Xenobiotics and the Evolution of Multicellular Animals: Emergence and Diversification of Ligand-Activated Transcription Factors

doi:10.1093/icb/45.1.172

Integrative and Comparative Biology 2005 45(1):172-178; doi:10.1093/icb/45.1.172

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The Society for Integrative and Comparative Biology

Xenobiotics and the Evolution of Multicellular Animals: Emergence and Diversification of Ligand-Activated Transcription Factors¹

Michael E. Baker²^,1
¹ Department of Medicine, 0693, University of California, San Diego, 9500 Gilman Drive, La Jolla, California 92093-0693

Multicellular animals, which evolved about 700 to 1,000 myrago, contain many of the genes found in yeast. Important forthe evolution of multicellular animals were new pathways forintercellular signaling that regulated more complex physiologicalresponses. Here we focus on the contribution to this processof lipophilic molecules that interact with nuclear receptorsand the aryl hydrocarbon receptor, as well as enzymes that regulatethe concentrations of these molecules. Both nuclear receptorsand the aryl hydrocarbon receptor are found in invertebratesand vertebrates. We propose that environmental chemicals (xenobiotics)have been an important influence on the evolution of multicellularanimals through a process involving the co-evolution of ligand-activatedtranscription factors and enzymes that detoxify xenobiotics.Indeed, this conversion of "xenobiotic swords" into "adaptiveplowshares" contributed to the diverse physiology found in multicelluaranimals. An important implication of this analysis is that enzymesas well as hormone receptors are vulnerable targets for endocrinedisruptors. That is, some toxic chemicals act by inhibitingthe enzymes that catalyze the formation or degradation of lipophilicsignals, such as steroids, thus, disrupting hormone action.

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Integrative and Comparative Biology

Xenobiotics and the Evolution of Multicellular Animals: Emergence and Diversification of Ligand-Activated Transcription Factors1

Xenobiotics and the Evolution of Multicellular Animals: Emergence and Diversification of Ligand-Activated Transcription Factors¹