Two novel symbiovars of Bradyrhizobium yuanmingense, americaense and caribense, the symbiovar tropici of Bradyrhizobium pachyrhizi and the symbiovar cajani of Bradyrhizobium cajani are microsymbionts of the legume Cajanus cajan in Dominican Republic.

Cajanus cajan L. (guandul) is commonly cultivated in Dominican Republic where this legume is a subsistence crop. Here we identified through MALDI-TOF MS several rhizobial strains nodulating C. cajan in two Dominican locations as Bradyrhizobium yuanmingense. The phylogenetic analysis of recA and glnII housekeeping genes showed that these strains belong to a wide cluster together with the type strain of B. yuanmingense and other C. cajan nodulating strains previously isolated in Dominican Republic. The comparison of genomes from strains representative of different lineages within this cluster support the existence of several genospecies within B. yuanmingense, which is the major microsymbiont of C. cajan in Dominican Republic where it is also nodulated by Bradyrhizobium cajani and Bradyrhizobium pachyrhizi. The analysis of the symbiotic nodC gene showed that the C. cajan nodulating strains from the B. yuanmingense complex belong to two clusters with less than 90% similarity between them. The strains from these two clusters showed nodC gene similarity values lower than 90% with respect to the remaining Bradyrhizobium symbiovars and then they correspond to two new symbiovars for which we propose the names americaense and caribense. The results of the nodC gene analysis also showed that C. cajan is nodulated by the symbiovar tropici, which has been found by first time in this work within the species Bradyrhizobium pachyrhizi. These results confirmed the high promiscuity degree of C. cajan, which is also nodulated by the symbiovar cajani of Bradyrhizobium cajani in Dominican Republic.

Whole-genome resequencing of 292 pigeonpea accessions identifies genomic regions associated with domestication and agronomic traits.

Pigeonpea (Cajanus cajan), a tropical grain legume with low input requirements, is expected to continue to have an important role in supplying food and nutritional security in developing countries in Asia, Africa and the tropical Americas. From whole-genome resequencing of 292 Cajanus accessions encompassing breeding lines, landraces and wild species, we characterize genome-wide variation. On the basis of a scan for selective sweeps, we find several genomic regions that were likely targets of domestication and breeding. Using genome-wide association analysis, we identify associations between several candidate genes and agronomically important traits. Candidate genes for these traits in pigeonpea have sequence similarity to genes functionally characterized in other plants for flowering time control, seed development and pod dehiscence. Our findings will allow acceleration of genetic gains for key traits to improve yield and sustainability in pigeonpea.

SSR genetic diversity assessment of popular pigeonpea varieties in Malawi reveals unique fingerprints

Background: Pigeonpea (Cajanus cajan (L.) Millsp.) is a drought tolerant legume of the Fabaceae family and the only cultivated species in the genus Cajanus. It is mainly cultivated in the semi-arid tropics of Asia and Oceania, Africa and America. In Malawi, it is grown as a source of food and income and for soil improvement in intercropping systems. However, varietal contamination due to natural outcrossing causes significant quality reduction and yield losses. In this study, 48 polymorphic SSR markers were used to assess the diversity among all pigeonpea varieties cultivated in Malawi to determine if a genetic fingerprint could be identified to distinguish the popular varieties. Results: A total of 212 alleles were observed with an average of 5.58 alleles per marker and a maximum of 14 alleles produced by CCttc019 (Marker 40). Polymorphic information content (PIC), ranged from 0.03 to 0.89 with an average of 0.30. A neighbor-joining tree produced 4 clusters. The most commonly cultivated varieties, which include released varieties and cultivated land races, were well-spread across all the clusters observed, indicating that they generally represented the genetic diversity available in Malawi, although substantial variation was evident that can still be exploited through further breeding. Conclusion: Screening of the allelic data associated with the five most popular cultivated varieties, revealed 6 markers - CCB1, CCB7, Ccac035, CCttc003, Ccac026 and CCttc019 - which displayed unique allelic profiles for each of the five varieties. This genetic fingerprint can potentially be applied for seed certification to confirm the genetic purity of seeds that are delivered to Malawi farmers.

Characterization of Ty1/copia-like retrotransposon families from pigeonpea genome.

Retrotransposons contribute significantly to the size, organization, and genetic diversity of their host genomes. To characterize novel retrotransposon families in pigeonpea and develop retrotransposon-based sequence-specific amplification polymorphic markers, in silico homology sequence search was carried out against the whole genome shotgun sequence of pigeonpea variety Asha (ICPL87119). For homology searching, 5 copia-like retro elements belonging to soybean, common bean, mungbean, chickpea, and field pea were used as query sequences. Contigs with at least 80% query coverage and >70% similarity were searched for retroelements using the long terminal repeat finder. A total of 28 copia-like retroelements were identified using this method. Multiple sequence alignment for the reverse transcriptase domain indicated conserved reverse transcriptase domains in all 28 elements compared with other reported elements. Phylogenetic analysis based on reverse transcriptase domains revealed 11 families. The copy number per family ranged from 1 (for B, J, and K family) to 8 (I). The sequence-specific amplification polymorphic marker-based insertion site profiling for one of the retrotransposon families (G) confirmed multiple insertions of this element across the pigeonpea genome. This study showed that our in silico homology search strategy was efficient for identifying and characterizing the Ty1/copia-like retrotransposon. The results of this study are useful for developing retrotransposon-based sequence-specific amplification polymorphic markers for pigeonpea crop improvement.