Project description:Bovine heart cyclic AMP phosphodiesterase, which has a requirement for Mg2+, hydrolyses cyclic AMP with inversion of configuration at the phosphorus atom, but only the (Sp)-diastereoisomer of adenosine cyclic 3':5'-phosphorothioate is hydrolysed by this enzyme. By contrast, the low-affinity yeast cyclic AMP phosphodiesterase, which contains tightly bound Zn2+, hydrolyses both the (Sp)- and the (Rp)-diastereoisomers of adenosine cyclic 3':5'-phosphorothioate, the (Rp)-diastereoisomer being the preferred substrate under V max. conditions. Both of the diastereoisomers of adenosine cyclic 3':5'-phosphorothioate, as well as cyclic AMP, are hydrolysed with inversion of configuration at the phosphorus atom by the yeast enzyme. It is proposed that, with both enzymes, the bivalent metal ion co-ordinates with the phosphate residue of the substrate, and that hydrolysis is catalysed by a direct "in-line' mechanism.

Project description:The inhibition of phosphatases by adenosine 5'-phosphorothioate (AMPS) was first reported in the late 1960s; however, the structural basis for the inhibition has remained unknown. Here, it is shown that AMPS is a submicromolar inhibitor of class C acid phosphatases, a group of bacterial outer membrane enzymes belonging to the haloacid dehalogenase structural superfamily. Furthermore, the 1.35-Å resolution crystal structure of the inhibited recombinant Haemophilus influenzae class C acid phosphatase was determined; this is the first structure of a phosphatase complexed with AMPS. The conformation of AMPS is identical to that of the substrate 5'-AMP, except that steric factors force a rotation of the thiophosphoryl out of the normal phosphoryl-binding pocket. This conformation is catalytically nonproductive, because the P atom is not positioned optimally for nucleophilic attack by Asp64, and the O atom of the scissile O-P bond is too far from the Asp (Asp66) that protonates the leaving group. The structure of 5'-AMP complexed with the Asp64?Asn mutant enzyme was also determined at 1.35-Å resolution. This mutation induces the substrate to adopt the same nonproductive binding mode that is observed in the AMPS complex. In this case, electrostatic considerations, rather than steric factors, underlie the movement of the phosphoryl. The structures not only provide an explanation for the inhibition by AMPS, but also highlight the precise steric and electrostatic requirements of phosphoryl recognition by class C acid phosphatases. Moreover, the structure of the Asp64?Asn mutant illustrates how a seemingly innocuous mutation can cause an unexpected structural change.

Project description:1. Gluconeogenesis from 10mm-lactate in the perfused liver of starved rats is inhibited by ethanol. The degree of inhibition reached a maximum of 66% at 10mm-ethanol under the test conditions and decreased at higher ethanol concentrations. The concentration-dependence of the inhibition is paralleled by the concentration-dependence of the activity of alcohol dehydrogenase. The enzyme is also inhibited by ethanol concentrations above 10mm. 2. Gluconeogenesis from pyruvate is not inhibited by ethanol. 3. The degree of the inhibition of gluconeogenesis from lactate by ethanol depends on the concentration of lactate and other oxidizable substances, e.g. oleate, in the perfusion medium. 4. Ethanol also inhibits, to different degrees, gluconeogenesis from glycerol, dihydroxyacetone, proline, serine, alanine, fructose and galactose. 5. The inhibition of gluconeogenesis from lactate by ethanol is reversed by acetaldehyde. 6. Pyrazole, a specific inhibitor of alcohol dehydrogenase, also reverses the inhibition of gluconeogenesis by ethanol. 7. Gluconeogenesis in kidney cortex, where the activity of alcohol dehydrogenase is very low, is not inhibited by ethanol. 8. Kidney cortex, testis, ovary, uterus and certain tissues of the alimentary tract were the only rat tissues, apart from the liver, that showed measurable alcohol dehydrogenase activity. 9. The concentrations of pyruvate in the liver were decreased to about one-fifth by ethanol. 10. The concentration of lactate in the perfused liver was about 3mm below that of the perfusion medium 30min. after the addition of 10mm-lactate. 11. The great majority of the findings support the view that the inhibition of gluconeogensis by ethanol is caused by the alcohol dehydrogenase reaction, which decreases the [free NAD(+)]/[free NADH] ratio. The decrease lowers the concentration of pyruvate and this is the immediate cause of the inhibition of gluconeogenesis from lactate, alanine and serine: the fall in the concentration of pyruvate lowers the rate of the pyruvate carboxylase reaction, one of the rate-limiting reactions of gluconeogenesis. The cause of the inhibition of gluconeogenesis from other substrates is discussed.

Project description:Chemical synthesis of phosphoromonothioate oligonucleotides (PS-ONs) is not stereo-specific and produces a mixture of Rp and Sp diastereomers, whose disparate reactivity can complicate applications. Although the current methods to separate these diastereomers which rely on chromatography are constantly improving, many Rp and Sp diastereomers are still co-eluted. Here, based on sulfur-binding domains that specifically recognize phosphorothioated DNA and RNA in Rp configuration, we developed a universal separation system for phosphorothioate oligonucleotide isomers using immobilized SBD (SPOIS). With the scalable SPOIS, His-tagged SBD is immobilized onto Ni-nitrilotriacetic acid-coated magnetic beads to form a beads/SBD complex, Rp isomers of the mixture can be completely bound by SBD and separated from Sp isomers unbound in liquid phase, then recovered through suitable elution approach. Using the phosphoromonothioate single-stranded DNA as a model, SPOIS separated PS-ON diastereomers of 4 nt to 50 nt in length at yields of 60-90% of the starting Rp isomers, with PS linkage not locating at 5' or 3' end. Within this length range, PS-ON diastereomers that co-eluted in HPLC could be separated by SPOIS at yields of 84% and 89% for Rp and Sp stereoisomers, respectively. Furthermore, as each Rp phosphorothioate linkage can be bound by SBD, SPOIS allowed the separation of stereoisomers with multiple uniform Sp configurations for multiple phosphorothioate modifications. A second generation of SPOIS was developed using the thermolabile and non-sequence-specific SBDPed, enabling fast and high-yield recovery of PS substrate stereoisomers for the DNAzyme Cd16 and further demonstrating the efficiency of this method. KEY POINTS: • SPOIS allows isomer separations of the Rp and Sp isomers co-eluted on HPLC. • SPOIS can obtain Sp isomers with 5 min and Rp in 20 min from PS-ON diastereomers. • SPOIS was successfully applied to separate isomers of PS substrates of DNAzyme.

Project description:ObjectiveThe liver performs a central role in regulating energy homeostasis by increasing glucose output during fasting. Recent studies on Argonaute2 (Ago2), a key RNA-binding protein mediating the microRNA pathway, have illustrated its role in adaptive mechanisms according to changes in metabolic demand. Here we sought to characterize the functional role of Ago2 in the liver in the maintenance of systemic glucose homeostasis.MethodsWe first analyzed Ago2 expression in mouse primary hepatocyte cultures after modulating extracellular glucose concentrations and in the presence of activators or inhibitors of glucokinase activity. We then characterized a conditional loss-of-function mouse model of Ago2 in liver for alterations in systemic energy metabolism.ResultsHere we show that Ago2 expression in liver is directly correlated to extracellular glucose concentrations and that modulating glucokinase activity is adequate to affect hepatic Ago2 levels. Conditional deletion of Ago2 in liver resulted in decreased fasting glucose levels in addition to reducing hepatic glucose production. Moreover, loss of Ago2 promoted hepatic expression of AMP-activated protein kinase α1 (AMPKα1) by de-repressing its targeting by miR-148a, an abundant microRNA in the liver. Deletion of Ago2 from hyperglycemic, obese, and insulin-resistant Lepob/ob mice reduced both random and fasted blood glucose levels and body weight and improved insulin sensitivity.ConclusionsThese data illustrate a central role for Ago2 in the adaptive response of the liver to fasting. Ago2 mediates the suppression of AMPKα1 by miR-148a, thereby identifying a regulatory link between non-coding RNAs and a key stress regulator in the hepatocyte.

Project description:Hepatic gluconeogenesis is essential for glucose homeostasis and also a therapeutic target for type 2 diabetes, but its mechanism is incompletely understood. Here, we report that Sam68, an RNA-binding adaptor protein and Src kinase substrate, is a novel regulator of hepatic gluconeogenesis. Both global and hepatic deletions of Sam68 significantly reduce blood glucose levels and the glucagon-induced expression of gluconeogenic genes. Protein, but not mRNA, levels of CRTC2, a crucial transcriptional regulator of gluconeogenesis, are >50% lower in Sam68-deficient hepatocytes than in wild-type hepatocytes. Sam68 interacts with CRTC2 and reduces CRTC2 ubiquitination. However, truncated mutants of Sam68 that lack the C- (Sam68ΔC) or N-terminal (Sam68ΔN) domains fails to bind CRTC2 or to stabilize CRTC2 protein, respectively, and transgenic Sam68ΔN mice recapitulate the blood-glucose and gluconeogenesis profile of Sam68-deficient mice. Hepatic Sam68 expression is also upregulated in patients with diabetes and in two diabetic mouse models, while hepatocyte-specific Sam68 deficiencies alleviate diabetic hyperglycemia and improves insulin sensitivity in mice. Thus, our results identify a role for Sam68 in hepatic gluconeogenesis, and Sam68 may represent a therapeutic target for diabetes.

Project description:The physiological and metabolic functions of PIMT/TGS1, a third-generation transcriptional apparatus protein, in glucose homeostasis sustenance are unclear. Here, we observed that the expression of PIMT was upregulated in the livers of short-term fasted and obese mice. Lentiviruses expressing Tgs1-specific shRNA or cDNA were injected into wild-type mice. Gene expression, hepatic glucose output, glucose tolerance, and insulin sensitivity were evaluated in mice and primary hepatocytes. Genetic modulation of PIMT exerted a direct positive impact on the gluconeogenic gene expression program and hepatic glucose output. Molecular studies utilizing cultured cells, in vivo models, genetic manipulation, and PKA pharmacological inhibition establish that PKA regulates PIMT at post-transcriptional/translational and post-translational levels. PKA enhanced 3'UTR-mediated translation of TGS1 mRNA and phosphorylated PIMT at Ser656, increasing Ep300-mediated gluconeogenic transcriptional activity. The PKA-PIMT-Ep300 signaling module and associated PIMT regulation may serve as a key driver of gluconeogenesis, positioning PIMT as a critical hepatic glucose sensor.

Project description:The relative activity of a zinc-containing cyclic AMP phosphodiesterase towards the (Sp)- compared with the (Rp)-diastereoisomer of cyclic adensine phosphorothioate varied with the identity of the free bivalent metal ion from more than 35 to 0.074 along the series Mg2+ greater than Mn2+ greater than Co2+ greater than Zn2+ greater than Cd2+, showing that this ion, and not the tightly bound zinc, bonds to the phosphorothioate moiety of the substrate.

Project description:Sodium meta-arsenite (SA) is implicated in the regulation of hepatic gluconeogenesis-related genes in vitro; however, the effects in vivo have not been studied. We investigated whether SA has antidiabetic effects in a type 2 diabetic mouse model. Diabetic db/db mice were orally intubated with SA (10?mg?kg(-1) body weight/day) for 8 weeks. We examined hemoglobin A1c (HbA1c), blood glucose levels, food intake, and body weight. We performed glucose, insulin, and pyruvate tolerance tests and analyzed glucose production and the expression of gluconeogenesis-related genes in hepatocytes. We analyzed energy metabolism using a comprehensive animal metabolic monitoring system. SA-treated diabetic db/db mice had reduced concentrations of HbA1c and blood glucose levels. Exogenous glucose was quickly cleared in glucose tolerance tests. The mRNA expressions of genes for gluconeogenesis-related enzymes, glucose 6-phosphatase (G6Pase), and phosphoenolpyruvate carboxykinase (PEPCK) were significantly reduced in the liver of SA-treated diabetic db/db mice. In primary hepatocytes, SA treatment decreased glucose production and the expression of G6Pase, PEPCK, and hepatocyte nuclear factor 4 alpha (HNF-4?) mRNA. Small heterodimer partner (SHP) mRNA expression was increased in hepatocytes dependent upon the SA concentration. The expression of Sirt1 mRNA and protein was reduced, and acetylated forkhead box protein O1 (FoxO1) was induced by SA treatment in hepatocytes. In addition, SA-treated diabetic db/db mice showed reduced energy expenditure. Oral intubation of SA ameliorates hyperglycemia in db/db mice by reducing hepatic gluconeogenesis through the decrease of Sirt1 expression and increase in acetylated FoxO1.

Project description:Background and purposeHepatic mitochondrial pyruvate carrier (MPC) transports pyruvate into mitochondria. This study investigated the involvement of MPC1 in hepatic glucagon response, in order to identify a possible pharmacological intervention.Experimental approachThe correlation between hepatic glucagon response and MPC1 induction was investigated in fasted mice and primary hepatocytes. The effects of ginsenoside Rb1 on MPC1 function were observed.Key resultsGlucagon challenge raised blood glucose with hepatic MPC1 induction, and inhibition of MPC induction coincided with a reduced rise in blood glucose. cAMP-responsive element-binding protein (CREB) knockdown blocked glucagon-induced MPC1 expression, while CREB overexpression increased MPC1 expression. Luciferase reporter, chromatin immunoprecipitation assay, and promoter mutation confirmed that CREB increased MPC1 transcription through gene promoter induction. CREB regulated transcription co-activator 2 nuclear translocation was also required for CREB to promote MPC1 induction. Glucagon shifted mitochondrial pyruvate towards carboxylation for gluconeogenesis via the opposite regulation of pyruvate dehydrogenase and carboxylase with respect to MPC1 induction. MPC1 induction was necessary for glucagon to promote pyruvate-driven hepatic glucose production (HGP), but glucagon failed to influence HGP from other gluconeogenic substrates routed into the tricarboxylic acid cycle, independent of MPC. Rb1 blocked cAMP signalling by inhibiting AC activity and deactivated CREB by dephosphorylation, possibly contributing to inhibiting MPC1 induction to reduce HGP.Conclusions and implicationsCREB transcriptionally up-regulates MPC1 to provide pyruvate for gluconeogenesis. Rb1 reduced cAMP formation which consequently reduced CREB-mediated MPC1 induction and thereby might contribute to limiting pyruvate-dependent HGP. These results suggest a therapeutic strategy to reduce hyperglycaemia in diabetes.