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. 2012 Jul;2(7):721-9.
doi: 10.1534/g3.112.002659. Epub 2012 Jul 1.

Development of a 10,000 locus genetic map of the sunflower genome based on multiple crosses

John E Bowers  1 Eleni BachlavaRobert L BrunickLoren H RiesebergSteven J KnappJohn M Burke
Affiliations

Development of a 10,000 locus genetic map of the sunflower genome based on multiple crosses

John E Bowers et al. G3 (Bethesda). 2012 Jul.

Abstract

Genetic linkage maps have the potential to facilitate the genetic dissection of complex traits and comparative analyses of genome structure, as well as molecular breeding efforts in species of agronomic importance. Until recently, the majority of such maps was based on relatively low-throughput marker technologies, which limited marker density across the genome. The availability of high-throughput genotyping technologies has, however, made possible the efficient development of high-density genetic maps. Here, we describe the analysis and integration of genotypic data from four sunflower (Helianthus annuus L.) mapping populations to produce a consensus linkage map of the sunflower genome. Although the individual maps (which contained 3500-5500 loci each) were highly colinear, we observed localized variation in recombination rates in several genomic regions. We also observed several gaps up to 26 cM in length that completely lacked mappable markers in individual crosses, presumably due to regions of identity by descent in the mapping parents. Because these regions differed by cross, the consensus map of 10,080 loci contained no such gaps, clearly illustrating the value of simultaneously analyzing multiple mapping populations.

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Figures

Figure 1
Figure 1
Comparison of relative recombination rates for selected chromosome/populations. (A) LG 3 for HA412-HO × ANN1238. (B) LG4 for HA412-HO × ANN1238. (C) LG3 for NMS373 × Hopi. (D) HA412-HO × RHA415.
Figure 2
Figure 2
Graphical depiction of marker density across chromosomes expressed as markers per centimorgan (maximum of 102). (A) Chromosomes 1–9. (B) Chromosomes 10–17.
See this image and copyright information in PMC

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