Arachidonic acid signaling is involved in the mechanism of imidazoline-induced KATP channel-independent stimulation of insulin secretion.

The mechanism by which the novel, pure glucose-dependent insulinotropic, imidazoline derivative BL11282 promotes insulin secretion in pancreatic islets has been investigated. The roles of KATP channels, alpha2-adrenoreceptors, the I1-receptor-phosphatidylcholine-specific phospholipase (PC-PLC) pathway and arachidonic acid signaling in BL11282 potentiation of insulin secretion in pancreatic islets were studied. Using SUR1(-/-) deficient mice, the previous notion that the insulinotropic activity of BL11282 is not related to its interaction with KATP channels was confirmed. Insulinotropic activity of BL11282 was not related to its effect on alpha2-adrenoreceptors, I1-imidazoline receptors or PC-PLC. BL11282 significantly increased [3H]arachidonic acid production. This effect was abolished in the presence of the iPLA2 inhibitor, bromoenol lactone. The data suggest that potentiation of glucose-induced insulin release by BL11282, which is independent of concomitant changes in cytoplasmic free Ca2+ concentration, involves release of arachidonic acid by iPLA2 and its metabolism to epoxyeicosatrienoic acids through the cytochrome P-450 pathway.

Single residue (K332A) substitution in Kir6.2 abolishes the stimulatory effect of long-chain acyl-CoA esters: indications for a long-chain acyl-CoA ester binding motif.

AIMS/HYPOTHESIS: The pancreatic beta cell ATP-sensitive potassium (K(ATP)) channel, composed of the pore-forming alpha subunit Kir6.2, a member of the inward rectifier K+channel family, and the regulatory beta subunit sulfonylurea receptor 1 (SUR1), a member of the ATP-binding cassette superfamily, couples the metabolic state of the cell to electrical activity. Several endogenous compounds are known to modulate K(ATP) channel activity, including ATP, ADP, phosphatidylinositol diphosphates and long-chain acyl coenzyme A (LC-CoA) esters. LC-CoA esters have been shown to interact with Kir6.2, but the mechanism and binding site(s) have yet to be identified. MATERIALS AND METHODS: Using multiple sequence alignment of known acyl-CoA ester interacting proteins, we were able to identify four conserved amino acid residues that could potentially serve as an acyl-CoA ester-binding motif. The motif was also recognised in the C-terminal region of Kir6.2 (R311-332) but not in SUR1. RESULTS: Oocytes expressing Kir6.2DeltaC26 K332A repeatedly generated K(+)currents in inside-out membrane patches that were sensitive to ATP, but were only weakly activated by 1 mumol/l palmitoyl-CoA ester. Compared with the control channel (Kir6.2DeltaC26), Kir6.2DeltaC26 K332A displayed unaltered ATP sensitivity but significantly decreased sensitivity to palmitoyl-CoA esters. Coexpression of Kir6.2DeltaC26 K332A and SUR1 revealed slightly increased activation by palmitoyl-CoA ester but significantly decreased activation by the acyl-CoA esters compared with the wild-type K(ATP) channel and Kir6.2DeltaC26+SUR1. Computational modelling, using the crystal structure of KirBac1.1, suggested that K332 is located on the intracellular domain of Kir6.2 and is accessible to intracellular modulators such as LC-CoA esters. CONCLUSIONS/INTERPRETATION: These results verify that LC-CoA esters interact at the pore-forming subunit Kir6.2, and on the basis of these data we propose an acyl-CoA ester binding motif located in the C-terminal region.

Loss of parafibromin expression in a subset of parathyroid adenomas.

Inactivation of the hyperparathyroidism-jaw tumour syndrome (HPT- JT) gene, HRPT2, was recently established as a genetic mechanism in the development of parathyroid tumours. Its encoded protein parafibromin has tumour-suppressor properties that play an important role in tumour development in the parathyroids, jaws and kidneys. Inactivating HRPT2 mutations are common in HPT- JT and parathyroid carcinomas, and have been described in a few cases of parathyroid adenomas with cystic features. In this study, 46 cases of cystic parathyroid adenomas previously investigated for HRPT2 mutations were characterized with regard to MEN1 gene mutations, cyclin D1 expression and parafibromin expression. In normal tissues and cell lines, parafibromin was ubiquitously expressed. Furthermore, parafibromin was detected as a dominating nuclear and a weaker cytoplasmic signal in transfected cell lines. In the three parathyroid tumours with inactivating HRPT2 mutations parafibromin expression was not detectable, and in one of two cases with aberrantly sized parafibromin the protein was delocalized. Both high and low cyclin D1 levels were found among HRPT2-mutated and -unmutated tumours, suggesting that these events are not mutually exclusive in parathyroid tumour development. The presented data suggest that in the majority of benign parathyroid tumours the expression of parafibromin remains unaltered, while the loss of parafibromin expression is strongly indicative of gene inactivation through mutation of the HRPT2 gene.

Selective insulin signaling through A and B insulin receptors regulates transcription of insulin and glucokinase genes in pancreatic beta cells.

Insulin signaling is mediated by a complex network of diverging and converging pathways, with alternative proteins and isoforms at almost every step in the process. We show here that insulin activates the transcription of its own gene and that of the beta cell glucokinase gene (betaGK) by different mechanisms. Whereas insulin gene transcription is promoted by signaling through insulin receptor A type (Ex11-), PI3K class Ia, and p70s6k, insulin stimulates the betaGK gene by signaling via insulin receptor B type (Ex11+), PI3K class II-like activity, and PKB (c-Akt). Our data provide evidence for selectivity in insulin action via the two isoforms of the insulin receptor, the molecular basis being preferential signaling through different PI3K and protein kinases.

Characterization of a novel human putative mitochondrial transporter homologous to the yeast mitochondrial RNA splicing proteins 3 and 4.

We report here a novel human gene, hMRS3/4, encoding a putative mitochondrial transporter structurally and functionally homologous to the yeast mitochondrial RNA splicing proteins 3 and 4. These proteins belong to the family of mitochondrial carrier proteins (MCF) and are likely to function as solute carriers. hMRS3/4 spans approximately 10 kb of genomic DNA on chromosome 10q24 and consists of four exons that encode a 364-aa protein with six transmembrane domains. A putative splice variant, encoding a 177-aa protein with three transmembrane domains, was also identified. hMRS3/4 has a well-conserved signature sequence of MCF and is targeted into the mitochondria. When expressed in yeast, hMRS3/4 efficiently restores the mitochondrial functions in mrs3(o)mrs4(o) knock-out mutants. Ubiquitous expression in human tissues and a well-conserved structure and function suggest an important role for hMRS3/4 in human cells.

Online monitoring of stimulus-induced gene expression in pancreatic beta-cells.

Fluorescent proteins have been extensively used as protein "tags" to study the subcellular localization of proteins and/or their translocation upon stimulation or as markers for transfection in transient and stable expression systems. However, they have not been frequently used as reporter genes to monitor stimulus-induced gene expression in mammalian cells. Here we demonstrate the use of fluorescent proteins to study stimulus-induced gene transcription. The general applicability of the approach is exemplified by doxycyclin-(Tet-On) and phorbol 12-myristate 13-acetate-induced (c-fos) promoter activation, with green fluorescent protein (GFP) and red fluorescent protein (DsRed) as semiquantitative and immediate reporters, of transcription activation. Under the control of beta-cell-specific promoters, such as the rat insulin 1 promoter or the rat upstream glucokinase promoter, this approach allowed us to monitor online glucose-induced gene transcription in primary beta-cells at the single-cell level as well as in the context of the islet of Langerhans. Applying discretely detectable fluorescent proteins, for example GFP and DsRed, enabled us to simultaneously monitor stimulus-induced transcription by two different promoters in the same cell.

Glucose-stimulated insulin biosynthesis depends on insulin-stimulated insulin gene transcription.

Glucose stimulation of pancreatic beta-cells leads to insulin secretion as well as up-regulation of insulin biosynthesis. The acute elevation in pro-insulin levels is thought to be exclusively because of the activation of translation of pre-existing prepro-insulin mRNA. Glucose-stimulated insulin gene transcription is believed to be a long term effect and should therefore not contribute to the acute elevation in pro-insulin levels. We have recently shown that glucose activates insulin gene transcription within minutes and that secreted insulin is one of the key factors triggering this process in an autocrine manner. We now provide evidence that 50% of the glucose-stimulated, acute pro-insulin biosynthesis within 30 min results from up-regulated insulin gene transcription. Our data led us to propose that glucose elevates pro-insulin levels by stimulating both transcriptional and post-transcriptional/post-translational events to an equal extent. Whereas the stimulatory effect on transcription is mediated by insulin secreted in response to glucose, glucose directly stimulates the post-transcriptional/post-translational processes.

Identification of a nuclear localization signal, RRMKWKK, in the homeodomain transcription factor PDX-1.

Pancreatic duodenal homeobox-containing transcription factor 1 (PDX-1) plays a crucial role in pancreas development and beta-cell gene regulation. Absence of PDX-1 leads to pancreas agenesis and its malfunction causes MODY4 diabetes mellitus. PDX-1 has been suggested to be involved in the glucose-dependent regulation of insulin gene transcription. Whereas DNA-binding and transactivation domains of PDX-1 are in the process of being characterized, protein sequences responsible for its nuclear translocation remain unknown. By combining site-directed mutagenesis of putative phosphorylation sites and nuclear localization signal (NLS) motifs with on-line monitoring of GFP-tagged PDX-1 translocation, we demonstrate that the NLS motif RRMKWKK is necessary and in conjunction with the integrity of the 'helix 3' domain of the PDX-1 homeodomain is sufficient for the nuclear import of PDX-1. Furthermore, we show that there is no glucose-dependent cytoplasmic-nuclear cycling of PDX-1.

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.

Short-term regulation of insulin gene transcription by glucose.

Whereas short-term regulation of insulin biosynthesis at the level of translation is well accepted, glucose-dependent transcriptional control is still believed to be a long-term effect occurring after more than 2 hr of glucose stimulation. Because pancreatic beta cells are exposed to elevated glucose levels for minutes rather than hours after food uptake, we hypothesized the existence of a short-term transcriptional control. By studying the dynamics of newly synthesized (prepro)insulin RNA and by employing on-line monitoring of gene expression in single, insulin-producing cells, we were able to provide convincing evidence that insulin gene transcription indeed is affected by glucose within minutes. Exposure of insulinoma cells and isolated pancreatic islets to elevated glucose for only 15 min resulted in a 2- to 5-fold elevation in (prepro)insulin mRNA levels within 60-90 min. Similarly, insulin promoter-driven green fluorescent protein expression in single insulin-producing cells was significantly enhanced after transient glucose stimulation. Thus, short-term signaling, such as that involved in insulin secretion, also may regulate insulin gene transcription.

Exocytosis of insulin promotes insulin gene transcription via the insulin receptor/PI-3 kinase/p70 s6 kinase and CaM kinase pathways.

The control of glucose homeostasis by insulin requires, in addition to the glucose-induced insulin release, a highly dynamic control of insulin biosynthesis. Although elevated glucose concentrations have been shown to trigger insulin biosynthesis at the levels of transcription and translation, the molecular mechanisms underlying the immediate transcriptional control are poorly understood. By investigating signal transduction pathways involved in the "glucose-dependent" transcriptional control, thereby analyzing endogenous (prepro)insulin mRNA levels and monitoring on-line insulin promoter-driven GFP expression, we provide, for the first time, evidence that physiologically stimulated insulin secretion from the pancreatic beta cell promotes insulin biosynthesis by enhancing insulin gene transcription in an autocrine manner. We show that secreted insulin acts via beta-cell insulin receptors and up-regulates insulin gene transcription by signaling through the IRS-2/PI-3 kinase/p70 s6k and CaM kinase pathways.

In situ activation of the type 2 ryanodine receptor in pancreatic beta cells requires cAMP-dependent phosphorylation.

Molecular mechanisms that regulate in situ activation of ryanodine receptors (RY) in different cells are poorly understood. Here we demonstrate that caffeine (10 mM) released Ca2+ from the endoplasmic reticulum (ER) in the form of small spikes in only 14% of cultured fura-2 loaded beta cells from ob/ob mice. Surprisingly, when forskolin, an activator of adenylyl cyclase was present, caffeine induced larger Ca2+ spikes in as many as 60% of the cells. Forskolin or the phosphodiesterase-resistant PKA activator Sp-cAMPS alone did not release Ca2+ from ER. 4-Chloro-3-ethylphenol (4-CEP), an agent that activates RYs in other cell systems, released Ca2+ from ER, giving rise to a slow and small increase in [Ca2+]i in beta cells. Prior exposure of cells to forskolin or caffeine (5 mM) qualitatively altered Ca2+ release by 4-CEP, giving rise to Ca2+ spikes. In glucose-stimulated beta cells forskolin induced Ca2+ spikes that were enhanced by 3,9-dimethylxanthine, an activator of RYs. Analysis of RNA from islets and insulin-secreting betaTC-3-cells by RNase protection assay, using type-specific RY probes, revealed low-level expression of mRNA for the type 2 isoform of the receptor (RY2). We conclude that in situ activation of RY2 in beta cells requires cAMP-dependent phosphorylation, a process that recruits the receptor in a functionally operative form.

Dual function of the intron of the rat insulin I gene in regulation of gene expression.

Since the short intron in the 5'-untranslated region (5'-UTR) has been preserved during duplication of the insulin genes in rodents we postulated a possible involvement of these sequences in the regulation of gene expression. To examine this hypothesis we fused nested 5'-deletion fragments of the rat insulin I (rins1) promoter and sequences of the 5'-UTR up to nucleotide +170 with the reporter gene chloramphenicol acetyltransferase (CAT) and generated two series of expression constructs differing by the presence or absence of the intron (rins11VS). Transient expression of these chimeric genes in HIT M2.2.2 cells revealed a four-fold higher CAT expression in the presence of rins1IVS. Comparison of the CAT transcript quantities generated by both counterparts showed only a 1.7-fold difference in the total nuclear RNA fraction, but a four-fold difference in the fraction of nuclear polyadenylated RNA. Further analysis of cytoplasmic RNA excluded nuclear-cytoplasmic transport, RNA stability, and efficiency of translation as targets of the rins1IVS-mediated effect. The higher rate in polyadenylated CAT transcripts generated by rins1IVS-containing vectors suggests a possible coupling between splicing and polyadenylation. Transient expression studies using chimeras containing mutations or deletions between nucleotides -87 and +110 showed a reduction of expression by 30%. These data suggest a dual function of the rins1 intron on transcription initiation and transcript maturation.

Functional analysis of a newly identified TAAT-box of the rat insulin-II gene promoter.

Transcriptional regulation of insulin gene expression is achieved by an interplay of tissue-specific and ubiquitous cis- and trans-acting elements. E-box like motifs and TAAT-motifs were shown to play a crucial role in initiating insulin gene transcription. Studying the AT-rich region of the rat insulin-II promoter between nucleotides -212 and -196, we observed a base difference at -211, an adenosine instead of a cytidine, compared to the previously reported sequence (EMBL Accession No. J00748). Sequence analysis of promoter fragments from different rat strains showed that adenosine at position -211 represents the wild type (EMBL Accession No. X82162). This base exchange leads to the formation of an additional TAAT-motif, i.e. TAAT3, at the complementary DNA strand directly upstream of the previously studied TAAT2 motif, formerly named CT-2. Here we show that the newly identified motif TAAT3 is involved in (i) transcriptional control in vivo, (ii) in vitro DNA/protein interactions, and that (iii) TAAT1, TAAT2 and TAAT3 are binding sites for the homeodomain-containing factor IPF-1.

Functional analysis of DNA-elements involved in transcriptional control of the human glucose transporter 2 (GLUT 2) gene in the insulin-producing cell line beta TC-3.

The uptake of glucose into pancreatic beta cells as a 'non-rate-limiting-step' is guaranteed by the expression and action of the high-Km glucose transporter 2 (GLUT 2). This transporter is not saturated by physiological plasma glucose levels and hence functions as a "glucose sensor/glucoreceptor". Here we describe DNA-elements of the human GLUT 2 gene promoter which contribute to transcriptional control in the insulin-producing cell line beta TC-3. Nested 5'-as well as 3'-deletions of a DNA-fragment containing up to 1245 bp of the 5'-flanking region and up to 308 bp of the first exon of the human GLUT 2 gene were investigated for their ability to control the expression of a CAT reporter gene in beta TC-3 cells. For tissue-specific transcriptional control 5'-deletional analysis revealed that the region -220/+309 was sufficient. Truncation from the 3'-end from nucleotide +308 to +204 led to a threefold drop in CAT expression. In vitro DNase I footprinting analysis was performed to delineate cis-elements within the region -220/+1. Five specifically protected areas could be defined.

CT-boxes are involved in control of the rat insulin II gene expression.

Expression of the rat insulin II gene is controlled mainly at the level of transcription initiation by multiple factors binding to specific cis-acting DNA-elements in the regulatory region. We have shown that two elements (CT-motifs) located between nucleotides -83 and -76 (CT-1) and -204 and -197 (CT-2) are involved in transcriptional regulation in the insulin-producing cell line HIT M2.2.2. Transient expression analysis of 5'-deletion as well as block replacement mutants revealed that CT-1 and CT-2 are mutational sensitive. Gel mobility shift assays showed that both motifs bind similar nuclear factors. Our results suggest the involvement of a third CT-motif located directly upstream of CT-2 on the complementary strand.

The role of the proximal CTAAT-box of the rat glucokinase upstream promoter in transcriptional control in insulin-producing cells.

Sequence analysis of the 5'flanking region of the beta-cell specific transcription unit of the rat glucokinase gene (r beta GK) revealed the presence of sequence motifs very similar to the IEB-(Far)-box and a CT-motif which play a crucial role in transcriptional control of insulin genes. 5'deletional analysis of the r beta GK proximal promoter element (localized between nucleotides -278 and -49) as well as site directed mutagenesis showed that both motifs are mutationally sensitive and contribute to transcriptional control in HIT M2.2.2 cells. The combination of the IEB-(Far)-like motif with the CT-box was unable to form a "mini-enhancer" similar to the Far-FLAT-element of the rat insulin I gene promoter but rather functions as a beta-cell specific control element in r beta GK expression. Electrophoretic mobility shift assays (EMSAs) and competition studies using oligonucleotides containing CT-motifs of rat insulin genes promoters, human insulin gene promoter, and rat amylin gene promoter showed similar binding patterns with nuclear extracts isolated from insulin-producing cell lines. These studies indicate that CT-motifs of rat glucokinase, insulin, and amylin gene promoters may bind similar--probably identical--nuclear factor(s) and may play a central role in the coordinated expression of these genes in insulin-producing cells.