Minocycline Inhibits Apoptotic Cell Death in a Murine Model of Partial Flap Loss

For breast reconstruction, the deep inferior epigastric perforator (DIEP) flap has become standard therapy. A feared complication is partial or even total flap loss. In a novel murine model of partial DIEP flap loss, the contribution of apoptotis to flap loss was investigated. The clinically available apoptosis-inhibiting compound minocycline was tested for its ability to reduce cell death. The effect of minocycline on cell proliferation was studied in cell cultures of breast carcinoma. In 12 mice, pedicled DIEP flaps were raised, which were subjected to 15 minutes of ischemia and 4 days of reperfusion. Six mice were treated with minocycline 2 hours before surgery and every 24 hours for 4 days. Apoptosis was revealed by injecting annexin A5 30 minutes before sacrifice. Annexin A5 binds to phosphatidylserines, which are expressed on the cell membrane during apoptotis. Prior to sacrifice, necrosis was measured using planimetry. Minocycline reduced cell death after 4 days from 35.9% (standard deviation - 10.6) to 13.9% (standard deviation - 8.0; p <0.05). Apoptosis, as shown by annexin A5 binding in nontreated animals, was abundant. Minocycline did not influence tumor growth in cell cultures of human breast cancer. Minocycline treatment leads to increased DIEP flap viability in mice. This study widens the perspective in the improvement of free flap survival in patients

GATA3 suppresses metastasis and modulates the tumour microenvironment by regulating microRNA-29b expression

Despite advances in our understanding of breast cancer, patients with metastatic disease have poor prognoses. GATA3 is a transcription factor that specifies and maintains mammary luminal epithelial cell fate, and its expression is lost in breast cancer, correlating with a worse prognosis in human patients. Here, we show that GATA3 promotes differentiation, suppresses metastasis and alters the tumour microenvironment in breast cancer by inducing microRNA-29b (miR-29b) expression. Accordingly, miR-29b is enriched in luminal breast cancers and loss of miR-29b, even in GATA3-expressing cells, increases metastasis and promotes a mesenchymal phenotype. Mechanistically, miR-29b inhibits metastasis by targeting a network of pro-metastatic regulators involved in angiogenesis, collagen remodelling and proteolysis, including VEGFA, ANGPTL4, PDGF, LOX and MMP9, and targeting ITGA6, ITGB1 and TGFB, thereby indirectly affecting differentiation and epithelial plasticity. The discovery that a GATA3-miR-29b axis regulates the tumour microenvironment and inhibits metastasis opens up possibilities for therapeutic intervention in breast cancer