Genetic differentiation of the G6/7 cluster of Echinococcus canadensis based on mitochondrial marker genes.

Among the genotype/species causing cystic echinococcosis, the taxonomic status of Echinococcus canadensis is only partially resolved. Within E. canadensis, four genotypes (G6, G7, G8 and G10) have been described based on short mitochondrial sequences, of which G6 and G7 (the 'camel' and the 'pig' strain, respectively) are closely related and variously regarded as microvariants of a single strain G6/7. Globally, this G6/7 cluster is the second most important agent of human cystic echinococcosis and is the predominant Echinococcus taxon in large parts of sub-Saharan Africa. To add data on the internal structure and the geographical distribution of this cluster, we analysed diversity and population structure of 296 isolates of E. canadensis from sub-Saharan Africa, the Middle East and Europe using the complete mitochondrial cytochrome c oxidase subunit 1 (cox1) (1,608bp) and NADH dehydrogenase subunit 1 (nad1) (894bp) gene sequences. Polymorphism of the mtDNA loci gave 51 (cox1), 33 (nad1) and 73 (cox1-nad1 concatenated) haplotypes. African and Middle Eastern isolates mainly grouped in a star-like structure around a predominant haplotype, while the European isolates produced more diversified networks. Although the cox1 diagnostic sequence for G6 is frequent in the African/Middle Eastern sub-cluster, and that for G7 is common in the European isolates, numerous intermediate variants prevent a clear distinction into 'G6' or 'G7', and the entire taxon is best treated as a common haplotype cluster G6/7. Meanwhile, the G6/7 cluster is clearly distinct from sequences of wildlife isolates of G8 and G10 from the northern hemisphere, and sequences of the latter genotypes were remarkably distant from each other. It is clear from the present study that, based on mitochondrial data, G6/7 is a coherent genotypic entity within E. canadensis that retains substantial intraspecific variance, and sub-populations share common ancestral polymorphisms and haplotypes. This study provides the basis for wider biogeographic comparison and population genetics studies of this taxon.

Genetic categorization of Echinococcus granulosus from humans and herbivorous hosts in Iran using an integrated mutation scanning-phylogenetic approach.

In the present study, we have extended earlier taxonomic, biochemical and experimental investigations to characterize Echinococcus granulosus from various hosts in Iran utilizing DNA regions (designated pcox1 and pnad1) within the cytochrome c oxidase subunit 1 and NADH dehydrogenase 1 mitochondrial genes, respectively. An emphasis was placed on the characterization of E. granulosus isolates (cyst material) from humans, sheep, goats, cattle and camels, and on assessing their genetic relationships. PCR-based SSCP analysis of pcox1 and pnad1 amplicons derived from individual isolates (n=148) of E. granulosus revealed five (pc1-pc5) and nine (pn1-pn9) electrophoretic profiles, respectively. Sequencing of pcox1 and pnad1 amplicons representing unique SSCP profiles demonstrated that each profile was linked unequivocally to a particular sequence and that single point mutations were readily detectable by SSCP. Phylogenetic analyses of pcox1 and/or pnad1 nucleotide sequence data were conducted using Bayesian inference and maximum likelihood tree-building methods. Following the phylogenetic analyses of concatenated pcox1+pnad1 sequence data, including representatives of all presently recognized Echinococcus species/genotypes as well as Taenia saginata (as the outgroup), the majority of cyst isolates (142 of 148; 95.9%) from humans, ruminants (sheep, goats and cattle) and camels were assigned to the G1-G3 complex of E. granulosus (or E. granulosus sensu stricto), whereas some E. granulosus cysts (6 of 19; 31.6%) from camels were assigned to the G6-G10 complex (or E. canadensis). The present study reinforces the advantages of the mutation scanning-sequencing-phylogenetic approach to explore variation in multiple mitochondrial loci within and among Echinococcus populations, which provides a platform for future, detailed studies of the molecular epidemiology of E. granulosus in Iran and other countries. (Note: The sequences determined in the present study have been deposited in the GenBank database under accession numbers: FJ796203-FJ796207 (pcox1) and FJ796208-FJ796216 (pnad1)).