BMC Genomics (May 2005)

Pigs in sequence space: A 0.66X coverage pig genome survey based on shotgun sequencing

  • Li Wei,
  • Dong Wei,
  • Hu Songnian,
  • Liu Bin,
  • Wang Jun,
  • Klein Ami,
  • Hornshøj Henrik,
  • Mailund Thomas,
  • Christensen Ole F,
  • Stærfeldt Hans-Henrik,
  • Panitz Frank,
  • Gorodkin Jan,
  • Jørgensen Frank G,
  • Schierup Mikkel H,
  • Wernersson Rasmus,
  • Wong Gane KS,
  • Yu Jun,
  • Wang Jian,
  • Bendixen Christian,
  • Fredholm Merete,
  • Brunak Søren,
  • Yang Huanming,
  • Bolund Lars

DOI
https://doi.org/10.1186/1471-2164-6-70
Journal volume & issue
Vol. 6, no. 1
p. 70

Abstract

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Abstract Background Comparative whole genome analysis of Mammalia can benefit from the addition of more species. The pig is an obvious choice due to its economic and medical importance as well as its evolutionary position in the artiodactyls. Results We have generated ~3.84 million shotgun sequences (0.66X coverage) from the pig genome. The data are hereby released (NCBI Trace repository with center name "SDJVP", and project name "Sino-Danish Pig Genome Project") together with an initial evolutionary analysis. The non-repetitive fraction of the sequences was aligned to the UCSC human-mouse alignment and the resulting three-species alignments were annotated using the human genome annotation. Ultra-conserved elements and miRNAs were identified. The results show that for each of these types of orthologous data, pig is much closer to human than mouse is. Purifying selection has been more efficient in pig compared to human, but not as efficient as in mouse, and pig seems to have an isochore structure most similar to the structure in human. Conclusion The addition of the pig to the set of species sequenced at low coverage adds to the understanding of selective pressures that have acted on the human genome by bisecting the evolutionary branch between human and mouse with the mouse branch being approximately 3 times as long as the human branch. Additionally, the joint alignment of the shot-gun sequences to the human-mouse alignment offers the investigator a rapid way to defining specific regions for analysis and resequencing.