Biochemical and Biophysical Research Communications
Regular ArticleMolecular Cloning of Human Epimorphin: Identification of Isoforms and Their Unique Properties
Abstract
Epithelial-mesenchymal interactions are crucial for various epithelial tissue organizations and epimorphin is one of the important signaling molecules from the mesenchyme (1). The sequence analysis of a human homologue revealed that both of primary and predicted secondary structures of epimorphin are highly conserved among species and this molecule has some isoforms including a putative soluble type. I found that human epimorphins also have a large discrepancy in molecular masses as the case of mouse (around 33kD are predicted by the sequences whereas two protein bands of 60-70kD and 150kD are detected in the cells), and it can be explained, at least in part, by the SDS-resistant complexes formed in the microsomal membranes.
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Epimorphin acts extracellularly to promote cell sorting and aggregation during the condensation of vertebral cartilage
2006, Developmental BiologyFormation of vertebrae occurs via endochondral ossification, a process involving condensation of precartilaginous cells. Here, we provide the first molecular evidence of mechanism that underlies initiation of this process by showing that the extracellular factor, Epimorphin, plays a role during early steps in vertebral cartilage condensation. Epimorphin mRNA is predominantly localized in the vertebral primordium. When provided exogenously in ovo, it causes precocious differentiation of chondrocytes, resulting in the formation of supernumerary vertebral cartilage in chicken embryos. To further analyze its mode of action, we used an in vitro co-culture system in which labeled 10T1/2 or sclerotomal prechondrogenic cells were co-cultured with unlabeled Epimorphin-producing cells. In the presence of Epimorphin, the labeled cells formed tightly packed aggregates, and sclerotomal cells displayed augmented accumulation of NCAM and other early markers of chondrocyte differentiation. Finally, we found that the Epimorphin expression is initiated during vertebrogenesis by Sonic hedgehog from the notochord mediated by Sox 9. We present a model in which successive action of Epimorphin in recruiting and stacking sclerotomal cells leads to a sequential elongation of a vertebral primordium.
The Mason–Pfizer monkey virus (M-PMV) Gag protein, precursor to the structural proteins of the infectious virion, assembles into immature capsid-like particles when expressed at high levels in bacterial cells. Similar capsid-like particles can be obtained by in vitro assembly using a high concentration of isolated Gag. M-PMV Gag contains a p12 protein that has no corresponding analogues in most other retroviruses and has been suggested to contain an internal scaffold domain (ISD). We have expressed and purified p12 and the N- and C-terminal halves (Np12 and Cp12) that are predicted to be structurally independent domains. The behavior of these proteins was analyzed using chemical cross-linking, CD spectroscopy, and electron microscopy. The N-terminal half of p12 is largely α-helical although the C-terminal portion lacks any apparent ordered structure. Both p12 and Np12 form high-order oligomers in vitro and when expressed in E. coli produce organized structures that are visible by electron microscopy. Interestingly, Cp12, as well as the whole protein, can form dimers in the presence of SDS. The data show that both domains of p12 contribute to its ability to multimerize with much of this potential residing in its N-terminal part, most probably within the leucine zipper-like (LZL) sequence.
Influences of keratinocyte-fibroblast interaction on the expression of epimorphin by fibroblasts in vitro
1999, Journal of Dermatological ScienceEpimorphin was demonstrated to be a mesenchymal signal factor modulating epithelial morphogenesis of skin, lung and liver in vitro. Most of the previous studies were performed biochemically and functionally. In the present study, expression of epimorphin was immunohistochemically compared between cultured fibroblasts and cocultured fibroblasts with keratinocytes obtained from normal skin. Cultured fibroblasts revealed a low level of epimorphin expression. In contrast, the expression by fibroblasts was greatly enhanced in skin explant culture where both fibroblasts and keratinocytes were present. In three-dimensional coculture of fibroblasts and keratinocytes, the expression of epimorphin was enhanced. The staining pattern of epimorphin in three-dimensional coculture was similar to that in human skin. These results suggest that dermal fibroblasts are manufacturers of epimorphin, and keratinocyte–fibroblast interaction may play important roles in the expression of epimorphin in vitro.
A novel hepatic stellate (Ito) cell-derived protein, epimorphin, plays a key role in the late stages of liver regeneration
1998, Biochemical and Biophysical Research CommunicationsLimited data exist regarding morphogenesis and differentiation during liver regeneration. We examined the role of epimorphin on liver regeneration. After 70% partial hepatectomy, mouse liver was collected on days 1, 3, 7, and 14 for immunohistochemistry and the detection of epimorphin mRNA and connexin 32. Using primary cultured rat hepatocytes, morphogenesis and differentiation of cells were tested with or without epimorphin. Seven days after cell inoculation, the expression of connexin 32 and the cell–cell communication was tested as a marker of differentiation. Epimorphin was detected exclusively in hepatic stellate cells. Connexin 32 was detected only in hepatocytes. After partial hepatectomy, epimorphin mRNA was detected on day 3 and peaked at day 7, followed by protein expression. Connexin 32 expression showed a similar time course. Cultured hepatocytes formed multicellular spheroids in an active epimorphin-coated culture dish and showed positive dye coupling, whereas the cell–cell communication was lost without active epimorphin. Because epimorphin was expressed late in liver regeneration, it might play a role in morphogenesis and differentiation.
Immunolocalization of epimorphin in skin
1996, Journal of Dermatological ScienceEpimorphin was originally identified as a mesenchymal cell surface-associated protein that modulates epithelial morphogenesis in embryonic skin and lung epithelia. A previous report which utilized embryonic mouse skin, showed that epimorphin was localized non-homogeneously in a region adjacent to the epidermis and in a mesenchymal cell condensation located in front of growing hair follicles. We report herein a further detailed localization of this protein in adult mouse skin using immunoelectron microscopy. Epimorphin was found to be localized on the undersurface of basal cells, in the cytoplasm of cell processes of fibroblasts, as well as on the plasma membrane of fibroblasts, endothelial cells, pericytes, perineurium and endomysium. Our present finding indicated that epimorphin is one of the factors involved in multiple biological functions in a variety of structures derived from various origins and that it is not a specific epithelial morphogenetic factor.
A genomic DNA fragment containing the rat epimorphin gene sequence was cloned from a rat DNA cosmid library using a mouse epimorphin cDNA probe. Within the cosmid insert, nine epimorphin exons were identified and sequenced. The predicted amino acid sequence of the rat epimorphin protein exhibited 96 and 86% identity with the mouse and human epimorphin proteins, respectively. Consistent with the developmentally related expression pattern of the mouse epimorphin gene, transcripts of the rat epimorphin gene were detected in 17-day postfertilization rat embryos. The gene, designatedEpim,was assigned to rat chromosome 12 by somatic cell hybrid analysis and localized to 12q16 by fluorescencein situhybridization. The mouse and human homologs of this gene were localized on mouse chromosome 5 and human chromosome 7 by linkage analysis and chromosomalin situhybridization, respectively.