Transgenic Research

, Volume 7, Issue 5, pp 387–398

Efficient BLG-Cre Mediated Gene Deletion in the Mammary Gland

  • Stefan Selbert
  • Darren J. Bentley

DOI: 10.1023/A:1008848304391

Cite this article as:
Selbert, S. & Bentley, D.J. Transgenic Res (1998) 7: 387. doi:10.1023/A:1008848304391


Using the phage P1-derived Cre/loxP recombination system, we have developed a strategy for efficient mammary tissue specific inactivation of floxed genes. Transgenic mice were generated which express Cre DNA-recombinase under the control of the mammary gland specific promoter of the ovine beta- lactoglobulin (BLG) gene. To test the specificity of Cre mediated recombination, we crossed these mice to animals harbouring a floxed DNA ligase I allele. We show that the BLG-Cre construct specifies mammary specific gene deletion, and furthermore that it is temporally regulated, predominantly occurring during lactation. We fully characterised the extent of gene deletion in one line (line 74). In this strain the virgin gland is characterised by low levels (7%) of Cre mediated deletion, whereas 70–80% of cells within the lactating mammary gland have undergone recombination. Immunohisto-chemistry and indirect in situ PCR were used respectively to demonstrate that both Cre protein and Cre activity were evenly distributed throughout the population of secretory epithelial cells. The level of background recombination in non-mammary tissues was found to be ≤1.1%, irrespective of mammary gland developmental status. Crossing the transgenic BLG-Cre strain described here to mice harbouring other floxed alleles will facilitate the functional analysis of those genes during differentiation and development of the mammary gland.

beta lactoglobulin promoter Cre recombinase DNA ligase I transgenics mouse mammary gland 

Copyright information

© Kluwer Academic Publishers 1998

Authors and Affiliations

  • Stefan Selbert
    • 1
  • Darren J. Bentley
    • 2
  1. 1.Department of PathologyUniversity Medical SchoolEdinburghUK
  2. 2.Institute of Cell and Molecular BiologyUniversity of Edinburgh, Darwin Building, Kings BuildingsEdinburghUK