Whole-cell conductive properties of rat pancreatic acini

Upregulation of α-ENaC induces pancreatic β-cell dysfunction, ER stress, and SIRT2 degradation

Islet beta cells (β-cells) produce insulin in response to high blood glucose levels, which is essential for preserving glucose homeostasis. Voltage-gated ion channels in β-cells, including Na +, K +, and Ca 2+ channels, aid in the release of insulin. The epithelial sodium channel alpha subunit (α-ENaC), a voltage-independent sodium ion channel, is also expressed in human pancreatic endocrine cells. However, there is no reported study on the function of ENaC in the β-cells. In the current study, we found that α-ENaC was expressed in human pancreatic glandule and pancreatic islet β-cells. In the pancreas of db/db mice and high-fat diet-induced mice, and in mouse islet β-cells (MIN6 cells) treated with palmitate, α-ENaC expression was increased. When α-ENaC was overexpressed in MIN6 cells, insulin content and glucose-induced insulin secretion were significantly reduced. On the other hand, palmitate injured islet β-cells and suppressed insulin synthesis and secretion, but increased α-ENaC expression in MIN6 cells. However, α-ENaC knockout ( Scnn1a -/-) in MIN6 cells attenuated β-cell disorder induced by palmitate. Furthermore, α-ENaC regulated the ubiquitylation and degradation of sirtuin 2 in β-cells. α-ENaC also modulated β-cell function in correlation with the inositol-requiring enzyme 1 alpha/X-box binding protein 1 (IRE1α/XBP1) and protein kinase RNA-like endoplasmic reticulum kinase/C/EBP homologous protein (PERK/CHOP) endoplasmic reticulum stress pathways. These results suggest that α-ENaC may play a novel role in insulin synthesis and secretion in the β-cells, and the upregulation of α-ENaC promotes islet β-cell dysfunction. In conclusion, α-ENaC may be a key regulator involved in islet β-cell damage and a potential therapeutic target for type 2 diabetes mellitus.

Physiology and pathophysiology of potassium channels in gastrointestinal epithelia

Epithelial cells of the gastrointestinal tract are an important barrier between the "milieu interne" and the luminal content of the gut. They perform transport of nutrients, salts, and water, which is essential for the maintenance of body homeostasis. In these epithelia, a variety of K(+) channels are expressed, allowing adaptation to different needs. This review provides an overview of the current literature that has led to a better understanding of the multifaceted function of gastrointestinal K(+) channels, thereby shedding light on pathophysiological implications of impaired channel function. For instance, in gastric mucosa, K(+) channel function is a prerequisite for acid secretion of parietal cells. In epithelial cells of small intestine, K(+) channels provide the driving force for electrogenic transport processes across the plasma membrane, and they are involved in cell volume regulation. Fine tuning of salt and water transport and of K(+) homeostasis occurs in colonic epithelia cells, where K(+) channels are involved in secretory and reabsorptive processes. Furthermore, there is growing evidence for changes in epithelial K(+) channel expression during cell proliferation, differentiation, apoptosis, and, under pathological conditions, carcinogenesis. In the future, integrative approaches using functional and postgenomic/proteomic techniques will help us to gain comprehensive insights into the role of K(+) channels of the gastrointestinal tract.

Voltage-dependent Changes of TRPV6-mediated Ca2+ Currents

The physiological role and activation mechanism for most proteins of the transient receptor potential (TRP) family are unknown. This is also the case for the highly Ca(2+) selective transient receptor potential vanilloid type 6 (TRPV6) channel. Patch clamp experiments were performed on transiently transfected human embryonic kidney (HEK) cells to address this issue. Currents were recorded under various conditions of intracellular Ca(2+) buffering and monitored at the same voltage throughout. No TRPV6-mediated Ca(2+) entry was detected under in vivo Ca(2+) buffering conditions at a slightly negative holding potential; however, moderate depolarization resulted in current activation. Very similar results were obtained with different Ca(2+) chelators, either EGTA or BAPTA dialyzing the cell. TRPV6 channel activity showed a negative correlation with the intracellular free Ca(2+) concentration ([Ca(2+)](i)) and was modulated by the membrane potential: Hyperpolarization decreases and depolarization increases TRPV6-mediated currents. Monovalent ions permeated TRPV6 channels in the absence of extracellular divalent cations. These currents were resistant to changes in the holding potential while the negative correlation to the [Ca(2+)](i) was conserved, indicating that the voltage-dependent current changes depend on blocking and unblocking the charge carrier Ca(2+) within the pore. In summary, these results suggest that the voltage dependence of TRPV6-mediated Ca(2+) influx is of physiological importance since it occurs at cytosolic Ca(2+) buffering and takes place within a physiologically relevant membrane potential range.

Effects of KCNQ1 channel blocker, 293B, on the acetylcholine-induced Cl- secretion of rat pancreatic acini

In rat pancreatic acini (RPAs), acetylcholine (ACh) typically induces a tonic depolarization of membrane potential (Vm) via increasing cytoplasmic Ca2+ concentration and subsequent activation of Cl- channels. In this study, to investigate the role of K+ channels during the ACh-induced Cl- secretion, the intracellular Cl- concentration ([Cl-]i) of RPAs was monitored using SPQ, a fluorescent dye quenchable by Cl-, and the effects of K+ channel blockers were examined. Also, the secretion of fluid and enzyme from the whole pancreas of rat was measured. The fluorescence of RPAs loaded with SPQ (FSPQ) was slightly increased by the application of ACh (ACh-Delta FSPQ), indicating net secretion of Cl-. However, the relative change of FSPQ normalized to the control fluorescence (F/F0) of RPAs was only about 20% of the effect observed in rat submandibular gland acinus. The ACh-Delta FSPQ of RPAs was not influenced by the pretreatment with 293B (20 micromol/L), a blocker of KCNQ-type K+ channels. Even the cocktail of K+ channel blockers (10 mmol/L TEA, 3 mmol/L Ba2+, 20 micromol/L 293B) exerted only minute inhibitory effects on ACh-Delta FSPQ in RPAs. In the vascularly perfused rat pancreas, the fluid and enzyme secretion induced by ACh was directly measured. 293B and HMR-1556, both specific blockers of KCNQ1 channel, did not block but even enhanced the secretion of fluid and amylase. These results suggest that the role of KCNQ1 channels may not be essential in the Ca2+-mediated Cl- secretion in rat pancreatic acini.

Where have all the Na+ channels gone? In search of functional ENaC in exocrine pancreas

Many epithelia express specific Na(+) channels (ENaC) together with the cystic fibrosis regulator (CFTR) Cl(-) channels. Pancreatic ducts secrete HCO(3)(-)-rich fluid and express CFTR. However, the question whether they possess ENaC has not been consistently addressed. The aim of the present study was to investigate if pancreatic ducts express functional ENaC. Membrane voltages (V) of ducts isolated from rat pancreas were measured with microelectrodes or whole-cell patch-clamp technique. Amiloride and benzamil given from bath or luminal sides did not hyperpolarize V. Lowering of extracellular Na(+) concentrations had effects that were not consistent with a simple Na(+) conductance, but rather with a Na(+)/Ca(2+) exchange. Acute or long-lasting treatment of pancreatic ducts with mineralocorticoids had no effect on V of unstimulated or secretin-stimulated preparations. Furthermore, pre-treatment of animals with glucocorticoids had no effect on pancreatic fluid secretion evoked from ducts, or from acini. Hence, our study shows that pancreas especially pancreatic ducts do not express functional ENaC.

Polarized calcium and calmodulin signaling in secretory epithelia

This review examines polarized calcium and calmodulin signaling in exocrine epithelial cells. The calcium ion is a simple, evolutionarily ancient, and universal second messenger. In exocrine epithelial cells, it regulates essential functions such as exocytosis, fluid secretion, and gene expression. Exocrine cells are structurally polarized, with the apical region usually dedicated to secretion. Recent advances in technology, in particular the development of videoimaging and confocal microscopy, have led to the discovery of polarized, subcellular calcium signals in these cell types. The properties of a rich variety of local and global calcium signals have now been described in secretory epithelial cells. Secretagogues stimulate apical-to-basal waves of calcium in many exocrine cell types, but there are some interesting exceptions to this rule. The shapes of intracellular calcium signals are determined by the distribution of calcium-releasing channels and mechanisms that limit calcium elevation. Polarized distribution of calcium-handling mechanisms also leads to transcellular calcium transport in exocrine epithelial cells. This transport can deliver considerable amounts of calcium into secreted fluids. Multicellular polarized calcium signals can coordinate the activity of many individual cells in epithelial secretory tissue. Certain particularly sensitive cells serve as pacemakers for initiation of intercellular calcium waves. Many calcium signaling pathways involve activation of calmodulin. This ubiquitous protein regulates secretion in exocrine cells and also activates interesting feedback interactions with calcium channels and transporters. Very recently it became possible to directly study polarized calcium-calmodulin reactions and to visualize the process of hormone-induced redistribution of calmodulin in live cells. The structural and functional polarity of secretory epithelia alongside the polarity of its calcium and calmodulin signaling present an interesting lesson in tissue organization.

Local uncaging of caged Ca(2+) reveals distribution of Ca(2+)-activated Cl(-) channels in pancreatic acinar cells

In exocrine acinar cells, Ca(2+)-activated Cl(-) channels in the apical membrane are essential for fluid secretion, but it is unclear whether such channels are important for Cl(-) uptake at the base. Whole-cell current recording, combined with local uncaging of caged Ca(2+), was used to reveal the Cl(-) channel distribution in mouse pancreatic acinar cells, where approximately 90% of the current activated by Ca(2+) in response to acetylcholine was carried by Cl(-). When caged Ca(2+) in the cytosol was uncaged locally in the apical pole, the Cl(-) current was activated, whereas local Ca(2+) uncaging in the basal or lateral areas of the cell had no effect. Even when Ca(2+) was uncaged along the whole inner surface of the basolateral membrane, no Cl(-) current was elicited. There was little current deactivation at a high cytosolic Ca(2+) concentration ([Ca(2+)](c)), but at a low [Ca(2+)](c) there was clear voltage-dependent deactivation, which increased with hyperpolarization. Functional Ca(2+)-activated Cl(-) channels are expressed exclusively in the apical membrane and channel opening is strictly regulated by [Ca(2+)](c) and membrane potential. Ca(2+)-activated Cl(-) channels do not mediate Cl(-) uptake at the base, but acetylcholine-elicited local [Ca(2+)](c) spiking in the apical pole can regulate fluid secretion by controlling the opening of these channels in the apical membrane.

Regulation of slowly activating potassium current (I(Ks)) by secretin in rat pancreatic acinar cells

1. The secretagogue-activated K(+) conductance is indispensable for the electrogenic Cl(-) secretion in exocrine tissue. In this study, we investigated the effect of secretin and other cAMP-mediated secretagogues on the slowly activating voltage-dependent K(+) current (I(Ks)) of rat pancreatic acinar cells (RPAs) with the whole-cell patch clamp technique. 2. Upon depolarization, RPAs showed I(Ks) superimposed upon the instantaneous background outward current. Secretin (5 nM), vasoactive intestinal peptide (5 nM), forskolin (5 microM), isoprenaline (10 microM) or 3-isobutyl-1-methylxanthine (IBMX, 0.1 mM) increased the amplitude of I(Ks) two- to fourfold. 3. The physiological concentration of secretin (50 pM) had a relatively weak effect on I(Ks) (160 % increase), which was significantly enhanced by transient co-stimulation with carbachol (CCh) (10 microM). However, the secretin-induced production of cAMP, which was measured by enzyme-linked immunosorbent assay, was not augmented by co-stimulation with CCh. 4. This study is the first to demonstrate the regulation of K(+) channels in RPAs by cAMP-mediated agonists. The I(Ks) channel is a common target for both Ca(2+) and cAMP agonists. The vagal stimulation under the physiological concentration of secretin facilitates I(Ks), which provides an additional driving force for Cl(-) secretion.

TWIK-2, a new weak inward rectifying member of the tandem pore domain potassium channel family

Potassium channels are found in all mammalian cell types, and they perform many distinct functions in both excitable and non-excitable cells. These functions are subserved by several different families of potassium channels distinguishable by primary sequence features as well as by physiological characteristics. Of these families, the tandem pore domain potassium channels are a new and distinct class, primarily distinguished by the presence of two pore-forming domains within a single polypeptide chain. We have cloned a new member of this family, TWIK-2, from a human brain cDNA library. Primary sequence analysis of TWIK-2 shows that it is most closely related to TWIK-1, especially in the pore-forming domains. Northern blot analysis reveals the expression of TWIK-2 in all human tissues assayed except skeletal muscle. Human TWIK-2 expressed heterologously in Xenopus oocytes is a non-inactivating weak inward rectifier with channel properties similar to TWIK-1. Pharmacologically, TWIK-2 channels are distinct from TWIK-1 channels in their response to quinidine, quinine, and barium. TWIK-2 is inhibited by intracellular, but not extracellular, acidification. This new clone reveals the existence of a subfamily in the tandem pore domain potassium channel family with weak inward rectification properties.

Inwardly rectifying, voltage-dependent and resting potassium currents in rat pancreatic acinar cells in primary culture

1. In exocrine pancreatic acinar cells in primary culture an inwardly rectifying, a voltage-dependent and a permanent resting K+ current were characterized. 2. Inwardly rectifying K+ currents could be elicited by elevation of the extracellular K+ concentration. The K+ inward currents were almost completely blocked by 5 mM Ba2+, whereas 10 mM TEA+ had only a partial effect. 3. Depolarizing voltage steps from negative clamp potentials evoked transient activation of a voltage-dependent K+ current. This voltage-dependent current could be blocked by 10 mM TEA+ and 1 mM 4-aminopyridine, but not by 5 mM Ba2+. 4. Neither the K+ inward rectifier nor the voltage-dependent K+ conductance produced a significant negative cell potential. Stable membrane potentials (-38.7 +/- 2.3 mV, n = 38) could only be recorded on cell clusters (> or = 5 cells). 5. Cell clusters, in contrast to single cells, had a permanent resting K+ conductance in addition to the inward rectifier and the voltage-dependent current. This resting K+ conductance was not blocked by TEA+, Ba2+, 4-aminopyridine or by the chromanol 293B. 6. Cytosolic alkalization by addition of NH4Cl to the bath solution decreased the resting K+ current. In parallel, electrical uncoupling of the cells and breakdown of the resting potential could be observed. The same effects could be produced when the cells were uncoupled by 0.2-1.0 mM n-octanol. It can be concluded that cell coupling is essential for maintenance of stable resting membrane potentials in pancreatic acinar cells.

The membrane transporters regulating epithelial NaCl secretion

Ten years ago, the basic principles operating in one specific, albeit non-mammalian, exocrine gland, the rectal gland of Squalus acanthias, were described in detail. The concept emerging from these studies appeared applicable to almost any other exocrine gland, because it involved membrane transporters which are also present in mammalian epithelial cells. Meanwhile, it has become clear that the mechanisms of NaCl secretion are diverse: the mechanisms of NaCl uptake; the ion channels involved; and also the mechanisms of hormonal control. Nevertheless, several steps in NaCl secretion still appear to be uniform: (1) several signalling pathways converge and act cooperatively, (2) one primary regulatory step is the upregulation of the luminal Cl- conductance, (3) secondarily active NaCl uptake mechanisms are upregulated, (4) increasing evidence links NaCl secretion to membrane trafficking and (5) the entire machinery seems to be primed to secure cellular homeostasis in terms of cytosolic ion concentrations. This brief review summarizes the mechanisms of control of NaCl secretion. The major issues addressed are the NaCl uptake mechanisms, the ion channels involved and the cellular mechanisms coordinating secretion. The major NaCl secreting cells discussed here will be the respiratory epithelial cells, the exocrine cells of pancreatic acini and the cells of colonic crypts.