Molecular Adaptation of Alanine : Glyoxylate Aminotransferase Targeting in Primates

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Molecular Biology and Evolution 17:387-400 (2000)
© 2000 Society for Molecular Biology and Evolution

Articles

Molecular Adaptation of Alanine : Glyoxylate Aminotransferase Targeting in Primates

Joanna D. Holbrook^*, Graeme M. Birdsey¹^,*, Ziheng Yang, Michael W. Bruford²^, and Christopher J. Danpure^,*

*MRC Laboratory for Molecular Cell Biology and
${dagger}$ Department of Biology, University College London, London, England; and
${ddagger}$ Institute of Zoology, London, England

The intermediary metabolic enzyme alanine : glyoxylate aminotransferase(AGT) is targeted to different organelles (mitochondria and/orperoxisomes) in different species. Possibly under the influenceof dietary selection pressure, the subcellular distributionof AGT has changed on at least eight occasions during the evolutionof mammals. AGT targeting is dependent on the variable use oftwo alternative transcription and translation initiation siteswhich determine whether or not the region encoding the N-terminalmitochondrial targeting sequence is contained within the openreading frame. In the present study, we sequenced the 5' regionof the AGT gene, including both ancestral translation startsites, for 11 anthropoid primates and compared the results withdata already available for two others. We show that while themore 3' of the two translation start sites is maintained inall species, the more 5' site has been lost in six species (fiveof seven catarrhines and one of six platyrrhines). In addition,the remaining two catarrhines, which have maintained the 5'translation start site, are predicted to have lost mitochondrialtargeting by a different mechanism, possibly loss of the more5' transcription start site. Analysis of the relative frequenciesof nonsynonymous and synonymous mutations in the region encodingthe extant or ancestral mitochondrial targeting sequences ledus to suggest that there has been recent strong positive selectionpressure to lose, or decrease the efficiency of, mitochondrialAGT targeting in several anthropoid lineages, and that the lossof mitochondrial targeting in this group of mammals is likelyto have occurred on at least four, and possibly five, separateoccasions.

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