Several genes encoding proteins critical to the neuronal phenotype, such as the brain type II sodium channel gene, are expressed to high levels only in neurons. This cell specificity is due, in part, to long-term repression in nonneural cells mediated by the repressor protein REST͞NRSF (RE1 silencing transcription factor͞neural-restrictive silencing factor). We show here that CoREST, a newly identified human protein, functions as a corepressor for REST. A single zinc finger motif in REST is required for A large number of genes encoding neuronal phenotypic traits, including ion channels, neurotransmitters, synaptic proteins, and cell-adhesion molecules, are expressed only in neurons. One mechanism important in establishing and maintaining this neural specificity involves the DNA-binding protein REST͞ NRSF (RE1 silencing transcription factor͞neural-restrictive silencing factor) (1-4), which serves to block expression of its target genes in nonneural tissues. Such maintained gene repression is in contrast to the more dynamic repression mechanism that regulates inducible gene expression in response to steroid hormone receptors, one of the best-studied mammalian repressor mechanisms (for review, see ref. 5).One REST target gene essential for neuronal physiology is that encoding the brain type II voltage-dependent sodium channel. This ion channel is required for the propagation of fast electrical signals in neurons, in the form of neuronal impulses, and is not expressed in nonneural tissues. As is true for other REST target genes, there is a reciprocal relationship between expression of the type II sodium channel gene and expression of REST. Additionally, when a REST expression plasmid is cotransfected into neuronal cells along with a type II sodium channel reporter, the expression of the reporter gene is reduced dramatically (1). This result indicates either that REST alone is sufficient to repress its target genes or that REST accessory factors are present in neuronal cells despite the absence of REST.Two distinct repressor domains have been identified and characterized in REST (6, 7). These domains are located in the amino and carboxyl termini of the protein. Both domains are required for full repression in the context of the intact molecule, but each domain is sufficient to repress type II sodium channel reporter genes when expressed as a Gal4 fusion protein (6). The C-terminal repressor domain contains a C 2 H 2 class zinc finger beginning approximately 40 aa upstream of the stop codon. Deleting this domain, or introducing a point mutation critical to the zinc finger motif, abolishes repressor activity (6). Because zinc finger motifs often mediate proteinprotein interactions, we proposed that REST might function in conjunction with other nuclear factors or corepressors.In this study, we find that repression of the type II sodium channel promoter by REST requires a newly identified protein, CoREST, which fulfills the criteria for a bona fide corepressor. CoREST is a repressor; mutations that disrupt CoREST...
The type II voltage-dependent sodium channel is present in neuronal cells, where it mediates the propagation of nerve impulses. Restricted expression of the type II sodium channel gene to neurons is due, at least in part, to binding of the repressor protein REST (also termed NRSF or XBR) to the RE1 (also called NRSE) sequence in the type II sodium channel gene. Previous studies have shown that a domain in REST containing eight GL1-Krüppel zinc finger motifs mediates DNA binding. Deletional and GAL4-fusion gene analyses now reveal repressor domains that lie outside of the DNA-binding domain in both the amino and carboxyl termini of REST. Mutational analysis further identifies a single zinc finger motif in the carboxyl-terminal domain as being essential for repressing type II sodium channel reporter genes. These studies reveal two domains in REST that may mediate interactions with other proteins involved in restricting expression of a large set of genes to the vertebrate nervous system.The ability to generate action potentials is often due to the presence of voltage-dependent sodium channels in the plasma membranes of the excitable cells. Sodium channels are encoded by a large multigene family, and members of this family are structurally distinct and expressed in a tissue-specific manner (reviewed in ref. 1). The type II sodium channel gene (2, 3) is expressed to high levels exclusively in neurons in the central nervous system (4, 5). Because of this selective expression pattern, the type II sodium channel has provided an excellent model for studies of the mechanisms regulating neural-specific gene expression.Type II sodium channel reporter genes containing 1050 bp of 5Ј flanking sequence are expressed in neuronal cell lines but not in nonneuronal cells, consistent with expression of the endogenous gene. Deletional analysis has identified a 23-bp element in the type II sodium channel regulatory region, termed repressor element 1 (RE1), that prevents expression of type II reporter genes in nonneuronal cell types (6, 7). Removal of the RE1 results in approximately 80-fold derepression of the type II sodium channel reporter gene specifically in nonneuronal cell types. Repressor elements with sequences and functional properties similar to those of the type II sodium channel RE1 are present in the regulatory region of several other genes expressed exclusively in the nervous system (reviewed in ref. 8), including SCG10 (9, 10), synapsin (11), the 1 subunit of the nicotinic acetylcholine receptor (12), the muscarinc M4 receptor (13,14), and neural-glial cell adhesion molecule (15). The widespread occurrence of RE1-like sequences in different genes suggests a more global role of repression in restricting gene expression to the nervous system. Recombinant RE1-silencing transcription factor (REST) is sufficient to repress reporter genes containing RE1-like target sequences in cotransfection analyses of neuronal cells (8,16,17). The deduced primary structure of REST does not reveal any amino acid homologies which wo...
In spite of all the fascinating properties of oral creatine supplementation, the mechanism(s) mediating its intestinal absorption has(have) not been investigated. The purpose of this study was to characterize intestinal creatine transport. [14C]Creatine uptake was measured in chicken enterocytes and rat ileum, and expression of the creatine transporter CRT was examined in human, rat and chicken small intestine by reverse transcription‐polymerase chain reaction, Northern blot, in situ hybridization, immunoblotting and immunohistochemistry. Results show that enterocytes accumulate creatine against its concentration gradient. This accumulation was electrogenic, Na+‐ and Cl−‐dependent, with a probable stoichiometry of 2 Na+: 1 Cl−: 1 creatine, and inhibited by ouabain and iodoacetic acid. The kinetic study revealed a Km for creatine of 29 μm. [14C]Creatine uptake was efficiently antagonized by non‐labelled creatine, guanidinopropionic acid and cyclocreatine. More distant structural analogues of creatine, such as GABA, choline, glycine, β‐alanine, taurine and betaine, had no effect on intestinal creatine uptake, indicating a high substrate specificity of the creatine transporter. Consistent with these functional data, messenger RNA for CRT was detected only in the cells lining the intestinal villus. The sequences of partial clones, and of the full‐length cDNA clone, isolated from human and rat small intestine were identical to previously cloned CRT cDNAs. Immunological analysis revealed that CRT protein was mainly associated with the apical membrane of the enterocytes. This study reports for the first time that mammalian and avian enterocytes express CRT along the villus, where it mediates high‐affinity, Na+‐ and Cl−‐dependent, apical creatine uptake.
Expression of reelin, reelin receptors [apolipoprotein E receptor 2 (ApoER2) and very low density lipoprotein receptor (VldlR)] and the Disabled-1 (Dab1) protein was investigated in rat intestinal mucosa. Intestinal reelin and Dab1 mRNA levels were maximal in the early stages of life, reaching adult levels in 1-month-old rats. Expression of reelin mRNA was restricted to fibroblasts, whereas mRNAs of Dab1, ApoER2, VldlR and integrins α3 and β1 were observed in enterocytes, crypts and fibroblasts. Reelin protein was only observed in isolated intestinal fibroblasts and in a cell layer subjacent to the villus epithelium, which seems to be composed of myofibroblasts because it also reacted to α-smooth muscle actin. The Disabled-1 and VldlR protein signals were detected in the crypt and villus cells, and they were particularly abundant in the terminal web domain of the enterocytes. The ApoER2 protein signal was detected in the upper half of the villi but not in the crypts. This is the first report showing that rat intestinal mucosa expresses the reelin-Disabled-1 signalling system.
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