The fouling marine mussel Mytilus edulis attaches itself to various substrates by spinning byssal threads, the adhesive discs of which are rich in the amino acid 3,4-dihydroxyphenylalanine (dopa). An acid-soluble protein was extracted and purified from the phenol gland located in the byssus-secreting foot of the animal. This protein is highly basic and contains large amounts of lysine, dopa, and 3- and 4-hydroxyproline. The composition of this protein and its sticky tendencies in vitro strongly suggest that it contributes to byssal adhesion.
The adhesive protein from Mytilus edulis contains 75-80 closely related, repeated peptide sequences in its primary structure. These peptides can be resolved following digestion with trypsin by reversed-phase high-pressure liquid chromatography. The most frequently repeated sequence is the decapeptide Ala-Lys-Pro-Ser-Tyr-Hyp-Hyp-Thr-Dopa-Lys (peptide E). Variations of this occur in peptides B with Hyp-3 and Dopa-5, C with Dopa-5, and D with Hyp-3, respectively. Lesser amounts of hexapeptides (A and B') that are lacking residues 4-7 also occur. Peptide A has the sequence Ala-Lys-Pro-Thr-Dopa-Lys, whereas B' contains Tyr instead of Dopa. 4-Hydroxyproline occurs at positions 3 and 7 and occasionally at position 6 of the decapeptide; 3-hydroxyproline occurs only at position 6. Adhesiveness of the protein may be related to the repetition of Dopa residues, the catecholic moiety of which has strong hydrogen-bonding and metal-liganding capabilities.
The formation of collagen cross-links is attributable to the presence of two aldehyde-containing amino acids which react with other amino acids in collagen to generate difunctional, trifunctional, and tetrafunctional cross-links. A necessary prerequisite for the development of these cross-links is that the collagen molecules be assembled in the naturally occurring fibrous polymer. Once this condition is met, cross-linking occurs in a spontaneous, progressive fashion. The chemical structures of the cross-links dictate that very precise intermolecular alignments must occur in the collagen polymer. This seems to be a function of each specific collagen because the relative abundance of the different cross-links varies markedly, depending upon the tissue of origin of the collagen.
B16 mouse melanoma cells adhere to and spread on laminin. We have previously shown that cell spreading is uncoupled from adhesion when unglycosylated laminin is used as a substratum; spreading was restored by a Pronase digest of laminin which became inactive when it was specifically depleted of its mannoside peptides; spreading was also specifically restored by mannosides such as mannan, Man9, and Man6, but not Man3. The effector mannosides bind to a cell surface receptor, previously shown by direct and indirect methods. We have now identified the receptor as cell surface calreticulin by isolating it via mannan affinity chromatography and showing its sequence identity with mouse calreticulin. Anti-calreticulin antibodies confirm this identity, decorate the B16 cell surface, and block cell spreading. Purified B16 cell calreticulin from whole cell lysates successfully competes with cell surface calreticulin and prevents cell spreading. The composite data implicate cell surface calreticulin as a putative lectin that must be occupied to initiate spreading of laminin-adherent B16 cells.
Procollagen and fibronectin are major products of confluent fibroblasts in culture and both are released from the cells. Procollagen is secreted by known pathways, while the mechanism of fibronectin release is controversial. We find that the secretion of both these proteins can be reduced to 20% by low concentrations (0.1-1 ,M) of ionophores that have affinity for monovalent cations. In contrast, little effect upon secretion was found for similar concentrations of an ionophore that binds divalent cations. Electron microscopy showed that the inhibition of secretion is accompanied by accumulation of membranous vacuoles. We believe that the ionophores impede secretion by acting on the secretory structures rather than on the proteins themselves. Biochemical studies supported this interpretation because no changes were detected in hydroxylation or glycosylation of procollagen or glycosylation of fibronectin, nor were significant changes in cellular amino acid incorporation observed. Pulse-chase studies indicated that the rates of secretion were impaired by the ionophore without enhancing intracellular degradation. The decreased secretory rates accounted for the lower levels of procollagen and fibronectin in the culture medium; no evidence for increased catabolism of the secreted proteins was found. Secretion could be readily restored by removing the ionophore from the culture medium. The results indicate that procollagen and fibronectin may be simultaneously secreted, possibly utilizing a common pathway for secretion; the ionophores effectively interfere with cellular secretory pathways without impairing protein synthesis or protein glycosy ation or altering protein catabolism. Collagen and fibronectin form an interconnected network about confluent cells in culture and both proteins are released into the culture medium (1, 2). The two proteins form a strong noncovalent complex, which may be important for cell adhesion and cell-cell recognition. Both collagen and fibronectin are usually decreased to 1/5th to 1/Oth after cell transformation by viruses. Although both are glycoproteins, the carbohydrate moieties do not appear necessary for their release from cells (3).Procollagen, the precursor of collagen, follows a defined intracellular secretory pathway (4-6). This pathway can be impaired by uncouplers of oxidative phosphorylation (7,8), by microtubule-disrupting drugs such as colchicine and vinblastine (9-11), and by inhibitors of proline hydroxylation (12, 13). In contrast, little is known about intracellular transit and release of fibronectin. It is controversial whether this protein is secreted or sloughed (2).We have investigated the relationship between procollagen and fibronectin by following the release of these two proteins by cultured fibroblasts. We have prevented their release by employing low levels of monovalent ionophores. The culture media were harvested, brought to 4VC, and centrifuged at 500 X g for 5 min to remove debris. Two milligrams of carrier type I collagen was added per 3 ml of mediu...
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