Genetic Diversity Among Jatropha and Jatropha-Related Species Based on ISSR Markers

Jatropha curcas (jatropha) is a potential biodiesel crop. A major limitation in production is that jatropha remains wild with low genetic variation. Related species/genera in the Euphorbiaceae can potentially be used for its genetic improvement. In this study, we employed inter-simple sequence repeats (ISSRs) to assess genetic variation among 30 accessions of jatropha, two accessions of bellyache bush (Jatropha gossypifolia), two accessions of spicy jatropha (Jatropha integerrima), two accessions of bottleplant shrub (Jatropha podagrica), and three accessions of castor bean hybrids. Genetic relationships were evaluated using 27 of 86 ISSR markers, yielding 307 polymorphic bands with polymorphism contents ranging from 0.76 to 0.95 for IMPN 1 and UBC 807 markers, respectively. Dice’s genetic similarity coefficient ranged from 0.39 to 0.99, which clearly separated the plant samples into seven groups at the coefficient of 0.48. The first group comprised J. curcas from Mexico, the second group comprised J. curcas from China and Vietnam, the third group comprised J. curcas from Thailand, the fourth group was J. integerrima, the fifth group was J. gossypifolia, the sixth group was J. podagrica, and the last and most distinct group was Ricinus communis. Analysis of molecular variance revealed that 63% of the variability was attributable to variation among groups, while 37% was due to variation within groups. Based on Nei’s genetic distance, the population from G2 (J. curcas from China) and G4 (J. curcas from Vietnam) had the least ISSR variability (0.0668), whereas G8 (R. communis) and Jatropha spp. displayed the highest distance (0.6005–0.7211).     

Quantitative trait loci mapping of Cercospora leaf spot resistance in mungbean, <Emphasis Type="Italic">Vigna radiata</Emphasis> (L.) Wilczek

Cercospora leaf spot (CLS) caused by the fungus Cercospora canescens Illis & Martin is a serious disease in mungbean (Vigna radiata (L.) Wilczek), and disease can reduce seed yield by up to 50%. We report here for the first time quantitative trait loci (QTL) mapping for CLS resistance in mungbean. The QTL analysis was conducted using F₂ (KPS1 × V4718) and BC₁F₁ [(KPS1 × V4718) × KPS1] populations developed from crosses between the CLS-resistant mungbean V4718 and CLS-susceptible cultivar Kamphaeng Saen 1 (KPS1). CLS resistance in F₂ populations was evaluated under field conditions during the wet seasons of 2008 and 2009, and resistance in BC₁F₁ was evaluated under field conditions during the wet season in 2008. Seven hundred and fifty-three simple sequence repeat (SSR) markers from various legumes were used to assess polymorphism between KPS1 and V4718. Subsequently, 69 polymorphic markers were analyzed in the F₂ and BC₁F₁ populations. The results of segregation analysis indicated that resistance to CLS is controlled by a single dominant gene, while composite interval mapping consistently identified one major QTL (qCLS) for CLS resistance on linkage group 3 in both F₂ and BC₁F₁ populations. qCLS was located between markers CEDG117 and VR393, and accounted for 65.5–80.53% of the disease score variation depending on seasons and populations. An allele from V4718 increased the resistance. The SSR markers flanking qCLS will facilitate transferral of the CLS resistance allele from V4718 into elite mungbean cultivars.     

Genetic diversity and structure of the zombi pea (<Emphasis Type="Italic">Vigna vexillata</Emphasis> (L.) A. Rich) gene pool based on SSR marker analysis

Zombi pea (Vigna vexillata (L.) A. Rich) is an underutilized legume species and a useful gene source for resistance to biotic and abiotic stresses, although there is little understanding on its genetic diversity and structure. In this study, 422 (408 wild and 14 cultivated) accessions of zombi pea from diverse origins (201 from Africa, 126 from America, 85 from Australia, 5 from Asia and 5 from unknown origin) were analyzed with 20 simple sequence repeat (SSR) markers to determine its genetic diversity and genetic structure. The SSR markers detected 273 alleles in total with a mean of 13.6 alleles per locus. Polymorphism information content values of the markers varied from 0.58 to 0.90 with an average of 0.76. Overall gene diversity was 0.715. Gene diversity and average allelic richness was highest in Africa (0.749 and 8.08, respectively) and lowest in America (0.435 and 4.10, respectively). Nei’s genetic distance analysis revealed that the highest distance was between wild Australia and cultivated Africa (0.559), followed by wild West Africa and wild Australia (0.415). STRUCTURE, neighbor-joining (NJ), and principal coordinate analyses consistently showed that these zombi pea accessions were clustered into three major groups, viz. America, Africa and Asia, and Australia. NJ tree also suggested that American and Australian accessions are originated from East African zombi peas, and that the cultivated accessions from Africa and Asia were genetically distinct, while those from America were clustered with some cultivated accessions from Africa. These results suggest that Africa is the center of origin and diversity of zombi pea, and that domestication of this pea took place more than once in different regions.     

A PCR-based marker for a locus conferring aroma in vegetable soybean (<Emphasis Type="Italic">Glycine max</Emphasis> L.)

Vegetable soybean (Glycine max L.) is an important economic and nutritious crop in South and Southeast Asian countries and is increasingly grown in the Western Hemisphere. Aromatic vegetable soybean is a special group of soybean varieties that produce young pods containing a sweet aroma, which is produced mainly by the volatile compound 2-acetyl-1-pyrroline (2AP). Due to the aroma, the aromatic vegetable soybean commands higher market prices and gains wider acceptance from unfamiliar consumers. We have previously reported that the GmAMADH2 gene encodes an AMADH that regulates aroma (2AP) biosynthesis in soybeans (Arikit et al. 2010). A sequence variation involving a 2-bp deletion in exon 10 was found in this gene in all investigated aromatic varieties. In this study, a codominant PCR-based marker for the aroma trait in soybeans was designed based on the 2-bp deletion in GmAMADH2. The marker was verified in five aromatic and five non-aromatic varieties as well as in F₂ soybean population segregating for aroma. The aromatic genotype with the 2-bp deletion was completely associated with the five aromatic soybean varieties as well as the aromatic progeny of the F₂ population with seeds containing 2AP. Similarly, the non-aromatic genotype was associated with the five non-aromatic varieties and non-aromatic progeny. The perfect co-segregation of the marker genotypes and aroma phenotypes confirmed that the marker could be efficiently used for molecular breeding of soybeans for aroma.     

Characterization of microsatellites and gene contents from genome shotgun sequences of mungbean (Vigna radiata (L.) Wilczek)

Background  

Mungbean is an important economical crop in Asia. However, genomic research has lagged behind other crop species due to the lack of polymorphic DNA markers found in this crop. The objective of this work is to develop and characterize microsatellite or simple sequence repeat (SSR) markers from genome shotgun sequencing of mungbean.     

Inheritance of resistance to iron deficiency and identification of AFLP markers associated with the resistance in mungbean (Vigna radiata (L.) Wilczek)

Iron deficiency chlorosis (IDC) is a major problem reducing yield of mungbean in many countries. In this study, we crossed “KPS1”, the most popular Thai mungbean cultivar susceptible to IDC with “NM10-12”, a mungbean line from Pakistan resistant to IDC. Segregation analysis of the F₂ population revealed that the resistance is controlled by a major gene (IR) with dominant effect. Two AFLP markers, E-ACT/M-CTA and E-ACC/M-CTG were identified closely linking with the IR gene. The frequencies of these markers were assessed in 241 mungbean accessions from several countries. The accessions could be divided, in relative to total chlorophyll content of the resistant check (NM10-12) and the susceptible check (KPS1), into the resistant group with 125 accessions and the susceptible group with 116 accessions. Among 125 resistant accessions, E-ACT/M-CTA and E-ACC/M-CTG were present in 119 (95%) and 109 (87%) accessions, respectively. Both markers can identify all resistant accessions from England, Indonesia and Pakistan, but only E-ACT/M-CTA linked to all resistant accessions from Australia, India, Iraq, Taiwan and Thailand. Understanding the inheritance and identifying molecular markers linking to the IR gene can help plant breeders to improve this crop for growing in iron-deficient soils.     

Development and characterization of EST-SSR markers from Jatropha curcas EST database and their transferability across jatropha-related species/genus

Jatropha curcas (jatropha) is a multipurpose plant with potential as a raw material for biofuel. In the present study, a total of 43,349 expressed sequence tags (ESTs) from J. curcas were searched for type and frequency of simple sequence repeat (SSR) markers. Five thousand one hundred and seventy-five sequences were indentified to contain 6,108 SSRs with 90.8% simple and 9.2% compound repeat motifs. One hundred and sixty-three EST-SSRs were developed and used to evaluate the transferability and genetic relatedness among 4 accessions of J. curcas from China, Mexico, Thailand and Vietnam; 5 accessions of congeneric species, viz. J. gossypiifolia, dwarf J. integerrima, normal J. integerrima, J. multifida, J. podagrica; and Ricinus communis. The polymorphic markers showed 75.56–85.19% transferability among four species of Jatropha and 26.67% transferability across genera in Ricinus communis. Investigation of genetic relatedness showed that J. curcas and J. integerrima are closely related. EST-SSRs used in this study demonstrate a high efficiency of cross species/genera amplification and are useful for identifying genetic diversity of jatropha and its close taxa and to choose the desired related species for wide crossing to improve new varieties of jatropha. The markers can also be further exploited for genetic resource management and genetic improvement of related species/genera through marker-assisted breeding programs.