KIAA1363 affects retinyl ester turnover in cultured murine and human hepatic stellate cells

Large quantities of vitamin A are stored as retinyl esters (REs) in specialized liver cells, the hepatic stellate cells (HSCs). To date, the enzymes controlling RE degradation in HSCs are poorly understood. In this study, we identified KIAA1363 (also annotated as arylacetamide deacetylase 1 or neutral cholesterol ester hydrolase 1) as a novel RE hydrolase. We show that KIAA1363 is expressed in the liver, mainly in HSCs, and exhibits RE hydrolase activity at neutral pH. Accordingly, addition of the KIAA1363-specific inhibitor JW480 largely reduced RE hydrolase activity in lysates of cultured murine and human HSCs. Furthermore, cell fractionation experiments and confocal microscopy studies showed that KIAA1363 localizes to the endoplasmic reticulum. We demonstrate that overexpression of KIAA1363 in cells led to lower cellular RE content after a retinol loading period. Conversely, pharmacological inhibition or shRNA-mediated silencing of KIAA1363 expression in cultured murine and human HSCs attenuated RE degradation. Together, our data suggest that KIAA1363 affects vitamin A metabolism of HSCs by hydrolyzing REs at the endoplasmic reticulum, thereby counteracting retinol esterification and RE storage in lipid droplets.     

Carbon-13 nuclear magnetic resonance study of spin labelled cholesteryl ester in model membranes

Carbon-13 NMR longitudinal relaxation times for unilamellar vesicles of egg phosphatidyl-choline (PC) in aqueous dispersion have been measured following the incorporation of spin labelled cholesteryl palmitate. The spin label induced relaxation rates. 1/T_1.5L, for fatty acyl chain carbons show that the C5 segment of the cholesteryl ester acyl chain is located near the C1 and C2 segments of the phospholipid acyl chains. A greater spin label induced enhancement of relaxation rate was observed for the inner vesicle layer than for the outer, and is attributed to a higher ester incorporation and/or tighter lipid packing in the inner layer.     

The accumulation and metabolism of glycosphingolipids in primary kidney cell cultures from beige mice

In the normal C57BL/6J male mouse a specific subset of the kidney glycosphingolipids which is associated with multilamellar bodies of lysosomal origin and represents about 10% of the total kidney glycolipids, is excreted into the urine each day. This excretion is blocked and glycosphingolipids accumulate in the kidney of bg ^J/bg^J mutants of this strain. To examine this process in vitro, glycosphingolipid metabolism and excretion were studied in beige mouse kidney cell cultures. Primary kidney cell cultures from male C57BL/6J control and bg ^J/bg ^J beige mutants were grown in D-valine medium and glycosphingolipids labeled with [³H]palmitate. As we have shown previously, the giant lysosomes of altered morphology were maintained in cultures of the beige kidney cells. Beige-J and control cells synthesized the same types of glycosphingolipids, but the mutant cells had quantitatively higher levels of these compounds than control cells, as determined by high performance liquid chromatography. Beige-J cells incorporated more [³H]palmitate into glycospingholipids than control cells on a cpm/mg protein basis and the specific activity (cpm/pmole glycosphingolipid) was lower in beige cells. Medium from beige-J cells accumulated more glycosphingolipids than that from control cells in a 24 h period. The glycosphingolipids released into the medium as determined by HPLC were primarily non-lysosomal types and both control and mutant cells retained the glycosphingolipids associated with lysosomal multilamellar bodies excreted in vivo. The elevated levels of lysosomal glycosphingolipids and the dysmorphic lysosomes in primary cultures of beige cells, then, are not caused by a mutant block in secretion of lysosomes. (Mol Cell Biochem 118: 61–66, 1992)     

Presence and titer of methyl palmitate in the Medfly (Ceratitis capitata) during reproductive maturation

The relative amounts of methyl palmitate (MP) during the first 10 days post-eclosion were determined in whole-body extracts of adult female Ceratitis capitata by SIM monitoring of the 74 m/z fragment. MP peaks in receptive 3-day-old virgin females coincide with previously reported production of Juvenile Hormone (JH) by the corpus allatum (CA). Mating in the Medfly induces female non-receptivity. Indirect evidence suggests that the mevalonate pathway to sesquiterpene biosynthesis is underdeveloped in newly eclosed females. We propose that the pathway leading to synthesis of JH is markedly diverted in non-receptive virgin females to fatty acid synthesis, and partly so-in non-receptive mated females, leading to production of palmitic acid, presumably methylated thereafter. MP is depressed and remains marginal thereafter for the 7 days examined in the virgin female but goes through an apparent second cycle in the mated female. This contrasts with the consistent increase of allatal biosynthesis of MP of virgin and mated females previously reported and suggests additional control mechanisms in vivo. During the period of reduced receptivity following the first mating a second apparent peak of MP is observed. MP is a metabolic default metabolite of reproductively immature females whose putative role in reproductive physiology remains to be defined.     

Arecoline Stimulation of Radiolabeled Arachidonate Incorporation from Plasma Into Brain Microvessels of Awake Rat

The cholinergic agonist, arecoline, was used to examine the effects of cholinergic stimulation upon incorporation of radiolabeled arachidonic acid from blood into cerebral microvessels of awake rats. Animals received a single I.P. injection of arecoline (1 mg/kg) followed 3 to 5 minutes later by a 5 minute intravenous infusion of [1-¹⁴C]arachidonic acid (AA) (170 Ci/kg) via the femoral vein. Timed arterial blood samples were collected over 20 minutes following the start of infusion, after which the animal was killed, and the brain was removed. The incorporation coefficient k* for [1-¹⁴C] AA was approximately 2-fold higher in microvessels isolated from arecoline-injected than from sham-injected animals. The data demonstrate in an in vivo paradigm, that activation of cholinergic pathways within the rat CNS stimulates arachidonic acid turnover in cerebral microvessels. This suggests a direct involvement of this fatty acid in second messenger function within microvessel endothelial cells and possibly attached pericytes.     

Relationship between the fatty acids of fat body triacylglycerol and lipophorin diacylglycerol of non-diapause and diapause larvae of the southwestern corn borer,Diatraea grandiosella

The fatty acids of the triacylglycerol reserves in the fat body and of the diacylglycerol of lipophorin in the hemolymph of non-diapause and diapause larvae of D. grandiosella were compared. For both non-diapause and diapause larvae palmitate, palmitoleate, oleate, and linoleate were the predominant fatty acids present in fatty body triacylglycerol, and palmitate, oleate, and linoleate were the predominant fatty acids present in lipophorin diacylglycerol. However, differences were detected in the relative amounts of oleate and linoleate present in lipophorin diacylglycerol of non-diapause and diapause larvae. The relative amount of linoleate in lipophorin diacylglycerol declined during diapause, whereas that of oleate remained relatively high during diapause. The fatty acid profile of lipophorin diacylglycerol from non-diapause larvae treated with a juvenile hormone analog to induce a diapause-like state more closely matched that of diapause larvae than that of non-diapause larvae. The differences detected in the fatty acid composition of lipophorin diacylglycerol in non-diapause and diapause larvae appear to be due mainly to the different physiological states rather than to the different rearing temperatures employed. The results are discussed in relation to the essential role fatty acids, especially oleate, play in the survival of diapause larvae.     

Ecophysiology of syntrophic communities that degrade saturated and unsaturated long-chain fatty acids

Syntrophic relationships are the key for biodegradation in methanogenic environments. We review the ecological and physiological features of syntrophic communities involved in the degradation of saturated and unsaturated long-chain fatty acids (LCFA), as well as their potential application to convert lipids/fats containing waste to biogas. Presently, about 14 species have been described with the ability to grow on fatty acids in syntrophy with methanogens, all belonging to the families Syntrophomonadaceae and Syntrophaceae . The principle pathway of LCFA degradation is through β-oxidation, but the initial steps in the conversion of unsaturated LCFA are unclear. Communities enriched on unsaturated LCFA also degrade saturated LCFA, but the opposite generally is not the case. For efficient methane formation, the physical and inhibitory effects of LCFA on methanogenesis need to be considered. LCFA adsorbs strongly to biomass, which causes encapsulation of active syntrophic communities and hampers diffusion of substrate and products in and out of the biomass. Quantification of archaea by real-time PCR analysis suggests that potential LCFA inhibitory effect towards methanogens might be reversible. Rather, the conversion of adsorbed LCFA in batch assays was shown to result in a significant increase of archaeal cell numbers in anaerobic sludge samples.     

Methyl palmitate: a novel product of the Medfly (Ceratitis capitata) corpus allatum

The corpus allatum (CA) of adult female Ceratitis capitata produces methyl palmitate (MP) in vitro, in addition to JHB₃ and JH III. Biosynthesized MP migrates on TLC and co-elutes from RP-18 HPLC with synthetic MP. Its identity is verified herein by GCMS. MP production is up-regulated twofold by mevastatin, an inhibitor of mevalonic acid-dependent isoprene biosynthesis. Fosmidomycin, an inhibitor of mevalonic acid-independent isoprene synthesis in graminaceous plants, up-regulates MP synthesis by about fourfold. However, it does not depress JHB₃ biosynthesis concurrently. This suggests that the initial enzyme(s) in the conversion of 1-deoxy-xylulose 5-phosphate to isoprene is presumably present in C. capitata, but is inhibited by fosmidomycin, and this inhibition diverts precursors to MP synthesis. Phytol, an acyclic diterpene, might be suppressing isoprene biosynthesis by CA, thereby resulting in a fourfold increase in the MP biosynthesis. Linolenic acid is an end-product and its presence in incubation media up-regulates MP biosynthesis by twofold, presumably due to the feedback diversion to biosynthesis of C_16:0 and its methyl ester. Biosynthesis of MP is markedly depressed after mating, while otherwise maintained at significantly higher levels in virgin females. MP biosynthesis is significantly reduced in virgin females by direct axonal control but is less consistent after mating.     

Rapid measurement of plasma free fatty acid concentration and isotopic enrichment using LC/MS

Measurements of plasma free fatty acids (FFA) concentration and isotopic enrichment are commonly used to evaluate FFA metabolism. Until now, gas chromatography-combustion-isotope ratio mass spectrometry (GC/C/IRMS) was the best method to measure isotopic enrichment in the methyl derivatives of ¹³C-labeled fatty acids. Although IRMS is excellent for analyzing enrichment, it requires time-consuming derivatization steps and is not optimal for measuring FFA concentrations. We developed a new, rapid, and reliable method for simultaneous quantification of ¹³C-labeled fatty acids in plasma using high-performance liquid chromatography-mass spectrometry (HPLC/MS). This method involves a very quick Dole extraction procedure and direct injection of the samples on the HPLC system. After chromatographic separation, the samples are directed to the mass spectrometer for electrospray ionization (ESI) and analysis in the negative mode using single ion monitoring. By employing equipment with two columns connected parallel to a mass spectrometer, we can double the throughput to the mass spectrometer, reducing the analysis time per sample to 5 min. Palmitate flux measured using this approach agreed well with the GC/C/IRMS method. This HPLC/MS method provides accurate and precise measures of FFA concentration and enrichment.     

Compound K protects MIN6N8 pancreatic β‐cells against palmitate‐induced apoptosis through modulating SAPK/JNK activation

Chronic elevation of NEFAs (non‐esterified fatty acids) due to insulin resistance and obesity has been shown to be associated with increased β‐cell apoptosis and with the aetiology of the reduced β‐cell mass of Type 2 diabetes. SAPK (stress‐activated protein kinase)/JNK (c‐Jun N‐terminal kinase) have been implicated in the control of apoptosis. C‐K [compound K; 20‐O‐β‐d ‐glucopyranosyl‐20(S)‐protopanaxadiol] is the main intestinal bacterial metabolite of protopanaxadiol ginsenosides. Currently, little is known about the effects of C‐K on β‐cells with the presence of NEFAs. The aim of the present study was to investigate the in vitro protective effect of C‐K on MIN6N8 mouse insulinoma β‐cells against NEFA‐induced apoptosis, as well as the modulating effect on SAPK/JNK activation. Our results have shown that C‐K inhibited the palmitate‐induced apoptosis through modulating SAPK/JNK activation. We conclude that C‐K protects against β‐cell death and that, by anti‐apoptotic activity, C‐K may contribute to the previously reported anti‐diabetic actions of ginseng.