Synopsis Zn is critical for a multitude of cellular processes, including gene expression, secretion and enzymatic activities. Cellular Zn is controlled by Zn-chelating proteins and by Zn transporters. The recent identification of Zn permeability of the lysosomal ion channel TRPML1, and the evidence of abnormal Zn levels in cells deficient in TRPML1, suggested a role for TRPML1 in Zn transport. Here we provide new evidence for such a role and identify additional cellular components responsible for it. In agreement with the previously published data, an acute siRNA-driven TRPML1 knockdown (KD) leads to the buildup of large cytoplasmic vesicles positive for Lysotracker and Zn staining, when cells are exposed to high concentrations of Zn. We now show that lysosomal enlargement and Zn buildup in TRPML1-KD cells exposed to Zn are ameliorated by KD of the Zn-sensitive transcription factor MTF-1 or Zn transporter ZnT4. TRPML1 KD is associated with a buildup of cytoplasmic Zn and with enhanced transcriptional response of mRNA for metallothionein 2a (MT2a). TRPML1 KD did not suppress lysosomal secretion, but it did delay Zn leak from the lysosomes into the cytoplasm. These data underscore a role for TRPML1 in Zn metabolism. Furthermore, they suggest that TRPML1 works in concert with ZnT4 to regulate Zn translocation between the cytoplasm and lysosomes.
The metabolic sensor AMP-activated protein kinase (AMPK) has emerged as an important link between cellular metabolic status and ion transport activity. We previously found that AMPK binds to and phosphorylates CFTR in vitro and inhibits PKA-dependent stimulation of CFTR channel gating in Calu-3 bronchial serous gland epithelial cells. To further characterize the mechanism of AMPK-dependent regulation of CFTR, whole cell patch-clamp measurements were performed with PKA activation in Calu-3 cells expressing either constitutively active or dominant-negative AMPK mutants (AMPK-CA or AMPK-DN). Baseline CFTR conductance in cells expressing AMPK-DN was substantially greater than controls, suggesting that tonic AMPK activity in these cells inhibits CFTR under basal conditions. Although baseline CFTR conductance in cells expressing AMPK-CA was comparable to that of controls, PKA stimulation of CFTR was completely blocked in AMPK-CA-expressing cells, suggesting that AMPK activation renders CFTR resistant to PKA activation in vivo. Phosphorylation studies of CFTR in human embryonic kidney-293 cells using tetracycline-inducible expression of AMPK-DN demonstrated AMPK-dependent phosphorylation of CFTR in vivo. However, AMPK activity modulation had no effect on CFTR in vivo phosphorylation in response to graded doses of PKA or PKC agonists. Thus, AMPK-dependent CFTR phosphorylation renders the channel resistant to activation by PKA and PKC without preventing phosphorylation by these kinases. We found that Ser768, a CFTR R domain residue considered to be an inhibitory PKA site, is the dominant site of AMPK phosphorylation in vitro. Ser-to-Ala mutation at this site enhanced baseline CFTR activity and rendered CFTR resistant to inhibition by AMPK, suggesting that AMPK phosphorylation at Ser768 is required for its inhibition of CFTR. In summary, our findings indicate that AMPK-dependent phosphorylation of CFTR inhibits CFTR activation by PKA, thereby tuning the PKA-responsiveness of CFTR to metabolic and other stresses in the cell.
The KCNQ1 K(+) channel plays a key role in the regulation of several physiological functions, including cardiac excitability, cardiovascular tone, and body electrolyte homeostasis. The metabolic sensor AMP-activated protein kinase (AMPK) has been shown to regulate a growing number of ion transport proteins. To determine whether AMPK regulates KCNQ1, we studied the effects of AMPK activation on KCNQ1 currents in Xenopus laevis oocytes and collecting duct epithelial cells. AMPK activation decreased KCNQ1 currents and channel surface expression in X. laevis oocytes, but AMPK did not phosphorylate KCNQ1 in vitro, suggesting an indirect regulatory mechanism. As it has been recently shown that the ubiquitin-protein ligase Nedd4-2 inhibits KCNQ1 plasma membrane expression and that AMPK regulates epithelial Na(+) channels via Nedd4-2, we examined the role of Nedd4-2 in the AMPK-dependent regulation of KCNQ1. Channel inhibition by AMPK was blocked in oocytes coexpressing either a dominant-negative or constitutively active Nedd4-2 mutant, or a Nedd4-2 interaction-deficient KCNQ1 mutant, suggesting that Nedd4-2 participates in the regulation of KCNQ1 by AMPK. KCNQ1 is expressed at the basolateral membrane in mouse polarized kidney cortical collecting duct (mpkCCD(c14)) cells and in rat kidney. Treatment with the AMPK activators AICAR (2 mM) or metformin (1 mM) reduced basolateral KCNQ1 currents in apically permeabilized polarized mpkCCD(c14) cells. Moreover, AICAR treatment of rat kidney slices ex vivo induced AMPK activation and intracellular redistribution of KCNQ1 from the basolateral membrane in collecting duct principal cells. AICAR treatment also induced increased ubiquitination of KCNQ1 immunoprecipitated from kidney slice homogenates. These results indicate that AMPK inhibits KCNQ1 activity by promoting Nedd4-2-dependent channel ubiquitination and retrieval from the plasma membrane.
The E3 ubiquitin ligase Nedd4-2 regulates several ion transport proteins, including the epithelial Na ؉ channel (ENaC). Nedd4-2 decreases apical membrane expression and activity of ENaC. Although it is subject to tight hormonal control, the mechanistic basis of Nedd4-2 regulation remains poorly understood. To characterize regulatory inputs to Nedd4-2 function, we screened for novel sites of Nedd4-2 phosphorylation using tandem mass spectrometry. Three of seven identified Xenopus Nedd4-2 Ser/Thr phosphorylation sites corresponded to previously identified target sites for SGK1, whereas four were novel, including Ser-293, which matched the consensus for a MAPK target sequence. Further in vitro and in vivo phosphorylation experiments revealed that Nedd4-2 serves as a target of JNK1, but not of p38 MAPK or ERK1/2. Additional rounds of tandem mass spectrometry identified two other phosphorylated residues within Nedd4-2, including Thr-899, which is present within the catalytic domain. Nedd4-2 with mutations at these sites had markedly inhibited JNK1-dependent phosphorylation, virtually no ENaC inhibitory activity, and significantly reduced ubiquitin ligase activity. These data identify phosphorylatable residues that activate Nedd4-2 and may work together with residues targeted by inhibitory kinases (e.g. SGK1 and protein kinase A) to govern Nedd4-2 regulation of epithelial ion transport.
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