Publications

Calcitonin (CT), a polypeptide hormone, regulates calcium homeostasis by activating surface receptors coupled to stimulation of adenylyl cyclase in bone and kidney cells. CT has also been reported to increase cytoplasmic Ca2+ in osteoclasts and renal tubule cells. Signaling pathways activated by a recombinant porcine renal calcitonin receptor transiently expressed in HEK-293 cells were studied. In cells expressing the recombinant CT receptor, salmon CT stimulated cAMP accumulation (EC50, 0.16 nM) and synthesis of inositol phosphates (IP; EC50, 3.7 nM). Two other recombinant receptors, the m1-muscarinic acetylcholine receptor and the LH receptor, activated synthesis of either IP or cAMP, respectively, but not both. Stable expression of the CT receptor in a CT receptor-deficient cell line, M18, restored the cells' ability to increase cytoplasmic Ca2+ in response to salmon CT. These results show that a single recombinant CT receptor can independently activate effector pathways mediated by cAMP and IP/Ca2+.

Integrins are a complex family of divalent cation-dependent cell adhesion receptors composed of one alpha and one beta subunit noncovalently bound to one another. A subset of integrins contains the alpha v subunit in association with one of several beta subunits (e.g. beta 3, beta 5, beta 1). We have recently identified a novel integrin beta subunit, beta 6, that is present in a number of epithelial cell lines. Using a polyclonal antibody raised against the carboxyl-terminal peptide of beta 6, we have now identified the integrin heterodimer, alpha v beta 6, on the surface of two human carcinoma cell lines. Using affinity chromatography of lysates from the pancreatic carcinoma cell line, FG-2, we demonstrate that alpha v beta 6 binds to fibronectin, but not to vitronectin or collagen I. In contrast, the alpha v beta 5 integrin, which is also expressed on FG-2 cells, binds exclusively to vitronectin. Immobilized collagen I does not interact with alpha v integrins, but binds beta 1-containing integrins. Both alpha v beta 6 and alpha v beta 5 are eluted from their respective immobilized ligands by a hexa-peptide containing the sequence Arg-Gly-Asp (RGD). RGD is highly effective in the presence of Ca2+, somewhat less effective in Mg2+, and virtually inactive in Mn2+. These results suggest that alpha v beta 6 functions as an RGD-dependent fibronectin receptor in FG-2 carcinoma cells. In agreement with this notion, cell adhesion assays show that FG-2 cell attachment to fibronectin is only partially inhibited by anti-beta 1 integrin antibodies, implying that other fibronectin receptors may be involved. Taken together with recent reports on the vitronectin receptor function of alpha v beta 5, our results suggest that the previously described carcinoma cell integrin, alpha v beta x (Cheresh, D. A., Smith, J. W., Cooper, H. M., and Quaranta, V. (1989) Cell 57, 59-69), is a mixture of at least two different receptors: alpha v beta 5, mediating adhesion to vitronectin, and alpha v beta 6, mediating adhesion to fibronectin.

During biosynthesis, class II major histocompatibility complex molecules are intimately associated with invariant chain (Ii). The Ii-class II association has been shown to block peptide-class II binding and to affect the ultimate conformation of class II expressed on the cell surface. To assess the biochemical basis for the effects of Ii on class II, we have analyzed the biosynthesis of class II in EL4 cells transfected with I-Ad with and without Ii. In these studies, we found that Ii had a profound effect on the biosynthesis of I-Ad. In the absence of Ii, class II could form dimers efficiently, but these dimers appeared to be misfolded and this altered conformation resulted in the loss of some monoclonal antibody epitopes and inefficient transport from the endoplasmic reticulum to the Golgi. In addition, class II that was transported through the Golgi accumulated an abnormally increased molecular mass associated with N-linked glycosylation. Subsequent transfection of Ii into these cells resulted in recovery of normal class II conformation, causing a restoration of monoclonal antibody epitopes, efficient intracellular transport, and normal glycosylation. Together, these data indicate that Ii can have a profound effect on the folding, transport, and modification of class II molecules and suggest that one function of Ii may be to act as a class II-specific chaperone.