Hirosato Mashima

Genetic variation in the gene encoding calpain-10 is associated with type 2 diabetes mellitus

Type 2 or non-insulin-dependent diabetes mellitus (NIDDM) is the most common form of diabetes worldwide, affecting approximately 4% of the worlds adult population. It is multifactorial in origin with both genetic and environmental factors contributing to its development. A genome-wide screen for type 2 diabetes genes carried out in Mexican Americans localized a susceptibility gene, designated NIDDM1, to chromosome 2. Here we describe the positional cloning of a gene located in the NIDDM1 region that shows association with type 2 diabetes in Mexican Americans and a Northern European population from the Botnia region of Finland. This putative diabetes-susceptibility gene encodes a ubiquitously expressed member of the calpain-like cysteine protease family, calpain-10 (CAPN10). This finding suggests a novel pathway that may contribute to the development of type 2 diabetes.

Betacellulin and activin A coordinately convert amylase-secreting pancreatic AR42J cells into insulin-secreting cells.

Rat pancreatic AR42J cells possess exocrine and neuroendocrine properties. Activin A induces morphological changes and converts them into neuron-like cells. In activin-treated cells, mRNA for pancreatic polypeptide (PP) but not that for either insulin or glucagon was detected by reverse transcription-PCR. About 25% of the cells were stained by anti-PP antibody. When AR42J cells were incubated with betacellulin, a small portion of the cells were stained positively with antiinsulin and anti-PP antibodies. The effect of betacellulin was dose dependent, being maximal at 2 nM. Approximately 4% of the cells became insulin positive at this concentration, and mRNAs for insulin and PP were detected. When AR42J cells were incubated with a combination of betacellulin and activin A, approximately 10% of the cells became insulin positive. Morphologically, the insulin-positive cells were composed of two types of cells: neuron-like and round-shaped cells. Immunoreactive PP was found in the latter type of cells. The mRNAs for insulin, PP, glucose transporter 2, and glucokinase, but not glucagon, were detected. Depolarizing concentration of potassium, tolbutamide, carbachol, and glucagon-like peptide-1 stimulated the release of immunoreactive insulin. These results indicate that betacellulin and activin A convert amylase-secreting AR42J cells into cells secreting insulin. AR42J cells provide a model system to study the formation of pancreatic endocrine cells.

Molecular cloning of a novel brain-type Na(+)-dependent inorganic phosphate cotransporter.

Abstract: We have isolated a human cDNA encoding a protein, designated DNPI, that shows 82% amino acid identity and 92% similarity to the human brain‐specific Na+‐dependent inorganic phosphate (Na+/Pi) cotransporter (BNPI), which is localized exclusively to neuron‐rich regions. Expression of DNPI mRNA in Xenopus oocytes resulted in a significant increase in Na+‐dependent Pi transport, indicating that DNPI is a novel Na+/Pi cotransporter. Northern blot analysis shows that DNPI mRNA is expressed predominantly in brain, where the highest levels are observed in medulla, substantia nigra, subthalamic nucleus, and thalamus, all of which express BNPI mRNA at low levels. In contrast, DNPI mRNA is expressed at low levels in cerebellum and hippocampus, where BNPI mRNA is expressed at high levels. No hybridizing signal for DNPI mRNA is observed in the glia‐rich region of corpus callosum. In other regions examined, both mRNAs are moderately or highly expressed. These results indicate that BNPI and DNPI, which coordinate Na+‐dependent Pi transport in the neuron‐rich regions of the brain, may form a new class within the Na+/Pi cotransporter family.

Derangements in the activin-follistatin system in hepatoma cells☆

BACKGROUND/AIMS The growth of normal hepatocytes is regulated by the activin-follistatin system. The aim of this study was to investigate the activin-follistatin system in hepatoma cells. METHODS The production and action of activin and follistatin in human hepatoma cell lines were examined. Activin A and follistatin were measured by bioassay and protein-binding assay, respectively. RESULTS Activin A inhibited cell growth in HepG2 cells but not in either PLC/PRF/5 or HLE cells. However, the effect of activin A in HepG2 cells was attenuated at high cell density. In HepG2 cells, two classes of activin-binding sites were expressed, and affinity cross-linking showed that 125I-activin A bound specifically to three proteins with molecular weights of 48, 67, and 94 kilodaltons. In PLC/PRF/5 cells, a single class of binding site was observed, and the binding capacity was approximately 60% of the capacity in HepG2 cells. Virtually no 125I-activin A binding was detected in HLE cells. Bioactivity and messenger RNA for activin A were undetectable in three cell lines. In contrast, follistatin was released from three cell lines. CONCLUSIONS Multiple alterations in the activin-follistatin system were found in three hepatoma cell lines. The accelerated growth observed in hepatoma cells may be caused, at least partly, by the attenuation of the action of activin A.

Production of activin A in human intestinal epithelial cell line.

Production of activin was studied in four cell lines of epithelial cells: FRTL-5, JCT-12, GH4C1, and FHs74Int cells. Bioactivity of activin was detected in conditioned media of FRTL-5, JCT-12, and FHs74Int cells. Among these three cell lines, FHs74Int cells, which were derived from human embryonic intestine, released a relatively large amount of bioactive activin. In these cells, serum and epidermal growth factor (EGF), which were capable of stimulating DNA synthesis, augmented release of bioactive activin in middle to late G1 phase. In addition, basic FGF (bFGF), which had no effect on DNA synthesis in these cells, also increased release of activin. In bFGF-treated FHs74Int cells, bioactive activin was released within 4 hr of the addition of bFGF. The reverse-transcription polymerase chain reaction reveals that mRNA for only the βA subunit of activin is expressed in these cells. Immunoblotting of lysate from serum-treated cells using anti-human activin A antibody indicated the existence of a 12.5-kDa protein under a reducing condition. FHs74Int cells did not express binding site for [125I]activin A and exogenous activin A did not affect DNA synthesis in these cells. These results indicate that FHs74Int cells derived from human embryonic intestine synthesize and release activin A. Activin A released from intestinal epithelial cells might be a modulatory factor in cells in intestinal mucosa.