Irisin/FNDC5: A participant in camel metabolism

The quantification, localization, production, function, and regulation of irisin/FNDC5 in camel species have not been previously studied. The objective of this study was to detect the irisin content in Arabian camel blood and tissues and study the gene expression of FNDC5 and PGC-1α in camel skeletal muscles and white adipose tissue depots under basal conditions. To monitor if exercise influences blood and tissue irisin protein levels as well as FNDC5 and PGC-1α gene expression levels, we analyzed irisin concentrations in the serum, skeletal muscles (soleus and gastrocnemius), and white adipose tissues (hump, subcutaneous, visceral, epididymal, and perirenal) in both control (n = 6) and exercised group (n = 6) using ELISA and determined the cellular localization of irisin/FNDC5 and the mRNA levels of FNDC5 and PGC-1α in skeletal muscles and adipose tissues via immunohistochemistry and real-time PCR, respectively. The possible regulatory roles of exercise on some hormones and metabolites as well as the detection of links between serum irisin and other circulating hormones (insulin, leptin, and cortisol) and metabolites (glucose, free fatty acids, triglycerides, and ATP) were explored for the first time in camels. Our results indicated that exercise induces tissue-specific regulation of the camel irisin, FNDC5, and PGC-1α levels, which subsequently regulates the circulating irisin level. Significant associations were detected between the levels of irisin/FNDC5/PGC-1α in camels and the metabolic and hormonal responses to exercise. Our study suggested that irisin regulates, or is regulated by, glucose, FFA, insulin, leptin, and cortisol in camels. The novel results of the present study will serve as baseline data for camels.     

2型糖尿病患者血糖波动与心律失常和下肢血管病变的关系及其影响因素分析

目的:探讨2型糖尿病(T2DM)患者血糖波动与心律失常和下肢血管病变的关系,分析影响T2DM心律失常和下肢血管病变的因素。方法:选择2019年7月到2020年6月我院收治的82例T2DM患者,根据是否合并心律失常分为心律失常组28例和无心律失常组54例,根据是否合并下肢血管病变分为下肢血管病变组31例和无下肢血管病变组51例。所有患者均通过72 h监测血糖获得日内平均血糖波动幅度(MAGE)、日间血糖平均绝对差(MODD)、全天血糖标准差(SDBG)、全天血糖波动次数(NGE)。比较组间差异,分析影响T2DM患者心律失常和下肢血管病变的因素。结果:心律失常组MAGE、MODD、SDBG、NGE、糖化血红蛋白(HbA1c)、胰岛素抵抗指数(HOMA-IR)、T2DM病程、同型半胱氨酸(Hcy)、丙二醛(MDA)高于无心律失常组(P<0.05)。下肢血管病变组T2DM病程、Hcy、MDA、HOMA-IR、MAGE、MODD、SDBG、NGE均高于无下肢血管病变组(P<0.05)。Logistic回归分析结果显示MDA、HOMA-IR、MAGE、MODD是T2DM患者心律失常的危险因素(P<0.001),MAGE、MODD、SDBG是T2DM患者下肢血管病变的危险因素(P<0.001)。结论:T2DM患者血糖波动与心律失常和下肢血管病变均有关,血糖波动增加是T2DM心律失常和下肢血管病变的危险因素。     

同型半胱氨酸对孕鼠糖代谢的影响与机制分析

目的:探讨同型半胱氨酸(homocysteine,HCY)摄入后对孕鼠糖代谢的影响以及生物学机制分析。方法:孕鼠妊娠10 d后,将实验动物随机分为3组,每组12只,妊娠对照组(Ctrl)腹腔注射生理盐水,同型半胱氨酸高剂量组(HCYH)和同型半胱氨酸低剂量组(HCYL)腹腔注射HCY溶液,注射浓度分别为200 mg/kg·d和100 mg/kg·d,持续20 d(即为HCY20 d)后,利用血糖含量检测试剂盒和胰岛素试剂盒分别检测孕鼠空腹血糖水平、胰岛素水平;葡萄糖检测试剂盒对孕鼠葡萄糖耐量和胰岛素抵抗进行检测;蛋白免疫印迹法检测孕鼠目的蛋白过氧化物酶体增殖物激活受体γ(PPARγ)、葡萄糖转运蛋白4(GLUT4)、蛋白激酶B(AKT)、磷酸化AKT蛋白(P-AKT)的表达。结果:与Ctrl组比较,在孕鼠注射HCY后,空腹血糖水平升高、血清中胰岛素浓度下降、HOMA-β指数下降、HOMA-IR指数升高(P<0.05);摄入葡萄糖后,孕鼠血糖随时间的变化而下降,葡萄糖曲线下面积升高(P<0.05);摄入胰岛素后,孕鼠血糖随时间的变化而升高,胰岛素曲线下面积升高(P<0.05);PPARγ、P-AKT、GLUT4蛋白表达水平下降,HCYH组降低水平更为显著(P<0.05)。结论:孕鼠HCY摄入后,生物体糖代谢紊乱,AKT磷酸化表达水平抑制,HCY可能通过降低PPARγ的表达减少AKT磷酸化,导致胰岛素受体的活化,进而激活了PI3K/AKT通路,减少了脂肪组织中的GLUT4表达,增加了对于葡萄糖的摄取能力。     

Oxidative Glycation and Free Radical Production: A Causal Mechanism of Diabetic Complications

Glucose may oxidise under physiological conditions and lead to the production of protein reactive ketoaldehydes, hydrogen peroxide and highly reactive oxidants. Glucose is thus able to modify proteins by the attachment of its oxidation derived aldehydes, leading to the development of novel protein fluoro-phores, as well as fragment protein via free radical mechanisms.

The fragmentation of protein by glucose is inhibitable by metal chelators such as diethylenetriamine pentaacetic acid (DETAPAC) and free radical scavengers such as benzoic acid, and sorbitol. The enzymic antioxidant, catalase, also inhibits protein fragmentation.

Protein glycation and protein oxidation are inextricably linked. Indeed, using boronate affinity chromatography to separate glycated from non-glycated material, we demonstrate that proteins which arc glycated exhibit an enhanced tryptophan oxidation. Our observation that both glycation and oxidation occur simultaneously further supports the hypothesis that tissue damage associated with diabetes and ageing has an oxidative origin.     

Characterization of Free Radical Defense System in High Glucose Cultured HeLa-tat Cells: Consequences for Glucose-induced Cytotoxicity

HeLa cell line stably transfected with the tat gene from human immunodeficiency virus type 1 has a decreased antioxidant potential. In this work, we used this model to investigate the effect of a high glucose level (20 mM) on the glucose induced cytotoxicity and on the antioxidant system. In comparison to cell culture under control medium, HeLa-wild cell cultured under 20 mM glucose did not exhibit necrosis or apoptosis, contrary to HeLa-tat cell presenting a significant increase in necrotic or apoptotic state. Moreover after 48 h culture under high glucose level the HeLa-tat proliferation rate was not higher than the one of HeLa-wild cells. In HeLa-wild cell high glucose level resulted in an induction of glutathione reductase activity in opposition to HeLa-tat cells where no change was observed. High glucose level resulted in 20% increase in GSSG/GSH ratio in HeLa-wild cells and 38% increase in HeLa-tat cells. Moreover, high glucose level resulted in a dramatic cytosolic thiol decrease and an important lipid peroxidation in HeLa-tat cells. No significant change of these two parameters was observed in HeLa-wild cells. In both cell lines, high glucose resulted in an increase of total SOD activity, as a consequence of the increase in Cu,Zn-SOD activity. High glucose did not result in an increase of Mn-SOD activity in both cell lines. As a consequence of tat tranfection Mn-SOD activity was 50% lower in HeLa-tat cells in comparison to HeLa-wild cells. This work emphasizes the importance of the antioxidant system in the glucose induced cytotoxicity.     

Pro-oxidant Role of Heme Oxygenase in Mediating Glucose-induced Endothelial Cell Damage

Oxidative damage to the vascular endothelial cells may play a crucial role in mediating glucose-induced cellular dysfunction in chronic diabetic complications. The present study was aimed at elucidating the role of glucose-induced alteration of highly inducible heme oxygenase (HO) in mediating oxidative stress in the vascular endothelial cells. We have also investigated the interaction between HO and the nitric oxide (NO) system, and its possible role in alteration of other vasoactive factors.

Human umbilical vein endothelial cells (HUVECs) were exposed to low (5?mmol/l) and high (25?mmol/l) glucose levels. In order to determine the role of HO in endothelial dysfunction and to elucidate a possible interaction between the HO and NO systems, cells were exposed to HO inducer (hemin, 10?μmol/l), HO antagonist (SnPPIX, 10?μmol/l), and NO synthase blocker (l-NAME, 200?μmol/l) with or without NO donor (arginine, 1?mmol/l). mRNA expression of HO and NO isoforms was measured by real time RT-PCR. HO activity was measured by bilirubin production and cellular oxidative stress was assessed by 8-hydroxy-2′-deoxyguanosine (8-OHdG) and nitrotyrosine staining. We also determined the expression of vasoactive factors, endothelin-1 (ET-1) and vascular endothelial growth factor (VEGF).

In the endothelial cells, glucose caused upregulation of HO-1 expression and increased HO activity. A co-stimulatory relationship between HO and NO was observed. Increased HO activity also associated with oxidative DNA and protein damage in the endothelial cells. Furthermore, increased HO activity augmented mRNA expression of vasoactive factors, ET-1 and VEGF. These data suggest that HO by itself and via elaboration of other vasoactive factors may cause endothelial injury and functional alteration. These findings are of importance in the context of chronic diabetic complications.     

Glucose Accelerates Copper- and Ceruloplasmin-induced Oxidation of Low-density Lipoprotein and Whole Serum

Glucose at pathophysiological concentrations was able to accelerate copper-induced oxidation of isolated low-density lipoprotein (LDL) and whole serum. The efficiency of glucose was favored under the following circumstances: (a) when LDL oxidation was induced by low copper concentration, (b) when LDL was partly oxidized, i.e. enriched with lipid peroxides. The glucose derivative methyl- &#102 - d -glucoside was ineffective on Cu 2+ -induced LDL oxidation, pointing out the essential role of the reactivity of the aldehydic carbon for the pro-oxidative effect. When LDL oxidation was induced by a peroxyl radical generator, as a model of transition metal independent oxidation, glucose was ineffective. Glucose was found to stimulate oxidation of LDL induced by ceruloplasmin, the major copper-containing protein of human plasma. Thus, glucose accelerated oxidation of LDL induced by both free and protein bound copper. Considering the requirement for catalytically active copper and for the aldehydic carbon, the pro-oxidative effect of glucose is likely to depend on the increased availability of Cu + ; this is more efficient in decomposing lipid peroxide than Cu 2+ , accounting for acceleration of LDL oxidation. The possible biological relevance of our work is supported by the finding that glucose was able to accelerate oxidation of whole serum, which was assessed by monitoring low-level chemiluminescence associated with lipid peroxidation.     

Polysome Isolation by Sepharose Column Chromatography

Polysomes from the mouse myeloma MOPC-21 were purified by gel filtration on Sepharose 6B, 4B and 2B columns. All three columns eliminated nearly all intracellular material smaller than 40 S subunits. In addition, passage through 4B and 2B columns substantially reduced the amount of subunits and monosomes in the preparations. Purified polysomes retained structural integrity when stored at -85°C for at least nine weeks.     

Optimization of the hydrolysis of lignocellulosic residues by using radial basis functions modeling and particle swarm optimization

The concentrations of glucose and total reducing sugars obtained by chemical hydrolysis of three different lignocellulosic feedstocks were maximized. Two response surface methodologies were applied to model the amount of sugars produced: (1) classical quadratic least-squares fit (QLS), and (2) artificial neural networks based on radial basis functions (RBF). The results obtained by applying RBF were more reliable and better statistical parameters were obtained. Depending on the type of biomass, different results were obtained. Improvements in fit between 35% and 55% were obtained when comparing the coefficients of determination (R²) computed for both QLS and RBF methods. Coupling the obtained RBF models with particle swarm optimization to calculate the global desirability function, allowed to perform multiple response optimization. The predicted optimal conditions were confirmed by carrying out independent experiments.     

A Model of Chronic Nutrient Infusion in the Rat

Chronic exposure to excessive levels of nutrients is postulated to affect the function of several organs and tissues and to contribute to the development of the many complications associated with obesity and the metabolic syndrome, including type 2 diabetes. To study the mechanisms by which excessive levels of glucose and fatty acids affect the pancreatic beta-cell and the secretion of insulin, we have established a chronic nutrient infusion model in the rat. The procedure consists of catheterizing the right jugular vein and left carotid artery under general anesthesia; allowing a 7-day recuperation period; connecting the catheters to the pumps using a swivel and counterweight system that enables the animal to move freely in the cage; and infusing glucose and/or Intralipid (a soybean oil emulsion which generates a mixture of approximately 80% unsaturated/20% saturated fatty acids when infused with heparin) for 72 hr. This model offers several advantages, including the possibility to finely modulate the target levels of circulating glucose and fatty acids; the option to co-infuse pharmacological compounds; and the relatively short time frame as opposed to dietary models. It can be used to examine the mechanisms of nutrient-induced dysfunction in a variety of organs and to test the effectiveness of drugs in this context.