The epithelial-mesenchymal transition (EMT) phenomenon.

The epithelial-mesenchymal transition (EMT) describes a rapid and often reversible modulation of phenotype by epithelial cells. EMT was originally defined in the context of developmental stages, including heart morphogenesis, mesoderm and neural crest formation. Epithelial cells loosen cell-cell adhesion structures throughout EMT. They modulate their polarity, cytoskeleton organization and typically express vimentin filaments and downregulate cytokeratins. They become isolated, mobile and resistant to anoikis. The EMT at least superficially resembles the evolution from normal to transformed cell phenotype during carcinoma progression. The relevance of the concept of EMT in this context was indicated by in vitro models using transformed epithelial cells. Transduction pathways typical of embryogenic EMT in vivo were also found to be activated during cancer progression. More recently, it has been found that such pathways indicate an increased plasticity linked to cellular stemness and ability to generate tumors. However, in the absence of direct evidence, a number of oncologists and pathologists remain skeptical about applying the EMT concept to human tumor progression. Typically in the cancer field, EMT concept appears to be fully relevant in some situations, but the concept has to be adjusted in other situations to reflect tumor cell renewal and plasticity during carcinoma progression and metastasis.

The zinc-finger protein slug causes desmosome dissociation, an initial and necessary step for growth factor-induced epithelial-mesenchymal transition.

Epithelial-mesenchymal transition (EMT) is an essential morphogenetic process during embryonic development. It can be induced in vitro by hepatocyte growth factor/scatter factor (HGF/SF), or by FGF-1 in our NBT-II cell model for EMT. We tested for a central role in EMT of a zinc-finger protein called Slug. Slug mRNA and protein levels were increased transiently in FGF-1-treated NBT-II cells. Transient or stable transfection of Slug cDNA in NBT-II cells resulted in a striking disappearance of the desmosomal markers desmoplakin and desmoglein from cell-cell contact areas, mimicking the initial steps of FGF-1 or HGF/SF- induced EMT. Stable transfectant cells expressed Slug protein and were less epithelial, with increased cell spreading and cell-cell separation in subconfluent cultures. Interestingly, NBT-II cells transfected with antisense Slug cDNA were able to resist EMT induction by FGF-1 or even HGF/SF. This antisense effect was suppressed by retransfection with Slug sense cDNA. Our results indicate that Slug induces the first phase of growth factor-induced EMT, including desmosome dissociation, cell spreading, and initiation of cell separation. Moreover, the antisense inhibition experiments suggest that Slug is also necessary for EMT.

Homing of hemopoietic precursor cells to the embryonic thymus: characterization of an invasive mechanism induced by chemotactic peptides.

During embryonic development, T cell precursors migrate to the thymus, where immunocompetency is acquired. Our previous studies have shown that avian hemopoietic precursor cells are recruited to the thymus by chemotactic peptides secreted by thymic epithelial cells (Champion, S., B. A. Imhof, P. Savagner, and J. P. Thiery, 1986, Cell, 44:781-790). In this study, we have characterized the homing of these precursor cells to the thymus in vivo by electron and light microscopy. Hemopoietic precursors could be seen to extravasate from blood or lymphatic vessels, migrate in the mesenchyme, traverse the perithymic basement membrane, and finally intercalate into the thymic epithelium. Labeled hemopoietic precursors injected into the blood circulation also followed the same pathway. Migrating hemopoietic precursor cells were found to express the fibronectin receptor complex. In the presence of thymic chemotactic peptides, hemopoietic precursors traverse a human amniotic basement membrane. This invasive process was inhibited by antibodies to laminin or to fibronectin, two major glycoproteins of the amniotic membrane, by monovalent Fab' fragments of antibodies to the fibronectin receptor, and, finally by synthetic peptides that contain the cell-binding sequence Arg-Gly-Asp-Ser of fibronectin. These results indicate that hemopoietic precursors respond to thymic chemotactic peptides by invasive behavior. Direct interactions between basement membrane components and fibronectin receptors appear to be required for this developmentally regulated invasion process.

Hepatocyte attachment to laminin is mediated through multiple receptors.

The interaction of hepatocytes with the basement membrane glycoprotein laminin was studied using synthetic peptides derived from laminin sequences. Rat hepatocytes bind to laminin and three different sites within the A and B1 chains of laminin were identified. Active laminin peptides include the PA22-2 peptide (close to the carboxyl end of the long arm in the A chain), the RGD-containing peptide, PA21 (in the short arm of the A chain) and the pentapeptide YIGSR (in the short arm of the B1 chain). PA22-2 was the most potent peptide, whereas the other two peptides had somewhat lower activity. Furthermore, hepatocyte attachment to laminin was inhibited by the three peptides, with PA22-2 being the most active. Various proteins from isolated membranes of cell-surface iodinated hepatocytes bound to a laminin affinity column including three immunologically related binding proteins : Mr = 67,000, 45,000, and 32,000. Several proteins--Mr = 80,000, 55,000, and 38,000-36,000--with a lower affinity for laminin were also identified. Affinity chromatography on peptide columns revealed that the PA22-2 peptide specifically bound the Mr = 80,000, 67,000, 45,000, and 32,000 proteins, the PA21 peptide bound the Mr = 45,000 and 38,000-36,000 proteins and the YIGSR peptide column bound the 38,000-36,000 protein. Antisera to a bacterial fusion protein of the 32-kD laminin-binding protein (LBP-32) reacted strongly with the three laminin-binding proteins, Mr = 67,000, 45,000, and 32,000, showing that they are immunologically related. Immunoperoxidase microscopy studies confirmed that these proteins are present within the plasma membrane of the hepatocyte. The antisera inhibited the adhesion of hepatocytes to hepatocytes to laminin by 30%, supporting the finding that these receptors and others mediate the attachment of hepatocytes to several regions of laminin.

Slug/Pcad pathway controls epithelial cell dynamics in mammary gland and breast carcinoma.

Mammary gland morphogenesis results from the coordination of proliferation, cohort migration, apoptosis and stem/progenitor cell dynamics. We showed earlier that the transcription repressor Slug is involved in these functions during mammary tubulogenesis. Slug is expressed by a subpopulation of basal epithelial cells, co-expressed with P-cadherin (Pcad). Slug-knockout mammary glands showed excessive branching, similarly to Pcad-knockout. Here, we found that Slug unexpectedly binds and activates Pcad promoter through E-boxes, inducing Pcad expression. We determined that Pcad can mediate several functions of Slug: Pcad promoted clonal mammosphere growth, basal epithelial differentiation, cell-cell dissociation and cell migration, rescuing Slug depletion. Pcad also promoted cell migration in isolated cells, in association with Src activation, focal adhesion reorganization and cell polarization. Pcad, similarly to Slug, was required for in vitro 3D tubulogenesis. Therefore, Pcad appears to be responsible for epithelial-mesenchymal transition-linked plasticity in mammary epithelial cells. In addition, we found that genes from the Slug/Pcad pathway components were co-expressed and specifically correlated in human breast carcinomas subtypes, carrying pathophysiological significance.

Alternative splicing in fibroblast growth factor receptor 2 is associated with induced epithelial-mesenchymal transition in rat bladder carcinoma cells.

We described previously that acidic fibroblast growth factor (aFGF), but not basic fibroblast growth factor (bFGF), can induce the rat carcinoma cell line NBT-II to undergo a rapid and reversible transition from epithelial to mesenchymal phenotype (EMT). We now find that NBT-II EMT is stimulated by keratinocyte growth factor (KGF) in cells grown at low density. Accordingly, a high-affinity receptor showing 98% homology to mouse FGF receptor 2b/KGF receptor was cloned and sequenced from NBT-II cells. Northern analysis indicated that mRNA for FGF receptor 2b/KGF receptor was drastically down-regulated within 1 wk in aFGF-induced mesenchymal NBT-II cells. This decrease coincided with an up-regulation of FGF receptor 2c/Bek, a KGF-insensitive, alternatively spliced form of FGF receptor 2b/KGF receptor. Functional studies confirmed that KGF could not maintain EMT induction on mesenchymal NBT-II cells. FGF receptor 1 and FGF receptor 2c/Bek could also support EMT induction when transfected into NBT-II cells in response to aFGF or bFGF. Such transfected cells could bind bFGF as well as aFGF. Therefore, EMT can be induced through different FGF receptors, but EMT may also regulate FGF receptor expression itself.

Collagen II promoter and enhancer interact synergistically through Sp1 and distinct nuclear factors.

The collagen II gene is expressed primarily in chondrocytes. Its transcription is activated through the interaction of cell type-specific regulatory elements located in the promoter region and in the first intron. In this study, we found that a short promoter sequence including two GC boxes was required for efficient enhancer-mediated transcription. Gel-shift analysis, site mutations, and footprint analysis showed that one of the GC boxes bound functionally to an Sp1-related factor and that an oligonucleotide containing this GC box did interact with an enhancer-nuclear factor complex. Additionally, an enhancer-derived oligonucleotide was found to complex CIIZFP, a zinc-finger protein that binds to the enhancer within the first intron and Sp1, but only in presence of CIIZFP. Antibodies against Sp1 specifically inhibited the formation of this complex. Western/Southwestern analysis also showed that a protein complex including Sp1 was able to bind the enhancer and the promoter regions in non-denaturing conditions. This complex was dissociated by denaturation. These results suggest that the formation of a nuclear protein-mediated loop structure between the promoter and enhancer may regulate transcription of the collagen II gene transcription.

Leaving the neighborhood: molecular mechanisms involved during epithelial-mesenchymal transition.

Several molecular mechanisms contribute directly and mechanically to the loss of epithelial phenotype. During epithelial-mesenchymal transition (EMT), adherens junctions and desmosomes are at least partially dissociated. At the same time, a massive cytoskeleton reorganization takes place, involving the rho family and the remodeling of the actin microfilament mesh. Numerous pathways have been described in vitro that control phenotype transition in specific cell models. In vivo developmental studies suggest that transcriptional control, activated by a specific pathway involving Ras, Src and potentially the Wnt pathway, is an essential step. Recent functional and localization experiments indicate that the slug/snail family of transcription factors functions overall as an epithelial phenotype repressor and could represent a key EMT contributor.

Two silencers regulate the tissue-specific expression of the collagen II gene.

Collagen II, the major component of cartilage, is synthesized primarily by chondrocytes and by certain cells in the eye. Previously, we have studied the regulatory regions of the collagen II gene by DNA transfection assays (Horton, W., Miyashita, T., Kohno, K., and Yamada, Y. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 8864-8868). These studies show that both the promoter and an enhancer sequence in the first intron are required for high transcriptional activity in chondrocytes. These elements do not show significant activity in cells which do not synthesize collagen II, such as in muscle cells and fibroblasts. In this report, we have constructed plasmids containing various deletions of the promoter of the collagen II gene, fused to a reporter gene for chloramphenicol acetyltransferase (CAT) and transfected them into both chick embryonic fibroblasts and HeLa cells. We have found that silencer elements in the collagen II promoter region reduce CAT activity 11-fold in fibroblasts, while not affecting the enhancer-mediated transcription in chondrocytes. Deletions in the promoter showed that most of the silencing activity was localized in two sites, between -360 and -460 base pairs and between -620 and -700 base pairs. Furthermore, a fragment containing these two sequences in a thymidine kinase promoter CAT construct reduced the activity of the promoter in an orientation independent fashion. Sequence analysis revealed that the two silencer regions are homologous and contain consensus motifs for silencer elements found in other genes. Gel retardation experiments showed that nuclear factors from HeLa cells bind specifically to a DNA fragment containing the silencer, whereas chondrocyte nuclear extracts did not show any activity. Thus, our study indicates that the expression of the collagen II gene is controlled by both negative and positive elements to ensure that the gene is only expressed in suitable cells.

Characterization of the promoter for the rat and human link protein gene.

We have isolated the 5'-end of the gene for the rat and human link protein by screening genomic libraries with oligonucleotides corresponding to the 5'-cDNA sequence. Several overlapping clones were isolated for the human link protein gene, while only one clone was obtained for the rat. All the clones contained a single exon of which the sequence was identical to the most 5'-end of the rat and human cDNAs. Transcription initiation sites for the rat link gene were identified by primer extension and S1 protection analysis using total RNA from the rat Swarm chondrosarcoma. Transcriptional initiation sites for the human link gene were determined by specific primer extension of RNA from human fetal cartilage. Comparison of 1500 bp of 5'-flanking sequence between the rat and human link protein genes showed strong sequence conservation near the start site of transcription with 80% overall identity. Analysis of the 5'-flanking regions also revealed a large inverted repeat consisting of repeating purine-pyrimidine, which has the potential to form left-handed Z-DNA. Transcriptional regulation of the link protein gene was studied by coupling either 7.0 kb or 0.85 kb of 5'-flanking rat DNA to the chloramphenicol acetyltransferase (CAT) gene followed by transfection into chick embryonic chondrocytes (CEC) and HeLa cells. Both constructs had considerable CAT activity in CEC cells and less activity in HeLa cells. Furthermore, inclusion of a DNA fragment from the first intron increased relative CAT activity in both of these cell types. The increased activity from the first intron was shown to be orientation independent in CEC. These results indicate the presence of positive cisacting regulatory elements in both the promoter and first intron of the rat gene for link protein.

The embryonic thymus produces chemotactic peptides involved in the homing of hemopoietic precursors.

During ontogeny, T cell precursors must colonize the thymus to acquire immunocompetency. Using migration assays, a chemotactic activity was detected in conditioned media from avian embryonic thymic epithelial cells. The responding cells were shown to acquire T lymphocyte markers after homing into the thymus. Absorption experiments demonstrated surface receptors for the chemotactic substance on these hemopoietic precursors, which were not found on thymus-derived lymphocytes. Two peaks of chemotactic activity in the 1 kd-4 kd molecular weight range were detected after fractionation of thymic epithelial cell-conditioned medium. One of these activities was retained after heating to 95 degrees C but was destroyed after proteolytic treatment. Thus chemotactic peptides may be responsible for the thymic recruitment of the first hemopoietic precursors and may also be involved in the renewal of these precursors throughout adult life.

Aspects of haemopoietic cell dynamics: ontogeny and targeted migration.

In the developing avian and mammalian embryo, haemopoietic cells appear first in transient foci whose function is restricted to discrete periods of embryogenesis. These foci are essentially represented by the yolk sac, intraembryonic dispersed foci and the liver. Haemopoietic cells then repopulate the developing spleen, thymus and bone marrow, organs which persist and develop after birth. In the present review, we describe a number of possible mechanisms controlling specific adhesion, oriented migration and invasiveness of haemopoietic cells. One concerns the high specificity of the interactions of homing receptors on the surface of haemopoietic cells with determinants on vascular endothelium and/or thymic epithelium. A second is the importance of the presence of some macromolecules in the extracellular matrix, such as fibronectin, collagen, laminin and elastin. These components can interact with the haemopoietic cells (and/or induce chemotaxis) via the existence of specific receptors on the surface of the haemopoietic cells. Another mechanism is the activation of the haemopoietic cells through the interactions of cell-chemotactic factor, cell-extracellular matrix and/or cell-thymic epithelium. This activation can lead to: 1) the expression of new specific cell-surface receptors for the target foci; 2) the secretion of specific protease and glycosidase systems active upon the extracellular matrix; and 3) the differentiation of these cells in the thymus.

Slug mRNA is expressed by specific mesodermal derivatives during rodent organogenesis.

We describe the expression pattern of the zinc-finger protein slug during rat and mouse embryonic development. Expression was mostly confined to migratory neural crest cells and several mesodermal derivatives. We could not detect slug expression in premigratory rodent neural crest cells, unlike previously studied vertebrates; the earliest substantial expression of slug was found in migratory cranial neural crest cells invading the first branchial arch. Their derivatives, comprising most of the craniofacial region, continued to express slug. Concomitantly, slug was expressed in sclerotome precursor cells prior to their separation from the differentiating somites. During organogenesis, slug was expressed in mesenchymal components of lung, digestive tract, meso- and metanephros until late stages. Slug was also found in mesenchymal cells undergoing cartilage and bone differentiation. Expression was down-regulated in parallel with chondrocyte phenotypic differentiation. Overall, slug appeared to be expressed by mesenchymal cells at predifferentiation stages involving cell migration and phenotype modulation. Expression was generally down-regulated afterwards. However, residual slug mRNA was found in several adult tissues, including liver and lung.

Expression and structure of cartilage proteins.

Cartilage has unique physical characteristics attributable to the presence of an unusually high content of proteoglycan embedded in the network of collagen fibrils. Advances in understanding the structure of these components and how their synthesis is regulated have been greatly assisted by the application of molecular biology. For example, an immortalized rat chondrocyte cell line was obtained by infection with a recombinant retrovirus encoding the myc gene product. Several positive and negative DNA regulatory elements of the collagen II gene have been identified that appear to be important in the regulation of this gene in chondrocytes. The complete primary structure of the cartilage proteoglycan (aggrecan) core protein deduced from cDNA sequence displays a complex multidomain structure including numerous repeats of Ser-Gly sequences and sequence homologies with link protein and animal lectins. Such studies advance our understanding of normal morphogenetic events and lay the groundwork for determining the basis of molecular and genetic defects.