Alternative Mechanism of Activation of the Epithelial Na+ Channel by Cleavage

108

Background: Epoxyeicosatrienoic acids (EETs) regulate sodium excretion in the distal nephron. Results: Lack of a Cyp2c44 epoxygenase blunts the ERK1/2-mediated inhibition of ENaC and causes salt-sensitive hypertension. Conclusion: Cyp2c44 is the epoxygenase responsible for the synthesis of natriuretic EETs during increased salt intake. Significance: Roles for the human CYP2C8 and CYP2C9 epoxygenases as antihypertensive therapeutic targets are proposed.

Section: Discussionmentioning

confidence: 99%

The Cyp2c44 Epoxygenase Regulates Epithelial Sodium Channel Activity and the Blood Pressure Responses to Increased Dietary Salt

Capdevila

Pidkovka

Mei

et al. 2014

108

“…4 To circumvent these problems, we developed this assay using peptides with sequences specific to ENaC. Assuming that these sites are solution-accessible in the channel, a finding verified experimentally by our laboratory and by other investigators (21,22,29), it is likely that the reported activity is a reasonable representation of the activity of proteases that can target these sites. This approach sacrifices the ability to identify a specific proteases, probably a complicated issue because many proteases may act on these ENaC sequences, especially given the number of proteases that have been shown to cleave the ENaC subunits (see discussion in Ref.…”

Section: Discussionmentioning

confidence: 99%

“…This approach sacrifices the ability to identify a specific proteases, probably a complicated issue because many proteases may act on these ENaC sequences, especially given the number of proteases that have been shown to cleave the ENaC subunits (see discussion in Ref. 29). However, this approach results in a better understanding of the overall activity of proteases targeting these sequences and therefore provides a better representation or index of real-time channel activation.…”

Section: Discussionmentioning

confidence: 99%

“…In this case, the ensuing effect is probably due to either a combination of potential direct effects of cholesterol on the channel mediated by modification of the lipid bilayer or secondary effects of ECD on ENaC by modifying the activity of ENaCacting proteases. In this respect, both mechanisms have been shown to affect ENaC activity, where it was shown in cell systems that membrane cholesterol content modifies the activity of channels and transporters, including ENaC (5,13,15,37,38) and that ␣-and ␥-ENaC cleavage enhances channel activity (21,22,29). Interestingly, recent data further indicate that it is cleavage of ␥ in vivo that is more important to channel activation rather than ␣ (28, 30, 32), a result consistent with the current findings.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Acute Cholesterol-induced Anti-natriuretic Effects

Awayda

Pochynyuk³

et al. 2011

Self Cite

The epithelial Na ؉ channel (ENaC) is modulated by membrane lipid composition. However, the effect of an in vivo change of membrane composition is unknown. We examined the effect of a 70-day enhanced cholesterol diet (ECD) on ENaC and renal Na ؉ handling. Rats were fed a standard chow or one supplemented with 1% cholesterol and 0.5% cholic acid (ECD). ECD animals exhibited marked anti-diuresis and antinatriuresis (40 and 47%), which peaked at 1-3 weeks. Secondary compensation returned urine output and urinary Na ؉ excretion to control levels by week 10. During these initial changes, there were no accompanying effects on systolic blood pressure, serum creatinine, or urinary creatinine excretion, indicating that the these effects of ECD preceded those which modify renal filtration and blood pressure. The effects of ECD on ENaC were evaluated by measuring the relative protein content of ␣, ␤, and ␥ subunits. ␣ and ␥ blots were further examined for subunit cleavage (a process that activates ENaC). No significant changes were observed in ␣ and ␤ levels throughout the study. However, levels of cleaved ␥ were elevated, suggesting that ENaC was activated. The changes of ␥ persisted at week 10 and were accompanied by additional subunit fragments, indicating potential changes of ␥-cleaving proteases. Enhanced protease activity, and specifically that which could act on the second identified cleavage site in ␥, was verified in a newly developed urinary protease assay. These results predict enhanced ENaC activity, an effect that was confirmed in patch clamp experiments of principal cells of split open collecting ducts, where ENaC open probability was increased by 40% in the ECD group. These data demonstrate a complex series of events and a new regulatory paradigm that is initiated by ECD prior to the onset of elevated blood pressure. These events lead to changes of renal Na ؉ handling, which occur in part by effects on extracellular ␥-ENaC cleavage.Hypercholesterolemia is an established contributor to atherosclerosis and cardiovascular diseases. Increased cholesterol is also known to cause or contribute to renal injury by impairing the filtration permeability barrier and podocyte permeability (1). However, little is known regarding the effects of elevated dietary cholesterol on membrane cholesterol and renal sodium transport. We have recently demonstrated that short term membrane cholesterol enrichment modifies renal sodium transport, leading to increased absorption and antinatriuresis (2). These short term effects were observed within minutes of enrichment and were mediated, in part, by effects on sodium absorption in the loop of Henle. No other reports have examined the effects of membrane cholesterol enrichment on renal Na ϩ transport in vivo and especially so under mild enrichment conditions that precede the vasculature effects of hypercholesterolemia.It is established that membrane cholesterol content can modulate the activity of integral membrane proteins and that experimental depletion or enrichment of cholesterol mod...

“…The exact mechanism of how cleavage activates ENaC is incompletely understood, but one hypothesis is that cleavage removes inhibitory peptides from ␣ENaC and ␥ENaC (12). An alternative mechanism of ENaC activation by cleavage, proposed by Hu et al (14), involves loss of the ␣ENaC N terminus (including the first transmembrane domain) from the channel complex. Cleavage by proteases does not change the number of ENaC channels at the surface but rather increases channel open probability and is a mechanism for regulating ENaC activity (13).…”

mentioning

confidence: 99%

Proteolytic Cleavage of Human Acid-sensing Ion Channel 1 by the Serine Protease Matriptase

Clark

Jovov

Rooj

et al. 2010

Acid-sensing ion channel 1 (ASIC1) is a H؉ -gated channel of the amiloride-sensitive epithelial Na ؉ channel (ENaC)/degenerin family. ASIC1 is expressed mostly in the central and peripheral nervous system neurons. ENaC and ASIC function is regulated by several serine proteases. The type II transmembrane serine protease matriptase activates the prototypical ␣␤␥ENaC channel, but we found that matriptase is expressed in glioma cells and its expression is higher in glioma compared with normal astrocytes. Therefore, the goal of this study was to test the hypothesis that matriptase regulates ASIC1 function. Matriptase decreased the acid-activated ASIC1 current as measured by two-electrode voltage clamp in Xenopus oocytes and cleaved ASIC1 expressed in oocytes or CHO K1 cells. Inactive S805A matriptase had no effect on either the current or the cleavage of ASIC1. The effect of matriptase on ASIC1 was specific, because it did not affect the function of ASIC2 and no matriptase-specific ASIC2 fragments were detected in oocytes or in CHO cells. Three matriptase recognition sites were identified in ASIC1 (Arg-145, Lys-185, and Lys-384). Site-directed mutagenesis of these sites prevented matriptase cleavage of ASIC1. Our results show that matriptase is expressed in glioma cells and that matriptase specifically cleaves ASIC1 in heterologous expression systems.