Sex-dependent antioxidant enzyme activities and lipid peroxidation in ageing mouse brain

We investigated whether oxidant status and antioxidant enzyme activities during ageing of mouse brain are regulated in sex-dependent manner. In the homogenate from the brain of 1, 4, 10 and 18 months old male and female CBA mice, lipid peroxidation (LPO), total superoxide dismutase (tSOD), catalase (CAT) and glutathione peroxidase (Gpx) were determined. LPO was age- and sex-related, favoring males over females throughout the lifespan with the peak in both sexes at 10 months of age. Throughout ageing, no difference in tSOD activity between male and female brains was observed, except in immature 1 month old mice. Gender-related difference in Gpx activity was observed, with higher level in females comparing to males, reaching statistical significance in senescent (18 months old) animals. CAT activity was drastically changed with ageing in both the male and female brain. We found different age associated trends in CAT activity in males and females: decreased with age in males and increased with age in females. Taken together, the present findings indicate that brains of female mice have lower oxidant and higher antioxidant capacity mostly related to CAT and to a lesser extent to Gpx activity.     

Parameters related to lipid metabolism as markers of myelination in mouse brain

Myelination, during both normal development and with respect to disorders of myelination, is commonly studied by morphological and/or biochemical techniques that assay as their end-points the extent of myelination. The rate of myelination is potentially a more useful parameter, but it is difficult and time-consuming to establish, requiring a complete developmental study with labor-intensive methodology. We report herein development of methodology to assay the absolute rate of myelination at any desired time during development. This involves intraperitoneal injection of (3)H(2)O to label body water pools, followed by determination of label in the myelin-specific lipid, cerebroside. The absolute amount of cerebroside synthesized can then be calculated from the specific radioactivity of body water and knowledge of the number of hydrogens from water incorporated into cerebroside. During development, the rate of cerebroside synthesis correlated well with the rate of accumulation of the myelin-specific components, myelin basic protein and cerebroside. For purposes of control, we also tested other putative, albeit less quantitative, indices of the rate of myelination. Levels of mRNA for ceramide galactosyltransferase (rate-limiting enzyme in cerebroside synthesis) and for myelin basic protein did not closely correlate with myelination at all times. Cholesterol synthesis closely matched the rate of cholesterol accumulation but did not track well with myelination. Synthesis of fatty acids did not correlate well with accumulation of either fatty acids (phospholipids) or myelin markers. We conclude that measurement of cerebroside synthesis rates provides a good measure of the rate of myelination. This approach may be useful as an additional parameter for examining the effects of environmental or genetic alterations on the rate of myelination.     

Somatostatin effects on the cyclic AMP system and lipid metabolism in mouse brain

The effect of somatostatin on cyclic AMP-protein kinase system and lipid metabolism was studied in mouse brain. Subcutaneous injection of the peptide decreased the cyclic AMP and cyclic GMP levels (70% and 60% respectively) as well as protein kinase and triglyceride lipase activities (30%). Cyclic AMP binding protein activity was not affected. Experiments carried out with [¹⁴C]acetate as precursor of lipids seem to indicate that somatostatin blocks the fatty acid turnover. On the other hand, the general decrease of³²P incorporation into all phospholipids by somatostatin suggests that the peptide interferes with the precursor uptake into phospholipids. The findings reported here indicate that somatostatin has a role on brain metabolism and further add more data in support for its neuromodulating action.     

Hydroperoxide isomerase: a new enzyme of lipid metabolism

An enzyme has been isolated from flaxseed (Linum usitatissimum) which utilizes the product of lipoxidase for its substrate. The enzyme, termed hydroperoxide isomerase, converts the conjugated diene hydroperoxide of linoleic acid to the corresponding monoenoic ketohydroxy fatty acid. The structure of the latter has been determined by ultraviolet, infrared, and nuclear magnetic resonance spectroscopy; periodate and permangate oxidation; gas chromatography; and thin layer chromatography. Hydroperoxide isomerase activity has also been demonstrated in crude extracts from barley (Hordeum vulgare), wheat germ (Triticum aestivum), mung beans (Phaseolus aureus), and corn (Zea mays) and from partially purified extracts of soybean (Glycine max).     

The role of the kidney in lipid metabolism

PURPOSE OF REVIEW: Cellular uptake of plasma lipids is to a large extent mediated by specific membrane-associated proteins that recognize lipid-protein complexes. In the kidney, the apical surface of proximal tubules has a high capacity for receptor-mediated uptake of filtered lipid-binding plasma proteins. We describe the renal receptor system and its role in lipid metabolism in health and disease, and discuss the general effect of the diseased kidney on lipid metabolism. RECENT FINDINGS: Megalin and cubilin are receptors in the proximal tubules. An accumulating number of lipid-binding and regulating proteins (e.g. albumin, apolipoprotein A-I and leptin) have been identified as ligands, suggesting that their receptors may directly take up lipids in the proximal tubules and indirectly affect plasma and tissue lipid metabolism. Recently, the amnionless protein was shown to be essential for the membrane association and trafficking of cubilin. SUMMARY: The kidney has a high capacity for uptake of lipid-binding proteins and lipid-regulating hormones via the megalin and cubilin/amnionless protein receptors. Although the glomerular filtration barrier prevents access of the large lipoprotein particles to the proximal tubules, the receptors may be exposed to lipids bound to filtered lipid-binding proteins not associated to lipoprotein particles. Renal filtration and receptor-mediated uptake of lipid-binding and lipid-regulating proteins may therefore influence overall lipid metabolism. The pathological mechanisms causing the pronounced atherosclerosis-promoting effect of uremia may involve impairment of this clearance pathway.     

Allene oxide cyclase: a new enzyme in plant lipid metabolism

The mechanism of the biosynthesis of 12-oxo-10,15(Z)-phytodienoic acid (12-oxo-PDA) from 13(S)-hydroperoxy-9(Z),11(E),15(Z)-octadecatrienoic acid in preparations of corn (Zea mays L.) was studied. In the initial reaction the hydroperoxide was converted into an unstable allene oxide, 12,13(S)-epoxy-9(Z),11,15(Z)-octadecatrienoic acid, by action of a particle-bound hydroperoxide dehydrase. A new enzyme, allene oxide cyclase, catalyzed subsequent cyclization of allene oxide into 9(S),13(S)-12-oxo-PDA. In addition, because of its chemical instability, the allene oxide underwent competing nonenzymatic reactions such as hydrolysis into alpha- and gamma-ketol derivatives as well as spontaneous cyclization into racemic 12-oxo-PDA. (+/-)-cis-12,13-Epoxy-9(Z)-octadecenoic acid and (+/-)-cis-12,13-epoxy-9(Z),15(Z)-octadecadienoic acid, in which the epoxy group was located in the same position as in the allene oxide substrate, served as potent inhibitors of corn allene oxide cyclase. On the other hand, the isomeric (+/-)-cis-9,10-epoxy-12(Z)-octadecenoic acid had little inhibitory effect. Allene oxide cyclase was present in the soluble fraction of corn homogenate and had a molecular weight of about 45,000 as judged by gel filtration. The enzyme activity was detected in several plant tissues, the highest levels being observed in potato tubers and in leaves of spinach and white cabbage.     

Sugar enrichment provides evidence for a role of nitrogen fixation in coral bleaching

The disruption of the coral–algae symbiosis (coral bleaching) due to rising sea surface temperatures has become an unprecedented global threat to coral reefs. Despite decades of research, our ability to manage mass bleaching events remains hampered by an incomplete mechanistic understanding of the processes involved. In this study, we induced a coral bleaching phenotype in the absence of heat and light stress by adding sugars. The sugar addition resulted in coral symbiotic breakdown accompanied by a fourfold increase of coral‐associated microbial nitrogen fixation. Concomitantly, increased N:P ratios by the coral host and algal symbionts suggest excess availability of nitrogen and a disruption of the nitrogen limitation within the coral holobiont. As nitrogen fixation is similarly stimulated in ocean warming scenarios, here we propose a refined coral bleaching model integrating the cascading effects of stimulated microbial nitrogen fixation. This model highlights the putative role of nitrogen‐fixing microbes in coral holobiont functioning and breakdown.     

Brain lipid metabolism in the cPLA2 knockout mouse

We examined brain phospholipid metabolism in mice in which the cytosolic phospholipase A(2) (cPLA(2,) Type IV, 85 kDa) was knocked out (cPLA(2)(-/-) mice). Compared with controls, these mice demonstrated altered brain concentrations of several phospholipids, reduced esterified linoleate, arachidonate, and docosahexaenoate in choline glycerophospholipid, and reduced esterified arachidonate in phosphatidylinositol. Unanesthetized cPLA(2)(-/-) mice had reduced rates of incorporation of unlabeled arachidonate from plasma and from the brain arachidonoyl-CoA pool into ethanolamine glycerophospholipid and choline glycerophospholipid, but elevated rates into phosphatidylinositol. These differences corresponded to altered turnover and metabolic loss of esterified brain arachidonate. These results suggests that cPLA(2) is necessary to maintain normal brain concentrations of phospholipids and of their esterified polyunsaturated fatty acids. Reduced esterified arachidonate and docosahexaenoate may account for the resistance of the cPLA(2)(-/-) mouse to middle cerebral artery occlusion, and should influence membrane fluidity, neuroinflammation, signal transduction, and other brain processes.     

The role of inositol lipid metabolism in the ovary

Two major signal transduction systems operate within ovarian cells to control their function. Gonadotropins, such as follicle-stimulating hormone and luteinizing hormone, primarily utilize the cyclic adenosine 3',5'-monophosphate (cAMP) pathway to stimulate steroid hormone biosynthesis. On the other hand, an inositol lipid metabolism pathway is used by other effector molecules such as gonadotropin-releasing hormone or prostaglandin F2 alpha, as well as gonadotropins, to alter ovarian hormone production. Membrane polyphosphoinositides are hydrolyzed to inositol phosphates and diacylglycerol, resulting in alterations of intracellular free calcium concentration, activation of protein kinase C, and liberation of arachidonic acid. Some or all of these intracellular messengers may interact with the gonadotropin-induced cAMP pathway to control ovarian function.     

Genetic evidence for the involvement of lipid metabolism in Alzheimer's disease

Alzheimer's disease (AD) is the most common cause of dementia in the elderly and presents a great burden to sufferers and to society. The genetics of rare Mendelian forms of AD have been central to our understanding of AD pathogenesis for the past twenty years and now the genetics of the common form of the disease in the elderly is beginning to be unravelled by genome-wide association studies. Four new genes for common AD have been revealed in the past year, CLU, CR1, PICALM and BIN1. Their possible involvement in lipid metabolism and how that relates to AD is discussed here.     

Functional role of lipid metabolism in activated T-lymphocytes

Exogenous long-chain fatty acids are readily taken up by unstimulated lymphocytes derived from the thymus of calves or rabbits and esterified to complex lipids, primarily phospholipids and triacylglycerols. Compared to saturated fatty acids, unsaturated fatty acids are incorporated preferentially. Furthermore, unsaturated fatty acids are transferred from triacylglycerols to phospholipids. The transfer cannot be observed with palmitic acid. With regard to individual phospholipid species, oleic acid and linoleic acid are found primarily in phosphatidylcholine. Arachidonic acid, however, is transferred to phosphatidylethanolamine and phosphatidylinositol as well. This suggests an arachidonic-specific transfer between individual phospholipids. Stimulation of the cells with the mitogen concanavalin A results in an enhanced incorporation of the fatty acids and an enhanced transfer from triacylglycerols to phospholipids. Triacylglycerols may thus be regarded as a labile intracellular storage pool that may be activated upon mitogenic stimulation.     

The integral role of mTOR in lipid metabolism

Comment on: Soliman GA, et al. Lipids 2010; 45:1089-100.     

The role of lactate in brain metabolism

According to the astrocyte-neurone-lactate shuttle (ANLS) hypothesis, activated neurones use lactate released by astrocytes as their energy substrate. The hypothesis, based largely on in vitro experiments, postulates that lactate is derived from the uptake by astrocytes of synaptically released glutamate. The time course of changes in lactate, derived from in vivo experiments, is incompatible with the ANLS model. Neuronal activation leads to a delayed rise in lactate followed by a slow decay, which greatly outlasts the period of neuronal activation. The present review proposes that the uptake of stimulated glutamate release from astrocytes, rather than synaptically released glutamate, is the source of lactate released following neuronal activation. This rise in lactate occurs too late to provide energy for neuronal activity. Furthermore, there is no evidence that lactate undergoes local oxidative phosphorylation. In conclusion, under physiological conditions, there is no evidence that lactate is a significant source of energy for activated neurones.     

The metabolism of phospholipids in mouse brain slices

1. Slices of mouse brain grey matter were incubated with [³²P]phosphate and [1-¹⁴C]acetate. Doubly labelled phospholipids were extracted from subcellular fractions prepared from the slices in a mixture of metabolic inhibitors, under conditions where there was negligible change in radioactive labelling during the preparation. Two tissue fractions were studied in detail; one contained a high proportion of mitochondria and the other was mainly microsomal. 2. In all tissue fractions the highest incorporations of both [³²P]phosphate and [1-¹⁴C]acetate occurred into phosphatidylcholine. 3. After incubation for 1hr., the ³²P/¹⁴C ratios for phosphatidylcholine, phosphatidylethanolamine and phosphatidic acid in the mitochondrial fraction were similar to those in the microsomal fraction. 4. The ³²P/¹⁴C ratios were similar in phosphatidylcholine and phosphatidylethanolamine and much lower than those in phosphatidic acid and phosphatidylinositol.     

ChREBP在肝细胞糖脂代谢中的作用

碳水化合物反应元件结合蛋白(carbohydrate response element binding protein,ChREBP)是一个在糖脂代谢过程中发挥重要作用的转录因子.ChREBP的分子量约为90kD,含有四个与其活性紧密相关的磷酸化位点.葡萄糖代谢旁路产物5-磷酸木酮糖可以激活蛋白磷酸酶2A,其促使ChREBP去磷酸化,去磷酸化的ChREBP进入细胞核,并与MLX形成异源二聚体ChREBP/MLX,ChREBP/MLX结合到靶基因启动子区域的ChRE上,激活靶基因的转录.ChREBP的靶基因主要是参与糖酵解和脂质合成的一些酶类,因而ChREBP的激活可促进葡萄糖向脂质转化.敲除ChREBP的小鼠虽可正常生长发育但其体内脂肪组织明显减少,同时肝中有大量糖原堆积而导致肝肿大.敲除ChREBP的ob/ob小鼠,体重及糖脂代谢紊乱也有明显改善.总之,现有的研究揭示ChREBP有可能成为治疗代谢综合征的一个新靶点.     

The central role of perilipin a in lipid metabolism and adipocyte lipolysis

The related disorders of obesity and diabetes are increasing to epidemic proportions. The role of neutral lipid storage and hydrolysis, and hence the adipocyte, is central to understanding this phenomenon. The adipocyte holds the major source of stored energy in the body in the form of triacylglycerols (TAG). It has been known for over 35 years that the breakdown of TAG and release of free (unesterified) fatty acids and glycerol from fat tissue can be regulated by a cAMP-mediated process. However, beyond the initial signaling cascade, the mechanistic details of this lipolytic reaction have remained unclear. Work in recent years has revealed that both hormone-sensitive lipase (HSL), generally thought to be the rate-limiting enzyme, and perilipin, a lipid droplet surface protein, are required for optimal lipid storage and fatty acid release. There are multiple perilipin proteins encoded by mRNA splice variants of a single perilipin gene. The perilipin proteins are polyphosphorylated by protein kinase A and phosphorylation is necessary for translocation of HSL to the lipid droplet and enhanced lipolysis. Hence, the surface of the lipid storage droplet has emerged as a central site of regulation of lipolysis. This review will focus on adipocyte lipolysis with emphasis on hormone signal transduction, lipolytic enzymes, the lipid storage droplet, and fatty acid release from the adipocyte.