Kyosuke Fujita

K+-Cl- Cotransporter-3a Up-regulates Na+,K+-ATPase in Lipid Rafts of Gastric Luminal Parietal Cells.

Gastric parietal cells migrate from the luminal to the basal region of the gland, and they gradually lose acid secretory activity. So far, distribution and function of K+-Cl- cotransporters (KCCs) in gastric parietal cells have not been reported. We found that KCC3a but not KCC3b mRNA was highly expressed, and KCC3a protein was predominantly expressed in the basolateral membrane of rat gastric parietal cells located in the luminal region of the glands. KCC3a and the Na+,K+-ATPase α1-subunit (α1NaK) were coimmunoprecipitated, and both of them were highly localized in a lipid raft fraction. The ouabain-sensitive K+-dependent ATP-hydrolyzing activity (Na+,K+-ATPase activity) was significantly inhibited by a KCC inhibitor (R-(+)-[(2-n-butyl-6,7-dichloro-2-cyclopentyl-2,3-dihydro-1-oxo-1H-inden-5-yl)oxy]acetic acid (DIOA)). The stable exogenous expression of KCC3a in LLC-PK1 cells resulted in association of KCC3a with endogenous α1NaK, and it recruited α1NaK in lipid rafts, accompanying increases of Na+,K+-ATPase activity and ouabain-sensitive Na+ transport activity that were suppressed by DIOA, whereas the total expression level of α1NaK in the cells was not significantly altered. On the other hand, the expression of KCC4 induced no association with α1NaK. In conclusion, KCC3a forms a functional complex with α1NaK in the basolateral membrane of luminal parietal cells, and it up-regulates α1NaK in lipid rafts, whereas KCC3a is absent in basal parietal cells.

The NH2-terminus of K+-Cl− cotransporter 3a is essential for up-regulation of Na+,K+-ATPase activity

K(+)-Cl(-) cotransporter-3 has two major amino terminal variants, KCC3a and KCC3b. In LLC-PK1 cells, exogenously expressed KCC3a co-immunoprecipitated with endogenous Na(+),K(+)-ATPase alpha1-subunit (alpha1NaK), accompanying significant increases of the Na(+),K(+)-ATPase activity. Exogenously expressed KCC3b did not co-immunoprecipitate with endogenous alpha1NaK inducing no change of the Na(+),K(+)-ATPase activity. A KCC inhibitor attenuated the Na(+),K(+)-ATPase activity in rat gastric mucosa in which KCC3a is predominantly expressed, while it had no effects on the Na(+),K(+)-ATPase activity in rat kidney in which KCC3b is predominantly expressed. In these tissue samples, KCC3a co-immunoprecipitated with alpha1NaK, while KCC3b did not. Our results suggest that the NH(2)-terminus of KCC3a is a key region for association with alpha1NaK, and that KCC3a but not KCC3b can regulate the Na(+),K(+)-ATPase activity.

Functional coupling of chloride–proton exchanger ClC-5 to gastric H+,K+-ATPase

Summary It has been reported that chloride–proton exchanger ClC-5 and vacuolar-type H+-ATPase are essential for endosomal acidification in the renal proximal cells. Here, we found that ClC-5 is expressed in the gastric parietal cells which secrete actively hydrochloric acid at the luminal region of the gland, and that it is partially localized in the intracellular tubulovesicles in which gastric H+,K+-ATPase is abundantly expressed. ClC-5 was co-immunoprecipitated with H+,K+-ATPase in the lysate of tubulovesicles. The ATP-dependent uptake of 36Cl− into the vesicles was abolished by 2-methyl-8-(phenylmethoxy)imidazo[1,2-a]pyridine-3-acetonitrile (SCH28080), an inhibitor of H+,K+-ATPase, suggesting functional expression of ClC-5. In the tetracycline-regulated expression system of ClC-5 in the HEK293 cells stably expressing gastric H+,K+-ATPase, ClC-5 was co-immunoprecipitated with H+,K+-ATPase, but not with endogenous Na+,K+-ATPase. The SCH28080-sensitive 36Cl− transporting activity was observed in the ClC-5-expressing cells, but not in the ClC-5-non-expressing cells. The mutant (E211A-ClC-5), which has no H+ transport activity, did not show the SCH28080-sensitive 36Cl− transport. On the other hand, both ClC-5 and its mutant (E211A) significantly increased the activity of H+,K+-ATPase. Our results suggest that ClC-5 and H+,K+-ATPase are functionally associated and that they may contribute to gastric acid secretion.

Modulation of H(+),K(+)-ATPase activity by the molecular chaperone ERp57 highly expressed in gastric parietal cells.

ERp57 is a ubiquitous ER chaperone that has disulfide isomerase activity. Here, we found that both ERp57 and gastric H+,K+‐ATPase are expressed in a sample derived from the apical canalicular membranes of parietal cells. Overexpression of ERp57 in HEK293 cells stably expressing H+,K+‐ATPase significantly increased the ATPase activity without changing the expression level of H+,K+‐ATPase. Interestingly, overexpression of a catalytically inactive mutant of ERp57 (C57S/C60S/C406S/C409S) in the cells also increased H+,K+‐ATPase activity. In contrast, knockdown of endogenous ERp57 in H+,K+‐ATPase‐expressing cells significantly decreased ATPase activity without changing the expression level of H+,K+‐ATPase. Overexpression and knockdown of ERp57 had no significant effect on the expression and function of Na+,K+‐ATPase. These results suggest that ERp57 positively regulates H+,K+‐ATPase activity apart from its chaperoning function.

Ursodeoxycholic Acid Suppresses Lipogenesis in Mouse Liver: Possible Role of the Decrease in β-Muricholic Acid, a Farnesoid X Receptor Antagonist

The farnesoid X receptor (FXR) is a major nuclear receptor of bile acids; its activation suppresses sterol regulatory element-binding protein 1c (SREBP1c)-mediated lipogenesis and decreases the lipid contents in the liver. There are many reports showing that the administration of ursodeoxycholic acid (UDCA) suppresses lipogenesis and reduces the lipid contents in the liver of experimental animals. Since UDCA is not recognized as an FXR agonist, these effects of UDCA cannot be readily explained by its direct activation of FXR. We observed that the dietary administration of UDCA in mice decreased the expression levels of SREBP1c and its target lipogenic genes. Alpha- and β-muricholic acids (MCA) and cholic acid (CA) were the major bile acids in the mouse liver but their contents decreased upon UDCA administration. The hepatic contents of chenodeoxycholic acid and deoxycholic acid (DCA) were relatively low but were not changed by UDCA. UDCA did not show FXR agonistic or antagonistic potency in in vitro FXR transactivation assay. Taking these together, we deduced that the above-mentioned change in hepatic bile acid composition induced upon UDCA administration might cause the relative increase in the FXR activity in the liver, mainly by the reduction in the content of β-MCA, a farnesoid X receptor antagonist, which suggests a mechanism by which UDCA suppresses lipogenesis and decreases the lipid contents in the mouse liver.

Changes in liver lipidomics associated with sodium cholate-induced liver injury and its prevention by boiogito, a Japanese herbal medicine, in mice

Bile acids play a crucial role in the development of cholestatic liver disease by mediating parenchymal cell injury and inflammation in the liver. Bile acids can also modulate lipid metabolism, although their role in the pathogenesis of cholestatic liver diseases is mostly unknown. We examined the effects of boiogito (BOT), a Japanese herbal medicine, on liver injury and lipid profile in liver lipid fractions in a mouse model of sodium cholate (CA)‐induced cholestasis.

Role of cholesterol in functional association between K+–Cl− cotransporter-3a and Na+,K+-ATPase

K(+)-Cl(-) cotransporter-3a (KCC3a) is associated with Na(+),K(+)-ATPase α1-subunit (α1NaK) in lipid rafts of gastric acid-secreting cells and positively regulates Na(+),K(+)-ATPase activity. Here, effects of cholesterol on association of KCC3a with α1NaK in lipid rafts were studied in LLC-PK1 cells stably expressing KCC3a. In the cells, lipid rafts destructed by methyl-β-cyclodextrin (MβCD) could be reconstructed by exogenous addition of cholesterol accompanying a shift of both KCC3a and α1NaK from non-rafts to rafts. The KCC3a-increased Na(+),K(+)-ATPase activity was abolished by MβCD, and recovered by repletion of cholesterol without changing expression levels of KCC3a and α1NaK in the cells. KCC3a was co-immunoprecipitated with α1NaK even after destruction of lipid rafts by MβCD, indicating that molecular association of KCC3a with α1NaK still retains in the non-raft environment. Our results suggest that cholesterol is essential for eliciting up-regulation of Na(+),K(+)-ATPase activity by KCC3a in the KCC3a-α1NaK complex.

Ameliorative effect of animal bile preparations on dextran sulfate sodium-induced colitis in mice: Bile acids and DSS-induced colitis

Animal bile preparations harvested from bears, cattle, and pigs are composed of distinct types of bile acids. Given that several types of bile acid activate the farnesoid X receptor (FXR) or Takeda G‐protein receptor 5 (TGR5) and thereby exert anti‐inflammatory effects, we compared the effects of the three animal bile preparations on dextran sulfate sodium (DSS)‐induced colitis in mice.

Crosstalk between Na+,K+-ATPase and a volume-regulated anion channel in membrane microdomains of human cancer cells

Low concentrations of cardiac glycosides including ouabain, digoxin, and digitoxin block cancer cell growth without affecting Na+,K+-ATPase activity, but the mechanism underlying this anti-cancer effect is not fully understood. Volume-regulated anion channel (VRAC) plays an important role in cell death signaling pathway in addition to its fundamental role in the cell volume maintenance. Here, we report cardiac glycosides-induced signaling pathway mediated by the crosstalk between Na+,K+-ATPase and VRAC in human cancer cells. Submicromolar concentrations of ouabain enhanced VRAC currents concomitantly with a deceleration of cancer cell proliferation. The effects of ouabain were abrogated by a specific inhibitor of VRAC (DCPIB) and knockdown of an essential component of VRAC (LRRC8A), and they were also attenuated by the disruption of membrane microdomains or the inhibition of NADPH oxidase. Digoxin and digitoxin also showed anti-proliferative effects in cancer cells at their therapeutic concentration ranges, and these effects were blocked by DCPIB. In membrane microdomains of cancer cells, LRRC8A was found to be co-immunoprecipitated with Na+,K+-ATPase α1-isoform. These ouabain-induced effects were not observed in non-cancer cells. Therefore, cardiac glycosides were considered to interact with Na+,K+-ATPase to stimulate the production of reactive oxygen species, and they also apparently activated VRAC within membrane microdomains, thus producing anti-proliferative effects.