Modulating the strength of cadherin adhesion: evidence for a novel adhesion complex.

Adherens junctions and desmosomes are critical for embryogenesis and the integrity of adult tissues. To form these junctions, classical cadherins interact via alpha- and beta-catenin with the actin cytoskeleton, whereas desmosomal cadherins interact with the intermediate filament system. Here, we used a hormone-activated mutant N-cadherin expressed in fibroblasts to show the existence of a novel classical cadherin adhesion system. N-cadherin was fused at its C-terminus to a modified estrogen receptor ligand-binding domain (NcadER) that binds 4-hydroxytamoxifen (4OHT) and expressed in L cells, which lack an endogenous cadherin. Cells with the mutant cadherin (LNER cells) aggregated in the absence of 4OHT, but only in its presence formed tightly compacted aggregates like those formed by L cells expressing wild-type N-cadherin (LN cells). Compaction of LNER cells treated with 4OHT was accompanied by elevated levels of p120ctn in NcadER immunoprecipitates, compared to immunoprecipitates of non-treated cells, but without changes in alpha- and beta-catenin, or actin. Compaction induced by 4OHT was also accompanied by increased interaction of the NcadER with the cytoskeleton and increased vimentin organization. Vimentin co-immunoprecipitated with the NcadER/catenin complex, suggesting an interaction between cadherin and vimentin. The mechanism by which vimentin interacts with the cadherin appears to involve p120ctn as it co-immunoprecipitates and colocalizes with vimentin in the parent L cells, which lack a cadherin and alpha- and beta-catenins. Disrupting the actin cytoskeleton with cytochalasin B inhibited aggregation, whereas knocking down vimentin with specific siRNAs inhibited compaction. Based on our results we propose that a vimentin-based classical cadherin complex functions together with the actin-based complex to promote strong cell-cell adhesion in fibroblasts.

Effect of N-cadherin misexpression by the mammary epithelium in mice.

N-cadherin is not typically expressed by epithelial cells. However, it is detected in breast cancers and increases tumor cell migration and invasion in vitro. To explore its misexpression, we generated transgenic mice with N-cadherin in the mammary epithelium. Mammary glands appeared normal and no tumors arose spontaneously. To investigate N-cadherin misexpression in mammary tumors, neu was overexpressed through breeding. Tumors developed in +/neu and N-cadherin/neu mice, although few tumors in bitransgenic mice expressed N-cadherin, and they did not differ from N-cadherin-negative tumors.

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.

Soluble p-cadherin found in human semen.

Cadherins constitute a family of calcium-dependent cell-cell adhesion molecules. P (placental)-cadherin is a 118-kd protein expressed by basal cells in epithelial tissues. P-cadherin also has been described as a soluble protein in certain biological fluids, including human serum and breast milk. Here, we report the presence of an 80-kD fragment of P-cadherin in human semen. No significant differences were found in semen samples from fertile and nonfertile patients. Our results add evidence to previous data indicating that soluble fragments of P-cadherin have a widespread distribution in bodily fluids and suggest that soluble P-cadherin might have functions other than basal epithelial cell-cell adhesion.

Inappropriate P-cadherin expression in the mouse mammary epithelium is compatible with normal mammary gland function.

Cadherins comprise a family of cell-cell adhesion proteins critical to the architecture and function of tissues. Expression of family members E-, N-, and P-cadherin is regulated in a spatial and temporal fashion in the developing and adult organism. Using in vivo and in vitro experimental systems, perturbation of cadherin expression by genetic deletion, overexpression, mutant dominant-negative constructs, and, to a lesser degree, expression of an inappropriate cadherin have all been shown to alter embryogenesis, tissue architecture, and cell behavior. Here we studied how expression of an inappropriate cadherin affects the adult mouse mammary gland. Human P-cadherin was expressed in mammary epithelial cells under control of the mouse mammary tumor virus (MMTV) promoter, and the effect on mammary gland behavior was studied. Typically, E-cadherin is expressed by mammary epithelial cells, whereas P-cadherin is found in myoepithelial cells and cap cells of the ductal terminal end bud. However, breast cancers frequently express P-cadherin, even though they are thought to arise from epithelial cells, and it is a marker of poor prognosis. We developed two independent transgenic mouse lines that exhibited high levels of P-cadherin protein expression in the mammary epithelium. P-cadherin was detected in most, but not all, luminal epithelial cells, and was appropriately localized to cell-cell borders. It was detected in the mammary glands of virgin, pregnant, lactating, post-lactation, and aged parous female mice. Despite the robust and widespread expression of an inappropriate cadherin, no effect was observed on mammary gland morphogenesis, architecture, lactation, or involution in transgenic mice compared to wild-type mice. No mammary tumors formed spontaneously in either wild-type or transgenic mice. Moreover, mammary tumors induced by the neu oncogene, which was introduced by a breeding strategy, showed no differences between mice with or without hP-cadherin. Surprisingly, however, none of the tumors expressed hP-cadherin protein. Together, our studies show no apparent effect on adult mammary gland or tumor behavior by inappropriate expression of P-cadherin in normal mammary epithelial cells.

Soluble fragment of P-cadherin adhesion protein found in human milk.

Classical cadherins such as E- and P-cadherin are transmembrane proteins that mediate specific cell-to-cell adhesion and are important to tissue development and function. Cadherin function can be modulated by various means, including proteolytic cleavage of the extracellular adhesion domain from the cells' surface, yielding large soluble fragments termed (soluble) sE- or sP-cadherin. In people with certain carcinomas, sE-cadherin can be detected at elevated levels in the serum and sometimes can serve as a prognostic marker. Soluble E-cadherin also is found in urine of patients with bladder cancer. In addition to being present in bodily fluids of cancer patients, sE- and sP-cadherin are present in the serum of healthy people, suggesting that shedding of cadherins is a normal event. Here, we report high levels of 80 kDa sP-cadherin in human milk. In the lactating mammary gland tissue, P-cadherin appears to be a protein secreted by epithelial cells, rather than an adhesion protein. This is in contrast to the non-lactating mammary gland where P-cadherin is restricted to myoepithelial cells, and is present at sites of cell-cell contact.

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. © 1998 Wiley-Liss, Inc.