Degranulation of RBL-2H3 rat basophilic leukemia cells is synergistically inhibited by combined treatment with nobiletin and lactoferrin.

The aim of this study was to elucidate the anti-allergic effects of polymethoxyflavonoids in combination with milk proteins and the mechanism of inhibition. Three polymethoxyflavonoids and two milk proteins were exposed to the rat basophilic leukemia cell line RBL-2H3. ß-hexosaminidase was used as an indicator of degranulation inhibition. The mechanism of inhibition was examined by measuring intracellular Ca2+ levels and western blot method. In the degranulation inhibition test with polymethoxyflavonoids and milk proteins alone, nobiletin was the strongest inhibitor in the polymethoxyflavonoid group and lactoferrin in the milk protein group. Next, co-stimulation with nobiletin and lactoferrin showed stronger synergistic degranulation inhibition than treatment with nobiletin or lactoferrin alone. Western blot analysis showed that co-stimulation with nobiletin and lactoferrin significantly downregulated the induction of phospholipase Cγ 1 phosphorylation. The degranulation response in RBL-2H3 cells was synergistically suppressed by co-stimulation of nobiletin and lactoferrin acting on both Ca2+-dependent and Ca2+-independent pathways.

Canna Starch Improves Intestinal Barrier Function, Inhibits Allergen Uptake, and Suppresses Anaphylactic Symptoms in Ovalbumin-Induced Food Allergy in Mice.

Edible canna rhizomes contain extremely high levels of resistant starch among cereals and potatoes. We previously showed that feeding canna rhizome starch to mice may increase intestinal barrier function and improve the intestinal environment. Here, we investigated the effects of canna starch intake in a murine food allergy model. Five-week-old female BALB/c mice were divided into four groups: Control and OVA groups fed on the control diet (AIN-93G) ad libitum and Canna and OVA-Canna groups fed on the canna diet (AIN-93G with 10% replaced with canna starch). The OVA and OVA-Canna groups were sensitized to ovalbumin (OVA), and the anaphylactic response was assessed by measuring body temperature. Body temperature was significantly lower in the OVA group than in the non-sensitized group, but no decrease was observed in the OVA-Canna group. Fecal weight, fecal mucin content, and goblet cells of colorectal tissue were significantly increased in the Canna and OVA-Canna groups compared with those in the Control and OVA groups. Allergen uptake into the liver was also increased in the OVA group and decreased in the OVA-Canna group to the same level as in the non-sensitized group. These results indicate that canna starch supplementation in a murine food allergy model suppresses anaphylactic symptoms by improving the intestinal environment and reducing allergen uptake by increasing intestinal barrier function.

Canna starch improves immune functions and the intestinal environment in mice.

The present study was conducted to elucidate the dietary effects of canna starch on the immune functions and intestinal luminal environment in mice. The amylose and resistant starch characteristics were determined for six types of starch, including edible canna. Canna starch was found to be higher in amylose and resistant starch compared with the other starches. BALB/c mice were fed 3.16% (low-canna group) and 6.32% (high-canna group) canna starch for 2 weeks, and then intestinal parameters were measured. Fecal IgA and mucin levels were markedly elevated by canna starch intake. IgA levels in serum and spleen lymphocytes were elevated by canna starch intake in the high-canna group, but not in the low-canna group. When the mice were fed canna starch, the cecum weight increased, and the pH in the cecum decreased. The high-canna group had significantly increased levels of Clostridium subcluster XIVa lactic acid, acetic acid, and n-butyric acid in the cecum compared with the control group. These results suggested that canna starch supplementation changed the intestinal microbiota and enhanced the intestinal immune and barrier functions and cecal organic acids in mice.