Syndecan-1 is required for Wnt-1-induced mammary tumorigenesis in mice.

Syndecan-1 is a cell-surface, heparan-sulphate proteoglycan (HSPG) predominantly expressed by epithelial cells. It binds specifically to many proteins, including oncoproteins. For example, it induces the assembly of a signalling complex between FGF ligands and their cognate receptors. But so far there has been no direct evidence that this proteoglycan contributes to tumorigenesis. Here we have examined the role of syndecan-1 (encoded by Sdc1) during mammary tumour formation in response to the ectopic expression of the proto-oncogene Wnt1. We crossed syndecan-1-deficient mice with transgenic mice that express Wnt1 in mammary gland (TgN(Wnt-1)1Hev; ref. 2). Ectopic Wnt-1 expression induces generalized mammary hyperplasia, followed by the development of solitary tumours (median time 22 weeks). We show that in Sdc1-/- mice, Wnt-1-induced hyperplasia in virgin mammary gland was reduced by 70%, indicating that the Wnt-1 signalling pathway was inhibited. Of the 39 tumours that developed in a test cohort of mice, only 1 evolved in the Sdc1-/- background. In addition, we show that soluble syndecan-1 ectodomain purified from mouse mammary epithelial cells stimulates the activity of a Wnt-1 homologue in a tissue culture assay. Our results provide both genetic and biochemical evidence that syndecan-1 can modulate Wnt signalling, and is critical for Wnt-1-induced tumorigenesis of the mouse mammary gland.

Transcriptional activation of the syndecan-1 promoter by the Wilms' tumor protein WT1.

The Wilms' tumor suppressor gene (wt1) encodes a zinc finger DNA binding protein (WT1) which functions as a transcriptional regulator and is essential for normal urogenital development. WTI has previously been shown to repress the transcription of a variety of target genes whose products stimulate growth, such as growth factors, growth factor receptors and other transcription factors. In this study, we identify syndecan-1 as a target gene for WT1-mediated activation. Syndecan-1 is a cell surface proteoglycan whose induction is coincident with epithelial differentiation during kidney development and whose loss of expression is correlated with the loss of the epithelial phenotype and malignant transformation. The murine syndecan-1 promoter contains several potential binding sites for WT1. We demonstrate that both WT1 (-KTS) and WT1 (+KTS) isoforms bind to multiple sites in this highly G + C-rich region, as detected by gel-shift analyses. These WT1 isoforms function as transcriptional activators of syndecan-1 expression in transient transfection assays. Activation of syndecan-1 by WT1 is dependent on an intact zinc-finger region as well as a 179 amino acid proline-rich region in the amino terminus of the protein. Moreover, the endogenous syndecan-1 gene is activated by WT1 in a novel inducible cell line based upon the sheep metallothionein promoter. These results highlight an emerging role for WT1 as an activator of genes like syndecan-1 which may potentiate epithelial differentiation and maintenance in the developing kidney.

Syndecan-1, a cell-surface proteoglycan, changes in size and abundance when keratinocytes stratify.

In epidermis, keratinocytes in the basal cell layer differentiate, lose their attachment to the underlying extracellular matrix, and form extensive intercellular adhesions as they stratify. The alterations in cell-matrix and cell-cell adhesion required for keratinocyte stratification result from changes in the expression of numerous adhesion molecules. Syndecan-1, a member of a family of cell-surface proteoglycans, is known to bind cells to interstitial matrix. Syndecan-1 localizes to specific layers of mouse epidermal keratinocytes; its expression is modest in the basal layer, heavy in the suprabasal layers, but absent from the most superficial, terminally differentiated layers. This layer-specific difference suggests that syndecan-1 expression changes with keratinocyte differentiation. To assess this hypothesis, syndecan-1 expression was evaluated before and after calcium-induced stratification and differentiation. Cells growing as an unstratified monolayer express a higher molecular mass form of syndecan-1 than do stratified cells (modal relative mass of 160 kD versus 110 kD). This structural difference is due to larger and more heparan sulfate chains on syndecan-1 from monolayer cells. In addition, the amount of cell-surface syndecan-1 changes with stratification; stratified cultures show approximately 2.5 times more syndecan-1 per cell than do unstratified cultures, but do not significantly change the level of syndecan-1-specific mRNA. Thus, the structure and amount of syndecan-1 may be regulated to meet the changing adhesive requirements of stratifying keratinocytes.

Developmental expression of the syndecans: possible function and regulation.

Recent work has made clear that heparan sulfate at the cell surface is essential for a wide variety of interactions of cells with their microenvironment, including the action of growth factors, extracellular matrix, proteases and protease inhibitors. A major source of this cell surface heparan sulfate is a multigene family of proteoglycans, the syndecans, that are expressed developmentally in association with changes in tissue organization and morphology and induced during wound repair. In this review, we describe mechanisms underlying the differential expression of the syndecans, focusing on syndecan-1. The induction of syndecan-1 can result from soluble extracellular factor(s) acting at multiple levels of cellular regulation. At the transcriptional level, the promoter of the murine syndecan-1 gene contains potential recognition sites for several well-known regulatory genes, including Hox and MyoD family members. Because changes in syndecan expression enable cells to become more or less responsive to their microenvironment, understanding these regulatory mechanisms can lead to an improved understanding of how cellular behavior is controlled during development and wound repair.

Organization and promoter activity of the mouse syndecan-1 gene.

Syndecan-1, the prototype of a family of heparan sulfate-containing integral membrane proteoglycans, associates extracellularly with a variety of matrix molecules and growth factors and intracellularly with the actin cytoskeleton. Expressed constitutively on epithelia in mature tissues and in a developmentally regulated manner on epithelial and induced mesenchymal cells during embryogenesis, syndecan-1 appears to be involved in controlling the shape and organization of cells and tissues. To better understand the function and regulation of syndecan-1, we determined the structure of the mouse syndecan-1 gene (Synd-1). Synd-1 is approximately 19.5 kilobases in size and is organized into five exons that appear conserved in other family members. Exon 1 encodes the signal peptide; exon 2, the N-terminal glycosaminoglycan attachment region; exon 3, the bulk of the extracellular domain; exon 4, the protease-susceptible site; and exon 5, the transmembrane and cytoplasmic domains which are highly homologous between syndecan family members. Synd-1 has three transcriptional start sites, two polyadenylation sites, and is not alternatively spliced to produce its 2.6- and 3.4-kilobase mRNA species. Upstream sequences have promoter activity and contain TATA and CAAT boxes as well as a variety of other potential binding sites for transcription factors, including Sp1 (GC box), NF-kappa B, MyoD (E box), and Antennapedia. The structure of the promoter region suggests that control of Synd-1 expression is both constitutive and developmentally regulated. Because Synd-1 exons encode discrete functional domains of the syndecan-1 protein that are conserved throughout the syndecan family, all syndecan genes are likely derived from a common ancestor.

Exploitation of syndecan-1 shedding by Pseudomonas aeruginosa enhances virulence.

Cell-surface heparan sulphate proteoglycans (HSPGs) are ubiquitous and abundant receptors/co-receptors of extracellular ligands, including many microbes. Their role in microbial infections is poorly defined, however, because no cell-surface HSPG has been clearly connected to the pathogenesis of a particular microbe. We have previously shown that Pseudomonas aeruginosa, through its virulence factor LasA, enhances the in vitro shedding of syndecan-1-the predominant cell-surface HSPG of epithelia. Here we show that shedding of syndecan-1 is also activated by P. aeruginosa in vivo, and that the resulting syndecan-1 ectodomains enhance bacterial virulence in newborn mice. Newborn mice deficient in syndecan-1 resist P. aeruginosa lung infection but become susceptible when given purified syndecan-1 ectodomains or heparin, but not when given ectodomain core protein, indicating that the ectodomain's heparan sulphate chains are the effectors. In wild-type newborn mice, inhibition of syndecan-1 shedding or inactivation of the shed ectodomain's heparan sulphate chains prevents lung infection. Our findings uncover a pathogenetic mechanism in which a host response to tissue injury-syndecan-1 shedding-is exploited to enhance microbial virulence apparently by modulating host defences.

Transgenic expression of syndecan-1 uncovers a physiological control of feeding behavior by syndecan-3.

Transgenic expression in the hypothalamus of syndecan-1, a cell surface heparan sulfate proteoglycan (HSPG) and modulator of ligand-receptor encounters, produces mice with hyperphagia and maturity-onset obesity resembling mice with reduced action of alpha melanocyte stimulating hormone (alphaMSH). Via their HS chains, syndecans potentiate the action of agouti-related protein and agouti signaling protein, endogenous inhibitors of alphaMSH. In wild-type mice, syndecan-3, the predominantly neural syndecan, is expressed in hypothalamic regions that control energy balance. Food deprivation increases hypothalamic syndecan-3 levels several-fold. Syndecan-3 null mice, otherwise apparently normal, respond to food deprivation with markedly reduced reflex hyperphagia. We propose that oscillation of hypothalamic syndecan-3 levels physiologically modulates feeding behavior.