Abstract
BackgroundSesame is an important and ancient oil crop in tropical and subtropical areas. China is one of the most important sesame producing countries with many germplasm accessions and excellent cultivars. Domestication and modern plant breeding have presumably narrowed the genetic basis of cultivated sesame. Several modern sesame cultivars were bred with a limited number of landrace cultivars in their pedigree. The genetic variation was subsequently reduced by genetic drift and selection. Characterization of genetic diversity of these cultivars by molecular markers is of great value to assist parental line selection and breeding strategy design.ResultsThree hundred and forty nine simple sequence repeat (SSR) and 79 insertion-deletion (InDel) markers were developed from cDNA library and reduced-representation sequencing of a sesame cultivar Zhongzhi 14, respectively. Combined with previously published SSR markers, 88 polymorphic markers were used to assess the genetic diversity, phylogenetic relationships, population structure, and allele distribution among 130 Chinese sesame accessions including 82 cultivars, 44 landraces and 4 wild germplasm accessions. A total of 325 alleles were detected, with the average gene diversity of 0.432. Model-based structure analysis revealed the presence of five subgroups belonging to two main groups, which were consistent with the results from principal coordinate analysis (PCA), phylogenetic clustering and analysis of molecular variance (AMOVA). Several missing or unique alleles were identified from particular types, subgroups or families, even though they share one or both parental/progenitor lines.ConclusionsThis report presented a by far most comprehensive characterization of the molecular and genetic diversity of sesame cultivars in China. InDels are more polymorphic than SSRs, but their ability for deciphering genetic diversity compared to the later. Improved sesame cultivars have narrower genetic basis than landraces, reflecting the effect of genetic drift or selection during breeding processes. Comparative analysis of allele distribution revealed genetic divergence between improved cultivars and landraces, as well as between cultivars released in different years. These results will be useful for assessing cultivars and for marker-assisted breeding in sesame.
Highlights
Sesame is an important and ancient oil crop in tropical and subtropical areas
Development and characterization of sesame simple sequence repeat (SSR) and InDels For those 1,949 non-redundant SSRs identified from unigenes of ‘Zhongzhi 14′ [44], 349 primer pairs named as SBM series were successfully designed and synthesized for genetic diversity analysis in sesame (Additional file 1: Table S1)
Superadded previously published sesame SSRs, a total of 815 Expressed sequence tag (EST)-SSRs and 134 genomic-SSRs were surveyed on the genomic DNA of ‘Zhongzhi 14′ and ‘Miaoqianzhima’
Summary
Sesame is an important and ancient oil crop in tropical and subtropical areas. China is one of the most important sesame producing countries with many germplasm accessions and excellent cultivars. Domestication and modern plant breeding have presumably narrowed the genetic basis of cultivated sesame. Sesame seeds are considered to have the highest oil contents among major oilseed crops including peanut, soybean and rapeseed [3]. Domestication and modern plant breeding have presumably narrowed the genetic basis of cultivated sesame, as has been in wheat, maize and other field crops [6,8,9]. These modern sesame cultivars were bred with a limited number of landrace cultivars in their pedigree. Assessment of genetic variation among these modern and landrace sesame cultivars can provide breeders with insight into the need to introgress more elite germplasm into their programs to broaden genetic variation
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