Comparison of the Allergenic Potency of House Dust Extract and House Dust Mite Allergen Extract for Subcutaneous Allergen Immunotherapy.

Subcutaneous allergen immunotherapy (SCIT) with non-standardized house dust (HD) extracts has been used in Japan since 1963 for house dust mite (HDM)-allergic patients. Since the potencies of HD extracts are unknown, the allergenic potency of HD extracts was examined by comparing with a standardized HDM allergen extracts. The major allergen content of HDM in the extracts was measured using a sandwich enzyme-linked immunosorbent assay (ELISA). The immunoglobulin E (IgE) inhibitory activities of the extracts were measured by a competitive ELISA. The extract concentrations giving 50% inhibition of IgE binding (log10 IC50) were determined from dose-response curves and defined as inhibitory activities. A linear regression line was constructed from the log10 IC50 values of the standardized HDM extract to interpolate the relative potency of the HD extract with strength of 1 : 10 w/v (HD 1 : 10). The amounts of major allergens (Der f 1, Der p 1 and Der 2) were 116.3 µg/mL in the HDM allergen extract (100000 Japanese Allergy Units [JAU]/mL) and 0.77 µg/mL in the HD 1 : 10. The inhibitory activity (log10 IC50 values) of HD 1 : 10 was 2.389 ± 0.078, indicating the allergenic potency was between 200 and 2000 JAU/mL. Based on regression analysis (R2 >0.99), the allergenic potency of HD 1 : 10 was estimated to be 842 ± 128 JAU/mL. The present study determined the major allergen content of HD extract, which contributes to its allergenic potency. The allergenic potency of HD 1 : 10 was ca. 100-fold less than that of HDM allergen extract.

A selective small molecule glucagon-like peptide-1 secretagogue acting via depolarization-coupled Ca(2+) influx.

Glucagon-like peptide-1 (GLP-1) is an incretin hormone that potentiates insulin secretion in a glucose-dependent manner. Selective GLP-1 secretagogue would be one of the potential therapeutic targets for type 2 diabetes. Here, we describe a newly identified small molecule compound (compound A) that stimulates secretion of GLP-1 in murine enteroendocrine cell lines, STC-1 and GLUTag cells, and in primary cultured fetal rat intestinal cells (FRIC). The underlying mechanism by which compound A stimulated GLP-1 secretion was also examined. Compound A stimulated GLP-1 secretion from STC-1 cells in a concentration-dependent manner, and also from GLUTag cells and FRIC. The action of compound A was selective against other tested endocrine functions such as secretion of insulin from rat islets, growth hormone from rat pituitary gland cells, and norepinephrine from rat PC-12 cells. In STC-1 cells, the compound A-stimulated GLP-1 secretion was neither due to cyclic AMP production nor to Ca(2+) release from intracellular stores, but to extracellular Ca(2+) influx. The response was inhibited by the presence of either L-type Ca(2+) channel blockers or K(+) ionophore. Perforated-patch clamp study revealed that compound A induces membrane depolarization. These results suggest that neither Galphas- nor Galphaq-coupled signaling account for the mechanism of action, but depolarization-coupled Ca(2+) influx from extracellular space is the primary cause for the GLP-1 secretion stimulated by compound A. Identifying a specific target molecule for compound A will reveal a selective regulatory pathway that leads to depolarization-mediated GLP-1 secretion.

Hepatic de novo lipogenesis is present in liver-specific ACC1-deficient mice.

Acetyl coenzyme A (acetyl-CoA) carboxylase (ACC) catalyzes carboxylation of acetyl-CoA to form malonyl-CoA. In mammals, two isozymes exist with distinct physiological roles: cytosolic ACC1 participates in de novo lipogenesis (DNL), and mitochondrial ACC2 is involved in negative regulation of mitochondrial beta-oxidation. Since systemic ACC1 null mice were embryonic lethal, to clarify the physiological role of ACC1 in hepatic DNL, we generated the liver-specific ACC1 null mouse by crossbreeding of an Acc1(lox(ex46)) mouse, in which exon 46 of Acc1 was flanked by two loxP sequences and the liver-specific Cre transgenic mouse. In liver-specific ACC1 null mice, neither hepatic Acc1 mRNA nor protein was detected. However, to compensate for ACC1 function, hepatic ACC2 protein and activity were induced 1.4 and 2.2 times, respectively. Surprisingly, hepatic DNL and malonyl-CoA were maintained at the same physiological levels as in wild-type mice. Furthermore, hepatic DNL was completely inhibited by an ACC1/2 dual inhibitor, 5-tetradecyloxyl-2-furancarboxylic acid. These results strongly demonstrate that malonyl-CoA from ACC2 can access fatty acid synthase and become the substrate for the DNL pathway under the unphysiological circumstances that result with ACC1 disruption. Therefore, there does not appear to be strict compartmentalization of malonyl-CoA from either of the ACC isozymes in the liver.