Voltage-dependent metabolic regulation of Kv2.1 channels in pancreatic β-cells

Voltage-gated potassium channels (Kv channels) play a crucial role in formation of action potentials in response to glucose stimulation in pancreatic β-ells. We previously reported that the Kv channel is regulated by glucose metabolism, particularly by MgATP. We examined whether the regulation of Kv channels is voltage-dependent and mechanistically related with phosphorylation of the channels. In rat pancreatic β-cells, suppression of glucose metabolism with low glucose concentrations of 2.8 mM or less or by metabolic inhibitors decreased the Kv2.1-channel activity at positive membrane potentials, while increased it at potentials negative to −10 mV, suggesting that modulation of Kv channels by glucose metabolism is voltage-dependent. Similarly, in HEK293 cells expressing the recombinant Kv2.1 channels, 0 mM but not 10 mM MgATP modulated the channel activity in a manner similar to that in β-cells. Both steady-state activation and inactivation kinetics of the channel were shifted toward the negative potential in association with the voltage-dependent modulation of the channels by cytosolic dialysis of alkaline phosphatase in β-cells. The modulation of Kv-channel current-voltage relations were also observed during and after glucose-stimulated electrical excitation. These results suggest that the cellular metabolism including MgATP production and/or channel phosphorylation/dephosphorylation underlie the physiological modulation of Kv2.1 channels during glucose-induced insulin secretion.     

Mechanism for antioxidative effects of thiazolidinediones in pancreatic β-cells

Thiazolidinediones (TZDs) are synthetic ligands of peroxisome proliferator-activated receptor-γ (PPARγ), a member of the nuclear receptor superfamily. TZDs are known to increase insulin sensitivity and also to have an antioxidative effect. In this study, we tested whether TZDs protect pancreatic β-cells from oxidative stress, and we investigated the mechanism involved in this process. To generate oxidative stress in pancreatic β-cells (INS-1 and βTC3) or isolated islets, glucose oxidase was added to the media. The extracellular and intracellular reactive oxygen species (ROS) were measured to directly determine the antioxidant effect of TZDs. The phosphorylation of JNK/MAPK after oxidative stress was detected by Western blot analysis, and glucose-stimulated insulin secretion and cell viability were also measured. TZDs significantly reduced the ROS levels that were increased by glucose oxidase, and they effectively prevented β-cell dysfunction. The antioxidative effect of TZDs was abolished in the presence of a PPARγ antagonist, GW9662. Real-time PCR was used to investigate the expression levels of antioxidant genes. The expression of catalase, an antioxidant enzyme, was increased by TZDs in pancreatic β-cells, and the knockdown of catalase significantly inhibited the antioxidant effect of TZDs. These results suggest that TZDs effectively protect pancreatic β-cells from oxidative stress, and this effect is dependent largely on PPARγ. In addition, the expression of catalase is increased by TZDs, and catalase, at least in part, mediates the antioxidant effect of TZDs in pancreatic β-cells.     

Two sites for adenine-nucleotide regulation of ATP-sensitive potassium channels in mouse pancreatic β-cells and HIT cells

Summary ATP-inhibited potassium channels (K(ATP)) were studied in excised, inside-out patches from cultured adult mouse pancreatic -cells and HIT cells. In the absence of ATP, ADP opened K(ATP) channels at concentrations as low as 10 m and as high as 500 m, with maximal activation between 10 and 100 m ADP in mouse -cell membrane patches. At concentrations greater than 500 m, ADP inhibited K(ATP) channels while 10 mm virtually abolished channel activity. HIT cell channels had a similar biphasic response to ADP except that more than 1 mm ADP was required for inhibition. The channel opening effect of ADP required magnesium while channel inhibition did not. Using creatine/creatine phosphate solutions with creatine phosphokinase to fix ATP and ADP concentrations, we found substantially different K(ATP)-channel activity with solutions having the same ATP/ADP ratio but different absolute total nucleotide levels. To account for ATP-ADP competition, we propose a new model of channel-nucleotide interactions with two kinds of ADP binding sites regulating the channel. One site specifically binds MgADP and increases channel opening. The other, the previously described ATP site, binds either ATP or ADP and decreases channel opening. This model very closely fits the ADP concentration-response curve and, when incorporated into a model of -cell membrane potential, increasing ADP in the 10 and 100 m range is predicted to compete very effectively with millimolar levels of ATP to hyperpolarize -cells.The results suggest that (i) K(ATP)-channel activity is not well predicted by the ATP/ADP ratio, and (ii) ADP is a plausible regulator of K(ATP) channels even if its free cytoplasmic concentration is in the 10–100 m range as suggested by biochemical studies.We would like to thank Mr. Louis Stamps for expert technical assistance and Dr. Wil Fujimoto and Ms. Jeanette Teague for generously providing HIT cells obtained from Dr. Robert Santerre at Eli Lilly. We would also like to thank Dr. Michel Vivaudou for providing the program ALEX. Support was provided by the NIH and the Department of Veterans Affairs.     

Effect of alogliptin, pioglitazone and glargine on pancreatic β-cells in diabetic db/db mice

Objective: Progressive β-cell dysfunction and loss of β-cell mass are fundamental pathogenic features of type 2 diabetes. To examine if anti-diabetic reagents, such as insulin, pioglitazone (pio), and alogliptin (alo), have protective effects on β-cell mass and function in vivo, we treated obese diabetic db/db mice with these reagents. Methods: Male db/db mice were treated with a chow including pio, alo, or both of them from 8 to 16 weeks of age. Insulin glargine (gla) was daily injected subcutaneously during the same period. Results: At 16 weeks of age, untreated db/db mice revealed marked increase of HbA1c level, whereas those treated with pio, pio + alo, or insulin revealed the almost same HbA1c levels as non-diabetic db/m mice. Islet mass evaluated by direct counting in the whole pancreas and insulin content in isolated islets were preserved in pio, pio + alo and gla groups compared with untreated or alo groups, and there was no difference among pio, pio + alo and gla groups. To precisely evaluate islet β-cell functions, islet perifusion analysis was performed. In pio, pio + alo and gla groups, biphasic insulin secretion was preserved compared with untreated or alo groups. In particular, pio + alo as well as gla therapy preserved almost normal insulin secretion, although pio therapy improved partially. To examine the mechanism how these reagents exerted beneficial effects on β-cells, we evaluated expression levels of various factors which are potentially important for β-cell functions by real-time RT-PCR and immunohistochemistry. The results showed that expression levels of MafA and GLP-1 receptor were markedly decreased in untreated and alo groups, but not in pio, pio + alo and gla groups. Conclusion: Combination therapy with pio and alo almost completely normalized β-cell functions in vivo, which was comparable with gla treatment.     

Ion channels underlying stimulus-exocytosis coupling and its cell-to-cell heterogeneity in β-cells of transplantable porcine islets of Langerhans

Given the growing interest in porcine islets as model tissue for studying the pathogenesis of human diabetes mellitus and its treatment by transplantation, we investigated stimulus-exocytosis coupling in single porcine β-cells using patch clamp electrophysiology, Ca²⁺ imaging, capacitance tracking and amperometry. We establish that porcine β-cells display several features prominently seen in β-cells from human islets of Langerhans. These include: (i) wide heterogeneity of electrical responsiveness to glucose; (ii) dependence of action potential activity on voltage-dependent Na⁺ as well as high voltage activated Ca²⁺ current; (iii) heterogeneity of time course of depolarization-evoked insulin granule exocytosis; and (iv) the dependence of vigorous single cell electrical activity and insulin granule exocytosis on the presence of agents that enhance cytosolic cAMP concentration. These findings promote the usefulness of porcine β-cells as a model for studying β-cell function in large mammals, including humans, as well as an appropriate source of tissue for xenotransplantation.     

SLC30A family expression in the pancreatic islets of humans and mice: cellular localization in the β-cells

Zinc is a vital co-factor for insulin metabolism in the pancreatic β-cell, involved in synthesis, maturation, and crystallization. Two families of zinc transporters, namely SLC30A (ZNT) and SLC39A (ZIP) are involved in maintaining cellular zinc homeostasis in mammalian cells. Single nuclear polymorphisms or mutations in zinc transporters have been associated with insulin resistance and risk of type 2 diabetes (T2D) in both humans and mice. Thus, mice can be useful for studying the underlying mechanisms of zinc-associated risk of T2D development. To determine potential differences in zinc transporter expression and cellular localization in the pancreatic β-cells between humans and mice, we examined all members (ZNT1-10) of the ZNT family in pancreatic islets and in β-cell lines derived from both species using immunohistochemistry and immunofluorescence microscopic analysis. We found that there were no substantial differences in the expression of nine ZNT proteins in the human and mouse islets and β-cells with exception of ZNT3, which was only detected in human β-cells, but not in mouse β-cells. Moreover, we found that ZNT2 was localized on the cell surface of both human and mouse β-cells, suggesting a role of ZNT2 in direct export of zinc out of the β-cell. Together, our study suggests functional conservations of the ZNT proteins between humans and mice. We believe that our results are of interest for future studies in the association of zinc metabolism with risk of T2D in humans using mouse models.     

Direct evidence for opposite effects of D-glucose and D-glyceraldehyde on cytoplasmic pH of mouse pancreatic β-cells

The effects of D-glucose, D-glyceraldehyde, glibenclamide, D-600, NH ₄ ⁺ and high concentrations of K⁺ on cytoplasmic pH (pH _i ) were investigated in dispersed and cultured pancreatic -cells fromob/ob mice. The cytoplasmic pH was measured with the fluorescent H⁺-indicator quene 1. The average pH _i value in resting -cells was 6.71. Addition of 20 mM of the physiological stimulus D-glucose increased pH _i with 0.05 units. Both glibenclamide and high concentrations of K⁺ decreased pH _i . The latter effects were completely reversed by D-600, supporting the notion that free cytoplasmic Ca²⁺ can be involved in the regulation of pH _i . In contrast to D-glucose, 10mM of D-glyceraldehyde decreased pH _i by 0.09 units, an effect persisting even in the presence of D-600. From the present study it is evident that D-glyceraldehyde and D-glucose have opposite effects on pH _i in pancreatic -cells.     

Evidence for the presence of β-lactamase inStreptomyces glaucescens and its inhibition by sodium clavulanate

Streptomyces glaucescens is shown to possess -lactamase activity which is inhibitable by clavulanate. This is important in regard to its use as a cloning host for enzymes of \-lactam biosynthesis.     

Protein kinase C (PKC) activity regulates functional effects of Kvβ1.3 subunit on KV1.5 channels: identification of a cardiac Kv1.5 channelosome

K(v)1.5 channels are the primary channels contributing to the ultrarapid outward potassium current (I(Kur)). The regulatory K(v)β1.3 subunit converts K(v)1.5 channels from delayed rectifiers with a modest degree of slow inactivation to channels with both fast and slow inactivation components. Previous studies have shown that inhibition of PKC with calphostin C abolishes the fast inactivation induced by K(v)β1.3. In this study, we investigated the mechanisms underlying this phenomenon using electrophysiological, biochemical, and confocal microscopy approaches. To achieve this, we used HEK293 cells (which lack K(v)β subunits) transiently cotransfected with K(v)1.5+K(v)β1.3 and also rat ventricular and atrial tissue to study native α-β subunit interactions. Immunocytochemistry assays demonstrated that these channel subunits colocalize in control conditions and after calphostin C treatment. Moreover, coimmunoprecipitation studies showed that K(v)1.5 and K(v)β1.3 remain associated after PKC inhibition. After knocking down all PKC isoforms by siRNA or inhibiting PKC with calphostin C, K(v)β1.3-induced fast inactivation at +60 mV was abolished. However, depolarization to +100 mV revealed K(v)β1.3-induced inactivation, indicating that PKC inhibition causes a dramatic positive shift of the inactivation curve. Our results demonstrate that calphostin C-mediated abolishment of fast inactivation is not due to the dissociation of K(v)1.5 and K(v)β1.3. Finally, immunoprecipitation and immunocytochemistry experiments revealed an association between K(v)1.5, K(v)β1.3, the receptor for activated C kinase (RACK1), PKCβI, PKCβII, and PKCθ in HEK293 cells. A very similar K(v)1.5 channelosome was found in rat ventricular tissue but not in atrial tissue.     

Insight into the modulation of Shaw2 Kv channels by general anesthetics: Structural and functional studies of S4–S5 linker and S6 C-terminal peptides in micelles by NMR

The modulation of the Drosophila Shaw2 Kv channel by 1-alkanols and inhaled anesthetics is correlated with the involvement of the S4–S5 linker and C-terminus of S6, and consistent with stabilization of the channel's closed state. Structural analysis of peptides from S4–S5 (L45) and S6 (S6c), by nuclear magnetic resonance and circular dichroism spectroscopy supports that an α-helical conformation was adopted by L45, while S6c was only in an unstable/dynamic partially folded α-helix in dodecylphosphocholine micelles. Solvent accessibility and paramagnetic probing of L45 revealed that L45 lies parallel to the surface of micelles with charged and polar residues pointing towards the solution while hydrophobic residues are buried inside the micelles. Chemical shift perturbation introduced by 1-butanol on residues Gln320, Thr321, Phe322 and Arg323 of L45, as well as Thr423 and Gln424 of S6c indicates possible anesthetic binding sites on these two important components in the channel activation apparatus. Diffusion measurements confirmed the association of L45, S6c and 1-butanol with micelles which suggests the capability of 1-butanol to influence a possible interaction of L45 and S6c in the micelle environment.     

The effect of ATP-sensitive K+ channels on the electrical burst activity and insulin secretion in pancreatic β-cells

In recent years, the electrical burst activity of the insulin releasing pancreatic β-cells has attracted many experimentalists and theoreticians, largely because of its functional importance, but also because of the nonlinear nature of the burst activity. The ATP-sensitive K⁺ channels are believed to play an important role in electrical activity and insulin release. In this paper, we show by computer simulation how ATP and antidiabetic drugs can lengthen the plateau fraction of bursting and how these chemicals can increase the intracellular Ca²⁺ level in the pancreatic β-cell.     

Expression of embryonic hemoglobin genes in mice heterozygous for α-thalassemia or β-duplication traits and in mice heterozygous for both traits

Hemoglobins of mouse embryos at 11.5 through 16.5 days of gestation were separated by electrophoresis on cellulose acetate and quantitated by a scanning densitometer to study the effects of two radiation-induced mutations on the expression of embryonic hemoglobin genes in mice. Normal mice produce three kinds of embryonic hemoglobins. In heterozygous α-thalassemic embryos, expression of EI (x₂y₂) and EII (α₂y₂) is deficient because the x- and α-globin genes of one of the allelic pairs of Hba on chromosome 11 was deleted or otherwise inactivated by X irradiation. Simultaneous inactivation of the x- and α-globin genes indicates that these genes must be closely linked. Reduced x- and α-chain synthesis results in an excess of y chains that associate as homotetramers. This unique y₄ hemoglobin also appears in β-duplication embryos where excess y chains are produced by the presence of three rather than two functional alleles of y- and β-globin genes. In double heterozygotes, which have a single functional allele of x- and α-globin genes and three functional alleles of y- and β-globin genes, synthesis of α and non-α chains is severely imbalanced and half of the total hemoglobin is y₄. Mouse y₄ has a high affinity for oxygen, P₅₀ of less than 10 mm Hg, but it lacks cooperativity so is inefficient for oxygen transport. The death of double heterozygotes in late fetal or neonatal life may be due in large part to oxygen deprivation to the tissues.     

UCHL1 deficiency exacerbates human islet amyloid polypeptide toxicity in β-cells: Evidence of interplay between the ubiquitin/proteasome system and autophagy

The islet in type 2 diabetes mellitus (T2DM) is characterized by a deficit in β-cells and increased β-cell apoptosis attributable at least in part to intracellular toxic oligomers of IAPP (islet amyloid polypeptide). β-cells of individuals with T2DM are also characterized by accumulation of polyubiquitinated proteins and deficiency in the deubiquitinating enzyme UCHL1 (ubiquitin carboxyl-terminal esterase L1 [ubiquitin thiolesterase]), accounting for a dysfunctional ubiquitin/proteasome system. In the present study, we used mouse genetics to elucidate in vivo whether a partial deficit in UCHL1 enhances the vulnerability of β-cells to human-IAPP (hIAPP) toxicity, and thus accelerates diabetes onset. We further investigated whether a genetically induced deficit in UCHL1 function in β-cells exacerbates hIAPP-induced alteration of the autophagy pathway in vivo. We report that a deficit in UCHL1 accelerated the onset of diabetes in hIAPP transgenic mice, due to a decrease in β-cell mass caused by increased β-cell apoptosis. We report that UCHL1 dysfunction aggravated the hIAPP-induced defect in the autophagy/lysosomal pathway, illustrated by the marked accumulation of autophagosomes and cytoplasmic inclusions positive for SQSTM1/p62 and polyubiquitinated proteins with lysine 63-specific ubiquitin chains. Collectively, this study shows that defective UCHL1 function may be an early contributor to vulnerability of pancreatic β-cells for protein misfolding and proteotoxicity, hallmark defects in islets of T2DM. Also, given that deficiency in UCHL1 exacerbated the defective autophagy/lysosomal degradation characteristic of hIAPP proteotoxicity, we demonstrate a previously unrecognized role of UCHL1 in the function of the autophagy/lysosomal pathway in β-cells.     

Further Evidence for the Formation in vivo of Phosphopeptide in the Intestinal Lumen from Dietary β-Casein

The occurrence of a new brassinosteroid of (22S,24R)-3β,22-dihydroxy-5α-ergostan-6-one, named cathasterone, was demonstrated by a GC-MS analysis in cultured cells of Catharanthus roseus. Its endogenous level was in the range of 2–4 ng/g fw, similar to those of brassinolide and castasterone. A feeding experiment with a deuterium-labeled substrate revealed that cathasterone was converted to teasterone and typhasterol. This is the first report of the natural occurrence of cathasterone as a brassinosteroid being the biosynthetic precursor of teasterone.     

Involvement of L-type calcium channels and mitochondria in post-tetanic potentiation: Is it a general rule for different types of synapses?

Our experiments and studies of a few other authors demonstrated that L-type calcium channels and mitochondria are involved in the induction of post-tetanic potentiation (PTP) in a number of preparations (Aplysia central nervous system, hippocampal cell cultures, crayfish neuromuscular junctions, etc.). We extend this conclusion on cortical synapses by the demonstration that inhibitors of mitochondrial Ca²⁺ uptake and release suppress PTP in rat neocortical cell cultures. Neirofiziologiya/Neurophysiology, Vol. 39, Nos. 4/5, pp. 403–404, July–October, 2007.