Interspecific comparisons of protein sequences can reveal regions of evolutionary conservation that are under purifying selection because of functional constraints. Interpreting these constraints requires combining evolutionary information with structural, biochemical, and physiological data to understand the biological function of conserved regions. We take this integrative approach to investigate the evolution and function of the nuclear-encoded subunits of cytochrome c oxidase (COX). We find that the nuclear-encoded subunits evolved subsequent to the origin of mitochondria and the subunit composition of the holoenzyme varies across diverse taxa that include animals, yeasts, and plants. By mapping conserved amino acids onto the crystal structure of bovine COX, we show that conserved residues are structurally organized into functional domains. These domains correspond to some known functional sites as well as to other uncharacterized regions. We find that amino acids that are important for structural stability are conserved at frequencies higher than expected within each taxon, and groups of conserved residues cluster together at distances of less than 5 A more frequently than do randomly selected residues. We, therefore, suggest that selection is acting to maintain the structural foundation of COX across taxa, whereas active sites vary or coevolve within lineages.

Examination of the genetic differences between aphids that can transmit citrus tristeza virus, CTV, and those which cannot, may lead to a greater understanding of the virus-aphid interactions necessitating virus acquisition and transmission. Since a cDNA library had been completed the previous year for the brown citrus aphid, a vector of CTV, a second aphid cDNA library was made to a non-CTV aphid vector, the pea aphid, Acyrthosiphon pisum. Comparisons between these two genetic datasets will provide a better understanding of the dynamics of aphid feeding, digestion, development, and may elucidate elements related to virus interactions that were previously unknown. Identification of the numerous proteins actively involved in feeding and digestion from aphids will provide specific targets for the development of new methods of control aimed at disrupting aphid feeding and ultimately reducing the acquisition and transmission of plant viruses which cause disease.

This paper identifies the prospects of using aphid species as ideal genetic model systems for the study of evolutionary developmental biology and genetic control of polyphenisms. The advantages and disadvantages of using aphids as genetic model organisms are discussed.