Cell-substrate adhesion

Abstract: The orientation of mitotic spindles is tightly regulated in polarized cells, but it has been unclear whether there is a mechanism regulating spindle orientation in nonpolarized cells. Here we show that integrin-dependent cell adhesion to the substrate orients the mitotic spindle of nonpolarized cultured cells parallel to the substrate plane. The spindle is properly oriented in cells plated on fibronectin or collagen, but misoriented in cells on poly-L-lysine or treated with the RGD peptide or anti-β1-integrin antibody, indicating requirement of integrin-mediated cell adhesion for this mechanism. Remarkably, this mechanism is independent of gravitation or cell–cell adhesion, but requires actin cytoskeleton and astral microtubules. Furthermore, myosin X and the microtubule plus-end-tracking protein EB1 are shown to play a role in this mechanism through remodeling of actin cytoskeleton and stabilization of astral microtubules, respectively. Our results thus uncover the existence of a mechanism that orients the spindle parallel to the cell–substrate adhesion plane, and identify crucial factors involved in this novel mechanism.

Abstract: cDNA clones coding for human S-protein have been isolated using monoclonal antibodies to screen a cDNA library in pEX. These clones are shown to be authentic S-protein clones on the basis of sequence, composition and immunological criteria. The complete open reading frame sequence for S-protein has been determined and shows it to be a single polypeptide chain of 459 amino acids preceded by a cleaved leader peptide of 19 residues. No evidence was found for polymorphism of S-protein suggesting that different molecular weight forms arise by proteolytic degradation. Of the first 44 amino-terminal residues 42 are identical with the so-called somatomedin B peptide suggesting that S-protein is the somatomedin B precursor. Striking homology is found in the rest of the sequence with the serum spreading factor, vitronectin, which has also been shown to contain somatomedin B sequences at its amino terminus. We conclude that S-protein and vitronectin are identical and discuss the relevance of this finding to the coagulation and complement pathways.