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Mutation affecting the conserved acidic WNK1 motif causes inherited hyperkalemic hyperchloremic acidosis. , Louis-Dit-Picard H., J Clin Invest. December 1, 2020; 130 (12): 6379-6394.
ROMK expression remains unaltered in a mouse model of familial hyperkalemic hypertension caused by the CUL3Δ403-459 mutation. , Murthy M., Physiol Rep. July 1, 2016; 4 (13):
Inhibition of ROMK channels by low extracellular K+ and oxidative stress. , Frindt G., Am J Physiol Renal Physiol. July 15, 2013; 305 (2): F208-15.
Downregulation of the renal outer medullary K(+) channel ROMK by the AMP-activated protein kinase. , Siraskar B., Pflugers Arch. February 1, 2013; 465 (2): 233-45.
Functional and developmental expression of a zebrafish Kir1.1 ( ROMK) potassium channel homologue Kcnj1. , Abbas L., J Physiol. March 15, 2011; 589 (Pt 6): 1489-503.
Tamm-Horsfall glycoprotein interacts with renal outer medullary potassium channel ROMK2 and regulates its function. , Renigunta A., J Biol Chem. January 21, 2011; 286 (3): 2224-35.
Effects of dietary K on cell-surface expression of renal ion channels and transporters. , Frindt G., Am J Physiol Renal Physiol. October 1, 2010; 299 (4): F890-7.
The miR-30 miRNA family regulates Xenopus pronephros development and targets the transcription factor Xlim1/ Lhx1. , Agrawal R ., Development. December 1, 2009; 136 (23): 3927-36.
Organization of the pronephric kidney revealed by large-scale gene expression mapping. , Raciti D ., Genome Biol. January 1, 2008; 9 (5): R84.
Xenopus Bicaudal-C is required for the differentiation of the amphibian pronephros. , Tran U ., Dev Biol. July 1, 2007; 307 (1): 152-64.
CFTR is required for PKA-regulated ATP sensitivity of Kir1.1 potassium channels in mouse kidney. , Lu M., J Clin Invest. March 1, 2006; 116 (3): 797-807.
WNK3, a kinase related to genes mutated in hereditary hypertension with hyperkalaemia, regulates the K+ channel ROMK1 ( Kir1.1). , Leng Q., J Physiol. March 1, 2006; 571 (Pt 2): 275-86.
Phosphorylation-regulated endoplasmic reticulum retention signal in the renal outer-medullary K+ channel ( ROMK). , O'Connell AD., Proc Natl Acad Sci U S A. July 12, 2005; 102 (28): 9954-9.
Apical localization of renal K channel was not altered in mutant WNK4 transgenic mice. , Yamauchi K., Biochem Biophys Res Commun. July 8, 2005; 332 (3): 750-5.
[WNK1 and WNK4, new players in salt and water homeostasis] , Hadchouel J., Med Sci (Paris). January 1, 2005; 21 (1): 55-60.
Barttin increases surface expression and changes current properties of ClC-K channels. , Waldegger S., Pflugers Arch. June 1, 2002; 444 (3): 411-8.
Influences of the N- and C-termini of the distal nephron inward rectifier, ROMK. , Bhandari S., Kidney Blood Press Res. January 1, 2001; 24 (3): 142-8.
Rat homolog of sulfonylurea receptor 2B determines glibenclamide sensitivity of ROMK2 in Xenopus laevis oocyte. , Tanemoto M., Am J Physiol Renal Physiol. April 1, 2000; 278 (4): F659-66.
pH-dependent modulation of the cloned renal K+ channel, ROMK. , McNicholas CM., Am J Physiol. December 1, 1998; 275 (6): F972-81.
pH-dependent modulation of the cloned renal K + channel, ROMK. , McNicholas CM., Am J Physiol Renal Physiol. December 1, 1998; 275 (6): F972-F981.
Localization of ROMK channels in the rat kidney. , Mennitt PA., J Am Soc Nephrol. December 1, 1997; 8 (12): 1823-30.
Molecular site for nucleotide binding on an ATP-sensitive renal K+ channel (ROMK2). , McNicholas CM., Am J Physiol. August 1, 1996; 271 (2 Pt 2): F275-85.
ROMK inwardly rectifying ATP-sensitive K+ channel. II. Cloning and distribution of alternative forms. , Boim MA., Am J Physiol. June 1, 1995; 268 (6 Pt 2): F1132-40.