OBJECTIVE: In vascular tissue, T-cadherin (T-cad) levels correlate with the progression of atherosclerosis, restenosis and tumour neovascularization. This study investigates whether T-cad influences proliferation of vascular cells. METHODS AND RESULTS: Cultures of human umbilical vein endothelial cells (HUVEC) and rat and human aortic smooth muscle cells (rSMC, hSMC) were used. T-cad was overexpressed in HUVEC and hSMC using an adenoviral expression system. In cultures released from G(1)/G(0) synchrony parallel immunoblot analysis of T-cad and cell cycle phase specific markers (p27(Kip1), cyclin D1, E2F1, PCNA, cyclin B) showed increased T-cad protein levels subsequent to entry into early S-phase with sustained elevation through S-and M-phases. T-cad was increased in G(2)/M-phase (colchicine) synchronized cultures. In FACS-sorted cell populations, expression of T-cad in S-and G(2)/M-phase was higher than G(1)/G(0)-phase. Compared with empty-and LacZ-vector infected controls, HUVEC and hSMC overexpressing T-cad exhibited increased proliferation as assessed in enumeration and DNA synthesis assays. Additionally, following release from G(1)/G(0) synchrony, HUVEC and hSMC overexpressing T-cad enter S-phase more rapidly. Flow cytometry after BrdU/propidium labelling confirmed increased cell cycle progression in T-cad overexpressing cells. CONCLUSION: In vascular cells, T-cad is dynamically regulated during the cell cycle and its expression functions in the promotion of proliferation. T-cad may facilitate progression of proliferative vascular disorders such as atherosclerosis, restenosis and tumour angiogenesis.
OBJECTIVE: In vascular tissue, T-cadherin (T-cad) levels correlate with the progression of atherosclerosis, restenosis and tumour neovascularization. This study investigates whether T-cad influences proliferation of vascular cells. METHODS AND RESULTS: Cultures of human umbilical vein endothelial cells (HUVEC) and rat and human aortic smooth muscle cells (rSMC, hSMC) were used. T-cad was overexpressed in HUVEC and hSMC using an adenoviral expression system. In cultures released from G(1)/G(0) synchrony parallel immunoblot analysis of T-cad and cell cycle phase specific markers (p27(Kip1), cyclin D1, E2F1, PCNA, cyclin B) showed increased T-cad protein levels subsequent to entry into early S-phase with sustained elevation through S-and M-phases. T-cad was increased in G(2)/M-phase (colchicine) synchronized cultures. In FACS-sorted cell populations, expression of T-cad in S-and G(2)/M-phase was higher than G(1)/G(0)-phase. Compared with empty-and LacZ-vector infected controls, HUVEC and hSMC overexpressing T-cad exhibited increased proliferation as assessed in enumeration and DNA synthesis assays. Additionally, following release from G(1)/G(0) synchrony, HUVEC and hSMC overexpressing T-cad enter S-phase more rapidly. Flow cytometry after BrdU/propidium labelling confirmed increased cell cycle progression in T-cad overexpressing cells. CONCLUSION: In vascular cells, T-cad is dynamically regulated during the cell cycle and its expression functions in the promotion of proliferation. T-cad may facilitate progression of proliferative vascular disorders such as atherosclerosis, restenosis and tumour angiogenesis.
Authors: K Rubina; E Talovskaya; V Cherenkov; D Ivanov; D Stambolsky; T Storozhevykh; V Pinelis; A Shevelev; Ye Parfyonova; T Resink; P Erne; V Tkachuk Journal: Mol Cell Biochem Date: 2005-05 Impact factor: 3.396
Authors: Lionel W Hebbard; Michèle Garlatti; Lawrence J T Young; Robert D Cardiff; Robert G Oshima; Barbara Ranscht Journal: Cancer Res Date: 2008-03-01 Impact factor: 12.701