Abstract
BackgroundQuality control (QC) analysis is an important component in maize breeding and seed systems. Genotyping by next-generation sequencing (GBS) is an emerging method of SNP genotyping, which is being increasingly adopted for discovery applications, but its suitability for QC analysis has not been explored. The objectives of our study were 1) to evaluate the level of genetic purity and identity among two to nine seed sources of 16 inbred lines using 191 Kompetitive Allele Specific PCR (KASP) and 257,268 GBS markers, and 2) compare the correlation between the KASP-based low and the GBS-based high marker density on QC analysis.ResultsGenetic purity within each seed source varied from 49 to 100 % for KASP and from 74 to 100 % for GBS. All except one of the inbred lines obtained from CIMMYT showed 98 to 100 % homogeneity irrespective of the marker type. On the contrary, only 16 and 21 % of the samples obtained from EIAR and partners showed ≥95 % purity for KASP and GBS, respectively. The genetic distance among multiple sources of the same line designation varied from 0.000 to 0.295 for KASP and from 0.004 to 0.230 for GBS. Five lines from CIMMYT showed ≤ 0.05 distance among multiple sources of the same line designation; the remaining eleven inbred lines, including two from CIMMYT and nine from Ethiopia showed higher than expected genetic distances for two or more seed sources. The correlation between the 191 KASP and 257,268 GBS markers was 0.88 for purity and 0.93 for identity. A reduction in the number of GBS markers to 1,343 decreased the correlation coefficient only by 0.03.ConclusionsOur results clearly showed high discrepancy both in genetic purity and identity by the origin of the seed sources (institutions) irrespective of the type of genotyping platform and number of markers used for analyses. Although there were some numerical differences between KASP and GBS, the overall conclusions reached from both methods was basically similar, which clearly suggests that smaller subset of preselected and high quality markers are sufficient for QC analysis that can easily be done using low marker density genotyping platforms, such as KASP. Results from this study would be highly relevant for plant breeders and seed system specialists.Electronic supplementary materialThe online version of this article (doi:10.1186/s12864-015-2180-2) contains supplementary material, which is available to authorized users.
Highlights
Quality control (QC) analysis is an important component in maize breeding and seed systems
To cope with these challenges, breeders of the time opted to develop and release hybrids using early generation parental inbred lines [3]. This strategy favors cheaper seed production and hybrids derived from such early generation parental lines out-yielded open pollinated varieties (OPVs), generally they remain inferior in uniformity as compared to hybrids developed from fixed lines
Our results showed that a subset of 100 to 200 Single nucleotide polymorphism (SNP) (KASP) markers would be sufficient for routine quality control (QC) analysis
Summary
Quality control (QC) analysis is an important component in maize breeding and seed systems. The formal state maize breeding program of Ethiopia was established in the early 1950’s and was instrumental in the development, evaluation and recommendation of adapted open pollinated varieties (OPVs). The breeding program released its first top cross hybrid, BH140, in 1988 [3] Subsequently, several high yielding and stress tolerant OPVs and hybrids adapted to different agro-ecologies have been released. These hybrid varieties, in conjunction with recent hybrids from private seed companies have significantly contributed to the current sharp increase in maize production in the country
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