Comparative analysis of primate and pig cells reveals primate-specific PINK1 expression and phosphorylation

PTEN-induced putative kinase 1(PINK1),a mitochondrial kinase that phosphorylates Parkin and other proteins,plays a crucial role in mitophagy and protection against neurodegeneration.Mutations in PINK1 and Parkin can lead to loss of function and early onset Parkinson's disease.However,there is a lack of strong in vivo evidence in rodent models to support the theory that loss of PINK1 affects mitophagy and induces neurodegeneration.Additionally,PINK1 knockout pigs(Sus scrofa)do not appear to exhibit neurodegeneration.In our recent work involving non-human primates,we found that PINK1 is selectively expressed in primate brains,while absent in rodent brains.To extend this to other species,we used multiple antibodies to examine the expression of PINK1 in pig tissues.In contrast to tissues from cynomolgus monkeys(Macaca fascicularis),our data did not convincingly demonstrate detectable PINK1expression in pig tissues.Knockdown of PINK1 in cultured pig cells did not result in altered Parkin and BAD phosphorylation,as observed in cultured monkey cells.A comparison of monkey and pig striatum revealed more PINK1-phosphorylated substrates in the monkey brain.Consistently,PINK1 knockout in pigs did not lead to obvious changes in the phosphorylation of Parkin and BAD.These findings provide new evidence that PINK1expression is specific to primates,underscoring the importance of non-human primates in investigating PINK1function and pathology related to PINK1 deficiency.

Novel insights into D-Pinitol based therapies:a link between tau hyperphosphorylation and insulin resistance

Alzheimer’s disease is a neurodegenerative disorder characterized by the amyloid accumulation in the brains of patients with Alzheimer’s disease.The pathogenesis of Alzheimer’s disease is mainly mediated by the phosphorylation and aggregation of tau protein.Among the multiple causes of tau hyperphosphorylation,brain insulin resistance has generated much attention,and inositols as insulin sensitizers,are currently considered candidates for drug development.The present narrative review revises the interactions between these three elements:Alzheimer’s disease-tau-inositols,which can eventually identify targets for new disease modifiers capable of bringing hope to the millions of people affected by this devastating disease.

Surviving winter on the Qinghai-Xizang Plateau:Extensive reversible protein phosphorylation plays a dominant role in regulating hypometabolism in hibernating Nanorana parkeri

Changes in protein abundance and reversible protein phosphorylation(RPP)play important roles in regulating hypometabolism but have never been documented in overwintering frogs at high altitudes.To test the hypothesis that protein abundance and phosphorylation change in response to winter hibernation,we conducted a comprehensive and quantitative proteomic and phosphoproteomic analysis of the liver of the Xizang plateau frog,Nanorana parkeri,living on the Qinghai-Xizang Plateau.In total,5170 proteins and 5695 phosphorylation sites in 1938 proteins were quantified.Based on proteomic analysis,674 differentially expressed proteins(438 up-regulated,236 down-regulated)were screened in hibernating N.parkeri versus summer individuals.Functional enrichment analysis revealed that higher expressed proteins in winter were significantly enriched in immune-related signaling pathways,whereas lower expressed proteins were mainly involved in metabolic processes.A total of 4251 modified sites(4147 up-regulated,104 down-regulated)belonging to 1638 phosphoproteins(1555 up-regulated,83 down-regulated)were significantly changed in the liver.During hibernation,RPP regulated a diverse array of proteins involved in multiple functions,including metabolic enzymatic activity,ion transport,protein turnover,signal transduction,and alternative splicing.These changes contribute to enhancing protection,suppressing energy-consuming processes,and inducing metabolic depression.Moreover,the activities of phosphofructokinase,glutamate dehydrogenase,and ATPase were all significantly lower in winter compared to summer.In conclusion,our results support the hypothesis and demonstrate the importance of RPP as a regulatory mechanism when animals transition into a hypometabolic state.

LATS1 Promotes B-ALL Tumorigenesis by Regulating YAP1 Phosphorylation and Subcellular Localization

Objective YAP1 plays a dual role as an oncogene and tumor suppressor gene in several tumors;differentiating between these roles may depend on the YAP1 phosphorylation pattern.The specific function of YAP1 in B cell acute lymphoblastic leukemia(B-ALL),however,is currently unclear.Thus,in the present study,the role of YAP1 in B-ALL was investigated using relevant cell lines and patient datasets.Methods The effects of shRNA-mediated knockdown on YAP1 and LATS1 levels in the NALM6 and MOLT-4 cell lines were examined using Western blotting,quantitative real-time polymerase chain reaction,flow cytometry,immunostaining,and nude mouse subcutaneous tumorigenesis experiments.Gene expression levels of Hippo pathway-related molecules before and after verteporfin(VP)treatment were compared using RNA-Seq to identify significant Hippo pathway-related genes in NALM6 cells.Results Patients with ALL showing high YAP1 expression and low YAP1-Ser127 phosphorylation levels had worse prognoses than those with low YAP1 protein expression and high YAP1-Ser127 phosphorylation levels.YAP1-Ser127 phosphorylation levels were lower in NALM6 cells than in MOLT-4 and control cells;YAP1 was distributed in the nuclei in NALM6 cells.Knockdown of YAP1 inhibited MOLT-4 and NALM6 cell proliferation and arrested the NALM6 cell cycle in the G0/G1 phase.Before and after VP treatment,the expression of the upstream gene LATS1 was upregulated;its overexpression promoted YAP1-Ser127 phosphorylation.Further,YAP1 was distributed in the plasma.Conclusion LATS1 may downregulate YAP1-Ser127 phosphorylation and maintain B-ALL cell function;thus,VP,which targets this axis,may serve as a new therapeutic method for improving the outcomes for B-ALL patients.

IL-17 induces NSCLC cell migration and invasion by elevating MMP19 gene transcription and expression through the interaction of p300-dependent STAT3-K631 acetylation and its Y705-phosphorylation

The cancer cell metastasis is a major death reason for patients with non-small cell lung cancer(NSCLC).Although researchers have disclosed that interleukin 17(IL-17)can increase matrix metalloproteinases(MMPs)induction causing NSCLC cell metastasis,the underlying mechanism remains unclear.In the study,we found that IL-17 receptor A(IL-17RA),p300,p-STAT3,Ack-STAT3,and MMP19 were up-regulated both in NSCLC tissues and NSCLC cells stimulated with IL-17.p300,STAT3 and MMP19 overexpression or knockdown could raise or reduce IL-17-induced p-STAT3,Ack-STAT3 and MMP19 level as well as the cell migration and invasion.Mechanism investigation revealed that STAT3 and p300 bound to the same region(−544 to−389 nt)of MMP19 promoter,and p300 could acetylate STAT3-K631 elevating STAT3 transcriptional activity,p-STAT3 or MMP19 expression and the cell mobility exposed to IL-17.Meanwhile,p300-mediated STAT3-K631 acetylation and its Y705-phosphorylation could interact,synergistically facilitating MMP19 gene transcription and enhancing cell migration and invasion.Besides,the animal experiments exhibited that the nude mice inoculated with NSCLC cells by silencing p300,STAT3 or MMP19 gene plus IL-17 treatment,the nodule number,and MMP19,Ack-STAT3,or p-STAT3 production in the lung metastatic nodules were all alleviated.Collectively,these outcomes uncover that IL-17-triggered NSCLC metastasis involves up-regulating MMP19 expression via the interaction of STAT3-K631 acetylation by p300 and its Y705-phosphorylation,which provides a new mechanistic insight and potential strategy for NSCLC metastasis and therapy.

Cardioprotective Potential of Cymbopogon citratus Essential Oil against Isoproterenol-induced Cardiomyocyte Hypertrophy:Possible Involvement of NLRP3 Inflammasome and Oxidative Phosphorylation Complex Subunits

Objective:Cymbopogon citratus(DC.)Stapf is a medicinal and edible herb that is widely used for the treatment of gastric,nervous and hypertensive disorders.In this study,we investigated the cardioprotective effects and mechanisms of the essential oil,the main active ingredient of Cymbopogon citratus,on isoproterenol(ISO)-induced cardiomyocyte hypertrophy.Methods:The compositions of Cymbopogon citratus essential oil(CCEO)were determined by gas chromatography-mass spectrometry.Cardiomyocytes were pretreated with 16.9µg/L CCEO for 1 h followed by 10µmol/L ISO for 24 h.Cardiac hypertrophy-related indicators and NLRP3 inflammasome expression were evaluated.Subsequently,transcriptome sequencing(RNA-seq)and target verification were used to further explore the underlying mechanism.Results:Our results showed that the CCEO mainly included citronellal(45.66%),geraniol(23.32%),and citronellol(10.37%).CCEO inhibited ISO-induced increases in cell surface area and protein content,as well as the upregulation of fetal gene expression.Moreover,CCEO inhibited ISO-induced NLRP3 inflammasome expression,as evidenced by decreased lactate dehydrogenase content and downregulated mRNA levels of NLRP3,ASC,CASP1,GSDMD,and IL-1β,as well as reduced protein levels of NLRP3,ASC,pro-caspase-1,caspase-1(p20),GSDMD-FL,GSDMD-N,and pro-IL-1β.The RNA-seq results showed that CCEO inhibited the increase in the mRNA levels of 26 oxidative phosphorylation complex subunits in ISO-treated cardiomyocytes.Our further experiments confirmed that CCEO suppressed ISO-induced upregulation of mt-Nd1,Sdhd,mt-Cytb,Uqcrq,and mt-Atp6 but had no obvious effects on mt-Col expression.Conclusion:CCEO inhibits ISO-induced cardiomyocyte hypertrophy through the suppression of NLRP3 inflammasome expression and the regulation of several oxidative phosphorylation complex subunits.

Microglial depletion impairs glial scar formation and aggravates inflammation partly by inhibiting STAT3 phosphorylation in astrocytes after spinal cord injury

Astrocytes and microglia play an orchestrated role following spinal cord injury;however,the molecular mechanisms through which microglia regulate astrocytes after spinal cord injury are not yet fully understood.Herein,microglia were pharmacologically depleted and the effects on the astrocytic response were examined.We further explored the potential mechanisms involving the signal transducers and activators of transcription 3(STAT3)pathway.For in vivo experiments,we constructed a contusion spinal cord injury model in C57BL/6 mice.To deplete microglia,all mice were treated with colony-stimulating factor 1 receptor inhibitor PLX3397,starting 2 weeks prior to surgery until they were sacrificed.Cell proliferation was examined by 5-ethynyl-2-deoxyuridine(EdU)and three pivotal inflammatory cytokines were detected by a specific Bio-Plex Pro^(TM) Reagent Kit.Locomotor function,neuroinflammation,astrocyte activation and phosphorylated STAT3(pSTAT3,a maker of activation of STAT3 signaling)levels were determined.For in vitro experiments,a microglia and astrocyte coculture system was established,and the small molecule STA21,which blocks STAT3 activation,was applied to investigate whether STAT3 signaling is involved in mediating astrocyte proliferation induced by microglia.PLX3397 administration disrupted glial scar formation,increased inflammatory spillover,induced diffuse tissue damage and impaired functional recovery after spinal cord injury.Microglial depletion markedly reduced EdU+proliferating cells,especially proliferating astrocytes at 7 days after spinal cord injury.RNA sequencing analysis showed that the JAK/STAT3 pathway was downregulated in mice treated with PLX3397.Double immunofluorescence staining confirmed that PLX3397 significantly decreased STAT3 expression in astrocytes.Importantly,in vitro coculture of astrocytes and microglia showed that microglia-induced astrocyte proliferation was abolished by STA21 administration.These findings suggest that microglial depletion impaired astrocyte proliferation and astrocytic scar formation,and induced inflammatory diffusion partly by inhibiting STAT3 phosphorylation in astrocytes following spinal cord injury.

Phosphorylation regulation of nitrogen,phosphorus,and potassium uptake systems in plants

The uptake of ammonium,nitrate,phosphorus,and potassium ions by roots is mediated by specific ion transporter or channel proteins,and protein phosphorylation regulation events occurring on these proteins and their regulators determine their ultimate activity.Elucidating the mechanism by which protein phosphorylation modification regulates nutrient uptake will advance plant breeding for high nutrientuse efficiency.In this review,it is concluded that the root nutrient absorption system is composed of several,but not all,members of a specific ion transporter or channel family.Under nutrient-starvation conditions,protein phosphorylation-based regulation of these proteins and associated transcription factors increases ion transporter-or channel-mediated nutrient uptake capacity via direct function activity enhancement,allowing more protein trafficking to the plasma membrane,by strengthening the interaction of transporters and channels with partner proteins,by increasing their protein stability,and by transcriptional activation.Under excessive nutrient conditions,protein phosphorylation-based regulation suppresses nutrient uptake by reversing these processes.Strengthening phosphorylation regulation items that increase nutrient absorption and weakening phosphorylation modification items that are not conducive to nutrient absorption show potential as strategies for increasing nutrient use efficiency.

Effect of titin phosphorylation on degradation of titin from skeletal muscles

The degradation of titin could make the myofibrillar fragmentation to improve meat tenderization during postmortem.This study aimed to investigate effect of phosphorylation on titin degradation.Protein kinase A(PKA)and alkaline phosphatase(AP)were added to crude titin extracted from ovine longissimus lumborum(LL)muscles.Phosphorylated/dephosphorylated titin were incubated withμ-calpain at 4℃ for 2 days.Results showed titin in AP group started degradation earlier than that in PKA and control groups.There were 20,16 and 12 phosphorylated sites identified by iTRAQ in the PKA,control and AP group,respectively.3D structure of dephosphorylated titin fragment was simulated and its molecular dynamics trajectory analysis was performed using Discovery StudioTM.The dihedral angle in AP group was less and the dephosphorylated fragment had a higher kinetic energy and total energy.We suggested that changes caused by AP treatment might make titin unstable,which easily degraded byμ-calpain.

Switch of phosphorylation to O-GlcNAcylation of AhR contributes to vascular oxidative stress induced by benzo[a]pyrene

Benzo[a]pyrene(B[a]P)is a food contaminant toxic for cardiovascular diseases.The nuclear translocation of Arylhydrocarbon receptor(AhR)plays an important role in B[a]P-induced oxidative stress and vascular diseases.We confi rmed that B[a]P promoted ROS production in vascular smooth muscle cells(VSMCs)in vitro and in vivo,associated with the nuclear translocation of AhR.It is known that phosphorylation inhibits while dephosphorylation of AhR promotes nuclear translocation of AhR.However,from the posttranslational modifi cation level,the mechanism by which B[a]P activates and regulates the nuclear translocation of AhR is unclear.Co-immunoprecipitation results showed that cytoplasmic AhR was phosphorylated before B[a]P stimulation,and switched to O-GlcNAcylation upon B[a]P 1-h stimulation in VSMCs,suggesting there may be a competitively inhibitory relationship between O-GlcNAcylation and phosphorylation of AhR.Next,siRNAs of O-linked N-acetylglucosamine transferase(OGT),O-GlcNAcase(OGA)and OGA inhibitor PUGNAc were used.SiOGT blocks but siOGA and PUGNAc promote B[a]P-dependent AhR nuclear translocation and oxidative stress.Ser11 may be the competitive binding site for phosphorylation and O-GlcNAcylation of AhR.Phosphorylation-mimic variant inhibits but O-GlcNAcylation of AhR promotes AhR nuclear translocation and oxidative stress.Our fi ndings highlight a new perspective for AhR nuclear translocation regulated by the competitive modifi cation between phosphorylation and O-GlcNAcylation.

鼠李糖乳杆菌对老年小鼠术后海马区小胶质细胞激活及Tau蛋白磷酸化的影响

【目的】探讨术前益生菌鼠李糖乳杆菌(LGG)灌胃对麻醉手术老年小鼠海马区小胶质细胞及Tau磷酸化的影响。【方法】18月龄C57BL/6J小鼠30只随机分为3组,10只/组:对照组,麻醉手术组,麻醉手术+鼠李糖乳杆菌组。生理盐水/LGG 109CFU 150μL灌胃,每日1次,连续20 d后接受异氟醚麻醉+剖腹探查手术,术后12 h免疫荧光染色检测海马区小胶质细胞激活状态,ELISA检测IL-6的浓度变化,Western blot检测Tau蛋白磷酸化位点Tau-pS202/pT205和total Tau蛋白表达变化。【结果】对照组海马区小胶质细胞呈静息状态,炎症因子IL-6浓度为(82.08±12.07)pg/mL。与对照组相比,麻醉手术组海马区小胶质细胞活化增生,胞体变大,突起缩短变粗,炎症因子IL-6上升至(123.7±5.72)pg/mL(P=0.000),磷酸化Tau-pS202/pT205蛋白表达量也明显增加(P=0.002)。而与麻醉手术组相比,麻醉手术+LGG组海马区小胶质细胞增生肥大不明显,炎症因子IL-6分泌减少至(96.68±9.59)pg/mL(P=0.008),磷酸化Tau-pS202/pT205蛋白表达量明显下降(P=0.002)。而3组total Tau蛋白表达水平差异无统计学意义。【结论】术前服用益生菌鼠李糖乳杆菌减轻麻醉手术导致的老年小鼠海马区小胶质细胞活化、炎症因子分泌增加、以及Tau蛋白磷酸化水平增加。

刺槐素通过核因子κB信号通路抑制脂多糖诱导的巨噬细胞损伤

目的:探讨刺槐素(Acacetin)对脂多糖(LPS)诱导的小鼠骨髓巨噬细胞(BMDMs)的抗炎作用机制。方法:CCK-8法检测各浓度刺槐素(5μmol/L,10μmol/L,20μmol/L,40μmol/L)对小鼠骨髓巨噬细胞增殖的影响,筛选最佳剂量;分离培养小鼠骨髓巨噬细胞,LPS(50 ng/mL)预处理BMDMs(0 min,10 min,30 min,60 min),加入刺槐素(10μmol/L)孵育0.5 h。蛋白质印迹法检测p65、磷酸化p65(p-p65)、核因子κB抑制蛋白α(IκBα)、磷酸化IκBα(p-IκBα)的表达,激光共聚焦观察核因子κB核转位情况。结果:CCK-8结果显示,5~40μmol/L的刺槐素对小鼠骨髓巨噬细胞增殖无明显影响,结合课题组前期研究结果,选择10μmol/L刺槐素作为后续研究剂量;与空白对照组比较,LPS不同时间刺激组p-p65、p-IκBα的表达水平均显著增加,给予刺槐素治疗后,能显著降低p-核因子κB p65和p-IκBα的表达;刺槐素能抑制LPS介导的核因子κB p65核转位。结论:刺槐素的抗炎作用与抑制核因子κB信号通路有关,刺槐素可作为一种有潜力的候选抗炎药物。

橙皮苷通过氧化磷酸化途径缓解高脂饲喂诱导的小鼠肝氧化应激

旨在研究橙皮苷(Hesperidin, HDN)对高脂饲喂诱导的小鼠肝氧化应激损伤的保护作用及作用机制。将18只雄性C57BL/6(体重20~23 g)小鼠,随机分为对照(control)组、高脂饮食(HFD)组、高脂饮食+橙皮苷(HFD+HDN)组(300 mg·kg^(-1)),每组6只。control组小鼠饲喂常规饲料(脂肪含量10%、碳水化合物含量70%、蛋白质含量20%);HFD组小鼠饲喂高脂饲料(脂肪含量60%、碳水化合物含量20%、蛋白质含量20%);HFD+HDN组在饲喂高脂饲料的同时每天灌胃给药HDN 300 mg·kg^(-1)。16周后腹腔注射3%戊巴比妥钠(60 mg·kg^(-1))麻醉小鼠后进行眼球采血,采血完毕后对小鼠进行脱颈处死并解剖取肝组织;使用试剂盒检测血液中肝功能指标丙氨酸转氨酶(ALT)和天冬氨酸转氨酶(AST)的活性;使用试剂盒检测肝组织中氧化应激指标丙二醛(MDA)、总超氧化物歧化酶(T-SOD)和谷胱甘肽过氧化物酶(GSH-Px)以及总抗氧化能力(T-AOC)的水平;采集肝组织进行转录组学测序,筛选出HFD组和HFD+HDN组的差异表达基因集进行KEGG通路富集分析,以P<0.05作为显著性富集的阈值,据此筛选出HDN干预后影响最显著的一条信号通路;从筛选出的信号通路上挑选显著变化的基因并采取qRT-PCR和蛋白免疫印迹的方法验证转录组学结果;检测mtDNA相对含量和线粒体外膜蛋白(TOMM20)相对表达量;检测肝组织ATP含量。结果显示:与HFD组相比,HDN干预改善了高脂饲喂引起的肝损伤,显著降低了小鼠血液中ALT以及AST活性(P<0.01);显著降低小鼠肝MDA含量(P<0.01);显著升高T-AOC、T-SOD以及GSH-Px水平(P<0.05),KEGG富集分析,筛选出氧化磷酸化(OXPHOS)途径是最显著上调的信号通路(P<0.000 1);与HFD组相比,HDN干预后肝组织Cox8b、Cox6a2、Gm10231、mt-Atp8、mt-Nd4l、Gm11237、Ndufb8、Ndufb10的mRNA相对表达量显著上调(P<0.05),Atp6v0d2、Cox6c2的mRNA的相对表达量显著下调(P<0.05)。Cox6a2、Ndufb8、Ndufb10的蛋白表达量显著升高(P<0.05),Atp6v0d2d蛋白表达量表达量显著降低(P<0.001),与转录组学结果一致;与HFD组相比,HDN干预后TOMM20相对表达量、mtDNA相对含量、ATP含量显著升高(P<0.05)。结果提示,HDN通过调节OXPHOS途径降低高脂饲喂诱导的小鼠肝氧化应激。

3-吲哚丙酸抑制腹膜间皮细胞EMT和纤维化的机制研究

目的 评估3-吲哚丙酸(3-indoleacetic acid, IPA)对脂多糖(lipolyaccharide, LPS)诱导的小鼠腹膜间皮细胞上皮-间质转化(epithelial-mesenchymal transition, EMT)和纤维化的影响。方法 CCK-8法检测不同浓度(0.1、1.0和10μmol/L)的IPA对LPS处理前后的小鼠腹膜间皮细胞增殖活性的影响,确定IPA最佳使用剂量。将小鼠腹膜间皮细胞分成Control组、LPS组、LPS+IPA组、LPS+LY364947(TGF-β1/Smad3通路抑制剂)组、LPS+IPA+LY364947组和LPS+IPA+SRI-011381(TGF-β1/Smad3通路激活剂)组;CCK-8法检测细胞增殖活力,Transwell法检测细胞侵袭,ELISA检测培养上清中间质表型α-平滑肌肌动蛋白(α-smooth muscle actin, α-SMA)的浓度,Western blot检测细胞中α-SMA,EMT相关因子E-cadherin, TGF-β1/Smad3通路相关因子Smad3、p-Smad3的蛋白表达。结果 IPA的最佳使用剂量为1.0μmol/L。与Control组相比,LPS组细胞增殖活力、E-cadherin表达水平下降(均P<0.01),侵袭能力、α-SMA表达水平和p-Smad3/Smad3升高(均P<0.01)。与LPS组相比,LPS+IPA组和LPS+LY364947组细胞增殖活力、E-cadherin表达水平上升(均P<0.01),侵袭能力、α-SMA表达和p-Smad3/Smad3下降(均P<0.01)。与LPS+IPA组相比,LPS+IPA+LY364947组所测指标趋势更加显著,LPS+IPA+SRI-011381组所测指标变化趋势均被逆转。结论 IPA通过抑制TGF-β1/Smad3通路中Smad3蛋白的磷酸化,从而抑制细胞EMT进展,减轻LPS诱导的腹膜间皮细胞损伤。

内皮型一氧化氮合酶在运动预适应改善心肌缺血-再灌注损伤中的作用

背景:运动是防治各种心血管疾病并保护心脏免受缺血-再灌注损伤的有效策略,其作用机制有待深入研究。目的:观察有氧运动预适应对心肌缺血-再灌注损伤的影响,并探讨内皮型一氧化氮合酶(endothelial nitric oxide synthase,eNOS)激活(包括偶联和磷酸化)在其间的作用。方法:取80只成年Wistar大鼠,采用随机数字表法分为安静组(n=40)和运动组(n=40),运动组进行8周有氧运动,安静组在鼠笼内安静饲养。8周后进行3项实验:①实验1:末次训练后,检测大鼠心功能、心脏NO代谢物含量及心脏eNOS、磷酸化eNOS-S1177、eNOS二聚体、eNOS单体的蛋白表达量;②实验2:将大鼠分为安静对照组、运动对照组、安静+eNOS抑制剂组、运动+eNOS抑制剂组,均进行体外心肌缺血-再灌注损伤实验,安静+eNOS抑制剂组、运动+eNOS抑制剂组再灌注前10 min持续灌注eNOS抑制剂,再灌注3 h后检测心功能与心肌梗死面积;③实验3:将大鼠分为安静对照组、运动对照组、安静+eNOS偶联剂组和运动+eNOS偶联剂组,均进行体外心肌缺血-再灌注损伤实验,安静+eNOS偶联剂组和运动+eNOS偶联剂组再灌注前10 min持续灌注eNOS偶联剂,再灌注3 h后检测心肌梗死面积、心脏NO代谢物含量及心脏eNOS、磷酸化eNOS-S1177、eNOS二聚体、eNOS单体和3-硝基酪氨酸的蛋白表达量(其中,磷酸化eNOS-S1177/eNOS比值反映eNOS磷酸化/去磷酸化水平,eNOS二聚体/单体比值反映eNOS偶联/解偶联水平)。结果与结论:①实验1:与安静组比较,运动组大鼠心输出量、左心室射血分数升高(P<0.05),亚硝酸盐和S-亚硝基硫醇含量升高(P<0.05),磷酸化eNOS-S1177、eNOS蛋白表达和磷酸化eNOS-S1177/eNOS比值上调(P<0.05),eNOS二聚体蛋白表达和eNOS二聚体/单体比值升高(P<0.05);②实验2:与安静对照组比较,运动对照组左心室发展压升高(P<0.05),心肌梗死面积下降(P<0.05);与运动对照组比较,运动+eNOS抑制剂组左心室发展压降低(P<0.05),心肌梗死面积增加(P<0.05);③实验3:与安静对照组比较,运动对照组左心室发展压升高(P<0.05),心肌梗死面积下降(P<0.05),磷酸化eNOS-S1177/eNOS比值下降(P<0.05),eNOS二聚体/单体比值下降(P<0.05),S-亚硝基硫醇含量增加(P<0.05),3-硝基酪氨酸蛋白表达量下调(P<0.05);与运动对照组比较,运动+eNOS偶联剂组左心室发展压降低(P<0.05),心肌梗死面积增加(P<0.05),磷酸化eNOS-S1177/eNOS比值升高(P<0.05),eNOS二聚体/单体比值升高(P<0.05),3-硝基酪氨酸蛋白表达升高(P<0.05);④结果表明:有氧运动预适应可诱导心脏保护效应,其机制与心脏缺血-再灌注期间eNOS解偶联以及去磷酸化进而抑制NO过度产生并降低硝基-氧化应激有关。

基于磷酸酯化魔芋葡甘聚糖的热可逆凝胶性能

采用真空-微波辅助半干法处理魔芋葡甘聚糖(konjac glucomannan,KGM)获得不同取代度(degrees of substitution,DS)磷酸魔芋葡甘聚糖酯(konjac glucomannan phosphate ester,KGMPs)。研究KGM和KGMP_(1)(DS 0.046)、KGMP_(2)(DS 0.131)、KGMP_(3)(DS 0.201)分别与卡拉胶复配并添加KCl(KGMPs-KC)加热-冷却形成的热可逆凝胶特性及阴阳离子和蔗糖对KGMP_(3)流变性能的影响。红外光谱分析结果表明,KGMPs与卡拉胶复配并添加KCl协同增效形成凝胶;动态黏弹流变特性结果表明,KGMPs与卡拉胶复配在KCl存在下可形成热可逆凝胶,与KGM相比,随着DS增加,KGMP复配体系形成凝胶温度逐渐降低;质构分析结果表明,28℃贮藏10 d,KGMP_(1)-KC和KGMP_(2)-KC形成凝胶硬度更好;析水性和透光率方面,KGMP_(3)-KC更具优势,适合高透明度果冻类凝胶的制备。KGMP_(3)的黏度和假塑性受到阴阳离子类型和价态的影响,其中NaH_(2)PO_(4)对KGMP溶胶影响最显著,CaCl 2次之;蔗糖能使KGMP的零表观黏度(η0)降低,但随着体系中蔗糖含量的增加,η0增加。该研究为KGMP用于高保水、高透明度、软凝胶型产品的加工提供理论和生产依据。

与肌少症发病相关的线粒体自噬靶点基因筛选及其在骨骼肌组织中表达观察

目的基于GEO数据库数据筛选与肌少症发病相关的线粒体自噬靶点基因,并观察其在肌少症患者骨骼肌组织中的表达变化。方法从GEO数据库检索肌少症的基因图谱数据,筛选肌少症发病的差异表达基因。从GeneCard数据库中检索并收集线粒体自噬相关基因。使用“VennDiagram”包将肌少症发病的差异表达基因与线粒体自噬相关基因取交集,得到与肌少症发病相关的线粒体自噬差异表达基因。运用基因本体论(GO)和京都基因与基因百科全书(KEGG)通路富集分析与肌少症发病相关的线粒体自噬差异表达基因的生物学功能,通过Cytoscape软件筛选与肌少症发病相关的线粒体自噬靶点基因,观察GSE136344基因表达图谱中肌少症、健康对照者骨骼肌与肌少症发病相关的线粒体自噬靶点基因表达情况。结果得到与肌少症发病相关的线粒体自噬差异表达基因99个。与肌少症发病相关的线粒体自噬差异表达基因主要涉及神经变性途径-多种疾病信号通路、帕金森疾病信号通路、朊毒体病信号通路等;主要调控能量代谢、细胞呼吸、氧化磷酸化调节等生物学过程,主要定位于线粒体内膜、线粒体内部的大分子蛋白质复合物等,参与调节跨膜转运活性等分子功能。与肌少症发病相关的线粒体自噬靶点基因有线粒体内膜蛋白基因(IMMT)、动态蛋白1样蛋白基因(DNM1L)及ATP合酶F1亚基α基因(ATP5A1)等;与正常骨骼肌组织相比,肌少症患者骨骼肌组织中IMMT、DNM1L表达低(P均<0.05)。结论与肌少症发病相关的线粒体自噬靶点基因为IMMT、DNM1L。与肌少症发病相关的线粒体自噬靶点基因可通过影响神经变性途径-多种疾病信号通路、帕金森疾病信号通路及朊毒体病信号通路等,参与调控能量代谢、细胞呼吸、氧化磷酸化调节等生物学过程,参与肌少症的发病。肌少症患者骨骼肌组织中IMMT、DNM1L低表达。

蛋白质磷酸化修饰及其在细胞周期调控中的作用研究进展

细胞周期是真核生物实现细胞分裂与增殖、从母代向子代传递遗传信息的连续过程.真核细胞通过蛋白质水平的周期性调控完成细胞的分裂与增殖,细胞周期的紊乱常与肿瘤等疾病密切相关.蛋白质磷酸化修饰是细胞周期进程中一种主要的调控方式,可以改变蛋白质的分子结构,影响其与其他分子间的相互作用,从而调节相关分子的生物学活性及功能.细胞周期相关蛋白的磷酸化与非磷酸化状态的改变犹如“分子开关”,精细地控制着周期进程和细胞分裂系列事件.周期相关蛋白质的多位点磷酸化机制研究是磷酸化研究的一个热点.本文综合评述细胞周期调控进程中部分重要蛋白的磷酸化修饰机制,总结了近年来细胞周期领域中蛋白质磷酸化修饰方面的新发现、新突破,为进一步深入理解蛋白质磷酸化及细胞周期调控机制提供参考.

广叶绣球菌多糖磷酸化修饰及体外抗氧化和降糖活性

对广叶绣球菌(Sparassis latifolia)多糖(SLPs)进行磷酸化修饰,表征磷酸化SLPs(P-SLPs)结构,分析其体外抗氧化、降糖活性。结果表明:与SLPs比较,P-SLPs的磷酸根质量分数较高,为(8.02±0.48)%;在相同质量浓度时,P-SLPs对DPPH、超氧阴离子、羟基自由基和H_(2)O_(2)的清除率均较高,对α-淀粉酶和α-葡萄糖苷酶的抑制率均较高。研究结果可为广叶绣球菌多糖进一步开发应用提供参考。

宰后贮藏期间滩羊肉线粒体氧化磷酸化与色泽稳定性的关系

为阐明滩羊肉贮藏期间氧化磷酸化与色泽稳定性的关系,以6月龄滩羊背最长肌(longissimus dorsi)为研究对象,测定其4℃贮藏0、1、2、3、4、6、8 d时色泽稳定性与氧化磷酸化各指标的变化。主要研究结果如下:贮藏0~8 d,L^(*)、a^(*)、b^(*)值均呈先上升后下降趋势(P<0.05);R_(630)/R_(580)先上升后下降(P<0.05);高铁肌红蛋白(metmyoglobin,MetMb)相对含量呈下降后上升趋势(P<0.05);氧合肌红蛋白相对含量先上升后下降(P<0.05);脱氧肌红蛋白相对含量变化整体呈下降趋势(P<0.05);线粒体膜通透性显著增大(P<0.05);线粒体膜电位显著降低(P<0.05);线粒体复合物Ⅰ、Ⅱ、Ⅲ、Ⅳ活性显著下降(P<0.05),复合物V活性显著升高(P<0.05);活性氧水平显著上升(P<0.05);超氧化物歧化酶、谷胱甘肽过氧化物酶活性显著下降(P<0.05);过氧化氢酶活性呈先上升后下降趋势(P<0.05);ATP、ADP、AMP含量显著下降(P<0.05)。各肌红蛋白衍生态相对含量、肉色指标与氧化磷酸化各指标互有显著相关性。以上结果表明,宰后贮藏期间滩羊肉中内源抗氧化酶系的失效导致肌细胞内产生过多的活性氧,致使线粒体完整性受到破坏,对线粒体氧化磷酸化相关酶活性产生影响,进而影响肌细胞中高铁肌红蛋白还原酶系统的活力,致使Met Mb无法被还原,最终导致滩羊肉色泽稳定性变差。