Cell migration promoted by a potent GRGDS-containing thrombin-cleavage fragment of osteopontin

AbstractOsteopontin (OPN) is a secreted adhesive glycoprotein with a gly-arg-gly-asp-ser (GRGDS) cell binding domain. Several independent studies have suggested that OPN functions in tumor growth and metastasis, and one likely possibility is that OPN facilitates tumor invasion by promoting tumor cell migration. Consistent with this hypothesis, immobilized OPN promoted concentration-dependent tumor cell migration (i.e., haptotaxis) in modified Boyden chambers. In particular, cleavage of OPN by thrombin, which likely occurs in the tumor microenvironment, resulted in enhancement of OPNs haptotactic activity; and assays performed with purified preparations of the two individual OPN thrombin-cleavage fragments demonstrated that all detectable activity was associated with the GRGDS-containing fragment. In contrast to the activity of both OPN and its GRGDS-containing fragment in promoting haptotaxis, neither of these proteins in solution promoted chemotaxis, indicating that each must be immobilized to promote cell migration. In haptotaxis assays, antibody LM609 to integrin αvβ3 blocked > 80% cell migration towards the GRGDS-containing OPN fragment, implicating αvβ3 as its principal functional receptor. In comparison with equimolar quantities of other adhesive proteins, the GRGDS-containing OPN thrombin-cleavage fragment was not only > 2-fold more effective than intact OPN at promoting haptotaxis, but also > 8-fold and > 6-fold more effective than fibrinogen and vitronectin, respectively, indicating that this OPN fragment is highly active relative to other αvβ3 ligands

Akt promotes Endocardial-Mesenchyme Transition

Endothelial to mesenchyme transition (EndMT) can be observed during the formation of endocardial cushions from the endocardium, the endothelial lining of the atrioventricular canal (AVC), of the developing heart at embryonic day 9.5 (E9.5). Many regulators of the process have been identified; however, the mechanisms driving the initial commitment decision of endothelial cells to EndMT have been difficult to separate from processes required for mesenchymal proliferation and migration. We have several lines of evidence that suggest a central role for Akt signaling in committing endothelial cells to enter EndMT. Akt1 mRNA was restricted to the endocardium of endocardial cushions while they were forming. The PI3K/Akt signaling pathway is necessary for mesenchyme outgrowth, as sprouting was inhibited in AVC explant cultures treated with the PI3K inhibitor LY294002. Furthermore, endothelial marker, VE-cadherin, was downregulated and mesenchyme markers, N-cadherin and Snail, were induced in response to expression of a constitutively active form of Akt1 (myrAkt1) in endothelial cells. Finally, we isolated the function of Akt1 signaling in the commitment to the transition using a transgenic model where myrAkt1 was pulsed only in endocardial cells and turned off after EndMT initiation. In this way, we determined that increased Akt signaling in the endocardium drives EndMT and discounted its other functions in cushion mesenchymal cells

RhoB controls coordination of adult angiogenesis and lymphangiogenesis following injury by regulating VEZF1-mediated transcription

Mechanisms governing the distinct temporal dynamics that characterize post-natal angiogenesis and lymphangiogenesis elicited by cutaneous wounds and inflammation remain unclear. RhoB, a stress-induced small GTPase, modulates cellular responses to growth factors, genotoxic stress and neoplastic transformation. Here we show, using RhoB null mice, that loss of RhoB decreases pathological angiogenesis in the ischaemic retina and reduces angiogenesis in response to cutaneous wounding, but enhances lymphangiogenesis following both dermal wounding and inflammatory challenge. We link these unique and opposing roles of RhoB in blood versus lymphatic vasculatures to the RhoB-mediated differential regulation of sprouting and proliferation in primary human blood versus lymphatic endothelial cells. We demonstrate that nuclear RhoB-GTP controls expression of distinct gene sets in each endothelial lineage by regulating VEZF1-mediated transcription. Finally, we identify a small-molecule inhibitor of VEZF1–DNA interaction that recapitulates RhoB loss in ischaemic retinopathy. Our findings establish the first intra-endothelial molecular pathway governing the phased response of angiogenesis and lymphangiogenesis following injury