Karen A. Knudsen

A role for the Ca2+-dependent adhesion molecule, N-cadherin, in myoblast interaction during myogenesis

The formation of multinucleate skeletal muscle cells (myotubes) is a Ca2(+)-dependent process involving the interaction and fusion of mononucleate muscle cells (myoblasts). Specific cell-cell adhesion precedes lipid bilayer union during myoblast fusion and has been shown to involve both Ca2(+)-independent (CI)2 and Ca2(+)-dependent (CD) mechanisms. In this paper we present evidence that CD myoblast adhesion involves a molecule similar or identical to two known CD adhesion glycoproteins, N-cadherin and A-CAM. These molecules were previously identified by other laboratories in brain and cardiac muscle, respectively, and are postulated to be the same molecule. Antibodies to N-cadherin and A-CAM immunoblotted a similar band with a molecular weight of approximately 125,000 in extracts of brain, heart, and pectoral muscle isolated from chick embryos and in extracts of muscle cells grown in vitro at Ca2+ concentrations that either promoted or inhibited myotube formation. In assays designed to measure the interaction of fusion-competent myoblasts in suspension, both polyclonal and monoclonal anti-N-cadherin antibodies inhibited CD myoblast aggregation, suggesting that N-cadherin mediates the CD aspect of myoblast adhesion. Anti-N-cadherin also had a partial inhibitory effect on myotube formation likely due to the effect on myoblast-myoblast adhesion. The results indicate that N-cadherin/A-CAM plays a role in myoblast recognition and adhesion during skeletal myogenesis.

A role for the neural cell adhesion molecule, NCAM, in myoblast interaction during myogenesis

The Ca2(+)-independent neural cell adhesion molecule, NCAM, is expressed by both nerve and muscle cells and has been shown to mediate both nerve-nerve and nerve-muscle cell interaction. A role for NCAM in muscle-muscle cell interaction has been proposed but not demonstrated. Here we report evidence that NCAM is expressed by embryonic chick muscle cells during in vitro development and functions together with Ca2(+)-dependent adhesion molecules in mediating myoblast interaction during the formation of multinucleate cells.

A role for cadherins in cellular signaling and differentiation.

Cadherins form a family of cell‐cell adhesion proteins that are critical to normal embryonic development. Expression of the various family members is regulated in a complex pattern during embryogenesis. Both reduced and inappropriate expression of cadherins have been associated with abnormal tissue formation in embryos and tumorigenesis in mature organisms. Evidence is accumulating that signals unique to individual members of the cadherin family, as well as signals common to multiple cadherins, contribute to the differentiated phenotype of various cell types. While a complete understanding of the regulation of cadherin expression of the molecular nature of intracellular signaling downstream of cadherin adhesion is essential to an understanding of embryogenesis and tumorigenesis, our knowledge in both areas is inadequate. Clearly, elucidating the factors and conditions that regulate cadherin expression and defining the signaling pathways activated by cadherins are frontiers for future research. J. Cell. Biochem. Suppls. 30/31:168–176, 1998.

Cadherins and the mammary gland

Cadherin cell–cell adhesion proteins are critical for the formation of tissues from single cells. E‐and P‐cadherin play important roles in the architecture and function of the normal mammary gland. In breast cancers, the expression, or lack thereof, of E‐cadherin can differentiate tumor types, whereas the misexpression of either P‐cadherin or N‐cadherin can be a marker of poor prognosis or increased malignancy, respectively. Additional research is needed to more precisely define the roles of both classical and desmosomal cadherins and their downstream signaling events, in the development and malignant behavior of breast cancers.

Inhibition of murine melanoma cell-matrix adhesion and experimental metastasis by albolabrin, an RGD-containing peptide isolated from the venom of Trimeresurus albolabris

Albolabrin, a 7.5-kDa cysteine-rich protein isolated from the venom of Trimeresurus albolabris, contains the arginine-glycine-aspartic acid (RGD) cell recognition sequence found in many cell adhesion-promoting extracellular matrix proteins, such as fibronectin and laminin. Albolabrin belongs to a family of RGD-containing peptides, termed disintegrins, recently isolated from the venom of various vipers and discovered to be potent inhibitors of both platelet aggregation and cell-substratum adhesion. Here we report that albolabrin inhibited the attachment of B16-F10 mouse melanoma cells to either fibronectin or laminin absorbed on plastic. When immobilized on plastic, albolabrin promoted B16-F10 melanoma cell attachment; this was inhibited by either RGD-serine (RGDS) or antibodies to integrins, suggesting that albolabrin binds via its RGD amino sequence to integrin receptors expressed on the melanoma cell surface. In an in vivo experimental metastasis system, albolabrin at a concentration of 300-600 nM inhibited C57BL/6 mouse lung colonization by tail vein-injected mouse melanoma cells and was at least 2000 times more active than RGDS in this assay. We propose that albolabrin inhibits tumor cell metastasis by inhibiting integrin-mediated attachment of melanoma cells to RGD-containing components of the extracellular matrix in the mouse lung.

Cadherin Junctions in Mammary Tumors

Cadherins are the transmembrane component of adherens junctions found between interacting cells in tissues. The cadherins bind cells to one another in a specific manner and link to the actin cytoskeleton through intracellular catenins. In addition to promoting strong cell-cell adhesion, cadherins appear to initiate and modify intracellular signaling pathways. The loss of E-cadherin function in epithelial cells is thought to be an important step in tumorigenesis. Moreover, anomalous expression of inappropriate cadherins in epithelial cells alters their behavior and may contribute to the tumorigenic phenotype. For breast cancer the decreased expression of E-cadherin alone may have limited value as a prognostic indicator; however, examining the repertoire of cadherins and catenins expressed by tumors may provide useful prognostic information.

Trigramin, an RGD-containing peptide from snake venom, inhibits cell-substratum adhesion of human melanoma cells☆

Trigramin, a cysteine-rich, RGD-containing peptide isolated from the venom of the Trimeresurus gramineus snake, inhibited the adhesion of human melanoma cells to fibronectin and fibrinogen. Compared on a molar basis to GRGDSP, trigramin was approximately 500 times more potent than the hexapeptide at inhibiting cell adhesion to fibronectin. The activity of trigramin was abolished by chemical reduction of the molecule, indicating that the secondary structure is important to the biological activity. Trigramin presents an example of an effective inhibitor of cell adhesion that has developed in nature and may prove to be a useful probe in studying the cell surface receptors involved in cell adhesion.

Nuclear Localization of E-Cadherin Expression in Merkel Cell Carcinoma

CONTEXTnCadherins are cell-cell adhesion proteins that act as tumor suppressor genes and have a critical role in cell sorting and tissue formation during organogenesis. The pattern of cadherin expression constitutes a useful diagnostic and prognostic tool in the evaluation of tumors and for determining the histogenesis of tumor cells. We have previously characterized the cell types of several tumors based on the expression of individual cadherins.nnnOBJECTIVEnTo investigate the expression of cadherins in Merkel cell carcinomas.nnnDESIGNnParaffin immunohistochemical analysis of the 3 best-studied cadherins was performed on 35 cases of Merkel cell carcinoma.nnnRESULTSnE-cadherin was expressed in 34 (97%) of 35 Merkel cell carcinomas examined, N-cadherin was expressed in 22 (63%) of 35 cases, and P-cadherin was expressed in 15 (43%) of 35 cases. This frequency of cadherin expression was similar to a group of small cell and neuroendocrine tumors from other primary sites. Interestingly, the localization of E-cadherin expression was unique in Merkel cell carcinomas compared with other primary neuroendocrine tumors. Merkel cell carcinomas showed marked preference for nuclear versus membrane localization, whereas small cell tumors from other sites showed fewer cases of nuclear E-cadherin expression. The nuclear localization of E-cadherin did not correlate with cadherin-associated protein beta-catenin nuclear expression.nnnCONCLUSIONSnOur findings show that E-cadherin is the most frequently expressed cadherin in Merkel cell carcinoma, followed in frequency by N-cadherin then P-cadherin. The pattern of nuclear E-cadherin expression is more frequent for Merkel cell carcinoma than small cell tumors of other primary sites. These observations suggest that E-cadherin expression and function are altered in Merkel cell carcinoma, and this finding has potential use in the differential diagnosis of these tumors.

Batroxostatin, an Arg-Gly-Asp-containing peptide from Bothrops atrox, is a potent inhibitor of platelet aggregation and cell interaction with fibronectin

A potent inhibitor of platelet aggregation and cell adhesion was isolated from the venom of Bothrops atrox. This peptide, referred to as batroxostatin, was composed of 71 amino acids and showed a high degree of homology with other snake venom peptides including trigramin, albolabrin, elegantin and applagin: all 12 cysteines and the RGD sequence (standard one-letter amino acid codes) aligned in the same position. Compared on a molar basis, the anti-platelet aggregation activity of batroxostatin was about 1000-times higher than that of RGDS. In addition, batroxostatin was about 400-times more potent than GRGDS at inhibiting melanoma cell adhesion to fibronectin. Batroxostatin covalently attached to plastic promoted adhesion of melanoma cells. The anti-GP140 antibody, recognizing beta 1 integrins, completely inhibited adhesion of mouse melanoma cells to batroxostatin. This observation, in addition to the inhibitory effect of batroxostatin on the adhesion of chick fibroblasts to fibronectin, suggests that batroxostatin interacts with integrins from both the beta 1 and beta 3 subfamilies.

Adhesion molecules and skeletal myogenesis

Skeletal muscle forms from proliferating myoblasts that differentiate, fuse into multinucleate myofibers, assemble a contractile apparatus, and form synapses with motor neurons. Proteins mediating both cell-cell and cell-matrix adhesion, including extracellular matrix proteins, integrins, cadherins, members of the immunoglobulin family, and the dystrophin-containing glycoprotein complex, are expressed by skeletal muscle and play important roles in muscle differentiation. Here, we review what is known about the function of various adhesion molecules in four major steps of skeletal muscle development: differentiation, fusion, myofibrillogenesis and synaptogenesis.