Evidence of diploidy in the wild Amerindian yam, a putative progenitor of the endangered species Dioscorea trifida (Dioscoreaceae).

The fundamental question about Dioscorea trifida (Dioscoreaceae), the most important Amerindian yam, that remains unresolved concerns its evolutionary origin, since no wild relative has been reported. In this paper we report the existence of D. trifida's wild relative for the first time. The diploidy of wild D. trifida (2n = 40) is clearly demonstrated by flow cytometry, chromosome counts, and microsatellite pattern analysis, whereas the cultivated form was previously shown to be autotetraploid (2n = 80). In the coastal region where the wild and cultivated forms are sympatric, tetraploid and triploid cytotypes coexist within the same populations. In the sites where the wild and cultivated forms are allopatric, the wild diploid cytotype predominates. AFLP (amplified fragment length polymorphism) analyses gave an initial idea of the position of the wild forms in relation to the cultivated forms. All the wild and cultivated types form a monophyletic group structured into two major subgroups corresponding to the tetraploid cytotype of the cultivated form and the diploid cytotype of the wild form. The triploid cytotypes of the wild form are in an intermediary position. Wild accessions are grouped on the basis of their geographic origin. The data presented in this paper are significant for the effective breeding and conservation of D. trifida and to assess its genetic diversity and population structure for the general understanding of the evolution and domestication of the species.

Dilemmas caused by endogenous pararetroviruses regarding the taxonomy and diagnosis of yam (Dioscorea spp.) badnaviruses: analyses to support safe germplasm movement.

The discovery of endogenous pararetroviral sequences (EPRVs) has had a deep impact on the approaches needed for diagnosis, taxonomy, safe movement of germplasm and management of diseases caused by pararetroviruses. In this article, we illustrate this through the example of yam (Dioscorea spp.) badnaviruses. To enable progress, it is first necessary to clarify the taxonomical status of yam badnavirus sequences. Phylogeny and pairwise sequence comparison of 121 yam partial reverse transcriptase sequences provided strong support for the identification of 12 yam badnavirus species, of which ten have not been previously named. Virus prevalence data were obtained, and they support the presence of EPRVs in D. rotundata, but not in D. praehensilis, D. abyssinica, D. alata or D. trifida. Five yam badnavirus species characterised by a wide host range seem to be of African origin. Seven other yam badnavirus species with a limited host range are probably of Asian-Pacific origin. Recombination under natural circumstances appears to be rare. Average values of nucleotide intra-species genetic distances are comparable to data obtained for other RNA and DNA virus families. The dispersion scenarios proposed here, combined with the fact that host-switching events appear common for some yam badnaviruses, suggest that the risks linked to introduction via international plant material exchanges are high.

Microsatellite segregation analysis and cytogenetic evidence for tetrasomic inheritance in the American yam Dioscorea trifida and a new basic chromosome number in the Dioscoreae.

Despite the economic and cultural importance of the indigenous "Amerindian" yam Dioscorea trifida, very little is known about their origin, phylogeny, diversity and genetics. Consequently, conventional breeding efforts for the selection of D. trifida genotypes resistant to potyviruses which are directly involved in the regression of this species have been seriously limited. Our objective of this paper is to contribute to the clarification of the cytogenetic status, i.e., inheritance and chromosome number. Our results provide genetic evidence supporting tetrasomic behaviour of the genome of D. trifida based on chromosomal segregation pattern analysis using eight SSRs markers in three different crosses. This is the first reliable evidence of an autopolyploid species in the genus Dioscorea. The second major result in this study is the revealing of a new base chromosome number in the botanical section Macrogynodium to which D. trifida belongs. To date, our assumptions about the ploidy level of yams are based on the observations that the basic chromosome number is 10 or 9, and D. trifida was described as octoploid. The chromosome number of D. trifida accessions was also assessed using somatic chromosomic count techniques. Flow cytometry did not show significant variation of 2C DNA content among 80 accessions indicating homogeneity of the ploidy level of the cultivated D. trifida. This suggests that autotetraploidy is well established as well as the rule for the cultivated pool of D. trifida, even if the direct diploid ancestor remains to be identified. The data presented in this paper are significant and important for the effective breeding and conservation of the species and for elucidating the phylogeny and the origins of the yam and the evolution of the genus Dioscorea.

Origin, world-wide dispersion, bio-geographical diversification, radiation and recombination: an evolutionary history of Yam mild mosaic virus (YMMV).

We developed an evolutionary epidemiological approach to understand the regional and world-wide dispersion of Yam mild mosaic virus (YMMV) by retracing its evolutionary history. Analyses of the distribution and the prevalence of YMMV in the Caribbean islands of Guadeloupe and Martinique, and in French Guyana revealed that YMMV has a wide repartition and different prevalence on Dioscorea alata L. (Asian and Oceanic origin), on D. cayenensis Lam.-D. rotundata Poir. (African origin) and on D. trifida L. (Amazon and the Caribbean origin) in this region. Considering the data on the current dispersion of the virus and the evolution and the history of the yams, the phylogenetic analysis of the 3' terminal part of the YMMV genome gave a consistent support of the Asian-Pacific origin of YMMV from D. alata species. The YMMV phylogenetic tree is star-like, suggesting an early split of the genetic lineages. An important part of the clades is constituted by a single lineage arisen by recombination. The largest emerging monophyletic group illustrates well YMMV geographical dispersion. This evolutionary pattern contrasts with the one revealed by the African distinct lineages and by the second significant monophyletic group, for which a host adaptation to D. trifida is suggested. The analysis of the pattern of nucleotide substitutions in the CP gene revealed that purifying selection dominates the evolution of the CP of potyviruses and strongly operates on the YMMV. Switching events, radiation, host and geographical adaptation and recombination events are proposed as major traits of YMMV evolutionary history.