K-Cl cotransporter expression in the human kidney

The K-Cl cotransporter protein KCC1 is a membrane transportprotein that mediates the coupled, electroneutral transport of K and Clacross plasma membranes. The precise cell type(s) in the kidney thatexpress the K-Cl cotransporter have remained unknown. The aim of thepresent investigation was to define the distribution of KCC1 mRNA inthe human kidney. We used in situ hybridization with a nonradioactivedigoxigenin-labeled riboprobe. We identified abundant KCC1 mRNAexpression in the epithelial cells throughout the distal and proximalrenal tubular epithelium. The transporter was also expressed inglomerular mesangial cells and endothelial cells of the renal vessels.These findings suggest that the K-Cl cotransporter may have animportant role in transepithelial K and Cl reabsorption.

     

Dendritic analysis of lobster stretch receptor neurons: Electrotonic properties with single and distributed inputs

Using steady-state cable analysis as derived by Rall, electrotonic properties of the dendritic trees of the tonic stretch receptor neuron of the spiny lobster, Panulirus interruptus,have been examined. By directly measuring the somatic input resistance and by visualizing the dendritic trees of this neuron by backfilling the axon with cobalt, the electrotonic properties of the dendritic trees have been derived. The calculated membrane resistivity is 800-3600 -cm ². Voltage and current transfer functions were calculated for (a) single dendritic tips the size observed in the cobalt preparations and (b) for processes 2 µm or smaller, as observed in electron microscopy. Current transfer to the soma was high in both cases (greater than 80%). Voltage transfer was 22% for large and 4% for small dendrites. When a more natural simultaneous conductance change at the tips of all major dendrites was modeled, voltage transfer was 84% and current transfer 56%. But the dynamic range of the cell (rheobase to saturation) is well-predicted by varying the simultaneous inputs, not by scaling up a single input, thus illustrating that convenient indices of electrotonic properties may not prove useful in appreciating the integrative properties of a neuron.     

Basolateral K-Cl cotransporter regulates colonic potassium absorption in potassium depletion

Active potassium absorption in the rat distal colon is electroneutral, Na(+)-independent, partially chloride-dependent, and energized by an apical membrane H,K-ATPase. Both dietary sodium and dietary potassium depletion substantially increase active potassium absorption. We have recently reported that sodium depletion up-regulates H,K-ATPase alpha-subunit mRNA and protein expression, whereas potassium depletion up-regulates H,K-ATPase beta-subunit mRNA and protein expression. Because overall potassium absorption is non-conductive, K-Cl cotransport (KCC) at the basolateral membrane may also be involved in potassium absorption. Although KCC1 has not been cloned from the colon, we established, in Northern blot analysis with mRNA from the rat distal colon using rabbit kidney KCC1 cDNA as a probe, the presence of an expected size mRNA in the rat colon. This KCC1 mRNA is substantially increased by potassium depletion but only minimally by sodium depletion. KCC1-specific antibody identified a 155-kDa protein in rat colonic basolateral membrane. Potassium depletion but not sodium depletion resulted in an increase in KCC1 protein expression in basolateral membrane. The increase of colonic KCC1 mRNA abundance and KCC1 protein expression in potassium depletion of the rat colonic basolateral membrane suggests that K-Cl cotransporter: 1) is involved in transepithelial potassium absorption and 2) regulates the increase in potassium absorption induced by dietary potassium depletion. We conclude that active potassium absorption in the rat distal colon involves the coordinated regulation of both apical membrane H,K-ATPase and basolateral membrane KCC1 protein.     

Functional interaction of the K-Cl cotransporter (KCC1) with the Na-K-Cl cotransporter in HEK-293 cells

We have studiedthe regulation of the K-Cl cotransporter KCC1 and its functionalinteraction with the Na-K-Cl cotransporter. K-Cl cotransporter activitywas substantially activated in HEK-293 cells overexpressing KCC1(KCC1-HEK) by hypotonic cell swelling, 50 mM external K, andpretreatment with N-ethylmaleimide(NEM). Bumetanide inhibited ⁸⁶Rbefflux in KCC1-HEK cells after cell swelling [inhibition constant (K_i) ~190µM] and pretreatment with NEM(K_i ~60 µM).Thus regulation of KCC1 is consistent with properties of the red cellK-Cl cotransporter. To investigate functional interactions between K-Cland Na-K-Cl cotransporters, we studied the relationship between Na-K-Clcotransporter activation and intracellular Cl concentration([Cl]_i). Without stimulation, KCC1-HEK cells had greater Na-K-Cl cotransporter activitythan controls. Endogenous Na-K-Cl cotransporter of KCC1-HEK cells wasactivated <2-fold by low-Cl hypotonic prestimulation, compared with10-fold activation in HEK-293 cells and >20-fold activation in cellsoverexpressing the Na-K-Cl cotransporter (NKCC1-HEK). KCC1-HEK cellshad lower resting[Cl]_i than HEK-293cells; cell volume was not different among cell lines. We found a steeprelationship between[Cl]_i and Na-K-Clcotransport activity within the physiological range, supporting aprimary role for [Cl]_iin activation of Na-K-Cl cotransport and in apical-basolateral crosstalk in ion-transporting epithelia.     

A novel N-terminal isoform of the neuron-specific K-Cl cotransporter KCC2

The neuronal K-Cl cotransporter KCC2 maintains the low intracellular chloride concentration required for the hyperpolarizing actions of inhibitory neurotransmitters gamma-aminobutyric acid and glycine in the central nervous system. This study shows that the mammalian KCC2 gene (alias Slc12a5) generates two neuron-specific isoforms by using alternative promoters and first exons. The novel KCC2a isoform differs from the only previously known KCC2 isoform (now termed KCC2b) by 40 unique N-terminal amino acid residues, including a putative Ste20-related proline alanine-rich kinase-binding site. Ribonuclease protection and quantitative PCR assays indicated that KCC2a contributes 20-50% of total KCC2 mRNA expression in the neonatal mouse brain stem and spinal cord. In contrast to the marked increase in KCC2b mRNA levels in the cortex during postnatal development, the overall expression of KCC2a remains relatively constant and makes up only 5-10% of total KCC2 mRNA in the mature cortex. A rubidium uptake assay in human embryonic kidney 293 cells showed that the KCC2a isoform mediates furosemide-sensitive ion transport activity comparable with that of KCC2b. Mice that lack both KCC2 isoforms die at birth due to severe motor defects, including disrupted respiratory rhythm, whereas mice with a targeted disruption of the first exon of KCC2b survive for up to 2 weeks but eventually die due to spontaneous seizures. We show that these mice lack KCC2b but retain KCC2a mRNA. Thus, distinct populations of neurons show a differential dependence on the expression of the two isoforms: KCC2a expression in the absence of KCC2b is presumably sufficient to support vital neuronal functions in the brain stem and spinal cord but not in the cortex.     

The neuron-specific K-Cl cotransporter, KCC2. Antibody development and initial characterization of the protein

The neuron-specific K-Cl cotransporter (KCC2) is hypothesized to function as an active Cl- extrusion pathway important in postsynaptic inhibition mediated by ligand-gated anion channels, like gamma-aminobutyric acid type A (GABAA) and glycine receptors. To understand better the functional role of KCC2 in the nervous system, we developed polyclonal antibodies to a KCC2 fusion protein and used these antibodies to characterize and localize KCC2 in the rat cerebellum. The antibodies specifically recognized the KCC2 protein which is an approximately 140-kDa glycoprotein detectable only within the central nervous system. The KCC2 protein displayed a robust and punctate distribution in primary cultured retinal amacrine cells known to form exclusively GABAAergic synapses in culture. In immunolocalization studies, KCC2 was absent from axons and glia but was highly expressed at neuronal somata and dendrites, indicating a specific postsynaptic distribution of the protein. In the granule cell layer, KCC2 exhibited a distinct colocalization with the beta2/beta3-subunits of the GABAA receptor at the plasma membrane of granule cell somata and at cerebellar glomeruli. KCC2 lightly labeled the plasma membrane of Purkinje cell somata. Within the molecular layer, KCC2 exhibited a distinctly punctate distribution along dendrites, indicating it may be highly localized at inhibitory synapses along these processes. The distinct postsynaptic localization of KCC2 and its colocalization with GABAA receptor in the cerebellum are consistent with the putative role of KCC2 in neuronal Cl- extrusion and postsynaptic inhibition.     

Influence of K-Cl cotransporter activity on activation of volume-sensitive Cl- channels in human osteoblasts

The whole cell recording mode of the patch-clamp technique was used to study the effect of hypotonic NaCl or isotonic high-KCl solution on membrane currents in a human osteoblast-like cell line, C1. Both hypotonic NaCl or isotonic high-KCl solution activated Cl^– channels expressed in these cells as described previously. The reversal potential of the induced Cl^– current is more negative when activated through hypotonic NaCl solution (–47 ± 5 mV; n = 6) compared with activation through isotonic high-KCl solution (–35 ± 3 mV; n = 8). This difference can be explained by an increase in intracellular [Cl^–] through the activity of a K-Cl cotransporter. Potassium aspartate was unable to activate the current, and furosemide or DIOA suppressed the increase in Cl^– current induced by isotonic high-KCl solution. In addition, we used the polymerase chain reaction to demonstrate the presence of KCC1–KCC4 mRNA in the osteoblast-like cell line. From these results, we conclude that human osteoblasts express functional K-Cl cotransporters in their cell membrane that seem to be able to induce the indirect activation of volume-sensitive Cl^– channels by KCl through an increase in the intracellular ion concentration followed by water influx and cell swelling. potasium-chloride cotransporter; KCC1–KCC4; chloride channels; extracellular potassium concentration buffering     

Effect of changes in respiratory blood parameters on equine red blood cell K-Cl cotransporter

K influx intoequine red blood cells (RBCs) was measured using⁸⁶Rb as a tracer for K underconditions designed to mimic the changes in respiratory bloodparameters that occur in vivo during strenuous exercise. The effects onK influx of physiological changes in pH, cell volume,O₂ tension(PO₂),CO₂ tension(PCO₂), and bicarbonate and lactateconcentrations were defined. Physiological PO₂ exerted a dominant controllinginfluence on the H⁺-stimulatedCl-dependent K influx, consistent with effects on the K-Clcotransporter; PO₂ required forhalf-maximal activity was 37 ± 3 mmHg (4.9 kPa). AlthoughRBCs were swollen at low pH, results showed explicitly that the volumechange per se had little effect on K influx. Lactate had no effect onvolume- or H⁺-stimulated Kinfluxes, nor did bicarbonate or PCO₂affect the magnitude of K influxes after these stimuli or aftertreatment with protein kinase/phosphatase inhibitors. These resultsrepresent the first detailed report ofO₂ dependence ofH⁺-stimulated K-Cl cotransport inRBCs from any mammalian species. They emphasize the importance ofPO₂ in control of RBC K-Clcotransport.

     

Functional characterization of the neuronal-specific K-Cl cotransporter: implications for [K+]o regulation

The neuronal K-Cl cotransporter isoform (KCC2) was functionallyexpressed in human embryonic kidney (HEK-293) cell lines. Two stablytransfected HEK-293 cell lines were prepared: one expressing anepitope-tagged KCC2 (KCC2-22T) and another expressing theunaltered KCC2 (KCC2-9). The KCC2-22T cells produced aglycoprotein of ~150 kDa that was absent from HEK-293 control cells.The ⁸⁶Rb influx in both cell lineswas significantly greater than untransfected control HEK-293 cells. TheKCC2-9 cells displayed a constitutively active⁸⁶Rb influx that could beincreased further by 1 mMN-ethylmaleimide (NEM) but not by cellswelling. Both furosemide [inhibition constant (K_i) ~25µM] and bumetanide (K_i~55 µM) inhibited the NEM-stimulated ⁸⁶Rb influx in the KCC2-9cells. This diuretic-sensitive⁸⁶Rb influx in theKCC2-9 cells, operationally defined as KCC2 mediated, required external Clbut not external Na⁺ and exhibiteda high apparent affinity for externalRb⁺(K⁺)[Michaelis constant(K_m) = 5.2 ± 0.9 (SE) mM; n = 5] but alow apparent affinity for externalCl(K_m >50 mM). Onthe basis of thermodynamic considerations as well as the unique kineticproperties of the KCC2 isoform, it is hypothesized that KCC2 may servea dual function in neurons: 1) themaintenance of low intracellularCl concentration so as toallow Cl influx vialigand-gated Cl channelsand 2) the buffering of externalK⁺ concentration([K⁺]_o) in the brain.

     

A dominant negative mutant of the KCC1 K-Cl cotransporter: both N- and C-terminal cytoplasmic domains are required for K-Cl cotransport activity

K-Cl cotransport regulates cell volume and chloride equilibrium potential. Inhibition of erythroid K-Cl cotransport has emerged as an important adjunct strategy for the treatment of sickle cell anemia. However, structure-function relationships among the polypeptide products of the four K-Cl cotransporter (KCC) genes are little understood. We have investigated the importance of the N- and C-terminal cytoplasmic domains of mouse KCC1 to its K-Cl cotransport function expressed in Xenopus oocytes. Truncation of as few as eight C-terminal amino acids (aa) abolished function despite continued polypeptide accumulation and surface expression. These C-terminal loss-of-function mutants lacked a dominant negative phenotype. Truncation of the N-terminal 46 aa diminished function. Removal of 89 or 117 aa (Delta(N)117) abolished function despite continued polypeptide accumulation and surface expression and exhibited dominant negative phenotypes that required the presence of the C-terminal cytoplasmic domain. The dominant negative loss-of-function mutant Delta(N)117 was co-immunoprecipitated with wild type KCC1 polypeptide, and its co-expression did not reduce wild type KCC1 at the oocyte surface. Delta(N)117 also exhibited dominant negative inhibition of human KCC1 and KCC3 and, with lower potency, mouse KCC4 and rat KCC2.     

Developmental regulation of the neuronal-specific isoform of K-Cl cotransporter KCC2 in postnatal rat brains.

We examined the expression of the KCC2 isoform of the K-Cl cotransporter in the developing and adult brain, using an affinity-purified antibody directed against a unique region of the KCC2 protein. Expression was shown to be limited to neurons at the cell bodies and cell processes in the hippocampus and cerebellum. Expression seemed to be the highest at the end of processes that originated from the CA1 pyramidal cells. Developmental up-regulation of KCC2 expression was demonstrated in the entire rat brain by Northern and Western blot analyses, and in the hippocampus by immunofluorescence. Level of KCC2 expression was minimal at birth and increased significantly during postnatal development. This pattern of expression was opposite to the one of the Na-K-2Cl cotransporter that is highly expressed in immature brain and decreases during development. The up-regulation of the K-Cl cotransporter expression is consistent with the developmental down-regulation of the intracellular Cl- concentration in neurons. The level of intracellular Cl-, in turn, determines the excitatory versus inhibitory response of the neurotransmitter gamma-aminobutyric acid in the immature versus mature brain. Finally, KCC2 expression was shown in dorsal root ganglion neurons, demonstrating that expression of the cotransporter is not strictly confined to central nervous system neurons.     

The role of an intracellular cysteine stretch in the sorting of the type II Na/phosphate cotransporter

The type II Na/phosphate cotransporters (NaPi-II) are critical for the control of plasma phosphate levels in vertebrates. NaPi-IIb mediates phosphate uptake from the small intestine followed by glomerular filtration and selective reabsorption from the renal proximal tubule by NaPi-IIa and NaPi-IIc. A C-terminal stretch of cysteine residues represents the hallmark of the NaPi-IIb isoforms. This motif is well conserved among NaPi-IIb type transporters but not found in other membrane proteins. To investigate the role of this motif we analyzed NaPi-II constructs in transiently and stably transfected MDCK cells. This cell line targets the NaPi-IIb isoforms from flounder and mouse to the apical membrane whereas the mouse IIa isoform shows no plasma membrane preference. Different parts of mouse NaPi-IIa and NaPi-IIb C-termini were fused to GFP-tagged flounder NaPi-II. The constructs showed strong staining of the plasma membrane with NaPi-IIb related constructs sorted predominantly apically, the IIa constructs localized apically and basolaterally with slight intracellular retention. When the cysteine stretch was inserted into the NaPi-IIa C-terminus, the construct was retained in a cytoplasmic compartment. 2-bromopalmitate, a specific palmitoylation inhibitor, released the transporter to apical and basolateral membranes. The drug also leads to a redistribution of the NaPi-IIb construct to both plasma membrane compartments. Immunoprecipitation of tagged NaPi-II constructs from [(3)H]-palmitate labeled MDCK cells indicated that the cysteine stretch is palmitoylated. Our results suggest that the modified cysteine motif prevents the constructs from basolateral sorting. Additional sorting determinants located downstream of the cysteine stretch may release the cargo to the apical compartment.     

The role of an intracellular cysteine stretch in the sorting of the type II Na/phosphate cotransporter

The type II Na/phosphate cotransporters (NaPi-II) are critical for the control of plasma phosphate levels in vertebrates. NaPi-IIb mediates phosphate uptake from the small intestine followed by glomerular filtration and selective reabsorption from the renal proximal tubule by NaPi-IIa and NaPi-IIc. A C-terminal stretch of cysteine residues represents the hallmark of the NaPi-IIb isoforms. This motif is well conserved among NaPi-IIb type transporters but not found in other membrane proteins. To investigate the role of this motif we analyzed NaPi-II constructs in transiently and stably transfected MDCK cells. This cell line targets the NaPi-IIb isoforms from flounder and mouse to the apical membrane whereas the mouse IIa isoform shows no plasma membrane preference. Different parts of mouse NaPi-IIa and NaPi-IIb C-termini were fused to GFP-tagged flounder NaPi-II. The constructs showed strong staining of the plasma membrane with NaPi-IIb related constructs sorted predominantly apically, the IIa constructs localized apically and basolaterally with slight intracellular retention. When the cysteine stretch was inserted into the NaPi-IIa C-terminus, the construct was retained in a cytoplasmic compartment. 2-bromopalmitate, a specific palmitoylation inhibitor, released the transporter to apical and basolateral membranes. The drug also leads to a redistribution of the NaPi-IIb construct to both plasma membrane compartments. Immunoprecipitation of tagged NaPi-II constructs from [³H]-palmitate labeled MDCK cells indicated that the cysteine stretch is palmitoylated. Our results suggest that the modified cysteine motif prevents the constructs from basolateral sorting. Additional sorting determinants located downstream of the cysteine stretch may release the cargo to the apical compartment.     

The spatial organization of the cytoskeleton in crayfish stretch receptor.

An electron microscopic study of the cytoskeleton of the crayfish stretch receptor was carried out. Longitudinal sections of the sensory neuron axons and dendrites showed wave-like arrays of microtubules with a period of about 5 microns. Transverse sections showed that the microtubules displayed no regularity in the arrays. In oblique sections, transverse and longitudinal views of microtubules (or shorter and longer segments of microtubules) alternated yielding a festoon-like pattern. The data obtained indicate that the cytoskeleton of the stretch receptor has a helical structure in which all the microtubules, the major cytoskeletal components, are arranged in parallel helices that are in register along the length of axons and dendrites. The helical organization of the cytoskeleton is probably responsible for the banded appearance of sensory axons and primary dendrites as seen in the polarized light. Decrease of contrast and disappearance of the banding during stretch of the receptor muscle are supposedly due to the desynchronization of the helical trajectories of the microtubules and to the decrease of the helical amplitude.     

The NH2-terminus of K-Cl cotransporter 3a is essential for up-regulation of Na,K-ATPase activity

K⁺-Cl⁻ cotransporter-3 has two major amino terminal variants, KCC3a and KCC3b. In LLC-PK1 cells, exogenously expressed KCC3a co-immunoprecipitated with endogenous Na⁺,K⁺-ATPase α1-subunit (α1NaK), accompanying significant increases of the Na⁺,K⁺-ATPase activity. Exogenously expressed KCC3b did not co-immunoprecipitate with endogenous α1NaK inducing no change of the Na⁺,K⁺-ATPase activity. A KCC inhibitor attenuated the Na⁺,K⁺-ATPase activity in rat gastric mucosa in which KCC3a is predominantly expressed, while it had no effects on the Na⁺,K⁺-ATPase activity in rat kidney in which KCC3b is predominantly expressed. In these tissue samples, KCC3a co-immunoprecipitated with α1NaK, while KCC3b did not. Our results suggest that the NH₂-terminus of KCC3a is a key region for association with α1NaK, and that KCC3a but not KCC3b can regulate the Na⁺,K⁺-ATPase activity.