PLoS ONE (Jan 2018)

Establishment of a bioluminescent canine B-cell lymphoma xenograft model for monitoring tumor progression and treatment response in preclinical studies.

  • Joana N R Dias,
  • Ana S André,
  • Sandra I Aguiar,
  • Joana Ministro,
  • Joana Oliveira,
  • Maria C Peleteiro,
  • Barbara Rütgen,
  • Lurdes Gano,
  • João D G Correia,
  • Soraia S Oliveira,
  • Joao Goncalves,
  • Solange Gil,
  • Luís Tavares,
  • Frederico Aires-da-Silva

DOI
https://doi.org/10.1371/journal.pone.0208147
Journal volume & issue
Vol. 13, no. 12
p. e0208147

Abstract

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Canine diffuse large B-cell lymphoma (DLBCL) is one of the most common cancers in dogs which shares remarkable similarities with its human counterpart, making the dog an excellent model for the investigation of novel therapeutic agents. However, the integration of canine lymphoma in comparative studies has been limited due in part to the lack of suitable xenograft mouse models for preclinical studies. To overcome these limitations, we established and characterized a localized subcutaneous bioluminescent canine DLBCL xenograft mouse model. The canine CLBL-1 cell line stably expressing the luciferase and green fluorescent protein reporters was generated and used to establish the xenograft tumor model. A pilot study was first conducted with three different cell densities (0.1×10(6), 0.5×10(6) and 1×10(6) cells) in SCID mice. All mice presented homogeneous tumor induction within eight days after subcutaneous injection, with a 100% engraftment efficiency and no significant differences were observed among groups. The tumors were highly aggressive and localized at the site of inoculation and reproduced histological features and immunophenotype consistent with canine DLBCL. Importantly, xenograft tumors were detected and quantified by bioluminescent imaging. To assess response to therapy, a therapeutic study with a histone deacetylase inhibitor, panobinostat, was performed. The results demonstrated that panobinostat (20 mg/kg) efficiently inhibited tumor growth and that bioluminescent imaging allowed the monitorization and quantification of tumor response to therapy. In summary, this study provides a bioluminescence canine DLBCL model that offers high engraftment efficiency, preservation of tumor features, and noninvasive monitoring of tumor progression, validating the model as a promising preclinical tool for both veterinary and human medicine.