposure by elucidating the molecular mechanisms that underlie them. DNA arrays have been developed and refined over the past 5 years and matured into a relatively accessible and affordable technology. They vary in design from membrane-based filters with a few hundred cDNAs, to glass-based 'chips' with tens of thousands of genetic elements. Mammalian DNA arrays will soon allow expression analysis on a genome-wide scale, similar to that already accomplished in some lower organisms (e.g. S. cerevisiae, E. coli). These whole-genome arrays will be powerful tools for identifying and characterizing toxicants in environmental and pharmaceutical science. This review discusses the technology behind the production of DNA arrays, the options available to those interested in applying them to their own research, and the possible toxicological applications of this exciting new technology.