Transcriptional downregulation of E-cadherin appears to be an important event in the progression of various epithelial tumors. SIP1 (ZEB-2) is a Smad-interacting, multi-zinc finger protein that shows specific DNA binding activity. Here, we report that expression of wild-type but not of mutated SIP1 downregulates mammalian E-cadherin transcription via binding to both conserved E2 boxes of the minimal E-cadherin promoter. SIP1 and Snail bind to partly overlapping promoter sequences and showed similar silencing effects. SIP1 can be induced by TGF-beta treatment and shows high expression in several E-cadherin-negative human carcinoma cell lines. Conditional expression of SIP1 in E-cadherin-positive MDCK cells abrogates E-cadherin-mediated intercellular adhesion and simultaneously induces invasion. SIP1 therefore appears to be a promoter of invasion in malignant epithelial tumors.
Mutations in the homologous presenilin 1 (PS1) and presenilin 2 (PS2) genes cause the most common and aggressive form of familial Alzheimer's disease. Although PS1 function and dysfunction have been extensively studied, little is known about the function of PS2 in vivo. To delineate the relationships of PS2 and PS1 activities and whether PS2 mutations involve gain or loss of function, we generated PS2 homozygous deficient (؊͞؊) and PS1͞PS2 double homozygous deficient mice. In contrast to PS1 ؊͞؊ mice, PS2 ؊͞؊ mice are viable and fertile and develop only mild pulmonary fibrosis and hemorrhage with age. Absence of PS2 does not detectably alter processing of amyloid precursor protein and has little or no effect on physiologically important apoptotic processes, indicating that Alzheimer's disease-causing mutations in PS2, as in PS1, result in gain of function. Although PS1 ؉͞؊ PS2 ؊͞؊ mice survive in relatively good health, complete deletion of both PS2 and PS1 genes causes a phenotype closely resembling full Notch-1 deficiency. These results demonstrate in vivo that PS1 and PS2 have partially overlapping functions and that PS1 is essential and PS2 is redundant for normal Notch signaling during mammalian embryological development.
Activation of transforming growth factor  receptors causes the phosphorylation and nuclear translocation of Smad proteins, which then participate in the regulation of expression of target genes. We describe a novel Smad-interacting protein, SIP1, which was identified using the yeast two-hybrid system. Although SIP1 interacts with the MH2 domain of receptor-regulated Smads in yeast and in vitro, its interaction with full-length Smads in mammalian cells requires receptor-mediated Smad activation. SIP1 is a new member of the ␦EF1/ Zfh-1 family of two-handed zinc finger/homeodomain proteins. Like ␦EF1, SIP1 binds to 5-CACCT sequences in different promoters, including the Xenopus brachyury promoter. Overexpression of either full-length SIP1 or its C-terminal zinc finger cluster, which bind to the Xbra2 promoter in vitro, prevented expression of the endogenous Xbra gene in early Xenopus embryos. Therefore, SIP1, like ␦EF1, is likely to be a transcriptional repressor, which may be involved in the regulation of at least one immediate response gene for activin-dependent signal transduction pathways. The identification of this Smad-interacting protein opens new routes to investigate the mechanisms by which transforming growth factor  members exert their effects on expression of target genes in responsive cells and in the vertebrate embryo.Ligands of the TGF- 1 family exert their biological effects by activating serine/threonine kinase receptor complexes, which in turn activate intracellular mediators, the Smad proteins. Smads were initially identified by means of genetic studies in Drosophila and Caenorhabditis elegans as Mad and Sma gene products, respectively. Nine different vertebrate Smads have been isolated (reviewed in Refs. 1-3; Ref. 4). These proteins are characterized by a three-domain structure containing conserved N-terminal and C-terminal domains, called the MH1 and MH2 domains, which flank a more variable, proline-rich linker region. The Smads can be classified into three subgroups based on their distinct functions. The receptor-regulated Smads (Smad1, 2, 3, 5, and 8) contain a conserved SSXS motif at their extreme C-terminal end. Upon ligand stimulation, two serines in this motif are directly phosphorylated by specific type I receptors. Once activated, these Smads associate with Smad4, a common mediator Smad, and the heteromeric complexes translocate to the nucleus where they mediate responses to specific ligands. Smads 1, 5, and 8 act in bone morphogenetic protein (BMP) pathways, whereas Smads 2 and 3 act in activin and TGF- pathways. A third group of Smads, the inhibitory Smads (Smad6 and Smad7), prevent the activation of receptorregulated Smads or their heteromerization with Smad4. Functional homologues of inhibitory Smads and the common mediator Smad in Drosophila have been identified as Dad and Medea, respectively (1-3).In the absence of signaling, Smads are kept in a latent conformation through an intramolecular interaction between the MH1 and MH2 domains. Activation of receptor-regulated Smads has...
The epidermis is a stratified squamous epithelium in which keratinocytes progressively undergo terminal differentiation towards the skin surface leading to programmed cell death. In this respect we studied the role of caspases. Here, we show that caspase-14 synthesis in the skin is restricted to differentiating keratinocytes and that caspase-14 processing is associated with terminal epidermal differentiation. The proapoptotic executioner caspases-3, -6, and -7 are not activated during epidermal differentiation. Caspase-14 does not participate in apoptotic pathways elicited by treatment of differentiated keratinocytes with various death-inducing stimuli, in contrast to caspase-3. In addition, we show that non-cornifying oral keratinocyte epithelium does not express caspase-14 and that the parakeratotic regions of psoriatic skin lesions contain very low levels of caspase-14 as compared to normal stratum corneum. These observations strongly suggest that caspase-14 is involved in the keratinocyte terminal differentiation program leading to normal skin cornification, while the executioner caspases are not
Abstract. Proteins in the TGF-[~ superfamily transduce their effects through binding to type I and type II serine/threonine kinase receptors. Osteogenic protein-1 (OP-1, also known as bone morphogenetic protein-7 or BMP-7), a member of the TGF-[3 superfamily which belongs to the BMP subfamily, was found to bind activin receptor type I (ActR-I), and BMP receptors type IA (BMPR-IA) and type IB (BMPR-IB) in the presence of activin receptors type II (ActR-II) and type liB (ActR-IIB). The binding affinity of OP-1 to ActR-II was two-to threefold lower than that of activin A. A transcriptional activation signal was transduced after binding of OP-1 to the complex of ActR-I and ActR-II, or that of BMPR-IB and ActR-II. These results indicate that ActR-II can act as a functional type II receptor for OP-1, as well as for activins. Some of the known biological effects of activin were observed for OP-1, including growth inhibition and erythroid differentiation induction. Compared to activin, OP-1 was shown to be a poor inducer of mesoderm in Xenopus embryos.Moreover, follistatin, an inhibitor of activins, was found to inhibit the effects of OP-1, if added at a 10-fold excess. However, certain effects of activin, like induction of follicle stimulating hormone secretion in rat pituitary cells were not observed for OP-1. OP-1 has overlapping binding specificities with activins, and shares certain but not all of the functional effects of activins. Thus, OP-1 may have broader effects in vivo than hitherto recognized.
Recently, mutations in ZFHX1B, the gene that encodes Smad-interacting protein-1 (SIP1), were found to be implicated in the etiology of a dominant form of Hirschsprung disease-mental retardation syndrome in humans. To clarify the molecular mechanisms underlying the clinical features of SIP1 deficiency, we generated mice that bear a mutation comparable to those found in several human patients. Here, we show that Zfhx1b-knockout mice do not develop postotic vagal neural crest cells, the precursors of the enteric nervous system that is affected in patients with Hirschsprung disease, and they display a delamination arrest of cranial neural crest cells, which form the skeletomuscular elements of the vertebrate head. This suggests that Sip1 is essential for the development of vagal neural crest precursors and the migratory behavior of cranial neural crest in the mouse. Furthermore, we show that Sip1 is involved in the specification of neuroepithelium.
The fate of cortical progenitors, which progressively generate neurons and glial cells during development, is determined by temporally and spatially regulated signaling mechanisms. We found that the transcription factor Sip1 (Zfhx1b), which is produced at high levels in postmitotic neocortical neurons, regulates progenitor fate non-cell autonomously. Conditional deletion of Sip1 in young neurons induced premature production of upper-layer neurons at the expense of deep layers, precocious and increased generation of glial precursors, and enhanced postnatal astrocytogenesis. The premature upper-layer generation coincided with overexpression of the neurotrophin-3 (Ntf3) gene and upregulation of fibroblast growth factor 9 (Fgf9) gene expression preceded precocious gliogenesis. Exogenous application of Fgf9 to mouse cortical slices induced excessive generation of glial precursors in the germinal zone. Our data suggest that Sip1 restrains the production of signaling factors in postmitotic neurons that feed back to progenitors to regulate the timing of cell fate switch and the number of neurons and glial cells throughout corticogenesis.
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