The integration of recombination and physical maps in a large-genome monocot using haploid genome analysis in a trihybrid allium population

L.I. Khrustaleva, P. de Melo, A.W. van Heusden, C. Kik

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39 Citations (Scopus)

Abstract

Integrated mapping in large-genome monocots has been carried out on a limited number of species. Furthermore, integrated maps are difficult to construct for these species due to, among other reasons, the specific plant populations needed. To fill these gaps, Alliums were chosen as target species and a new strategy for constructing suitable populations was developed. This strategy involves the use of trihybrid genotypes in which only one homeolog of a chromosome pair is recombinant due to interspecific recombination. We used genotypes from a trihybrid Allium cepa x (A. roylei x A. fistulosum) population. Recombinant chromosomes 5 and 8 from the interspecific parent were analyzed using genomic in situ hybridization visualization of recombination points and the physical positions of recombination were integrated into AFLP linkage maps of both chromosomes. The integrated maps showed that in Alliums recombination predominantly occurs in the proximal half of chromosome arms and that 57.9% of PstI/MseI markers are located in close proximity to the centromeric region, suggesting the presence of genes in this region. These findings are different from data obtained on cereals, where recombination rate and gene density tends to be higher in distal regions
Original languageEnglish
Pages (from-to)1673-1685
JournalGenetics
Volume169
Issue number3
DOIs
Publication statusPublished - 2005

Keywords

  • in-situ hybridization
  • gene-rich region
  • meiotic recombination
  • cytogenetic map
  • linkage maps
  • chromosome structure
  • sequence-analysis
  • a1-sh2 interval
  • dna methylation
  • maize genome

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