Otto Fröhlich

Phosphorylation of UT-A1 urea transporter at serines 486 and 499 is important for vasopressin-regulated activity and membrane accumulation

The UT-A1 urea transporter plays an important role in the urine concentrating mechanism. Vasopressin (or cAMP) increases urea permeability in perfused terminal inner medullary collecting ducts and increases the abundance of phosphorylated UT-A1, suggesting regulation by phosphorylation. We performed a phosphopeptide analysis that strongly suggested that a PKA consensus site(s) in the central loop region of UT-A1 was/were phosphorylated. Serine 486 was most strongly identified, with other potential sites at serine 499 and threonine 524. Phosphomutation constructs of each residue were made and transiently transfected into LLC-PK1 cells to assay for UT-A1 phosphorylation. The basal level of UT-A1 phosphorylation was unaltered by mutation of these sites. We injected oocytes, assayed [14C]urea flux, and determined that mutation of these sites did not alter basal urea transport activity. Next, we tested the effect of stimulating cAMP production with forskolin. Forskolin increased wild-type UT-A1 and T524A phosphorylation in LLC-PK1 cells and increased urea flux in oocytes. In contrast, the S486A and S499A mutants demonstrated loss of forskolin-stimulated UT-A1 phosphorylation and reduced urea flux. In LLC-PK1 cells, we assessed biotinylated UT-A1. Wild-type UT-A1, S486A, and S499A accumulated in the membrane in response to forskolin. However, in the S486A/S499A double mutant, forskolin-stimulated UT-A1 membrane accumulation and urea flux were totally blocked. We conclude that the phosphorylation of UT-A1 on both serines 486 and 499 is important for activity and that this phosphorylation may be involved in UT-A1 membrane accumulation.

Vasopressin Increases Plasma Membrane Accumulation of Urea Transporter UT-A1 in Rat Inner Medullary Collecting Ducts

Urea transport, mediated by the urea transporter A1 (UT-A1) and/or UT-A3, is important for the production of concentrated urine. Vasopressin rapidly increases urea transport in rat terminal inner medullary collecting ducts (IMCD). A previous study showed that one mechanism for rapid regulation of urea transport is a vasopressin-induced increase in UT-A1 phosphorylation. This study tests whether vasopressin or directly activating adenylyl cyclase with forskolin also increases UT-A1 accumulation in the plasma membrane of rat IMCD. Inner medullas were harvested from rats 45 min after injection with vasopressin or vehicle. UT-A1 abundance in the plasma membrane was significantly increased in the membrane fraction after differential centrifugation and in the biotinylated protein population. Vasopressin and forskolin each increased the amount of biotinylated UT-A1 in rat IMCD suspensions that were treated ex vivo. The observed changes in the plasma membrane are specific, as the amount of biotinylated UT-A1 but not the calcium-sensing receptor was increased by forskolin. Next, whether forskolin or the V(2)-selective agonist dDAVP would increase apical membrane expression of UT-A1 in MDCK cells that were stably transfected with UT-A1 (UT-A1-MDCK cells) was tested. Forskolin and dDAVP significantly increased UT-A1 abundance in the apical membrane in UT-A1-MDCK cells. It is concluded that vasopressin and forskolin increase UT-A1 accumulation in the plasma membrane in rat IMCD and in the apical plasma membrane of UT-A1-MDCK cells. These findings suggest that vasopressin regulates urea transport by increasing UT-A1 accumulation in the plasma membrane and/or UT-A1 phosphorylation.

The Na–H exchanger revisited: an update on Na–H exchange regulation and the role of the exchanger in hypertension and cardiac function in health and disease

Time for primary review 21 days. The Spotlight Issue of Cardiovascular Research , published in early 1995, was dedicated to various aspects of the Na–H exchanger (NHE) as they pertain to the cardiovascular system. It is appropriate to state that since the publication of that issue major strides have occurred which serve to enhance our understanding and appreciation of the importance of this major pH regulatory process in the cardiovascular system, both with respect to normal homeostasis as well as pathology. This brief revue has been written in order to provide an ‘update’ on developments in this active field since the publication of the Cardiovascular Research Spotlight Issue, again with a focus on the cardiovascular system in health and disease. The review is not intended as an exhaustive treatment of this topic, but rather it concentrates on recent developments and, accordingly, the authors have relied primarily on publications which have appeared in 1994 and later, except when an earlier article was deemed appropriate to reinforce a particular concept. For readers interested in comprehensive discussion of the NHE, particularly with respect to cardiovascular function, a number of recent reviews [1–4]and a monograph [5]can be recommended. At the time the reviews of the Spotlight Issue on the NHE were prepared, four exchanger gene isoforms were known to exist in mammals. This list has now been expanded by a fifth NHE gene and possibly even a sixth. NHE-1 has been recognized for some time as the ubiquitous ‘housekeeping’ isoform. It participates in the regulation of cytoplasmic pH and volume of the cells, which includes, of course, the cardiac myocyte (but is not the sole mechanism responsible for these functions). The function of NHE-2, which is found in renal and intestinal epithelia, is still is not well understood although it had been … * Corresponding author. Tel.: (+1-519) 6613872; Fax: (+1-519) 6614051; E-mail: mkarm@julian.uwo.ca

Loss of N-Linked Glycosylation Reduces Urea Transporter UT-A1 Response to Vasopressin

The vasopressin-regulated urea transporter (UT)-A1 is a transmembrane protein with two glycosylated forms of 97 and 117 kDa; both are derived from a single 88-kDa core protein. However, the precise molecular sites and the function for UT-A1 N-glycosylation are not known. In this study, we compared Madin-Darby canine kidney cells stably expressing wild-type (WT) UT-A1 to Madin-Darby canine kidney cell lines stably expressing mutant UT-A1 lacking one (A1m1, A1m2) or both glycosylation sites (m1m2). Site-directed mutagenesis revealed that UT-A1 has two glycosylation sites at Asn-279 and -742. Urea flux is stimulated by 10 nm vasopressin (AVP) or 10 μm forskolin (FSK) in WT cells. In contrast, m1m2 cells have a delayed and significantly reduced maximal urea flux. A 15-min treatment with AVP and FSK significantly increased UT-A1 cell surface expression in WT but not in m1m2 cells, as measured by biotinylation. We confirmed this finding using immunostaining. Membrane fractionation of the plasma membrane, Golgi, and endoplasmic reticulum revealed that AVP or FSK treatment increases UT-A1 abundance in both Golgi and plasma membrane compartments in WT but not in m1m2 cells. Pulse-chase experiments showed that UT-A1 half-life is reduced in m1m2 cells compared with WT cells. Our results suggest that mutation of the N-linked glycosylation sites reduces urea flux by reducing UT-A1 half-life and decreasing its accumulation in the apical plasma membrane. In vivo, inner medullary collecting duct cells may regulate urea uptake by altering UT-A1 glycosylation in response to AVP stimulation.

Organization of the Human Gene Encoding the Epididymis-Specific EP2 Protein Variants and Its Relationship to Defensin Genes

Abstract The EP2 gene codes for at least nine message variants that are all specifically expressed in the epididymis. These variants putatively encode small secretory proteins that differ in their N- and C-termini, resulting in proteins that can have little or no sequence similarity to each other. We have isolated and sequenced the human EP2 gene to determine the molecular origin of these variants. The EP2 gene has two promoters, eight exons, and seven introns. Exons 3 and 6 encode protein sequences homologous to β-defensins, a family of antimicrobial peptides. This sequence homology and the arrangement of promoters and defensin-encoding exons suggest that the EP2 gene originated from two ancestral β-defensin genes arranged in tandem, each contributing a promoter and two exons encoding a leader sequence and a defensin peptide. The proposed evolutionary relationship between the EP2 gene and defensin genes is supported by the observation that the EP2 gene is located on chromosome 8p23 near the defensin gene cluster and is separated by 100 kilobases or less from DEFB2, the gene for β-defensin-2. While the EP2 gene transcribes β-defensin-like message variants, most of the known message variants code for nondefensin proteins or proteins containing only a partial defensin peptide sequence. We suggest that, during its evolution, the EP2 gene has acquired new functions that may be important for sperm maturation and/or storage in the epididymis.

MDM2 E3 ubiquitin ligase mediates UT-A1 urea transporter ubiquitination and degradation.

UT-A1 is the primary urea transporter in the apical plasma membrane responsible for urea reabsorption in the inner medullary collecting duct. Although the physiological function of UT-A1 has been well established, the molecular mechanisms that regulate its activity are less well understood. Analysis of the UT-A1 amino acid sequence revealed a potential MDM2 E3 ubiquitin ligase-binding motif in the large intracellular loop of UT-A1, suggesting that UT-A1 urea transporter protein may be regulated by the ubiquitin-proteasome pathway. Here, we report that UT-A1 is ubiquitinated and degraded by the proteasome but not the lysosome proteolytic pathway. Inhibition of proteasome activity causes UT-A1 cell surface accumulation and concomitantly increases urea transport activity. UT-A1 interacts directly with MDM2; the binding site is located in the NH2-terminal p53-binding region of MDM2. MDM2 mediates UT-A1 ubiquitination both in vivo and in vitro. Overexpression of MDM2 promotes UT-A1 degradation. The mechanism is likely to be physiologically important as UT-A1 ubiquitination was identified in kidney inner medullary tissue. The ubiquitin-proteasome degradation pathway provides an important novel mechanism for UT-A1 regulation.

Mature N-linked glycans facilitate UT-A1 urea transporter lipid raft compartmentalization

The UT‐A1 urea transporter is a glycoprotein with two different glycosylated forms of 97 and 117 kDa. In this study, we found the 117‐kDa UT‐A1 preferentially resides in lipid rafts, suggesting that the glycosylation status may interfere with UT‐A1 lipid raft trafficking. This was confirmed by a site‐directed mutagenesis study in MDCK cells. The nonglycosylated UT‐A1 showed reduced localization in lipid rafts. By using sugar‐specific binding lectins, we further found that the UT‐A1 in nonlipid rafts contained a high amount of mannose, as detected by concanavalin A, while the UT‐A1 in lipid rafts was the mature N‐acetylglucosamine‐containing form, as detected by wheat germ agglutinin. In the inner medulla (IM) of diabetic rats, the more abundant 117‐kDa UT‐A1 in lipid rafts was the mature glycosylation form, with high amounts of N ‐acetylglucosamine and sialic acid. In contrast, in the IM of normal rats, the predominant 97‐kDa UT‐A1 was the form enriched in mannose. Functionally, inhibition of glycosylation by tunicamycin or elimination of the glycosylation sites by mutation significantly reduced UT‐A1 activity in oocytes. Taken together, our study reveals a new role of N‐linked glycosylation in regulating UT‐A1 activity by promoting UT‐A1 trafficking into membrane lipid raft subdomains.—Chen, G., Howe, A. G., Xu, G., Fröhlich, O., Klein, J. D., Sands, J. M. Mature N‐linked glycans facilitate UT‐A1 urea transporter lipid raft compartmentalization. FASEB J. 25, 4531–4539 (2011). www.fasebj.org

Caveolin-1 directly interacts with UT-A1 urea transporter: the role of caveolae/lipid rafts in UT-A1 regulation at the cell membrane.

The cell plasma membrane contains specialized microdomains called lipid rafts which contain high amounts of sphingolipids and cholesterol. Lipid rafts are involved in a number of membrane protein functions. The urea transporter UT-A1, located in the kidney inner medullary collecting duct (IMCD), is important for urine concentrating ability. In this study, we investigated the possible role of lipid rafts in UT-A1 membrane regulation. Using sucrose gradient cell fractionation, we demonstrated that UT-A1 is concentrated in the caveolae-rich fraction both in stably expressing UT-A1 HEK293 cells and in freshly isolated kidney IMCD suspensions. In these gradients, UT-A1 at the cell plasma membrane is codistributed with caveolin-1, a major component of caveolae. The colocalization of UT-A1 in lipid rafts/caveolae was further confirmed in isolated caveolae from UT-A1-HEK293 cells. The direct association of UT-A1 and caveolin-1 was identified by immunoprecipitation and GST pull-down assay. Examination of internalized UT-A1 in pEGFP-UT-A1 transfected HEK293 cells fluorescent overlap with labeled cholera toxin subunit B, a marker of the caveolae-mediated endocytosis pathway. Disruption of lipid rafts by methyl-beta-cyclodextrin or knocking down caveolin-1 by small-interference RNA resulted in UT-A1 cell membrane accumulation. Functionally, overexpression of caveolin-1 in oocytes decreased UT-A1 urea transport activity and UT-A1 cell surface expression. Our results indicate that lipid rafts/caveolae participate in UT-A1 membrane regulation and this effect is mediated via a direct interaction of caveolin-1 with UT-A1.

The UT-A1 Urea Transporter Interacts with Snapin, a SNARE-associated Protein

The UT-A1 urea transporter mediates rapid transepithelial urea transport across the inner medullary collecting duct and plays a major role in the urinary concentrating mechanism. To transport urea, UT-A1 must be present in the plasma membrane. The purpose of this study was to screen for UT-A1-interacting proteins and to study the interactions of one of the identified potential binding partners with UT-A1. Using a yeast two-hybrid screen of a human kidney cDNA library with the UT-A1 intracellular loop (residues 409–594) as bait, we identified snapin, a ubiquitously expressed SNARE-associated protein, as a novel UT-A1 binding partner. Deletion analysis indicated that the C-terminal coiled-coil domain (H2) of snapin is required for UT-A1 interaction. Snapin binds to the intracellular loop of UT-A1 but not to the N- or C-terminal fragments. Glutathione S-transferase pulldown experiments and co-immunoprecipitation studies verified that snapin interacts with native UT-A1, SNAP23, and syntaxin-4 (t-SNARE partners), indicating that UT-A1 participates with the SNARE machinery in rat kidney inner medulla. Confocal microscopic analysis of immunofluorescent UT-A1 and snapin showed co-localization in both the cytoplasm and in the plasma membrane. When we co-injected UT-A1 with snapin cRNA in Xenopus oocytes, urea influx was significantly increased. In the absence of snapin, the influx was decreased when UT-A1 was combined with t-SNARE components syntaxin-4 and SNAP23. We conclude that UT-A1 may be linked to the SNARE machinery via snapin and that this interaction may be functionally and physiologically important for urea transport.

Internalization of UT-A1 urea transporter is dynamin dependent and mediated by both caveolae- and clathrin-coated pit pathways

Dynamin is a large GTPase involved in several distinct modes of cell endocytosis. In this study, we examined the possible role of dynamin in UT-A1 internalization. The direct relationship of UT-A1 and dynamin was identified by coimmunoprecipitation. UT-A1 has cytosolic NH(2) and COOH termini and a large intracellular loop. Dynamin specifically binds to the intracellular loop of UT-A1, but not the NH(2) and COOH termini. In cell surface biotinylation experiments, coexpression of dynamin and UT-A1 in HEK293 cells resulted in a decrease of UT-A1 cell surface expression. Conversely, cells expressing dynamin mutant K44A, which is deficient in GTP binding, showed an increased accumulation of UT-A1 protein on the cell surface. Cell plasma membrane lipid raft fractionation experiments revealed that blocking endocytosis with dynamin K44A causes UT-A1 protein accumulation in both the lipid raft and nonlipid raft pools, suggesting that both caveolae- and clathrin-mediated mechanisms may be involved in the internalization of UT-A1. This was further supported by 1) small interfering RNA to knock down either caveolin-1 or μ2 reduced UT-A1 internalization in HEK293 cells and 2) inhibition of either the caveolae pathway by methyl-β-cyclodextrin or the clathrin pathway by concanavalin A caused UT-A1 cell membrane accumulation. Functionally, overexpression of dynamin, caveolin, or μ2 decreased UT-A1 urea transport activity and decreased UT-A1 cell surface expression. We conclude that UT-A1 endocytosis is dynamin-dependent and mediated by both caveolae- and clathrin-coated pit pathways.