Abstract
MDA-MB-435S human breast cancer cells (435S) secrete nucleoside diphosphate kinase (NDPK) that supports metastases and is inhibited by epigallocatechin gallate (EGCG) and ellagic acid (EA). We hypothesise that 435S cell-secreted NDPK-B supports tumour formation by modulating ATP levels locally to activate endothelial cell (EC) P2Y receptor-mediated angiogenesis. Epigallocatechin gallate (IC50=8-10 microM) and EA (IC50=2-3 microM) suppressed 435S cell growth, but had less effect on human CD31+ EC growth. Epigallocatechin gallate (IC50=11 microM) and EA (IC50=1 microM) also prevented CD31+ EC tubulogenesis on Matrigeltrade mark. 435S cell-conditioned media induced tubulogenesis in a cell number, time, and nucleotide-dependent manner. Ellagic acid (1 microM), but not equimolar EGCG, reduced cell number-dependent angiogenesis. P2Y 1 receptor activation by NDPK-generated nucleotide (100 microM ATP) or by 10 microM 2-methyl-thio-ATP (2MS-ATP) promoted tubulogenesis on collagen and was blocked by the P2Y 1 antagonist MRS2179 (10 microM). Physiological amounts of purified as well as 435S cell-secreted NDPK also promoted angiogenesis that was attenuated by NDPK depletion or 10 microM MRS2179, indicating a P2Y 1 receptor-mediated pathway. These results support the notion that secreted NDPK mediates angiogenesis via P2Y receptor signalling and suggests that novel inhibitors of NDPK may be useful as therapeutics.