Glucose-induced oscillations in cytoplasmic free Ca2+ concentration precede oscillations in mitochondrial membrane potential in the pancreatic beta-cell

Using dual excitation and fixed emission fluorescence microscopy, we were able to measure changes in cytoplasmic free Ca(2+) concentration ([Ca(2+)](i)) and mitochondrial membrane potential simultaneously in the pancreatic beta-cell. The beta-cells were exposed to a combination of the Ca(2+) indicator fura-2/AM and the indicator of mitochondrial membrane potential, rhodamine 123 (Rh123). Using simultaneous measurements of mitochondrial membrane potential and [Ca(2+)](i) during glucose stimulation, it was possible to measure the time lag between the onset of mitochondrial hyperpolarization and changes in [Ca(2+)](i). Glucose-induced oscillations in [Ca(2+)](i) were followed by transient depolarizations of mitochondrial membrane potential. These results are compatible with a model in which nadirs in [Ca(2+)](i) oscillations are generated by a transient, Ca(2+)-induced inhibition of mitochondrial metabolism resulting in a temporary fall in the cytoplasmic ATP/ADP ratio, opening of plasma membrane K(ATP) channels, repolarization of the plasma membrane, and thus transient closure of voltage-gated L-type Ca(2+) channels.

Beliefs, knowledge and attitudes as predictors of sunbathing habits and use of sun protection among Swedish adolescents

In 1996, a random population sample of 2615 adolescents completed a questionnaire concerning habitual sun-related behaviours, attitudes towards sunbathing, and knowledge about skin cancer. Females, older adolescents, those with less sun-sensitive skin, those with higher knowledge and those with a positive attitude towards sunbathing were more likely to be frequent sunbathers. Younger adolescents, those who today sunbathe moderately, and those with sensitive skin were more likely to believe that they would sunbathe more often in the future. Males, adolescents with less sensitive skin, those with a positive attitude towards sunbathing and those sunbathing often, were less likely to use protection when sunbathing. Interventions to decrease sun exposure among adolescents should focus on changing attitudes toward sunbathing and having a tan, since knowledge of skin cancer and the damaging affect of sunbathing did not seem to effect current sunbathing habits, or use of sun protection.

The imidazoline RX871024 stimulates insulin secretion in pancreatic beta-cells from mice deficient in K(ATP) channel function

Effects of the imidazoline compound RX871024 on cytosolic free Ca(2+) concentration ([Ca(2+)]i) and insulin secretion in pancreatic beta-cells from SUR1 deficient mice have been studied. In beta-cells from wild-type mice RX871024 increased [Ca(2+)]i by blocking ATP-dependent K(+)-current (K(ATP)) and inducing membrane depolarization. In beta-cells lacking a component of the K(ATP)-channel, SUR1 subunit, RX871024 failed to increase [Ca(2+)]i. However, insulin secretion in these cells was strongly stimulated by the imidazoline. Thus, a major component of the insulinotropic activity of RX871024 is stimulation of insulin exocytosis independently from changes in K(ATP)-current and [Ca(2+)]i. This means that effects of RX871024 on insulin exocytosis are partly mediated by interaction with proteins distinct from those composing the K(ATP)-channel.

Syntaxin 1 interacts with the L(D) subtype of voltage-gated Ca(2+) channels in pancreatic beta cells

Interaction of syntaxin 1 with the alpha(1D) subunit of the voltage-gated L type Ca(2+) channel was investigated in the pancreatic beta cell. Coexpression of the enhanced green fluorescent protein-linked alpha(1D) subunit with the enhanced blue fluorescent protein-linked syntaxin 1 and Western blot analysis together with subcellular fractionation demonstrated that the alpha(1D) subunit and syntaxin 1 were colocalized in the plasma membrane. Furthermore, the alpha(1D) subunit was coimmunoprecipitated efficiently by a polyclonal antibody against syntaxin 1. Syntaxin 1 also played a central role in the modulation of L type Ca(2+) channel activity because there was a faster Ca(2+) current run-down in cells incubated with antisyntaxin 1 compared with controls. In parallel, antisyntaxin 1 markedly reduced insulin release in both intact and permeabilized cells, subsequent to depolarization with K(+) or exposure to high Ca(2+). Exchanging Ca(2+) for Ba(2+) abolished the effect of antisyntaxin 1 on both Ca(2+) channel activity and insulin exocytosis. Moreover, antisyntaxin 1 had no significant effects on Ca(2+)-independent insulin release trigged by hypertonic stimulation. This suggests that there is a structure-function relationship between the alpha(1D) subunit of the L type Ca(2+) channel and the exocytotic machinery in the pancreatic beta cell.

Long chain coenzyme A esters activate the pore-forming subunit (Kir6. 2) of the ATP-regulated potassium channel

The ATP-dependent potassium (KATP) channel in the pancreatic beta-cell is a complex of two proteins, the pore-forming Kir6.2 and the sulfonylurea receptor type 1 (SUR1). Both subunits are required for functional KATP channels because expression of Kir6.2 alone does not result in measurable currents. However, truncation of the last 26 or 36 amino acids of the C terminus of Kir6.2 enables functional expression of the pore-forming protein in the absence of SUR1. Thus, by using the truncated form of Kir6.2, expressed in the absence and presence of SUR1, it has been shown that the site at which ATP mediates channel inhibition is likely to be situated on Kir6.2. We have now examined the effects of long chain acyl-CoA (LC-CoA) esters on the C-terminally truncated mouse Kir6.2Delta365-390 (Kir6. 2DeltaC26) in inside-out patches isolated from Xenopus laevis oocytes. LC-CoA esters, saturated (C14:0, C16:0) and unsaturated (C18:1), increased Kir6.2DeltaC26 currents, whereas short and medium chain CoA esters (C3:0, C8:0, C12:0) were unable to affect channel activity. The LC-CoA esters were also able to counteract the blocking effect of ATP on Kir6.2DeltaC26. The stimulatory effect of the esters could be explained by the induction of a prolonged open state of Kir6.2DeltaC26. In the presence of the esters, channel open time was increased approximately 3-fold, which is identical to what was obtained in the native mouse KATP channel. Coexpression of SUR1 together with Kir6.2DeltaC26 did not further increase the ability of LC-CoA esters to stimulate channel activity. We conclude that Kir6.2 is the primary target for LC-CoA esters to activate the KATP channel and that the esters are likely to induce a conformational change by a direct interference with the pore-forming subunit, leading to openings of long duration.

Cysteine string protein (CSP) is an insulin secretory granule-associated protein regulating beta-cell exocytosis

Cysteine string proteins (CSPs) are novel synaptic vesicle-associated protein components characterized by an N-terminal J-domain and a central palmitoylated string of cysteine residues. The cellular localization and functional role of CSP was studied in pancreatic endocrine cells. In situ hybridization and RT-PCR analysis demonstrated CSP mRNA expression in insulin-producing cells. CSP1 mRNA was present in pancreatic islets; both CSP1 and CSP2 mRNAs were seen in insulin-secreting cell lines. Punctate CSP-like immunoreactivity (CSP-LI) was demonstrated in most islets of Langerhans cells, acinar cells and nerve fibers of the rat pancreas. Ultrastructural analysis showed CSP-LI in close association with membranes of secretory granules of cells in the endo- and exocrine pancreas. Subcellular fractionation of insulinoma cells showed CSP1 (34/36 kDa) in granular fractions; the membrane and cytosol fractions contained predominantly CSP2 (27 kDa). The fractions also contained proteins of 72 and 70 kDa, presumably CSP dimers. CSP1 overexpression in INS-1 cells or intracellular administration of CSP antibodies into mouse ob/ob beta-cells did not affect voltage-dependent Ca2+-channel activity. Amperometric measurements showed a significant decrease in insulin exocytosis in individual INS-1 cells after CSP1 overexpression. We conclude that CSP is associated with insulin secretory granules and that CSP participates in the molecular regulation of insulin exocytosis by mechanisms not involving changes in the activity of voltage-gated Ca2+-channels.

Direct inhibition of the pancreatic beta-cell ATP-regulated potassium channel by alpha-ketoisocaproate

The ATP-regulated potassium (KATP) channel plays an essential role in the control of insulin release from the pancreatic beta-cell. In the present study we have used the patch-clamp technique to study the direct effects of alpha-ketoisocaproate on the KATP channel in isolated patches and intact pancreatic beta-cells. In excised inside-out patches, the activity of the KATP channel was dose-dependently inhibited by alpha-ketoisocaproate, half-maximal concentration being approximately 8 mM. The blocking effect of alpha-ketoisocaproate was fully reversible. Stimulation of channel activity by the addition of ATP/ADP (ratio 1) did not counteract the inhibitory effect of alpha-ketoisocaproate. In the presence of the metabolic inhibitor sodium azide, alpha-ketoisocaproate was still able to inhibit single channel activity in excised patches and to block whole cell KATP currents in intact cells. No effect of alpha-ketoisocaproate could be obtained on either the large or the small conductance Ca2+-regulated K+ channel. Enzymatic treatment of the patches with trypsin prevented the inhibitory effect of alpha-ketoisocaproate. Based on these observations, it is unlikely that the blocking effect of alpha-ketoisocaproate is due to an unspecific effect on K+ channel pores. Leucine, the precursor of alpha-ketoisocaproate, did not affect KATP channel activity in excised patches. Our findings are compatible with the view that alpha-ketoisocaproate not only affects the beta-cell stimulus secretion coupling by generation of ATP but also by direct inhibition of the KATP channel.

Mediation of irregular spiking activity by multiple neurokinin-receptors in the small intestine of the rat

1. We have studied the small intestinal myoelectric response to the natural tachykinins substance P (SP), neurokinin A (NKA), neurokinin B (NKB), and the neurokinin-receptor selective agonists substance P methyl esther (SPME), [beta-Ala8]neurokinin A 4-10, and senktide in conscious rats. 2. The effects of the agonists were studied before and after administration of the selective neurokinin2 (NK2)-receptor antagonist MEN 10,627. 3. Under basal conditions SP, NKA, NKB, as well as the selective NK1-receptor agonist SPME, the NK2-receptor agonist [beta-Ala8]NKA 4-10, and the NK3-receptor agonist senktide, disrupted the interdigestive rhythm with regularly recycling migrating myoelectric complexes and induced a phase II-like irregular spiking activity. 4. MEN 10,627 given alone did not affect the interdigestive rhythm. 5. MEN 10,627 inhibited the response to [beta-Ala8]NKA 4-10 but not to SP, SPME, NKA, NKB or senktide. 6. It is concluded that not only NK2 receptors, but also other receptors, such as NK1 and NK3 receptors, may mediate the motility-stimulating action of different tachykinins in vivo. 7. It is further concluded that MEN 10,627 exerts a selective NK2-receptor antagonism, and may be a valuable tool for assessing the functional role of NK2-receptors in gastrointestinal physiology.

[Mechanisms of action of peroral antidiabetics. Sulfonylurea preparations block the ATP-dependent potassium channels]

Although hypoglycaemic sulphonylureas have been used to treat non-insulin-dependent diabetes mellitus (NIDDM) for the past forty years, their mechanisms of action at the molecular level have only recently been elucidated. A combination of electrophysiological and molecular biological techniques showed the target of sulphonylureas to be a sulphonylurea receptor (SUR1) and potassium channel (Kir6.2) complex. Together, these two proteins form the ATP-dependent potassium (KATP) channel occurring in insulin-secreting cells. An increase in the blood glucose level triggers a chain of events in insulin-secreting cells and K(ATP) channel closure which is a prerequisite for insulin secretion. In NIDDM, however, an increase in blood glucose fails to close the K(ATP) channel satisfactorily, but this can be remedied by the administration of sulphonylureas.

RIN14B: a pancreatic delta-cell line that maintains functional ATP-dependent K+ channels and capability to secrete insulin under conditions where it no longer secretes somatostatin

The delta-cell line RIN14B was characterized with regard to ATP-regulated K+ (K(ATP)) channel activity and hormone release. By applying the patch-clamp technique, dose-response curves for ATP and the sulfonylurea tolbutamide were obtained in inside-out patches. The concentration causing half-maximal K(ATP) channel inhibition was found to be 23.7 and 27.6 microM for ATP and tolbutamide, respectively. ADP and diazoxide stimulated K(ATP) channel activity, an effect dependent on the presence of intracellular Mg2+. The stimulatory effect of diazoxide also required the presence of ATP. The kinetic properties of the K(ATP) channel were analysed in the presence of ATP, a combination of ADP and ATP and in nucleotide-free solutions. The distribution of K(ATP) channel open time could be described by a single exponential function with a time constant of approximately 30 ms in nucleotide-free and in ATP-containing solutions. The presence of both ATP and ADP resulted in the appearance of an additional time constant of > 150 ms. Single-channel unitary current-voltage (i-V) relation was characterised for the K((ATP) channel present in RIN14B cells. The slope conductance, measured at the reversal potential was found to be 19.1 +/- 2.4 pS. The permeability for K+ ions was calculated to be 0.31 x 10(-13) cm3 x s(-1). We have not been able to confirm the somatostatin releasing profile of the RIN14B cells using radioimmunoassays, nor could we find positive somatostatin stain with immunocytochemical techniques. We conclude that the RIN14B cell line, previously characterized as a somatostatin-secreting cell line, contains K(ATP) channels with properties closely resembling the K(ATP) channel described in the pancreatic beta-cell. However, the cell line appears to have dedifferentiated with regard to the ability to secrete somatostatin, maintaining the highly differentiated function of both insulin biosynthesis and exocytosis.

Evidence for a unique long chain acyl-CoA ester binding site on the ATP-regulated potassium channel in mouse pancreatic beta cells

The mechanism by which long chain acyl-CoA (LC-CoA) esters affect the ATP-regulated potassium channel (KATP channel) was studied in inside-out patches isolated from mouse pancreatic beta cells. Addition of LC-CoA esters dramatically increased KATP channel activity. The stimulatory effect of the esters could be explained by the induction of a prolonged open state of the channel and did not involve alterations in single channel unitary conductance. Under control conditions, absence of adenine nucleotides, the distribution of KATP channel open time could be described by a single exponential, with a time constant of about 25 ms. Exposing the same patch to LC-CoA esters resulted in the appearance of an additional component with a time constant of >>150 ms, indicating a conformational change of the channel protein. LC-CoA esters were also able to potently activate channel activity at different ratios of ATP/ADP. Simultaneous additions of MgADP and LC-CoA esters resulted in a supra-additive effect on channel mean open time, characterized by openings of very long duration. Following modification of the KATP channel by a short exposure of the patch to the protease trypsin, the stimulatory effect of ADP on channel activity was lost while activation by LC-CoA esters still persisted. This indicates that LC-CoA esters and MgADP do not bind to the same site. We conclude that LC-CoA esters may play an important role in the physiological regulation of the KATP channel in the pancreatic beta cell by binding to a unique site and thereby inducing repolarization of the beta cell-membrane potential.

Augmented thermic effect of amino acids under general anaesthesia occurs predominantly in extra-splanchnic tissues

1. Intravenous infusion of amino acid mixtures stimulates human oxidative heat production more effectively under general anaesthesia than in the unanaesthetized state. To analyse the splanchnic and extra-splanchnic regional distribution of this stimulation, whole body and splanchnic oxygen uptake, blood flow and blood temperatures were measured by a catheterization technique in 14 patients undergoing isoflurane anaesthesia for abdominal surgery. During the anaesthesia period, a mixture of 19 amino acids (240 kJ/h) was infused intravenously into seven of the patients while the others served as controls, receiving isovolumic infusions of a nutrient-free saline solution. 2. Whole body oxygen consumption fell by approximately 40% during anaesthesia and surgery in the controls. Approximately 80-95% of the reduction occurred in the extra-splanchnic tissues. The splanchnic oxygen uptake fell by 31 +/- 6% in the controls during the initial phase of anaesthesia, after which it returned to the pre-anaesthesia level. The initial reduction of the controls' splanchnic oxygen consumption accounted for only approximately 23% of the simultaneous anaesthesia-induced reduction in pulmonary oxygen uptake. No initial reduction of the splanchnic oxygen uptake was observed in the patients treated with amino acid. 3. The amino acid infusion stimulated the whole body oxidative heat production by approximately 18 W during anaesthesia and surgery and by approximately 70 W at the emergence from anaesthesia. Approximately 74% of the stimulation occurred in the extra-splanchnic tissues. At awakening, the splanchnic oxygen uptake rose to approximately 64% above the pre-anaesthesia level in the amino acid group. 4. During the entire period of anaesthesia, the whole body heat content fell by 282 +/- 68 kJ in the controls and by 57 +/- 25 kJ in the amino acid group. Amino acid treatment thus prevented approximately 80% of the anaesthesia-induced reduction in whole body heat content. 5. During anaesthesia and surgery, cardiac output was approximately 25% and approximately 16% below the baseline, preanaesthesia levels in the control and amino acid groups, respectively. At awakening, it rose to approximately 44% above baseline in the amino acid group while in the controls it remained unchanged. In both groups the splanchnic blood flow was unaffected by anaesthesia or by amino acid infusions.

Effects of oral vs. i.v. glucose administration on splanchnic and extrasplanchnic O2 uptake and blood flow

The metabolic and circulatory responses to intravenous or oral administration of glucose (75 g) were studied in healthy subjects. Pulmonary oxygen uptake increased promptly after oral but not during intravenous glucose infusion. The average 2-h rise above basal in whole body oxygen uptake was 8 +/- 1% (P < 0.001) after oral glucose and 3 +/- 1% (P < 0.05) during intravenous glucose infusion. After oral glucose, splanchnic oxygen uptake rose initially by approximately 15% (P < 0.01) and then declined; its average 2-h postprandial level was not significantly higher than that in the basal state. During intravenous glucose, splanchnic oxygen uptake decreased gradually during the first 75 min, reaching a level approximately 25% below basal (P < 0.05). Oxygen consumption by extrasplanchnic tissues rose significantly and to a similar extent (8%, 2 h average) with both intravenous and oral glucose. Splanchnic blood flow increased significantly after oral but not during intravenous glucose. It is concluded that 1) intravenous infusion and oral glucose administration elicit extrasplanchnic thermogenic effects of similar magnitude, 2) during intravenous glucose infusion, the extrasplanchnic thermogenic effect is counterbalanced by a simultaneous reduction in splanchnic oxygen uptake, resulting in a minimal (3%) net rise in whole body oxygen uptake, and 3) oral glucose ingestion but not intravenous glucose infusion increases the splanchnic blood flow.

Characteristics of fasting and fed myoelectric activity in rat small intestine: evaluation by computer analysis

Evaluation of gastrointestinal myoelectric activity has been limited by the assessment techniques and the complexity of the recorded myoelectric signal. Commonly, myoelectric activity is evaluated as motor patterns, which only gives a semiquantitative measure of myoelectric events within the bowel wall. Using myoelectric recordings from the proximal small intestine in rats, a computerized system for acquisition, storage, display and calculation of characteristics for the myoelectric activity was developed. The software was tested in myoelectric recordings from nine rats in fasting and fed states. All migrating myoelectric complexes (MMCs) during fasting and fed myoelectric patterns were recognized in both digital and analog recordings. Reproduction of myoelectric recordings by the computerized system was indistinguishable from that of the analog system. Employing an appropriate cut-off trigger level and a high sampling frequency, spike potentials were recorded in the proximal jejunum with 0.4 (0.3-0.5) spikes 10 s-1 during phase 1 of MMC, 19.5 (15.1-23.9) (P < 0.001) during phase 2, and 103.8 (97.2-110.5) (P < 0.001) during phase 3. In fasted state, MMCs were most frequent in the proximal jejunum whereas fewer were found in the duodenum and distal jejunum. To achieve stable values for MMC cycle length at least four MMCs had to be calculated. After feeding in phase 1, the myoelectric activity increased to 23.8 (13.6-33.9) spikes 10 s-1 (P < 0.001), whereafter the spiking activity decreased over a period of 2 h until a fasting motor pattern was resumed. It is concluded that computerized technology enables evaluation not only of myoelectric patterns, but also of spiking activity per time unit, i.e. the intensity of myoelectric activity in the gut.

Activation of the ATP-sensitive K+ channel by long chain acyl-CoA. A role in modulation of pancreatic beta-cell glucose sensitivity

Long-term exposure to elevated levels of long chain free fatty acids decreases glucose-induced insulin secretion from pancreatic islets and clonal pancreatic beta-cells. The mechanism for this loss of glucose sensitivity is at present not known. In this study, we evaluated the possibility that increases in long chain acyl-CoA esters (LC-CoA), the metabolically active form of free fatty acids, might mediate the loss of glucose sensitivity. We observed that cellular levels of LC-CoA increased more than 100% in response to overnight incubation with 0.5 mM palmitic acid complexed to albumin. In the same studies, the total CoA pool increased by about 40%. Patch-clamp studies demonstrated that saturated and unsaturated LC-CoA, but not malonyl-CoA or free CoASH, induced a rapid and slowly reversible opening of ATP-sensitive K+ channels. The effect was concentration-dependent between 10 nM and 1 microM. These findings indicate that the ATP-regulated K/ channels is a sensitive target for LC-CoA and suggest that high levels of LC-CoA, which accumulate in response to hyperglycemia or prolonged exposure to free fatty acids, may prevent channel closure and contribute to the development of beta-cell glucose insensitivity.

Preoperative infusion of amino acids prevents postoperative hypothermia

Intraoperative infusion of amino acids has been found to stimulate energy expenditure and thereby prevent anaesthesia-induced hypothermia. Rectal temperature and respiratory gas exchange were measured in 24 female patients before and after isoflurane anaesthesia. Sixteen patients had an amino acid mixture of 240 kJ h-1, infused over 1-2 h before anaesthesia and eight control patients received saline. We compared the results with data from six female volunteers treated with amino acids; they were not premedicated or anaesthetized. In lorazepam premedicated patients, amino acids increased the pre-anaesthesia temperature by 0.3 degrees C h-1, twice that observed in the volunteers. At awakening after anaesthesia, energy expenditure increased to 50-60% above baseline in the amino acid treated patients, while in the control patients, receiving saline, no increase occurred, despite vigorous shivering. Amino acid infusion prevented hypothermia by increasing heat accumulation and causing delayed stimulation of heat production. The heat accumulation response to amino acid infusion was increased after premedication with lorazepam.