Acetyl-CoA carboxylase 2 inhibition reduces skeletal muscle bioactive lipid content and attenuates progression of type 2 diabetes in Zucker diabetic fatty rats.

Intramyocellular lipid (IMCL) accumulation in skeletal muscle is closely associated with development of insulin resistance. In particular, diacylglycerol and ceramide are currently considered as causal bioactive lipids for impaired insulin action. Recently, inhibition of acetyl-CoA carboxylase 2 (ACC2), which negatively modulates mitochondrial fatty acid oxidation, has been shown to reduce total IMCL content and improve whole-body insulin resistance. This study aimed to investigate whether ACC2 inhibition-induced compositional changes in bioactive lipids, especially diacylglycerol and ceramide, within skeletal muscle contribute to the improved insulin resistance. In skeletal muscle of normal rats, treatment of the ACC2 inhibitor compound 2e significantly decreased both diacylglycerol and ceramide levels while having no significant impact on other lipid metabolite levels. In skeletal muscle of Zucker diabetic fatty (ZDF) rats, which exhibited greater lipid accumulation than that of normal rats, compound 2e significantly decreased diacylglycerol and ceramide levels corresponding to reduced long chain acyl-CoA pools. Additionally, in the lipid metabolomics study, ZDF rats treated with compound 2e also showed improved diabetes-related metabolic disturbance, as reflected by delayed hyperinsulinemia as well as upregulated gene expression associated with diabetic conditions in skeletal muscle. These metabolic improvements were strongly correlated with the bioactive lipid reductions. Furthermore, long-term treatment of compound 2e markedly improved whole-body insulin resistance, attenuated hyperglycemia and delayed insulin secretion defect even at severe diabetic conditions. These findings suggest that ACC2 inhibition decreases diacylglycerol and ceramide accumulation within skeletal muscle by enhancing acyl-CoA breakdown, leading to attenuation of lipid-induced insulin resistance and subsequent diabetes progression.

Elevating acetyl-CoA levels reduces aspects of brain aging.

Because old age is the greatest risk factor for dementia, a successful therapy will require an understanding of the physiological changes that occur in the brain with aging. Here, two structurally distinct Alzheimer's disease (AD) drug candidates, CMS121 and J147, were used to identify a unique molecular pathway that is shared between the aging brain and AD. CMS121 and J147 reduced cognitive decline as well as metabolic and transcriptional markers of aging in the brain when administered to rapidly aging SAMP8 mice. Both compounds preserved mitochondrial homeostasis by regulating acetyl-coenzyme A (acetyl-CoA) metabolism. CMS121 and J147 increased the levels of acetyl-CoA in cell culture and mice via the inhibition of acetyl-CoA carboxylase 1 (ACC1), resulting in neuroprotection and increased acetylation of histone H3K9 in SAMP8 mice, a site linked to memory enhancement. These data show that targeting specific metabolic aspects of the aging brain could result in treatments for dementia.

An Intestinal Farnesoid X Receptor-Ceramide Signaling Axis Modulates Hepatic Gluconeogenesis in Mice.

Increasing evidence supports the view that intestinal farnesoid X receptor (FXR) is involved in glucose tolerance and that FXR signaling can be profoundly impacted by the gut microbiota. Selective manipulation of the gut microbiota-FXR signaling axis was reported to significantly impact glucose intolerance, but the precise molecular mechanism remains largely unknown. Here, caffeic acid phenethyl ester (CAPE), an over-the-counter dietary supplement and an inhibitor of bacterial bile salt hydrolase, increased levels of intestinal tauro-ß-muricholic acid, which selectively suppresses intestinal FXR signaling. Intestinal FXR inhibition decreased ceramide levels by suppressing expression of genes involved in ceramide synthesis specifically in the intestinal ileum epithelial cells. The lower serum ceramides mediated decreased hepatic mitochondrial acetyl-CoA levels and pyruvate carboxylase (PC) activities and attenuated hepatic gluconeogenesis, independent of body weight change and hepatic insulin signaling in vivo; this was reversed by treatment of mice with ceramides or the FXR agonist GW4064. Ceramides substantially attenuated mitochondrial citrate synthase activities primarily through the induction of endoplasmic reticulum stress, which triggers increased hepatic mitochondrial acetyl-CoA levels and PC activities. These results reveal a mechanism by which the dietary supplement CAPE and intestinal FXR regulates hepatic gluconeogenesis and suggest that inhibiting intestinal FXR is a strategy for treating hyperglycemia.

Acetate-dependent mechanisms of inborn tolerance to ethanol.

AIMS: To clarify the role of acetate in neurochemical mechanisms of the initial (inborn) tolerance to ethanol. METHODS: Rats with low and high inborn tolerance to hypnotic effect of ethanol were used. In the brain region homogenates (frontal and parietal cortex, hypothalamus, striatum, medulla oblongata) and brain cortex synaptosomes, the levels of acetate, acetyl-CoA, acetylcholine (AcH), the activity of pyruvate dehydrogenase (PDG) and acetyl-CoA synthetase were examined. RESULTS: It has been found that brain cortex of rats with high tolerance to hypnotic effect of ethanol have higher level of acetate and activity of acetyl-CoA synthetase, but lower level of acetyl-СCoA and activity of PDG. In brain cortex synaptosomes of tolerant rats, the pyruvate oxidation rate as well as the content of acetyl-CoA and AcH synthesis were lower when compared with intolerant animals. The addition of acetate into the medium significantly increased the AcH synthesis in synaptosomes of tolerant, but not of intolerant animals. Calcium ions stimulated the AcH release from synaptosomes twice as high in tolerant as in intolerant animals. Acetate eliminated the stimulating effect of calcium ions upon the release of AcH in synaptosomes of intolerant rats, but not in tolerant animals. As a result, the quantum release of AcH from synaptosomes in the presence of acetate was 6.5 times higher in tolerant when compared with intolerant rats. CONCLUSION: The brain cortex of rats with high inborn tolerance to hypnotic effect of ethanol can better utilize acetate for the acetyl-CoA and AcH synthesis, as well as being resistant to inhibitory effect of acetate to calcium-stimulated release of AcH. It indicates the metabolic and cholinergic mechanisms of the initial tolerance to ethanol.

Does caffeine alter muscle carbohydrate and fat metabolism during exercise?

Caffeine, an adenosine receptor antagonist, has been studied for decades as a putative ergogenic aid. In the past 2 decades, the information has overwhelmingly demonstrated that it indeed is a powerful ergogenic aid, and frequently theories have been proposed that this is due to alterations in fat and carbohydrate metabolism. While caffeine certainly mobilizes fatty acids from adipose tissue, rarely have measures of the respiratory exchange ratio indicated an increase in fat oxidation. However, this is a difficult measure to perform accurately during exercise, and small changes could be physiologically important. The few studies examining human muscle metabolism directly have also supported the fact that there is no change in fat or carbohydrate metabolism, but these usually have had a small sample size. We combined the data from muscle biopsy analyses of several similar studies to generate a sample size of 16-44, depending on the measure. We examined muscle glycogen, citrate, acetyl-CoA, glucose-6-phosphate, and cyclic adenosine monophosphate (cAMP) in resting samples and in those obtained after 10-15 min of exercise at 70%-85% maximal oxygen consumption. Exercise decreased (p < 0.05) glycogen and increased (p < 0.05) citrate, acetyl-CoA, and glucose-6-phosphate. The only effects of caffeine were to increase (p < 0.05) citrate in resting muscle and cAMP in exercise. There is very little evidence to support the hypothesis that caffeine has ergogenic effects as a result of enhanced fat oxidation. Individuals may, however, respond differently to the effects of caffeine, and there is growing evidence that this could be explained by common genetic variations.

Effects of zinc on SN56 cholinergic neuroblastoma cells.

Zinc is a trace element necessary for proper development and function of brain cells. However, excessive accumulation of zinc exerts several cytotoxic effects in the brain. The aim of this work was to see whether cytotoxic effects of zinc are quantitatively correlated with changes in acetyl-CoA metabolism. The zinc levels up to 0.20 mmol/L caused concentration-dependent inhibition of pyruvate dehydrogenase (PDH) activity that correlated with the increase in trypan blue-positive fraction and the decrease in cultured cell number (r = 0.96, p = 0.0001). Chronic exposure of cells to 0.15 mmol/L zinc decreased choline acetyltransferase and aconitase activities, cytoplasmic acetyl-CoA and whole cell ATP level by 38%, 57%, 35%, and 62%, respectively but caused no change in mitochondrial acetyl-CoA level and activities of other enzymes of glycolytic and tricarboxylic acid cycle. dl-alpha-lipoamide when added simultaneously with zinc to cultured cells or their homogenates attenuated its chronic or acute suppressive effects. In homogenates of chronically Zn-treated cells, lipoamide overcame PDH but not aconitase inhibition. Presented data indicate that acute-transient elevation of zinc caused reversible inhibition of PDH, aconitase activities and acetyl-CoA metabolism, which when prolonged could lead to irreversible enzyme inactivation yielding decrease in cell viability and secondary suppression of their cholinergic phenotype.

Acute and chronic effects of aluminum on acetyl-CoA and acetylcholine metabolism in differentiated and nondifferentiated SN56 cholinergic cells.

Mechanisms of preferential loss of cholinergic neurons in the course of neurodegenerative diseases are unknown. Therefore, we investigated whether differentiation-evoked changes in acetyl-CoA and acetylcholine metabolism contribute to the susceptibility of cholinergic neuroblastoma to cytotoxic effects of Al. In SN56 cells differentiated with retinoic acid and dibutyryl cAMP (DC), pyruvate utilization and acetyl-CoA content were lower and acetylcholine level higher than in nondifferentiated cells (NC), respectively. In DC Al and Ca accumulations were 50% and 100%, respectively higher than in NC. Acute Al addition caused inhibition, whereas its chronic application had no effect on pyruvate utilization both in NC and in DC. On the other hand, in both experiments, Al evoked a greater decrease of acetyl-CoA level in DC than in NC. Acute addition of Al depressed acetylcholine release from DC to two times lower values than in NC. On the other hand, chronic addition of Al increased ACh release from DC over twofold, being without effect on its release from NC. These findings indicate that higher accumulation of Ca, along with low levels of acetyl-CoA, could make DC more susceptible to neurotoxic inputs than NC. Excessive acetylcholine release, evoked by Al, is likely to increase acetyl-CoA utilization for resynthesis of the neurotransmitter pool and cause deficit of this metabolite in DC. On the other hand, NC, owing to lower Ca accumulation, slower ACh metabolism, and higher level of acetyl-CoA, would be less prone to these harmful conditions.

Transient mRNA responses in chemostat cultures as a method of defining putative regulatory elements: application to genes involved in Saccharomyces cerevisiae acetyl-coenzyme A metabolism.

To identify common regulatory sequences in the promoters of genes, transcription of 31 genes of Saccharomyces cerevisiae was analysed during the transient response to a glucose pulse in a chemostat culture. mRNA levels were monitored during the subsequent excess glucose, ethanol and acetate phases, while other conditions were kept constant. This setup allowed a direct comparison between regulation by glucose, ethanol and acetate. Genes with identical regulation patterns were grouped to identify regulatory elements in the promoters. In respect to regulation on glucose four classes were identified: no transcription under any of the conditions tested, no difference in regulation on glucose, induced on glucose and repressed on glucose. In addition, genes were found that were repressed or induced on ethanol or acetate. Sequence alignment of genes with similar regulation patterns revealed five new, putative regulatory promoter elements. (i) The glucose-inducible fermentation genes PDC1 and ADH1 share the sequence ATACCTTCSTT. (ii) Acetate-repression might be mediated by the decamer CCCGAG RGGA, present in the promoters of ACS2 and ACR1. (iii) A specific element (CCWTTSRNCCG) for the glyoxylate cycle was present in seven genes studied: CIT2, ICL1, MLS1, MDH2, CAT2, ACR1 and ACH1. These genes were derepressed on ethanol or acetate. (iv) The sequence ACGTSCRGAATGA was found in the promoters of the partially ethanol-repressed genes ACS1 and YAT1. (v) Ethanol induction, as seen for ACS2, ADH3 and MDH1, might be mediated via the sequence CGGSGCCGRAG.

Regulation of poly(beta-hydroxybutyrate) synthesis in Methylobacterium rhodesianum MB 126 growing on methanol or fructose.

The intracellular concentration of CoA metabolites and nucleotides was determined in batch cultures of Methylobacterium rhodesianum grown on methanol and shifted to growth on fructose. The intracellular concentration of CoA decreased from a high value of 0.6 nmol/mg poly(beta-hydroxybutyrate)-free bacterial dry mass during growth on methanol to a low value of 0.03 nmol/mg poly(beta-hydroxybutyrate)-free bacterial dry mass after a shift to fructose as a carbon source. The levels of NADH, NADPH, and acetyl-CoA were also lower. Under these conditions, acetyl-CoA was metabolized by both citrate synthase and beta-ketothiolase, and poly(beta-hydroxybutyrate) synthesis and growth occurred simultaneously during growth on fructose. Moreover, the level of ATP was approximately 50% lower during growth on fructose, supporting the hypothesis of a bottleneck in the energy supply during the growth of M. rhodesianum with fructose.

Inhibition studies of the carnitine acetyltransferase from skeletal muscle of the camel (Camelus dromedarius) by sulfhydryl reagents and metal ions.

The effect of certain sulfhydryl reagents and metal ions were studied on the carnitine acetyltransferase (CAT) activity from the skeletal muscle of the Arabian camel (Camelus dromedarius). DTNB and iodoacetamide caused concentration and time dependent inhibition of CAT activity. The inhibition seen with these sulfhydryl reagents could be protected with prior incubation of the enzyme with acetyl-Co A, suggesting that these reagents might interact with the same site. Among the various metal ions tested, Cu2+, Zn2+ and Hg2+ caused total inhibition at very low concentrations, while, Mn2+, Mo6+ and Co2+ caused between 32-52% inhibition at 10 mM concentrations. Alkali earth divalent metals Mg2+ and Ca2+ caused less than 15% inhibition at this concentration. These metal ions are probably interacting at certain nucleophilic groups in the enzyme thus disrupting its tertiary structure.

Free and esterified coenzyme A in the liver and muscles of chronically hyperammonemic mice treated with sodium benzoate.

Ammonia toxicity and relative sodium benzoate toxicity alters the energy metabolism, leading to a decrease of adenosine triphosphate and free coenzyme A levels. The object of the present study was to analyze the hepatic and muscular acyl-coenzyme A profiles in chronically hyperammonemic mice treated with varying doses of the sodium benzoate. An enzymatic method was used for the measurement of free coenzyme A, acetyl-coenzyme A, and medium and long chain acyl-coenzyme A. Untreated chronic hyperammonemia resulted in a decrease in acetyl-coenzyme A and an increase in the long chain acyl-coenzyme A in the liver, accompanied by an increase in total coenzyme A in the muscular tissues. Treatment with sodium benzoate at moderate doses, caused a decrease in the hepatic free and esterified coenzyme A while these were increased at higher doses. We conclude that chronic hyperammonemia is responsible for qualitative changes in the free and esterified coenzyme A profile in the liver, while causing qualitative and quantitative changes in the muscular tissue, probably due to an inhibition of mitochondrial oxidation. The sodium benzoate had a biphasic effect on the hepatic content of free and esterified coenzyme A, suggesting a degradation of coenzyme A at moderate doses. However, at a higher dose of benzoate, the possibility of glycine mobilization and/or a significant formation of acylcarnitines is proposed as an important factor in an increase of the hepatic total coenzyme A.