BMC Genetics (Jul 2011)

Robustness of genome-wide scanning using archived dried blood spot samples as a DNA source

  • Børglum Anders D,
  • Harboe Zitta B,
  • Sørensen Henrik T,
  • Mors Ole,
  • Mortensen Preben B,
  • Nørgaard-Pedersen Bent,
  • Benfield Thomas L,
  • Nørgaard Mette,
  • Bønnelykke Klaus,
  • Kreiner-Møller Eskil,
  • Grauholm Jonas,
  • Grove Jakob,
  • Hollegaard Mads V,
  • Demontis Ditte,
  • Ørntoft Torben F,
  • Bisgaard Hans,
  • Hougaard David M

DOI
https://doi.org/10.1186/1471-2156-12-58
Journal volume & issue
Vol. 12, no. 1
p. 58

Abstract

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Abstract Background The search to identify disease-susceptible genes requires access to biological material from numerous well-characterized subjects. Archived residual dried blood spot (DBS) samples, also known as Guthrie cards, from national newborn screening programs may provide a DNA source for entire populations. Combined with clinical information from medical registries, DBS samples could provide a rich source for productive research. However, the amounts of DNA which can be extracted from these precious samples are minute and may be prohibitive for numerous genotypings. Previously, we demonstrated that DBS DNA can be whole-genome amplified and used for reliable genetic analysis on different platforms, including genome-wide scanning arrays. However, it remains unclear whether this approach is workable on a large sample scale. We examined the robustness of using DBS samples for whole-genome amplification following genome-wide scanning, using arrays from Illumina and Affymetrix. Results This study is based on 4,641 DBS samples from the Danish Newborn Screening Biobank, extracted for three separate genome-wide association studies. The amount of amplified DNA was significantly (P Conclusion Our study indicates that archived DBS samples from the Danish Newborn Screening Biobank represent a reliable resource of DNA for whole-genome amplification and subsequent genome-wide association studies. With call-rates equivalent to high quality DNA samples, our results point to new opportunities for using the neonatal biobanks available worldwide in the hunt for genetic components of disease.