The ubiquitin ligase Nedd4 has been proposed to regulate a number of signaling pathways, but its physiological role in mammals has not been characterized. Here we present an analysis of Nedd4-null mice to show that loss of Nedd4 results in reduced insulin-like growth factor 1 (IGF-1) and insulin signaling, delayed embryonic development, reduced growth and body weight, and neonatal lethality. In mouse embryonic fibroblasts, mitogenic activity was reduced, the abundance of the adaptor protein Grb10 was increased, and the IGF-1 receptor, which is normally present on the plasma membrane, was mislocalized. However, surface expression of IGF-1 receptor was restored in homozygous mutant mouse embryonic fibroblasts after knockdown of Grb10, and Nedd4 −/− lethality was rescued by maternal inheritance of a disrupted Grb10 allele. Thus, in vivo, Nedd4 appears to positively control IGF-1 and insulin signaling partly through the regulation of Grb10 function.
The E3 ubiquitin ligase NEDD4-2 (encoded by the Nedd4L gene) regulates the amiloride-sensitive epithelial Na + channel (ENaC/SCNN1) to mediate Na + homeostasis. Mutations in the human β/γENaC subunits that block NEDD4-2 binding or constitutive ablation of exons 6-8 of Nedd4L in mice both result in salt-sensitive hypertension and elevated ENaC activity (Liddle syndrome). To determine the role of renal tubular NEDD4-2 in adult mice, we generated tetracycline-inducible, nephron-specific Nedd4L KO mice. Under standard and highNa + diets, conditional KO mice displayed decreased plasma aldosterone but normal Na + /K + balance. Under a high-Na + diet, KO mice exhibited hypercalciuria and increased blood pressure, which were reversed by thiazide treatment. Protein expression of βENaC, γENaC, the renal outer medullary K + channel (ROMK), and total and phosphorylated thiazide-sensitive Na + Cl -cotransporter (NCC) levels were increased in KO kidneys. Unexpectedly, Scnn1a mRNA, which encodes the αENaC subunit, was reduced and proteolytic cleavage of αENaC decreased. Taken together, these results demonstrate that loss of NEDD4-2 in adult renal tubules causes a new form of mild, salt-sensitive hypertension without hyperkalemia that is characterized by upregulation of NCC, elevation of β/γENaC, but not αENaC, and a normal Na + /K + balance maintained by downregulation of ENaC activity and upregulation of ROMK.
Ubiquitination plays a crucial role in regulating proteins post-translationally. The focus of this review is on NEDD4, the founding member of the NEDD4 family of ubiquitin ligases that is evolutionarily conserved in eukaryotes. Many potential substrates of NEDD4 have been identified and NEDD4 has been shown to play a critical role in the regulation of a number of membrane receptors, endocytic machinery components and the tumour suppressor PTEN. In this review we will discuss the diverse pathways in which NEDD4 is involved, and the patho-physiological significance of this important ubiquitin ligase.
The epithelial sodium channel (ENaC) is essential for sodium homoeostasis in many epithelia. ENaC activity is required for lung fluid clearance in newborn animals and for maintenance of blood volume and blood pressure in adults. In vitro studies show that the ubiquitin ligase Nedd4-2 ubiquitinates ENaC to regulate its cell surface expression. Here we show that knockout of Nedd4-2 in mice leads to increased ENaC expression and activity in embryonic lung. This increased ENaC activity is the likely reason for premature fetal lung fluid clearance in Nedd4-2−/− animals, resulting in a failure to inflate lungs and perinatal lethality. A small percentage of Nedd4-2−/− animals survive up to 22 days, and these animals also show increased ENaC expression and develop lethal sterile inflammation of the lung. Thus, we provide critical in vivo evidence that Nedd4-2 is essential for correct regulation of ENaC expression, fetal and postnatal lung function and animal survival.
The muscarine-sensitive K ؉ current (M-current) stabilizes the resting membrane potential in neurons, thus limiting neuronal excitability. The M-current is mediated by heteromeric channels consisting of KCNQ3 subunits in association with either KCNQ2 or KCNQ5 subunits. The role of KCNQ2/3/5 in the regulation of neuronal excitability is well established; however, little is known about the mechanisms that regulate the cell surface expression of these channels. Ubiquitination by the Nedd4/Nedd4-2 ubiquitin ligases is known to regulate a number of membrane ion channels and transporters. In this study, we investigated whether Nedd4/Nedd4-2 could regulate KCNQ2/ 3/5 channels. We found that the amplitude of the K ؉ currents mediated by KCNQ2/3 and KCNQ3/5 were reduced by Nedd4-2 (but not Nedd4) in a Xenopus oocyte expression system. Deletion experiments showed that the C-terminal region of the KCNQ3 subunit is required for the Nedd4-2-mediated regulation of the heteromeric channels. Glutathione S-transferase fusion pulldowns and co-immunoprecipitations demonstrated a direct interaction between KCNQ2/3 and Nedd4-2. Furthermore, Nedd4-2 could ubiquitinate KCNQ2/3 in transfected cells. Taken together, these data suggest that Nedd4-2 is potentially an important regulator of M-current activity in the nervous system.The muscarine-sensitive K ϩ current (M-current) 4 is a low threshold, non-inactivating K ϩ current that was first identified in sympathetic neurons (1) and is now known to be an important regulator of the excitability of many neuronal cell types in the central and peripheral nervous systems. The characteristic voltage and time dependence of the M-current leads to a "clamping" of the resting membrane potential upon activation of the current. The M-current therefore exerts a stabilizing effect on the resting membrane potential and attenuates neuronal excitability, thus limiting repetitive firing of neurons (2, 3). The M-current is mediated by members of the K v 7 family, which form a heterotetrameric channel consisting of KCNQ3 subunits associated with either KCNQ2 or KCNQ5 subunits, all containing six transmembrane domains (S1-S6), a short intracellular N-terminal segment, and a large intracellular C-terminal region (4 -8). Mutations in KCNQ2 and KCNQ3 are associated with epilepsy, in particular, benign neonatal familial seizures, and suppression of the M-current in conditional transgenic mice has been reported to cause spontaneous seizures (7, 9).At the single channel level, the M-current has been reported to be regulated by several receptor-mediated pathways and changes in intracellular Ca 2ϩ concentration ([Ca 2ϩ ] i ) (reviewed in Refs. 2 and 10); however, little is known about the factors that determine the cell surface density of the channels that underlie this current. One recently characterized mechanism for the regulation of cell surface levels of membrane proteins is ubiquitination by the Nedd4/ Nedd4-2 ubiquitin ligases, which results in the removal of the protein from the membrane (reviewed in Refs. ...
SummaryIn Aspergillus nidulans , it is known that creB encodes a deubiquitinating enzyme that forms a complex with the WD40 motif containing protein encoded by creC , that mutations in these genes lead to altered carbon source utilization and that the creD34 mutation suppresses the phenotypic effects of mutations in creC and creB . Therefore, creD was characterized in order to dissect the regulatory network that involves the CreB-CreC deubiquitination complex. CreD contains arrestin domains and PY motifs and is highly similar to the Rod1p and Rog3p proteins from Saccharomyces cerevisiae . An additional gene was identified in the A. nidulans genome that also encodes an arrestin and PY motif-containing protein, which we have designated apyA , and thus two similar proteins also exist in A. nidulans . In S. cerevisiae , Rod1p and Rog3p interact with the ubiquitin ligase Rsp5p, and so the A. nidulans homologue of Rsp5p was identified, and the gene encoding this HECT ubiquitin ligase was designated hulA . CreD and ApyA were tested for proteinprotein interactions with HulA via the bacterial twohybrid system, and ApyA showed strong interaction, and CreD showed weak interaction, with HulA in this system.
Nedd4-2, a HECT (homologous with E6-associated protein C-terminus)-type ubiquitin protein ligase, has been implicated in regulating several ion channels, including Navs (voltage-gated sodium channels). In Xenopus oocytes Nedd4-2 strongly inhibits the activity of multiple Navs. However, the conditions under which Nedd4-2 mediates native Nav regulation remain uncharacterized. Using Nedd4-2-deficient mice, we demonstrate in the present study that in foetal cortical neurons Nedd4-2 regulates Navs specifically in response to elevated intracellular Na(+), but does not affect steady-state Nav activity. In dorsal root ganglia neurons from the same mice, however, Nedd4-2 does not control Nav activities. The results of the present study provide the first physiological evidence for an essential function of Nedd4-2 in regulating Navs in the central nervous system.
NEDD4-2 (NEDD4L), a ubiquitin protein ligase of the Nedd4 family, is a key regulator of cell surface expression and activity of the amiloride-sensitive epithelial Na+ channel (ENaC). While hypomorphic alleles of Nedd4-2 in mice show salt-sensitive hypertension, complete knockout results in pulmonary distress and perinatal lethality due to increased cell surface levels of ENaC. We now show that Nedd4-2 deficiency in mice also results in an unexpected progressive kidney injury phenotype associated with elevated ENaC and Na+Cl− cotransporter expression, increased Na+ reabsorption, hypertension and markedly reduced levels of aldosterone. The observed nephropathy is characterized by fibrosis, tubule epithelial cell apoptosis, dilated/cystic tubules, elevated expression of kidney injury markers and immune cell infiltration, characteristics reminiscent of human chronic kidney disease. Importantly, we demonstrate that the extent of kidney injury can be partially therapeutically ameliorated in mice with nephron-specific deletions of Nedd4-2 by blocking ENaC with amiloride. These results suggest that increased Na+ reabsorption via ENaC causes kidney injury and establish a novel role of NEDD4-2 in preventing Na+-induced nephropathy. Contrary to some recent reports, our data also indicate that ENaC is the primary in vivo target of NEDD4-2 and that Nedd4-2 deletion is associated with hypertension on a normal Na+ diet. These findings provide further insight into the critical function of NEDD4-2 in renal pathophysiology.
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