@article{fdi:010070213,
  title = {{G}enetic architecture of a rice nested association mapping population},
  author = {{F}ragoso, {C}. {A}. and {M}oreno, {M}. and {W}ang, {Z}. {H}. and {H}effelfinger, {C}. and {A}rbelaez, {L}. {J}. and {A}guirre, {J}. {A}. and {F}ranco, {N}. and {R}omero, {L}. {E}. and {L}abadie, {K}. and {Z}hao, {H}. {Y}. and {D}ellaporta, {S}. {L}. and {L}orieux, {M}athias},
  editor = {},
  language = {{ENG}},
  abstract = {{D}escribing the genetic diversity in the gene pool of crops will provide breeders with novel resources for varietal improvement. {N}ested {A}ssociation {M}apping ({NAM}) populations are uniquely suited for characterizing parental diversity through the shuffling and fixation of parental haplotypes. {H}ere, we describe a set of 1879 rice {NAM} lines created through the selfing and single-seed descent of {F}-1 hybrids derived from elite {IR}64 indica crossed with 10 diverse tropical japonica lines. {G}enotyping data indicated tropical japonica alleles were captured at every queried locus despite the presence of segregation distortion factors. {S}everal distortion loci were mapped, both shared and unique, among the 10 populations. {U}sing two-point and multi-point genetic map calculations, our datasets achieved the similar to 1500 c{M} expected map size in rice. {F}inally, we highlighted the utility of the {NAM} lines for {QTL} mapping, including joint analysis across the 10 populations, by confirming known {QTL} locations for the trait days to heading.},
  keywords = {{QTL} mapping ; computational biology ; genetic maps ; nested association ; mapping ; plant genomics},
  booktitle = {},
  journal = {{G}3-{G}enes {G}enomes {G}enetics},
  volume = {7},
  numero = {6},
  pages = {1913--1926},
  ISSN = {2160-1836},
  year = {2017},
  DOI = {10.1534/g3.117.041608},
  URL = {https://www.documentation.ird.fr/hor/fdi:010070213},
}