The Evolution of Controlled Multitasked Gene Networks: The Role of Introns and Other Noncoding RNAs in the Development of Complex Organisms

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Molecular Biology and Evolution 18:1611-1630 (2001)
© 2001 Society for Molecular Biology and Evolution

Review Article

The Evolution of Controlled Multitasked Gene Networks: The Role of Introns and Other Noncoding RNAs in the Development of Complex Organisms

John S. Mattick and Michael J. Gagen

Centre for Functional and Applied Genomics, Institute for Molecular Bioscience, University of Queensland, Brisbane, Queensland, Australia;
Department of Mechanical Systems Engineering, Kanazawa University, Kanazawa, Ishikawa, Japan

Eukaryotic phenotypic diversity arises from multitasking ofa core proteome of limited size. Multitasking is routine incomputers, as well as in other sophisticated information systems,and requires multiple inputs and outputs to control and integratenetwork activity. Higher eukaryotes have a mosaic gene structurewith a dual output, mRNA (protein-coding) sequences and introns,which are released from the pre-mRNA by posttranscriptionalprocessing. Introns have been enormously successful as a classof sequences and comprise up to 95% of the primary transcriptsof protein-coding genes in mammals. In addition, many othertranscripts (perhaps more than half) do not encode proteinsat all, but appear both to be developmentally regulated andto have genetic function. We suggest that these RNAs (eRNAs)have evolved to function as endogenous network control moleculeswhich enable direct gene-gene communication and multitaskingof eukaryotic genomes. Analysis of a range of complex geneticphenomena in which RNA is involved or implicated, includingco-suppression, transgene silencing, RNA interference, imprinting,methylation, and transvection, suggests that a higher-orderregulatory system based on RNA signals operates in the highereukaryotes and involves chromatin remodeling as well as otherRNA-DNA, RNA-RNA, and RNA-protein interactions. The evolutionof densely connected gene networks would be expected to resultin a relatively stable core proteome due to the multiple reuseof components, implying that cellular differentiation and phenotypicvariation in the higher eukaryotes results primarily from variationin the control architecture. Thus, network integration and multitaskingusing trans-acting RNA molecules produced in parallel with protein-codingsequences may underpin both the evolution of developmentallysophisticated multicellular organisms and the rapid expansionof phenotypic complexity into uncontested environments suchas those initiated in the Cambrian radiation and those seenafter major extinction events.

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