BMC Genetics (Jul 2008)

Genomic characterisation, chromosomal assignment and <it>in vivo</it> localisation of the canine High Mobility Group A1 (HMGA1) gene

  • Reimann-Berg Nicola,
  • Willenbrock Saskia,
  • Richter Andreas,
  • Schelling Claude,
  • Dolf Gaudenz,
  • Muth Michaela,
  • Wagner Sigfried,
  • Soller Jan T,
  • Beuing Claudia,
  • Winkler Susanne,
  • Nolte Ingo,
  • Bullerdiek Jorn,
  • Escobar Hugo

DOI
https://doi.org/10.1186/1471-2156-9-49
Journal volume & issue
Vol. 9, no. 1
p. 49

Abstract

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Abstract Background The high mobility group A1 proteins (HMGA1a/HMGA1b) are highly conserved between mammalian species and widely described as participating in various cellular processes. By inducing DNA conformation changes the HMGA1 proteins indirectly influence the binding of various transcription factors and therefore effect the transcription regulation. In humans chromosomal aberrations affecting the HMGA1 gene locus on HSA 6p21 were described to be the cause for various benign mesenchymal tumours while high titres of HMGA1 proteins were shown to be associated with the neoplastic potential of various types of cancer. Interestingly, the absence of HMGA1 proteins was shown to cause insulin resistance and diabetes in humans and mice. Due to the various similarities in biology and presentation of human and canine cancers the dog has joined the common rodent animal model for therapeutic and preclinical studies. Accordingly, the canine genome was sequenced completely twice but unfortunately this could not solve the structure of canine HMGA1 gene. Results Herein we report the characterisation of the genomic structure of the canine HMGA1 gene consisting of 7 exons and 6 introns spanning in total 9524 bp, the in vivo localisation of the HMGA1 protein to the nucleus, and a chromosomal assignment of the gene by FISH to CFA12q11. Additionally, we evaluated a described canine HMGA1 exon 6 SNP in 55 Dachshunds. Conclusion The performed characterisations will make comparative analyses of aberrations affecting the human and canine gene and proteins possible, thereby providing a basis for revealing mechanisms involved in HMGA1 related pathogenesis in both species.