The signal transduction adapter protein Disabled-2 (Dab2) is one of the two mammalian orthologs of the Drosophila Disabled. The brain-specific Disabled-1 (Dab1) functions in positional organization of brain cells during development. Dab2 is widely distributed and is highly expressed in many epithelial cell types. The dab2 gene was interrupted by in-frame insertion of beta-galactosidase (LacZ) in embryonic stem cells and transgenic mice were produced. Dab2 expression was first observed in the primitive endoderm at E4.5, immediately following implantation. The homozygous Dab2-deficient mutant is embryonic lethal (earlier than E6.5) due to defective cell positioning and structure formation of the visceral endoderm. In E5.5 dab2 (-/-) conceptus, visceral endoderm-like cells are present in the deformed primitive egg cylinder; however, the visceral endoderm cells are not organized, the cells of the epiblast have not expanded, and the proamniotic cavity fails to form. Disorganization of the visceral endodermal layer is evident, as cells with positive visceral endoderm markers are scattered throughout the dab2 (-/-) conceptus. Only degenerated remains were observed at E6.5 for dab2 (-/-) embryos, and by E7.5, the defective embryos were completely reabsorbed. In blastocyst in vitro culture, initially cells with characteristics of endoderm, trophectoderm, and inner cell mass were observed in the outgrowth of the hatched dab2 (-/-) blastocysts. However, the dab2 (-/-) endodermal cells are much more dispersed and disorganized than those from wild-type blastocysts, the inner cell mass fails to expand, and the outgrowth degenerates by day 7. Thus, Dab2 is required for visceral endodermal cell organization during early mouse development. The absence of an organized visceral endoderm in Dab2-deficient conceptus leads to the growth failure of the inner cell mass. We suggest that Dab2 functions in a signal pathway to regulate endodermal cell organization using endocytosis of ligands from the blastocoel cavity as a positioning cue.
Mesoporous silica nanomaterial is one of the most promising candidates as drug carrier for cancer therapy. Herein, in vitro and in vivo study of silica nanorattle (SN) with mesoporous and rattle-type structure as a drug delivery system was first reported. Hydrophobic antitumor drug docetaxel (Dtxl) was loaded into the PEGylated silica nanorattle (SN-PEG) with a diameter of 125 nm via electrostatic absorption. In human liver cancer cell Hep-G2, the half-maximum inhibiting concentration (IC(50)) of silica nanorattle encapsulated docetaxel (SN-PEG-Dtxl) was only 7% of that of free Dtxl at 72 h. In vivo toxicity assessment showed that both nanocarrier of silica nanorattle (40 mg/kg, single dose) and SN-PEG-Dtxl (20 mg/kg of Dtxl, three doses) had low systematic toxicity in healthy ICR mice. The SN-PEG-Dtxl (20 mg/kg, intravenously) showed greater antitumor activity with about 15% enhanced tumor inhibition rate compared with Taxotere on the marine hepatocarcinoma 22 subcutaneous model. The results prove that the SN-PEG-Dtxl has low toxicity and high therapy efficacy, which provides convincing evidence for the silica nanorattle as a promising candidate for a drug delivery system.
In vivo recycling of nitrate (NO 3 − ) and nitrite (NO 2 − ) is an important alternative pathway for the generation of nitric oxide (NO) and maintenance of systemic nitrate–nitrite–NO balance. More than 25% of the circulating NO 3 − is actively removed and secreted by salivary glands. Oral commensal bacteria convert salivary NO 3 − to NO 2 − , which enters circulation and leads to NO generation. The transporters for NO 3 − in salivary glands have not yet been identified. Here we report that sialin ( SLC17A 5 ), mutations in which cause Salla disease and infantile sialic acid storage disorder (ISSD), functions as an electrogenic 2NO 3 − /H + cotransporter in the plasma membrane of salivary gland acinar cells. We have identified an extracellular pH-dependent anion current that is carried by NO 3 − or sialic acid (SA), but not by Br − , and is accompanied by intracellular acidification. Both responses were reduced by knockdown of sialin expression and increased by the plasma membrane-targeted sialin mutant (L22A-L23A). Fibroblasts from patients with ISSD displayed reduced SA- and NO 3 − -induced currents compared with healthy controls. Furthermore, expression of disease-associated sialin mutants in fibroblasts and salivary gland cells suppressed the H + -dependent NO 3 − conductance. Importantly, adenovirus-dependent expression of the sialinH183R mutant in vivo in pig salivary glands decreased NO 3 − secretion in saliva after intake of a NO 3 − -rich diet. Taken together, these data demonstrate that sialin mediates nitrate influx into salivary gland and other cell types. We suggest that the 2NO 3 − /H + transport function of sialin in salivary glands can contribute significantly to clearance of serum nitrate, as well as nitrate recycling and physiological nitrite-NO homeostasis.
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