Oxygen regulation of the epithelial Na channel in the collecting duct.

The PO(2) within the kidney changes dramatically from cortex to medulla. The present experiments examined the effect of changing PO(2) on epithelial Na channel (ENaC)-mediated Na transport in the collecting duct using the mpkCCD-c14 cell line. Decreasing ambient O(2) concentration from 20 to 8% decreased ENaC activity by 40%; increasing O(2) content to 40% increased ENaC activity by 50%. The O(2) effect required several hours to develop and was not mimicked by the acid pH that developed in monolayers incubated in low-O(2) medium. Corticosteroids increased ENaC activity at each O(2) concentration; there was no interaction. The pathways for O(2) and steroid regulation of ENaC are different since O(2) did not substantially affect Sgk1, α-ENaC, Gilz, or Usp2-45 mRNA levels, genes involved in steroid-mediated ENaC regulation. The regulation of ENaC activity by these levels of O(2) appears not to be mediated by changes in hypoxia-inducible factor-1α or -2α activity or a change in AMP kinase activity. Changes in O(2) concentration had minimal effect on α- or γ-ENaC mRNA and protein levels; there were moderate effects on ß-ENaC levels. However, 40% O(2) induced substantially greater total ß- and γ-ENaC on the apical surface compared with 8% O(2); both subunits demonstrated a greater increase in the mature forms. The α-ENaC subunit was difficult to detect on the apical surface, perhaps because our antibodies do not recognize the major mature form. These results identify a mechanism of ENaC regulation that may be important in different regions of the kidney and in responses to changes in dietary NaCl.

Osmoregulation of ceroid neuronal lipofuscinosis type 3 in the renal medulla.

Recessive inheritance of mutations in ceroid neuronal lipofuscinosis type 3 (CLN3) results in juvenile neuronal ceroid lipofuscinosis (JNCL), a childhood neurodegenerative disease with symptoms including loss of vision, seizures, and motor and mental decline. CLN3p is a transmembrane protein with undefined function. Using a Cln3 reporter mouse harboring a nuclear-localized bacterial beta-galactosidase (beta-Gal) gene driven by the native Cln3 promoter, we detected beta-Gal most prominently in epithelial cells of skin, colon, lung, and kidney. In the kidney, beta-Gal-positive nuclei were predominant in medullary collecting duct principal cells, with increased expression along the medullary osmotic gradient. Quantification of Cln3 transcript levels from kidneys of wild-type (Cln3(+/+)) mice corroborated this expression gradient. Reporter mouse-derived renal epithelial cultures demonstrated a tonicity-dependent increase in beta-Gal expression. RT-quantitative PCR determination of Cln3 transcript levels further supported osmoregulation at the Cln3 locus. In vivo, osmoresponsiveness of Cln3 was demonstrated by reduction of medullary Cln3 transcript abundance after furosemide administration. Primary cultures of epithelial cells of the inner medulla from Cln3(lacZ/lacZ) (CLN3p-null) mice showed no defect in osmolyte accumulation or taurine flux, arguing against a requirement for CLN3p in osmolyte import or synthesis. CLN3p-deficient mice with free access to water showed a mild urine-concentrating defect but, upon water deprivation, were able to concentrate their urine normally. Unexpectedly, we found that CLN3p-deficient mice were hyperkalemic and had a low fractional excretion of K(+). Together, these findings suggest an osmoregulated role for CLN3p in renal control of water and K(+) balance.

Discordant effects of corticosteroids and expression of subunits on ENaC activity.

In renal distal nephron and airway epithelial cells, adrenocortical steroids increase epithelial Na+ channel (ENaC) activity and also markedly increase the expression of the alpha-subunit. The present experiments were designed to reconstitute this steroid effect in ENaC-expressing cells by overexpressing the subunits whose expression is enhanced by corticosteroids. In renal collecting duct monolayers, corticosteroids increased ENaC activity 5- to 8-fold, endogenous alpha-ENaC mRNA and protein approximately 10-fold, and beta-ENaC protein and mRNA 1.2- to 2-fold. gamma-ENaC expression was unchanged. To determine whether this increase in expression was sufficient to increase ENaC activity, we used a regulated adenovirus system to increase expression of each subunit alone and in combination. Unexpectedly, increased expression of the alpha- and/or beta-subunit had no effect on ENaC activity in collecting duct cells or lung epithelial cells. In contrast, a small increase in gamma-ENaC expression increased ENaC activity about threefold. This increase in activity was additive to the effect of steroids. Thus, even though corticosteroids strongly increase alpha-ENaC expression and moderately increase beta-ENaC expression, these effects are not, by themselves, sufficient to increase ENaC activity. Knockdown experiments are consistent with the idea that the increased expression of alpha-ENaC is necessary for the full steroid effect on ENaC. Increased expression of gamma-ENaC and corticosteroid treatment enhances ENaC activity by parallel, noninteracting pathways. These results underscore the importance of other actions of steroid hormones for long-term enhancement of ENaC activity and raise new possibilities for regulation of ENaC activity by gamma-ENaC expression.

Mice heterozygous for beta-ENaC deletion have defective potassium excretion.

The present studies were designed to determine whether mice heterozygous for deletion of beta-ENaC exhibited defects in Na+/K+ transport and blood pressure regulation. In response to an acute KCl infusion, +/-mice developed higher serum [K+] and excreted only 40% of the K+ excreted by +/+mice. After 6 days on a low (0.01%)-Na+ diet, the cumulative Na+ excretion from days 3-6 was greater for +/-mice. This low-Na+ diet caused higher serum [K+] and lower K+ excretion rates in +/-mice than in +/+mice, but the rectal potential differences were not different. Analyses of mRNA from mice on this diet showed the expected approximately 50% reduction of beta-ENaC in kidney and colon of +/-mice. Unexpectedly, the level of gamma-ENaC mRNA was similarly reduced. NHE3 mRNA was approximately 30% higher in +/-mice whereas mRNA of the Na-K-2Cl cotransporter was not different. Also unexpectedly, the amount of beta-ENaC proteins was similar in both groups of mice but there was a reduction of one form of gamma-ENaC in +/-mice. These experiments demonstrate that mice heterozygous for beta-ENaC have a small but detectable defect in their ability to conserve Na+ and a more readily apparent defect in the ability to secrete K+.

Overexpression of the epithelial Na+ channel gamma subunit in collecting duct cells: interactions of Liddle's mutations and steroids on expression and function.

The epithelial Na(+) channel (ENaC) has three subunits; the expression of each can be regulated. Liddle's syndrome is caused by an activating mutation in the C terminus of either the beta or gamma subunit. We used a doxycycline-regulated adenovirus system to express varying levels of human gammaENaC in renal collecting duct (M1 cell) monolayers. Increasing levels of wild type human gamma ENaC (gammahENaC) produced a 2.5-fold enhancement of Na(+) transport. Expression of a truncated C terminus produced less protein than wild type or a gammaY627A missense mutation. However, either of these mutations produced a approximately 4-fold increase in Na(+) transport despite the different levels of protein expression. Unexpectedly, overexpression of a marginally detectable amount of gammahENaC was sufficient to produce a full increase in Na(+) transport; a further increase in protein expression produced no further increase in Na(+) transport. Steroid treatment increased Na(+) transport to a similar absolute magnitude in control monolayers and in monolayers expressing all types of gammahENaC. Withdrawal of steroids after 24 h produced a decline in Na(+) transport over 8 h in monolayers expressing wild type but not the Liddle's mutation. Using treatment with brefeldin A to estimate the disappearance rate constants, we found progressively slower disappearance rates in monolayers overexpressing gammahENaC and the Liddle's mutant. Calculated insertion rates were slower for the Liddle's mutant than for wild type despite increasing rates of Na(+) transport. These results raise questions regarding previously held assumptions about the behavior of ENaC.