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Query: UNIPROT:P06889 (
Mol
)
630,302
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Microarray analyses combined with laser-capture microdissection have been applied for risk assessments of gastric cancer as well as for identification of novel genes associated with gastric cancer. EST AA393089 derived from an unknown gene has been reported to be frequently down-regulated in intestinal-type gastric cancer. Here, we identified and characterized the gene corresponding to EST AA393089 by using bioinformatics. EST AA393089 overlapped with BC016047 cDNA, and BC016047 overlapped with EST BM821052. Because the mRNA determined by assembling BM821052 and BC016047 was derived from a novel Claudin (CLDN) family gene, the gene corresponding to EST AA393089 was designated CLDN23. Human CLDN23 mRNA was expressed in germinal center B cells, placenta, stomach as well as in colon tumor. Mouse AK009330 and AK037108 cDNAs were derived from mouse Cldn23 gene. Human CLDN23 (292 aa) and mouse Cldn23 (296 aa) were four-transmembrane proteins, showing 79.5% total-amino-acid identity. WWCC motif, defined by W-X(17-22)-W-X(2)-C-X(8-10)-C, was conserved among four-transmembrane proteins of CLDN family. CLDN23 gene, linked to MFHAS1 and PPP1R3B genes, was mapped to human chromosome 8p23.1. CLDN21, CLDN22, and CLDN24 genes were also identified in this study. CLDN21 and CLDN22 genes were located within human genomic contig NT_022792.13. CLDN24 gene on human chromosome 11q23 was located within human genomic contig NT_033899.3. Among 23 CLDN family genes within the human genome, CLDN1 and CLDN16 genes were clustered on human chromosome 3q28, CLDN3 and CLDN4 on 7q11, CLDN6 and CLDN9 on 16p13.3, CLDN8 and
CLDN17
on 21q22.11, CLDN21 and CLDN22 on 4q35.1. This is the first report on comprehensive characterization of CLDN23 gene, a candidate tumor suppressor gene implicated in intestinal-type gastric cancer.
Int J
Mol
Med 2003 Jun
PMID:CLDN23 gene, frequently down-regulated in intestinal-type gastric cancer, is a novel member of CLAUDIN gene family. 1273 7
Barrier properties of tight junctions are determined by the claudin protein family. Many claudins seal this barrier, but others form paracellular channels. Among these, no claudins with general and clear-cut anion selectivity have yet been described, while for claudin-10a and claudin-4, only circumstantial or small anion selectivities have been shown. A claudin with unknown function and tissue distribution is
claudin-17
. We characterized
claudin-17
by overexpression and knock-down in two renal cell lines. Overexpression in MDCK C7 cell layers caused a threefold increase in paracellular anion permeability and switched these cells from cation- to anion-selective. Knockdown in LLC-PK(1) cells indorsed the finding of
claudin-17
-based anion channels. Mutagenesis revealed that
claudin-17
anion selectivity critically depends on a positive charge at position 65.
Claudin-17
expression was found in two organs: marginal in brain but abundant in kidney, where expression was intense in proximal tubules and gradually decreased towards distal segments. As
claudin-17
is predominantly expressed in proximal nephrons, which exhibit substantial, though molecularly not defined, paracellular chloride reabsorption, we suggest that
claudin-17
has a unique physiological function in this process. In conclusion,
claudin-17
forms channels within tight junctions with distinct anion preference.
Cell
Mol
Life Sci 2012 Aug
PMID:Claudin-17 forms tight junction channels with distinct anion selectivity. 2240 29
Claudin-17
is a paracellular channel-forming tight junction protein. Unlike the cation channels claudin-2 and -15,
claudin-17
forms a distinct anion-selective channel. Aim of this study was to determine the molecular basis of channel formation and charge selectivity of this protein. To achieve this, residues located in the extracellular loops (ECL) 1 and 2 of
claudin-17
were substituted, preferably those whose charges differed in
claudin-17
and in claudin-2 or -15. The respective mutants were stably expressed in MDCK C7 cells and their ability to form charge-selective channels was analyzed by measuring ion permeabilities and transepithelial electrical resistance. The functional data were combined with homology modeling of the
claudin-17
protomer using the structure of claudin-15 as template. In ECL1, K65, R31, E48, and E44 were found to be stronger involved in Cldn17 channel function than the clustered R45, R56, R59, and R61. For K65, not only charge but also stereochemical properties were crucial for formation of the anion-selective channel. In ECL2, both Y149 and H154 were found to contribute to constitution of the anion channel in a distinct manner. In conclusion, we provide insight into the molecular mechanism of the formation of charge- and size-selective paracellular ion channels. In detail, we propose a hydrophilic furrow in the
claudin-17
protomer spanning from a gap between the ends of TM2 and TM3 along R31, E48, and Y67 to a gap between K65 and S68 lining the anion channel.
Cell
Mol
Life Sci 2016 Jan
PMID:Molecular basis of claudin-17 anion selectivity. 2619 46
Trans-species polymorphism has been widely used as a key sign of long-term balancing selection across multiple species. However, such sites are often rare in the genome and could result from mutational processes or technical artifacts. Few methods are yet available to specifically detect footprints of trans-species balancing selection without using trans-species polymorphic sites. In this study, we develop summary- and model-based approaches that are each specifically tailored to uncover regions of long-term balancing selection shared by a set of species by using genomic patterns of intraspecific polymorphism and interspecific fixed differences. We demonstrate that our trans-species statistics have substantially higher power than single-species approaches to detect footprints of trans-species balancing selection, and are robust to those that do not affect all tested species. We further apply our model-based methods to human and chimpanzee whole-genome sequencing data. In addition to the previously established major histocompatibility complex and malaria resistance-associated FREM3/GYPE regions, we also find outstanding genomic regions involved in barrier integrity and innate immunity, such as the GRIK1/
CLDN17
intergenic region, and the SLC35F1 and ABCA13 genes. Our findings not only echo the significance of pathogen defense but also reveal novel candidates in maintaining balanced polymorphisms across human and chimpanzee lineages. Finally, we show that these trans-species statistics can be applied to and work well for an arbitrary number of species, and integrate them into open-source software packages for ease of use by the scientific community.
Mol
Biol Evol 2019 01 01
PMID:Detection of Shared Balancing Selection in the Absence of Trans-Species Polymorphism. 3038 Jan 22
