ß3-Endonexin interacts with ninein in vascular endothelial cells to promote angiogenesis.

Anti-angiogenesis serves as an effective tumor therapy approach. In a previous study, we found that ß3-endonexin expressed in vascular endothelial cells was involved in promoting proliferation and angiogenesis partially by facilitating VEGF expression. However, it still remains unclear if ß3-endonexin in vascular endothelial cells also employs other mechanisms in regulating angiogenesis. In this study, we utilized a ß3-endonexin mutant (M2) carrying a defective nuclear localization sequence to disrupt its nuclear localization and evaluated its ability to promote HUVEC proliferation and formation of tube-like vascular structures. In addition, we performed yeast 2-hybrid assay to identify potential functional effectors of ß3-endonexin. We found that both wild type ß3-endonexin and the M2 mutant could localize to centrosomes in HUVECs and both were able to promote HUVEC proliferation and formation of vascular structures. However, the M2 mutant failed to promote VEGF expression in HUVECs. Further, we found that both wild type ß3-endonexin and the M2 mutant were capable of binding to ninein, a centrosomal protein with a proangiogenic effect. Knockdown of ninein in HUVECs impeded centrosome localization of wild type ß3-endonexin and the M2 mutant and inhibited HUVEC proliferation and formation of vascular structures. Taken together, these findings suggest that ß3-endonexin interacts with centrosome ninein and contributes to HUVEC proliferation and formation of vascular structures.

Kindlin-3 in platelets and myeloid cells differentially regulates deep vein thrombosis in mice.

Platelets and myeloid cells cooperate to promote deep vein thrombosis (DVT). Here we evaluated the role of kindlin-3, a key integrin activator in these cells, in regulating stenosis-induced DVT in mice. DVT was significantly suppressed in mice that express a kindlin-3 mutant defective for integrin binding, showing that kindlin-3-mediated integrin signaling in blood cells is required for DVT. While platelet-specific deficiency of kindlin-3 in Kindlin-3fl/flPF4-Cre mice significantly suppressed DVT, deficiency of kindlin-3 specifically in myeloid cells in Kindlin-3fl/flLysM-Cre mice remarkably enhanced the early development of DVT, indicating that kindlin-3 in platelets and myeloid cells can play distinct roles in regulating DVT. Mechanistically, the levels of neutrophil extracellular traps (NETs) in plasma, a key DVT facilitator, were significantly elevated in Kindlin-3fl/flLysM-Cre mice upon the IVC stenosis; and treatment with either DNase I or PAD4 inhibitor could effectively compromise the enhancement of DVT in these mice, suggesting that kindlin-3 in neutrophils may affect DVT via restraining NET release. In addition, we found that the kindlin-3-integrin αIIbß3 signaling in platelets was required to promote NET release. Together, our studies reveal that kindlin-3 in platelets and myeloid cells can differentially regulate DVT through orchestrating NET release, thus providing further mechanistic insights into DVT.

Sharpin suppresses ß1-integrin activation by complexing with the ß1 tail and kindlin-1.

BACKGROUND: Previously sharpin has been identified as an endogenous inhibitor of ß1-integrin activation by directly binding to a conserved region in the cytoplasmic tails (CTs) of the integrin ß1-associated α subunits. METHODS: Here we employed biochemical approaches and cellular analyses to evaluate the function and molecular mechanism of the sharpin-kindlin-1 complex in regulating ß1-integrin activation. RESULTS: In this study, we found that although the inhibition of sharpin on ß1-integrin activation could be confirmed, sharpin had no apparent effect on integrin αIIbß3 activation in CHO cell system. Notably, a direct interaction between sharpin and the integrin ß1 CT was detected, while the interaction of sharpin with the integrin αIIb and the ß3 CTs were substantially weaker. Importantly, sharpin was able to inhibit the talin head domain binding to the integrin ß1 CT, which can mechanistically contribute to inhibiting ß1-integrin activation. Interestingly, we also found that sharpin interacted with kindlin-1, and the interaction between sharpin and the integrin ß1 CT was significantly enhanced when kindlin-1 was present. Consistently, we observed that instead of acting as an activator, kindlin-1 actually suppressed the talin head domain mediated ß1-integrin activation, indicating that kindlin-1 may facilitate recruitment of sharpin to the integrin ß1 CT. CONCLUSION: Taken together, our findings suggest that sharpin may complex with both kindlin-1 and the integrin ß1 CT to restrict the talin head domain binding, thus inhibiting ß1-integrin activation.