Helle A. Praetorius

Removal of the MDCK Cell Primary Cilium Abolishes Flow Sensing

The hypothesis that cell primary cilium is solely responsible for the flow-induced Ca2+ response in MDCK cells was tested by removal of the cilia from mature, responsive cells. Incubation of the cells with 4 mM chloral hydrate for 68 hours resulted in the complete loss of the primary cilia and in disorganization of microtubules, as visualized by immunofluorescence. When intracellular Ca2+ concentration was measured with Fluo-4, the elevation that normally accompanies an increase in fluid flow was abolished after 20 hours exposure to chloral hydrate. At this time, the primary cilia still remained attached to the cells but had become twisted and flexible. Twentyfour hours after return of the deciliated cells to normal medium, intracellular microtubule organization appeared normal, but primary cilia had not yet been expressed. The cells failed to increase intracellular Ca2+ in response to fluid flow until after they had been in normal medium for 120 hours, at which time the primary cilia were 3–4 mm long. Chloral hydrate did not impair the Ca2+ mobilization machinery, as the Ca2+ response to mechanical contact and the spread to neighboring cells was unaffected by the drug. We conclude that the primary cilium is the only sensor for the flow-induced Ca2+ response in MDCK cells and estimate that a single mechanically sensitive channel in the cilium could provide the requisite Ca2+ influx.

ATP release from non-excitable cells

All cells release nucleotides and are in one way or another involved in local autocrine and paracrine regulation of organ function via stimulation of purinergic receptors. Significant technical advances have been made in recent years to quantify more precisely resting and stimulated adenosine triphosphate (ATP) concentrations in close proximity to the plasma membrane. These technical advances are reviewed here. However, the mechanisms by which cells release ATP continue to be enigmatic. The current state of knowledge on different suggested mechanisms is also reviewed. Current evidence suggests that two separate regulated modes of ATP release co-exist in non-excitable cells: (1) a conductive pore which in several systems has been found to be the channel pannexin 1 and (2) vesicular release. Modes of stimulation of ATP release are reviewed and indicate that both subtle mechanical stimulation and agonist-triggered release play pivotal roles. The mechano-sensor for ATP release is not yet defined.

Bending the primary cilium opens Ca2+-sensitive intermediate-conductance K+ channels in MDCK cells

Increasing tubular fluid flow rate has previously been shown to induce K+ secretion in mammalian cortical collecting duct. The mechanism responsible was examined in the present study using MDCK cells as a model. The change in membrane potential difference (EM) of MDCK cells was measured with a fluorescent voltage-sensitive dye, DiBAC4(3), when the cells primary cilium was continuously bent with a micropipette or by the flow of perfusate. Bending the cilium produced a hyperpolarization of the membrane that lagged behind the increase in intracellular Ca2+ concentration by an average of 36 seconds. Gd3+ , an inhibitor of the flow-induced Ca2+ increase, prevented the hyperpolarization. Blocking K+ channels with Ba2+ reduced the flow-induced hyperpolarization, implying that it resulted from activation of Ca2+-sensitive K+ channels. Further studies demonstrated that the hyperpolarization was diminished by the blocker of Ca2+-activated K+ channels, charybdotoxin, whereas iberiotoxin or apamin had no effect, results consistent with the activation of intermediate-conductance Ca2+-sensitive K+ channels. RT-PCR analysis and sequencing confirmed the presence of intermediate-conductance K+ channels in MDCK cells. We conclude that the increase in intracellular Ca2+ associated with bending of the primary cilium is the cause of the hyperpolarization and increased K+ conductance in MDCK cells.

Flow-induced [Ca2+]i increase depends on nucleotide release and subsequent purinergic signaling in the intact nephron

Flow induces cytosolic Ca(2+) increases ([Ca(2+)](i)) in intact renal tubules, but the mechanism is elusive. Mechanical stimulation in general is known to promote release of nucleotides (ATP/UTP) and trigger auto- and paracrine activation of P2 receptors in renal epithelia. It was hypothesized that the flow-induced [Ca(2+)](i) response in the renal tubule involves mechanically stimulated nucleotide release. This study investigated (1) the expression of P2 receptors in mouse medullary thick ascending limb (mTAL) using P2Y(2) receptor knockout (KO) mice, (2) whether flow increases induce [Ca(2+)](i) elevations in mTAL, and (3) whether this flow response is affected in mice that are deplete of the main purinergic receptor. [Ca(2+)](i) was imaged in perfused mTAL with fura-2 or fluo-4. It is shown that luminal and basolateral P2Y(2) receptors are the main purinergic receptor in this segment. Moreover, the data suggest presence of basolateral P2X receptors. Increases of tubular flow were imposed by promptly rising the inflow pressure, which triggered a marked increase of [Ca(2+)](i). This [Ca(2+)](i) response was significantly reduced in P2Y(2) receptor KO tubules (fura-2 ratio increase WT 0.44 +/- 0.09 [n = 28] versus KO 0.16 +/- 0.04 [n = 13]). Furthermore, the flow response was greatly inhibited with luminal and basolateral scavenging of extracellular ATP (apyrase 7.5 U/ml) or blockage of P2 receptors (suramin 300 microM). The flow response could still be elicited in the absence of extracellular Ca(2+). These results strongly suggest that increase of tubular flow elevates [Ca(2+)](i) in intact renal epithelia. This flow response is caused by release of bilateral nucleotides and subsequent activation of P2 receptors.

α-Hemolysin from Escherichia coli uses endogenous amplification through P2X receptor activation to induce hemolysis

Escherichia coli is the dominant facultative bacterium in the normal intestinal flora. E. coli is, however, also responsible for the majority of serious extraintestinal infections. There are distinct serotypical differences between facultative and invasive E. coli strains. Invasive strains frequently produce virulence factors such as α-hemolysin (HlyA), which causes hemolysis by forming pores in the erythrocyte membrane. The present study reveals that this pore formation triggers purinergic receptor activation to mediate the full hemolytic action. Non-selective ATP-receptor (P2) antagonists (PPADS, suramin) and ATP scavengers (apyrase, hexokinase) concentration dependently inhibited HlyA-induced lysis of equine, murine, and human erythrocytes. The pattern of responsiveness to more selective P2-antagonists implies that both P2X1 and P2X7 receptors are involved in HlyA-induced hemolysis in all three species. In addition, our results also propose a role for the pore protein pannexin1 in HlyA-induced hemolysis, as non-selective inhibitors of this channel significantly reduced hemolysis in the three species. In conclusion, activation of P2X receptors and possibly also pannexins augment hemolysis induced by the bacterial toxin, HlyA. These findings potentially have clinical perspectives as P2 antagonists may ameliorate symptoms during sepsis with hemolytic bacteria.

Intrarenal Purinergic Signaling in the Control of Renal Tubular Transport

Renal tubular epithelial cells receive hormonal input that regulates volume and electrolyte homeostasis. In addition, numerous intrarenal, local signaling agonists have appeared on the stage of renal physiology. One such system is that of intrarenal purinergic signaling. This system involves all the elements necessary for agonist-mediated intercellular communication. ATP is released from epithelial cells, which activates P2 receptors in the apical and basolateral membrane and thereby modulates tubular transport. Termination of the signal is conducted via the breakdown of ATP to adenosine. Recent far-reaching advances indicate that ATP is often used as a local transmitter for classical sensory transduction. This transmission apparently also applies to sensory functions in the kidney. Locally released ATP is involved in sensing of renal tubular flow or in detecting the distal tubular load of NaCl at the macula densa. This review describes the relevant aspects of local, intrarenal purinergic signaling and outlines its integrative concepts.

Vasopressin-independent targeting of aquaporin-2 by selective E-prostanoid receptor agonists alleviates nephrogenic diabetes insipidus

In the kidney, the actions of vasopressin on its type-2 receptor (V2R) induce increased water reabsorption alongside polyphosphorylation and membrane targeting of the water channel aquaporin-2 (AQP2). Loss-of-function mutations in the V2R cause X-linked nephrogenic diabetes insipidus. Treatment of this condition would require bypassing the V2R to increase AQP2 membrane targeting, but currently no specific pharmacological therapy is available. The present study examined specific E-prostanoid receptors for this purpose. In vitro, prostaglandin E2 (PGE2) and selective agonists for the E-prostanoid receptors EP2 (butaprost) or EP4 (CAY10580) all increased trafficking and ser-264 phosphorylation of AQP2 in Madin-Darby canine kidney cells. Only PGE2 and butaprost increased cAMP and ser-269 phosphorylation of AQP2. Ex vivo, PGE2, butaprost, or CAY10580 increased AQP2 phosphorylation in isolated cortical tubules, whereas PGE2 and butaprost selectively increased AQP2 membrane accumulation in kidney slices. In vivo, a V2R antagonist caused a severe urinary concentrating defect in rats, which was greatly alleviated by treatment with butaprost. In conclusion, EP2 and EP4 agonists increase AQP2 phosphorylation and trafficking, likely through different signaling pathways. Furthermore, EP2 selective agonists can partially compensate for a nonfunctional V2R, providing a rationale for new treatment strategies for hereditary nephrogenic diabetes insipidus.

Colonic potassium handling

Homeostatic control of plasma K+ is a necessary physiological function. The daily dietary K+ intake of ~100 mmol is excreted predominantly by the distal tubules of the kidney. About 10% of the ingested K+ is excreted via the intestine. K+ handling in both organs is specifically regulated by hormones and adapts readily to changes in dietary K+ intake, aldosterone and multiple local paracrine agonists. In chronic renal insufficiency, colonic K+ secretion is greatly enhanced and becomes an important accessory K+ excretory pathway. During severe diarrheal diseases of different causes, intestinal K+ losses caused by activated ion secretion may become life threatening. This topical review provides an update of the molecular mechanisms and the regulation of mammalian colonic K+ absorption and secretion. It is motivated by recent results, which have identified the K+ secretory ion channel in the apical membrane of distal colonic enterocytes. The directed focus therefore covers the role of the apical Ca2+ and cAMP-activated BK channel (KCa1.1) as the apparently only secretory K+ channel in the distal colon.

Aldosterone increases KCa1.1 (BK) channel-mediated colonic K+ secretion

Mammalian K+ homeostasis results from highly regulated renal and intestinal absorption and secretion, which balances the unregulated K+ intake. Aldosterone is known to enhance both renal and colonic K+ secretion. In mouse distal colon K+ secretion occurs exclusively via luminal KCa1.1 (BK) channels. Here we investigate if aldosterone stimulates colonic K+ secretion via BK channels. Luminal Ba2+ and iberiotoxin (IBTX)‐sensitive electrogenic K+ secretion was measured in Ussing chambers. In vivo aldosterone was augmented via a high K+ diet. High K+ diet led to a 2‐fold increase of luminal Ba2+ and IBTX‐sensitive short‐circuit current in distal mouse colonic mucosa. This effect was absent in BK α‐subunit‐deficient (BK−/−) mice. The resting and diet‐induced K+ secretion was stimulated by luminal ionomycin. In BK−/− mice luminal ionomycin did not stimulate K+ secretion. In vitro addition of aldosterone likewise triggered a 2‐fold increase in K+ secretion, which was inhibited by the mineralocorticoid receptor antagonist spironolactone and the BK channel blocker IBTX. Semi‐quantification of mRNA from colonic crypts showed up‐regulation of BK α‐ and β2‐subunits in high K+ diet mice. The BK channel could be detected luminally in colonic crypt cells by immunohistochemistry. The expression level of the channel in the luminal membrane was strongly up‐regulated in K+‐loaded animals. Taken together, these data strongly suggest that aldosterone‐induced K+ secretion occurs via increased expression of luminal BK channels.

Released nucleotides amplify the cilium-dependent, flow-induced [Ca2+]i response in MDCK cells.

Aim:  Changes in perfusate flow produce increases in [Ca2+]i in renal epithelial cells. Cultured renal epithelia require primary cilia to sense subtle changes in flow. In perfused kidney tubules this flow response is caused by nucleotide signalling via P2Y2 receptors. It is, however, not known whether nucleotides are released by mechanical stress applied to renal primary cilia. Here we investigate whether nucleotides are released during the cilium‐dependent flow response and contribute to the flow‐induced, cilium‐dependent [Ca2+]i signal.