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Codon usage and bias in mitochondrial genomes of parasitic platyhelminthes  

Le, Thanh-Hoa (Molecular Parasitology Laboratory, Australian Centre for International and Tropical Health and Nutrition, The Queensland Institute of Medical Research and The University of Queensland, Institute of Biotechnolog(IBT))
Mcmanus, Donald-Peter (Molecular Parasitology Laboratory, Australian Centre for International and Tropical Health and Nutrition, The Queensland Institute of Medical Research and The University of Queensland)
Blair, David (School of Tropical Biology, James Cook University)
Publication Information
Parasites, Hosts and Diseases / v.42, no.4, 2004 , pp. 159-167 More about this Journal
Abstract
Sequences of the complete protein-coding portions of the mitochondrial (mt) genome were analysed for 6 species of cestodes (including hydatid tapeworms and the pork tapeworm) and 5 species of trematodes (blood flukes and liver- and lung-flukes). A near-complete sequence was also available for an additional trematode (the blood fluke Schistosoma malayensis). All of these parasites belong to a large flatworm taxon named the Neodermata. Considerable variation was found in the base composition of the protein-coding genes among these neodermatans. This variation was reflected in statistically-significant differences in numbers of each inferred amino acid between many pairs of species. Both convergence and divergence in nucleotide, and hence amino acid, composition was noted among groups within the Neodermata. Considerable variation in skew (unequal representation of complementary bases on the same strand) was found among the species studied. A pattern is thus emerging of diversity in the mt genome in neodermatans that may cast light on evolution of mt genomes generally.
Keywords
base composition; codon usage; mitochondrial genome organisation; mitochondrial genomes; Platyhelminthes; skew;
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