Ku80 as a novel receptor for thymosin beta4 that mediates its intracellular activity different from G-actin sequestering.

Our data demonstrate that increased intracellular expression of thymosin beta4(Tbeta4) is necessary and sufficient to induce plasminogen activator inhibitor type 1 (PAI-1) gene expression in endothelial cells. To describe the mechanism of this effect, we produced Tbeta4 mutants with impaired functional motifs and tested their intracellular location and activity. Cytoplasmic distributions of Tbeta4((AcSDKPT/4A)), Tbeta4((KLKKTET/7A)), and Tbeta4((K16A)) mutants fused with green fluorescent protein did not differ significantly from those of wild-type Tbeta4. Overexpression of Tbeta4, Tbeta4((AcSDKPT/4A)), and Tbeta4((K16A)) affected intracellular formation of actin filaments. As expected, Tbeta4((K16A)) uptake by nuclei was impaired. On the other hand, overexpression of Tbeta4((KLKKTET/7A)) resulted in developing the actin filament network typical of adhering cells, indicating that the mutant lacked the actin binding site. The mechanism by which intracellular Tbeta4 induced the PAI-1 gene did not depend upon the N-terminal tetrapeptide AcSDKP and depended only partially on its ability to bind G-actin or enter the nucleus. Both Tbeta4 and Tbeta4((AcSDKPT/4A)) induced the PAI-1 gene to the same extent, whereas mutants Tbeta4((KLKKTET/7A)) and Tbeta4((K16A)) retained about 60% of the original activity. By proteomic analysis, the Ku80 subunit of ATP-dependent DNA helicase II was found to be associated with Tbeta4. Ku80 and Tbeta4 consistently co-immunoprecipitated in a complex from endothelial cells. Co-transfection of endothelial cells with the Ku80 deletion mutants and Tbeta4 showed that the C-terminal arm domain of Ku80 is directly involved in this interaction. Furthermore, down-regulation of Ku80 by specific short interference RNA resulted in dramatic reduction in PAI-1 expression at the level of both mRNA and protein synthesis. These data suggest that Ku80 functions as a novel receptor for Tbeta4 and mediates its intracellular activity.

Adhesive and proteolytic phenotype of migrating endothelial cells induced by thymosin beta-4.

The early stages of angiogenesis are usually accompanied by the occurrence of vascular leakage, and the deposition of fibrin in extravascular spaces. Initially, the fibrin network acts as a sealing matrix, but later on also as a scaffolding for invading endothelial cells. This process is induced by angiogenic growth factors, particularly by vascular endothelial growth factor (VEGF). Angiogenesis involves proteolytic activities, in particular cell-bound urokinase/plasmin and matrix metalloproteinase (MMPs) activities that modulate the fibrin structure and affect adhesion and migration of endothelial cells. Recent data show that formation of new vessels may be stimulated by thymosin beta-4 (Tbeta-4), but it is still not clear whether Tbeta-4 alone is angiogenic or the angiogenic potential of Tbeta-4 is mediated by VEGF. In this report to further characterize Tbeta-4 angiogenic activity, we produced its mutants that were deprived of the N-terminal tetrapeptide AcSDKP (Tbeta-4((AcSDKPT/4A))), the actin-binding sequence KLKKTET (Tbeta-4((KLKKTET/7A))) and with the nuclear localization sequence damaged by a point mutation Lys16Ala (Tbeta-4((K16A))). Then we tested their activity to induce expression and release of MMPs as well as plasminogen activators inhibitor type-1 (PAI-1). We also analyzed their effect on migration and proliferation of endothelial cells in three-dimensional (3D) fibrin matrix as well as on their ability to stimulate the outgrowth of human endothelial cells in capillary-like tubular structures. Our data demonstrate that increased intracellular expression of Tbeta-4 and its mutants is necessary and sufficient to induce PAI-1 gene expression in endothelial cells. Similarly, they stimulate expression and release of MMP-1, -2, and -3. As evaluated by using specific inhibitors to these MMPs, they modified specifically the structure of fibrin and thus facilitated migration of endothelial cells. To sum up, our data show that the mechanism by which Tbeta-4 induced transition of endothelial cells from quiescent to proangiogenic phenotype is characterized by increased expression of PAI-1 and MMPs did not require the presence of the N-terminal sequence AcSDKP, and depended only partially on its ability to bind G-actin or to enter the nucleus.

Thymosin beta 4 induces the synthesis of plasminogen activator inhibitor 1 in cultured endothelial cells and increases its extracellular expression.

Thymosin beta 4(T beta 4), a 4.9-kDa polypeptide primarily known as a main G-actin-sequestering peptide, is present in high concentrations in various cells and in the circulation. We have found that T beta 4 upregulates the expression of plasminogen activator inhibitor 1 (PAI-1) in endothelial cells measured both at the level of mRNA and protein synthesis. This effect seems to be cell specific and was not observed when other cells such as human fibroblasts, PC3, and U937 were tested. T beta 4 significantly activated the PAI-1 promoter in EA.hy 926 cells transiently transfected either with plasmid p800LUC containing PAI-1 promoter fragment (-800 to +71) or the PAI-1 promoter linked with green fluorescent protein. T beta 4 mediated up-regulation of PAI-1 involved activation of the mitogen-activated protein kinase cascade. Furthermore, T beta 4 enhanced c-Fos/c-Jun DNA-binding activity to the activator protein 1 (AP-1)-like element (-59 to -52). The specificity of this binding activity was demonstrated by competition electrophoretic mobility shift assay and after transfection of EA.hy 926 cells with the mutated PAI-1 promoter. Taken together, these data indicate that, in response to T beta 4 stimulation, AP-1 activity increases to enhance PAI-1 transcription through its unique AP-1-like element at -59 to -52 in the PAI-1 promoter.

Identification and characterization of two cation binding sites in the integrin beta 3 subunit.

The midsegment of the beta(3) subunit has been implicated in the ligand and cation binding functions of the beta(3) integrins. This region may contain a metal ion-dependent adhesion site (MIDAS) and fold into an I domain-like structure. Two recombinant fragments, beta(3)-(95-373) and beta(3)-(95-301), were expressed and found to bind fibrinogen. Whereas 0.1 mm Ca(2+) supported ligand binding to both recombinant fragments, 1.0 mm Ca(2+) suppressed binding to the longer but not the shorter fragment. These properties suggest that beta(3)-(95-373) contains both the ligand-competent (LC) and inhibitory (I) cation binding sites, and beta(3)-(95-301) lacks the I site. In equilibrium dialysis experiments, beta(3)-(95-373) contained two divalent cation binding sites, one reactive with either Mg(2+) or Ca(2+) and one Ca(2+)-specific, whereas beta(3)-(95-301) lacked the Ca(2+)-specific site. Mutant forms of beta(3)-(95-373) suggested that the LC site is a MIDAS motif involving Asp(119), Ser(121), Ser(123), Asp(217), and/or Glu(220) as coordination sites, and the I site was dependent upon residues within beta(3)-(301-323). In a molecular model of beta(3)-(95-373), a second Ca(2+) could be docked onto a flexible loop in close proximity to the MIDAS. These results indicate that the ligand competent and Ca(2+)-specific inhibitory cation binding sites are distinct and reside in beta(3)-(95-373).