F. Van Roy

Genetic manipulation of E-cadherin expression by epithelial tumor cells reveals an invasion suppressor role

A cDNA encoding the cell-cell adhesion molecule E-cadherin was transfected into highly invasive epithelial tumor cell lines of dog kidney or mouse mammary gland origin. Transfectants with a homogeneously high expression of E-cadherin showed a reproducible loss of activity in two types of in vitro invasion assays. Invasiveness of these transfectants could be reinduced specifically by treatment with anti-E-cadherin antibodies. In vivo, they formed partly differentiated tumors, instead of fully undifferentiated tumors. Alternatively, a plasmid encoding E-cadherin-specific anti-sense RNA was introduced into noninvasive ras-transformed cells with high endogenous E-cadherin expression. The resulting down-regulation, albeit partial, rendered the cells invasive. These data provide direct evidence that E-cadherin acts as an invasion suppressor molecule.

E-cadherin is a tumour/invasion suppressor gene mutated in human lobular breast cancers.

Compelling experimental evidence exists for a potent invasion suppressor role of the cell‐cell adhesion molecule E‐cadherin. In addition, a tumour suppressor effect has been suggested for E‐cadherin. In human cancers, partial or complete loss of E‐cadherin expression correlates with malignancy. To investigate the molecular basis for this altered expression we developed a comprehensive PCR/SSCP mutation screen for the human E‐cadherin gene. For 49 breast cancer patients the occurrence of tumour‐specific mutations in the E‐cadherin gene was examined. No relevant DNA changes were encountered in any of 42 infiltrative ductal or medullary breast carcinoma samples. In contrast, four out of seven infiltrative lobular breast carcinomas harboured protein truncation mutations (three nonsense and one frameshift) in the extracellular part of the E‐cadherin protein. Each of the four lobular carcinomas with E‐cadherin mutations showed tumour‐specific loss of heterozygosity of chromosomal region 16q22.1 containing the E‐cadherin locus. In compliance with this, no E‐cadherin expression was detectable by immunohistochemistry in these four tumours. These findings offer a molecular explanation for the typical scattered tumour cell growth in infiltrative lobular breast cancer.

The cell-cell adhesion molecule E-cadherin

Abstract.This review is dedicated to E-cadherin, a calcium-dependent cell-cell adhesion molecule with pivotal roles in epithelial cell behavior, tissue formation, and suppression of cancer. As founder member of the cadherin superfamily, it has been extensively investigated. We summarize the structure and regulation of the E-cadherin gene and transcript. Models for E-cadherin-catenin complexes and cell junctions are presented. The structure of the E-cadherin protein is discussed in view of the diverse functions of this remarkable protein. Homophilic and heterophilic adhesion are compared, including the role of E-cadherin as a receptor for pathogens. The complex post-translational processing of E-cadherin is reviewed, as well as the many signaling activities. The role of E-cadherin in embryonic development and morphogenesis is discussed for several animal models. Finally, we review the multiple mechanisms that disrupt E-cadherin function in cancer: inactivating somatic and germline mutations, epigenetic silencing by DNA methylation and epithelial to mesenchymal transition-inducing transcription factors, and dysregulated protein processing.

E-cadherin inactivation in lobular carcinoma in situ of the breast: an early event in tumorigenesis

In breast cancer, inactivating point mutations in the E-cadherin gene are frequently found in invasive lobular carcinoma (ILC) but never in invasive ductal carcinoma (IDC). Lobular carcinoma in situ (LCIS) adjacent to ILC has previously been shown to lack E-cadherin expression, but whether LCIS without adjacent invasive carcinoma also lacks E-cadherin expression and whether the gene mutations present in ILC are already present in LCIS is not known. We report here that E-cadherin expression is absent in six cases of LCIS and present in 150 cases of ductal carcinoma in situ (DCIS), both without an adjacent invasive component. Furthermore, using mutation analysis, we could demonstrate the presence of the same truncating mutations and loss of heterozygosity (LOH) of the wild-type E-cadherin in the LCIS component and in the adjacent ILC. Our results indicate that E-cadherin is a very early target gene in lobular breast carcinogenesis and plays a tumour-suppressive role, additional to the previously suggested invasion-suppressive role.

The role of the ZEB family of transcription factors in development and disease

Abstract.The ZEB family of zinc finger transcription factors are essential players during normal embryonic development. One characteristic is that they induce epithelial to mesenchymal transition (EMT), a process that reorganizes epithelial cells to become migratory mesenchymal cells. E-cadherin is a major target gene of these transcriptional repressors, and this downregulation is considered a hallmark of EMT. In recent years, the involvement of the ZEB proteins in pathological contexts has been documented as well. Mutations in ZEB encoding genes cause severe syndromic malformations and evidence is mounting that links these factors to malignant tumor progression. In this review, we describe what is currently known on the molecular pathways these transcription factors are implicated in, and we highlight their roles in development and human diseases, with a focus on tumor malignancy.

The E-cadherin/Catenin Complex in Invasion and Metastasis

Cancer cells are genetically predisposed to contribute to the formation of a malignant tumor. As a population they do not respect tissue boundaries, but penetrate into the surrounding normal tissues. On their way to lymph or blood vessels they create a path of destruction. This invasive behavior eventually gives access to the circulation, and opens a gate to metastatic dissemination(Nicolson et al.; Fidler and Hart 1982; Mareel et al. 1993).

Regulation of vimentin by SIP1 in human epithelial breast tumor cells

The expression of Smad interacting protein-1 (SIP1; ZEB2) and the de novo expression of vimentin are frequently involved in epithelial-to-mesenchymal transitions (EMTs) under both normal and pathological conditions. In the present study, we investigated the potential role of SIP1 in the regulation of vimentin during the EMT associated with breast tumor cell migration and invasion. Examining several breast tumor cell lines displaying various degrees of invasiveness, we found SIP1 and vimentin expression only in invasive cell lines. Also, using a model of cell migration with human mammary MCF10A cells, we showed that SIP1 is induced specifically in vimentin-positive migratory cells. Furthermore, transfection of SIP1 cDNA in MCF10A cells increased their vimentin expression both at the mRNA and protein levels and enhanced their migratory abilities in Boyden Chamber assays. Inversely, inhibition of SIP1 expression by RNAi strategies in BT-549 cells and MCF10A cells decreased vimentin expression. We also showed that SIP1 transfection did not activate the TOP-FLASH reporter system, suggesting that the β-catenin/TCF pathway is not implicated in the regulation of vimentin by SIP1. Our results therefore implicate SIP1 in the regulation of vimentin observed in the EMT associated with breast tumor cell migration, a pathway that may contribute to the metastatic progression of breast cancer.

δ-Protocadherins: unique structures and functions

Abstract.δ-Protocadherins constitute a group of cadherins characterized by several conserved motifs in their cytoplasmic domains. We present a phylogenetic analysis that further divides this group into δ1-protocadherins (comprising protocadherin-1, −7, −9 and −11 or -X/Y) and δ2-protocadherins (comprising protocadherin-8, −10, −17, −18 and −19). The δ-protocadherin genes, which are located on different chromosomes in man and mouse, have a similar gene structure. They are expressed as multiple splice forms, differing mostly in their cytoplasmic domains. Some δ-protocadherins were reported to mediate weak cell-cell adhesion in vitro and cell sorting in vivo. In addition, individual δ-protocadherins might play important roles in signaling pathways, as they bind to proteins such as TAF1/Set, protein phosphatase-1α and the Frizzled 7 receptor. The spatiotemporally restricted expression of δ-protocadherins in different tissues and species and the results of their functional analysis, mainly in Xenopus, suggest that they play multiple, tightly regulated roles in vertebrate development.

Inflammatory breast cancer shows angiogenesis with high endothelial proliferation rate and strong E-cadherin expression

Inflammatory breast cancer (IBC) is the most aggressive form of breast cancer. Improved understanding of the mechanisms responsible for the differences between IBC and non-IBC might provide novel therapeutic targets. We studied 35 consecutive patients with IBC, biopsied prior to the initiation of chemotherapy. Angiogenesis was evaluated by Chalkley counting and by assessment of endothelial cell proliferation (ECP) and vessel maturity. The presence of fibrin, expression of the hypoxia marker carbonic anhydrase IX (CA IX) and epithelialcadherin (E-cadherin) expression were immunohistochemically detected. The same parameters were obtained in a group of 104 non-IBC patients. Vascular density, assessed by Chalkley counting (P<0.0001), and ECP (P=0.01) were significantly higher in IBC than in non-IBC. Abundant stromal fibrin deposition was observed in 26% of IBC and in only 8% of non-IBC (P=0.02). Expression of CA IX was significantly less frequent in IBC than in non-IBC with early metastasis (P=0.047). There was a significant positive correlation between the expression of CA IX and ECP in IBC (r=0.4, P=0.03), implying that the angiogenesis is partly hypoxia driven. However, the higher ECP in IBC and the less frequent expression of CA IX in IBC vs non-IBC points at a role for other factors than hypoxia in stimulating angiogenesis. Strong, homogeneous E-cadherin expression was found at cell–cell contacts in all but two IBC cases, both in lymphovascular tumour emboli and in infiltrating tumour cells, challenging our current understanding of the metastatic process. Both the intense angiogenesis and the strong E-cadherin expression may contribute to the highly metastatic phenotype of IBC.

δ-Protocadherins: a gene family expressed differentially in the mouse brain

Abstract.Phylogenetic analysis of protocadherin genes identified a new gene subfamily, the δ-protocadherins, containing several conserved motifs in their cytoplasmic domains. This subfamily can be further subdivided into two subgroups, named δ1-protocadherins (comprising protocadherin-1, -7, -9, and -11 or X/Y) and δ2-protocadherins (comprising protocadherin-8, -10, -17, -18, and -19). The members of the δ1-protocadherin subgroup were analyzed in greater detail here. They share a similar gene structure that results in the expression of multiple alternative transcripts. All members of this subgroup have at least one transcript that contains a binding site for protein phosphatase-1α. Like most classic cadherins, each of three δ1-protocadherins analyzed in this study by in situ hybridization showed a unique expression pattern that differed from the patterns of the other δ1-protocadherins. Together, these results suggest that the members of the δ1-protocadherin subgroup exercise tightly regulated functions in the development, regionalization, and functional differentiation of the mouse brain.