Peter Bergsten

Glucose-Induced Amplitude Regulation of Pulsatile Insulin Secretion From Individual Pancreatic Islets

The insulin secretory response to glucose was studied in single pancreatic islets isolated from ob/ob mice and rats. The perfusate from an individual islet was collected during 18-s periods and analyzed for insulin with an ELISA technique. Increase of the glucose concentration from 3 to ≥ 5.5 mM resulted in pulses of insulin release often originating from the basal level and having a frequency of 0.4/min. Glucose regulation of insulin release from the individual islet was manifested by alterations of the amplitudes of the pulses but not of their frequency. It is concluded that the large amplitude oscillations of cytoplasmic Ca2+ known to occur in the pancreatic β-cells have their counterpart in pulses of insulin release and that glucose stimulation of the secretory activity may be the result of recruitment of more β-cells into an oscillatory state.

GLUCOSE INDUCES OSCILLATORY CA2+ SIGNALLING AND INSULIN RELEASE IN HUMAN PANCREATIC BETA CELLS

SummaryMechanisms of pulsatile insulin release in man were explored by studying the induction of oscillatory Ca2+ signals in individual beta cells and islets isolated from the human pancreas. Evidence was provided for a glucose-induced closure of ATP-regulated K+ channels, resulting in voltage-dependent entry of Ca2+. The observation of step-wise increases of capacitance in response to depolarizing pulses suggests that an enhanced influx of Ca2+ is an effective means of stimulating the secretory activity of the isolated human beta cell. Activation of muscarinic receptors (1–10 μmol/l carbachol) and of purinergic P2 receptors (0.01–1 μmol/l ATP) resulted in repetitive transients followed by sustained elevation of the cytoplasmic Ca2+ concentration ([Ca2+]i). Periodic mobilisation of intracellular calcium was seen also when injecting 100 μmol/l GTP-γ-S into beta cells hyperpolarized to −70 mV. Individual beta cells responded to glucose and tolbutamide with increases of [Ca2+]i, manifested either as large amplitude oscillations (frequency 0.1–0.5/min) or as a sustained elevation. Glucose regulation was based on sudden transitions between the basal and the two alternative states of raised [Ca2+]i at threshold concentrations of the sugar characteristic for the individual beta cells. The oscillatory characteristics of coupled cells were determined collectively rather than by particular pacemaker cells. In intact pancreatic islets the glucose induction of well-synchronized [Ca2+]i oscillations had its counterpart in 2–5 min pulses of insulin. Each of these pulses could be resolved into regularly occurring short insulin transients. It is concluded that glucose stimulation of insulin release in man is determined by the number of beta cells entering into a state with Ca2+-induced secretory pulses.

Pathophysiology of impaired pulsatile insulin release

Plasma insulin displays 5–10 min oscillations. In Type 2 diabetes the regularity of the oscillations disappears, which may lead to insulin receptor down‐regulation and glucose intolerance and explain why pulsatile delivery of the hormone has a greater hypoglycemic effect than continuous delivery. The rhythm is intrinsic to the islet. Variations in metabolism, cytoplasmic Ca2+ concentration ([Ca2+]i), other hormones, neuronal signaling and possibly β‐cell insulin receptor expression have been implicated in the regulation of plasma insulin oscillations. Most of these factors are important for amplitude‐regulation of the insulin pulses. Although evidence exists supporting a role of both metabolism and [Ca2+]i as pacemakers of the pulses, metabolic oscillations probably have a primary role and [Ca2+]i oscillations a permissive role. Results from islets from animal models of diabetes suggest that altered plasma insulin pattern could be due to lowering of pulse amplitude of insulin oscillations rather than alterations in their frequency. Supporting a role of metabolism, altered plasma insulin oscillations were found in MODY2, MIDD and glycogenosis Type VII, which are linked to alterations in glucokinase, mitochondrial tRNALeu(UUR) and phosphofructokinase. Plasma insulin oscillations require coordination of islet secretory activities in the pancreas. The intrapancreatic ganglia have been suggested as coordinators. The diabetes‐associated neuropathy may contribute to the deranged pattern as indicated by glucose intolerance in chagasic patients. Continued investigation of the role and regulation of pulsatile insulin release will lead to better understanding of the pathophysiology of impaired pulsatile insulin release, which could lead to new approaches to restore normal plasma insulin oscillations in diabetes and related diseases. Copyright

The use of proteomics in identifying differentially expressed serum proteins in humans with type 2 diabetes

BackgroundThe aim of the study was to optimize protocols for finding and identifying serum proteins that are differentially expressed in persons with normal glucose tolerance (NGT) compared to individuals with type 2 diabetes mellitus (T2DM).Serum from persons with NGT and persons with T2DM was profiled using ProteinChip arrays and time-of-flight mass spectra were generated by surface enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF MS).ResultsMass spectra from NGT- and T2DM-groups were compared. Fifteen proteins ranging from 5 to 79 kDa were differentially expressed (p < 0.05). Five of these proteins showed decreased and ten showed increased serum levels in individuals with T2DM. To be able to identify the proteins, the complexity of the sample was reduced by fractionation approaches. Subsequently, the purified fractions containing biomarkers were separated by one-dimensional SDS-polyacrylamide gel electrophoresis (SDS-PAGE) in two identical lanes. Protein bands of the first lane were excised and subjected to passive elution to recapture the biomarkers on ProteinChip arrays. The corresponding bands of the second lane were subjected to peptide-mass fingerprinting (PMF). Using this approach four of the differentially expressed proteins were identified as apolipoprotein C3 (9.4 kDa), transthyretin (13.9 kDa), albumin (66 kDa) and transferrin (79 kDa). Whereas apolipoprotein C3 and transthyretin were up-regulated, albumin and transferrin were down-regulated in T2DM.ConclusionProtocols for protein profiling by SELDI-TOF MS and protein identification by fractionation, SDS-PAGE and PMF were optimized for serum from humans with T2DM. With these protocols differentially expressed proteins were discovered and identified when serum from NGT- and T2DM-individuals was analyzed.

FFAR1 Is Involved in Both the Acute and Chronic Effects of Palmitate on Insulin Secretion

Free fatty acids (FFAs) have pleiotropic effects on the pancreatic β-cell. Although acute exposure to FFAs stimulates glucose-stimulated insulin secretion (GSIS), prolonged exposure impairs GSIS and causes apoptosis. FFAs exert their effects both via intracellular metabolism and interaction with the FFA receptor 1 (FFAR1/GPR40). Here we studied the role of FFAR1 in acute and long-term effects of palmitate on GSIS and insulin content in isolated human islets by using the FFAR1 agonist TAK-875 and the antagonist ANT203. Acute palmitate exposure potentiated GSIS approximately 3-fold, whereas addition of the antagonist decreased this potentiation to approximately 2-fold. In the absence of palmitate, the agonist caused a 40% increase in GSIS. Treatment with palmitate for 7 days decreased GSIS to 70% and insulin content to 25% of control level. These negative effects of long-term exposure to palmitate were ameliorated by FFAR1 inhibition and further aggravated by additional stimulation of the receptor. In the absence of extracellularly applied palmitate, long-term treatment with the agonist caused a modest increase in GSIS. The protective effect of FFAR1 inhibition was verified by using FFAR1-deficient MIN6 cells. Improved β-cell function by the antagonist was paralleled by the decreased apoptosis and lowered oxidation of palmitate, which may represent the potential mechanisms of protection. We conclude that FFAR1 in the pancreatic β-cell plays a substantial role not only in acute potentiation of GSIS by palmitate but also in the negative long-term effects of palmitate on GSIS and insulin content.

Diazoxide-induced β-cell rest reduces endoplasmic reticulum stress in lipotoxic β-cells

Elevated levels of glucose and lipids are characteristics of individuals with type 2 diabetes mellitus (T2DM). The enhanced nutrient levels have been connected with deterioration of beta-cell function and impaired insulin secretion observed in these individuals. A strategy to improve beta-cell function in individuals with T2DM has been intermittent administration of K(ATP) channel openers. After such treatment, both the magnitude and kinetics of insulin secretion are markedly improved. In an attempt to further delineate mechanisms of how openers of K(ATP) channels improve beta-cell function, the effects of diazoxide on markers of endoplasmic reticulum (ER) stress was determined in beta-cells exposed to the fatty acid palmitate. The eukaryotic translation factor 2-alpha kinase 3 (EIF2AK3; also known as PERK) and endoplasmic reticulum to nucleus signaling 1 (ERN1; also known as IRE1) pathways, but not the activating transcription factor (ATF6) pathway of the unfolded protein response, are activated in such lipotoxic beta-cells. Inclusion of diazoxide during culture attenuated activation of the EIF2AK3 pathway but not the ERN1 pathway. This attenuation was associated with reduced levels of DNA-damage inducible transcript 3 (DDIT3; also known as CHOP) and beta-cell apoptosis was decreased. It is concluded that reduction of ER stress may be a mechanism by which diazoxide improves beta-cell function.

Oscillations in oxygen tension and insulin release of individual pancreatic ob/ob mouse islets.

Aims/hypothesis. The role of beta-cell metabolism for generation of oscillatory insulin release was investigated by simultaneous measurements of oxygen tension (pO2) and insulin release from individual islets of Langerhans.¶Methods. Individual islets isolated from the ob/ob-mice were perifused. Insulin in the perifusate was measured with a sensitive ELISA and pO2 with a modified Clark-type electrode inserted into the islets.¶Results. In the presence of 3 mmol/l d-glucose, pO2 was 102 ± 9 mmHg and oscillatory (0.26 ± 0.04 oscillations/min). Corresponding insulin measurements showed oscillatory release with similar periodicity (0.25 ± 0.02 oscillations/min). When the d-glucose concentration was increased to 11 mmol/l, pO2 decreased by 30 % to 72 ± 10 mmHg with maintained frequency of the oscillations. Corresponding insulin secretory rate rose from 5 ± 2 to 131 ± 16 pmol · g–1· s–1 leaving the frequency of the insulin pulses unaffected. The magnitude of glucose-induced change in pO2 varied between islets but was positively correlated to the amount of insulin released (r2 = 0.85). When 1 mmol/l tolbutamide was added to the perifusion medium containing 11 mmol/l glucose no change in average oscillatory pO2 was observed despite a doubling in the secretory rate. When 8 mmol/l 3-oxymethyl glucose was added to perifusion medium containing 3 mmol/l d-glucose, neither pO2 nor insulin release of the islets were changed. Temporal analysis of oscillations in pO2 and insulin release revealed that maximum respiration correlated to maximum or close to maximum insulin release.¶Conclusion/interpretation. The temporal relation between oscillations in pO2 and insulin release supports a role for metabolic oscillations in the generation of pulsatile insulin release. [Diabetologia (2000) 43: 1313–1318]

Fatty acid-induced oxidation and triglyceride formation is higher in insulin-producing MIN6 cells exposed to oleate compared to palmitate

Palmitate negatively affects insulin secretion and apoptosis in the pancreatic β‐cell. The detrimental effects are abolished by elongating and desaturating the fatty acid into oleate. To investigate mechanisms of how the two fatty acids differently affect β‐cell function and apoptosis, lipid handling was determined in MIN6 cells cultured in the presence of the fatty acids palmitate (16:0) and oleate (18:1) and also corresponding monounsaturated fatty acid palmitoleate (16:1) and saturated fatty acid stearate (18:0). Insulin secretion was impaired and apoptosis accentuated in palmitate‐, and to some extent, stearate‐treated cells. Small or no changes in secretion or apoptosis were observed in cells exposed to palmitoleate or oleate. Expressions of genes associated with fatty acid esterification (SCD1, DGAT1, DGAT2, and FAS) were augmented in cells exposed to palmitate or stearate but only partially (DGAT2) in palmitoleate‐ or oleate‐treated cells. Nevertheless, levels of triglycerides were highest in cells exposed to oleate. Similarly, fatty acid oxidation was most pronounced in oleate‐treated cells despite comparable up‐regulation of CPT1 after treatment of cells with the four different fatty acids. The difference in apoptosis between palmitate and stearate was paralleled by similar differences in levels of markers of endoplasmic reticulum (ER) stress in cells exposed to the two fatty acids. Palmitate‐induced ER stress was not accounted for by ceramide de novo synthesis. In conclusion, although palmitate initiated stronger expression changes consistent with lipid accumulation and combustion in MIN6 cells, rise in triglyceride levels and fatty acid oxidation was favored specifically in cells exposed to oleate. J. Cell. Biochem. 111: 497–507, 2010.

Pulsatile insulin release from pancreatic islets with nonoscillatory elevation of cytoplasmic Ca2

The relationship between insulin release and cytoplasmic Ca2+ concentration ([Ca2+]i) was studied in isolated pancreatic islets from ob/ob mice. Although [Ca2+]i was low and stable in the presence of 3 mM glucose, basal insulin release exhibited low amplitude pulsatility, with a frequency of 0.32 +/- 0.04 min-1. Depolarization by raising K+ from 5.9 to 30.9 mM or by the addition of 1 mM tolbutamide caused a pronounced initial insulin pulse followed by declining pulses, but there was no change in frequency. This decline in amplitude of the insulin pulses was prevented in similar experiments performed in the presence of 11 mM glucose. Corresponding measurements of [Ca2+]i in islets exposed to tolbutamide or the high K+ concentration revealed stable elevations without oscillations. Although the [Ca2+]i level is an important determinant for the rate of secretion, the results indicate that pulsatile insulin release does not always depend on [Ca2+]i oscillations. It is suggested that cyclic generation of ATP may fuel pulsatile release under conditions when [Ca2+]i remains stable.

Pulsatile insulin release from mouse islets occurs in the absence of stimulated entry of Ca2

Pancreatic islets are known to respond to a raise of the glucose concentration with Ca2+ -induced 2-3-min pulses of insulin release. The reports of cyclic variations of circulating insulin in the fasting state made it important to explore whether insulin release is also pulsatile in the absence of stimulated entry of Ca2+. Individual pancreatic islets were isolated from a local colony of ob/ob mice and perifused under conditions allowing dual wavelength recordings of the cytoplasmic Ca2+ concentration ([Ca2+]i) with fura-2 and measurements of insulin with ELISA technique. At 3 mM of glucose, [Ca2+]i remained at a stable low level, but insulin was released in pulses with a frequency of 0.41+/-0.02 min-1, determined by Fourier transformation of original and autocorrelated data. Pulses of basal insulin release were also seen when glucose was omitted and 1 microM clonidine or 400 microM diazoxide was added to a glucose-free medium. The results indicate that pulsatile insulin release can be generated in the absence of stimulated entry of Ca2+. A tentative explanation for this phenomenon is inherent fluctuations in the ATP production of the beta cells.