美仁牦牛 PDK4 基因克隆及组织表达

为研究美仁牦牛PDK4基因在各组织中的表达特征,探索其与脂肪沉积机制的相关性,采集了美仁牦牛背最长肌、心脏、肝脏、脾脏、肺脏、肾脏、脂肪和睾丸等组织样,并提取了其总RNA,通过RT-PCR、生物信息学软件及qPCR等技术对美仁牦牛PDK4基因进行了扩增、生信分析和表达特征研究。结果表明,美仁牦牛PDK4基因CDS区全长1224 bp,编码407个氨基酸,蛋白相对分子质量为46.15914 ku,理论等电点6.60,总平均亲水性-0.169,为亲水性蛋白;系统进化树结果表明,美仁牦牛与野牦牛亲缘关系最近,与鬣狗亲缘关系最远;PDK4蛋白有34处磷酸化位点,无信号肽和跨膜区,主要在线粒体中发挥生物学功能;美仁牦牛PDK4蛋白主要是由α-螺旋和无规则卷曲组成。PDK4基因在7日龄美仁牦牛肝脏和肺脏中的表达量显著高于其他组织(P<0.05),在肌肉、脂肪、脾脏和睾丸中中度表达,在肾和心脏中低表达。随着牦牛年龄增长,PDK4基因在30月龄美仁牦牛脂肪组织中的表达量增加,并显著高于7日龄美仁牦牛脂肪中的表达量(P<0.05)。以上结果表明,PDK4基因可能在美仁牦牛的生长过程中参与脂肪调控,在脂肪沉积过程中发挥重要作用。

不同训练方式对静息骨骼肌糖酵解能力及线粒体PDK4、CPT-1基因转录的影响

目的:比较耐力训练和间歇性速度训练对静息骨骼肌糖酵解能力及线粒体PDK4、CPT-1基因转录的影响;方法:30只大鼠随机分为3组:安静组(C,n=10)、耐力训练组(E,n=10)、间歇性速度训练组(S,n=10),训练8周。间歇性速度训练:每天9～10次10s极量强度(≥42m/min)的跑台运动,间歇时间30～60s;耐力训练:每天30～60min低强度(≤16.7m/min)的持续跑台运动;每周均训练6天。最后一次训练结束后的24～48h内切取腓肠肌,比色法检测丙酮酸、乳酸、HK、PK活性,Real-timePCR检测PDK4、CPT-1的mR-NA表达;结果:1)E组和S组丙酮酸均非常显著地高于C组(P<0.01),E组与S组无显著差异;乳酸浓度E组与C组无显著差异,但S组显著高于E组(P<0.05)和C组(P<0.01);2)E组(P<0.05)和S组(P<0.01)HK活性显著高于C组,但E组、S组PK活性与C组无显著差异;E组与S组的HK、PK活性均无显著差异;3)E组PDK4mRNA表达显著低于C组(P<0.05),S组CPT-1mRNA表达显著高于C组(P<0.05),E组与S组的PDK4、CPT-1mRNA表达均无显著差异;结论:1)耐力训练与间歇性速度训练都能提高静息骨骼肌的丙酮酸水平,但只有间歇性速度训练提高静息骨骼肌的乳酸水平,说明间歇性速度训练很可能使骨骼肌在静息时的无氧代谢已处于活跃状态。耐力训练使丙酮酸升高则可能是脂肪酸氧化能力提高所必需的匹配效应;2)耐力训练与间歇性速度训练都能提高HK活性,但对PK活性无影响。耐力训练与间歇性速度训练在糖脂代谢中有着许多类似效应。间歇性速度训练也能作为一种节省时间的方式提高有氧代谢能力,但在提高有氧代谢能力的同时也能促进静息骨骼肌丙酮酸向乳酸的转化;3)耐力训练使PDK4转录抑制,间歇性速度训练使CPT-1转录上调,这与各训练方式下静息骨骼肌的乳酸水平有着高度一致性。

终末期肾病患者骨骼肌中丙酮酸脱氢酶活性与丙酮酸脱氢酶激酶4的表达

目的·探讨终末期肾病(end-stage renal disease,ESRD)患者骨骼肌丙酮酸脱氢酶(pyruvate dehydrogenase,PDH)活性及丙酮酸脱氢酶激酶4(pyruvate dehydrogenase kinase 4,PDK4)在骨骼肌中表达水平的变化。方法·收取ESRD患者和非慢性肾脏病(non-chronic kidney diseases,non-CKD)患者骨骼肌样本,比较2组患者的临床特征,ELISA法检测PDH活性,实时荧光定量PCR法检测PDK1~PDK4型同工酶、PDH各亚基的基因转录水平,Western blotting检测PDK1和PDK4蛋白表达水平。结果·non-CKD组和ESRD组患者在一般人口学资料上无明显差异,ESRD组血浆肌酐、尿素氮显著升高(均P<0.05),估算的肾小球滤过率、血红蛋白、白蛋白则显著降低(均P<0.05)。ESRD组骨骼肌PDH活性显著低于non-CKD组(P=0.014),2组患者骨骼肌PDK1~PDK4及PDH各亚基mRNA转录水平无明显差异,ESRD组PDK4蛋白表达量显著高于non-CKD对照组(P=0.000)。结论·ESRD患者骨骼肌中PDH活性下降,可能与PDK4表达上调有关。

Deficiency of pyruvate dehydrogenase kinase 4 sensitizes mouse liver to diethylnitrosamine and arsenic toxicity through inducing apoptosis

Background and Aim:Pyruvate dehydrogenase kinase 4(PDK4)is a metabolism switch that regulates glucose oxidation and the tricarboxylic acid cycle(TCA cycle)in the mitochondria.Liver detoxifies xenobiotics and is constantly challenged by various injuries.This study aims at understanding how the loss of the metabolism regulator PDK4 contributes to liver injuries.Methods:Wild-type(WT)and Pdk4 knockout(Pdk4-/-)mice of different ages were examined for spontaneous hepatic apoptosis.Juvenile or adult mice of two genotypes were insulted by diethylnitrosamine(DEN),arsenic,galactosamine(GalN)/lipopolysaccharide(LPS),anti-CD95(Jo2)antibody or carbon tetrachloride(CCl4).Liver injury was monitored by blood biochemistry test.Apoptosis was determined by terminal deoxynucleotidyl transferase dUTP nick end labeling(TUNEL)staining,poly(ADP-ribose)polymerase(PARP)cleavage,and caspase activity assay.Inflammatory response was determined by nuclear factor(NF)-kB activation and the activation of NF-kB target genes.Primary hepatocytes were isolated and cell viability was evaluated by MTS assay.Results:We showed that systematic Pdk4-/-in mice resulted in age-dependent spontaneous hepatic apoptosis.PDK4-deficiency increased the toxicity of DEN in juvenile mice,which correlated with a lethal consequence and massive hepatic apoptosis.Similarly,chronic arsenic administration induced more severe hepatic apoptosis in Pdk4-/-mice compared to WT control mice.An aggravated hepatic NF-kB mediated-inflammatory response was observed in Pdk4-/-mice livers.In vitro,Pdk4-deficient primary hepatocytes were more vulnerable to DEN and arsenic challenges and displayed higher caspase activity than wild type cells.Notably,hepatic PDK4 mRNA level was remarkably reduced during acute liver failure induced by GalN/LPS or Jo2 antibody.The diminished PDK4 expression was also observed in CCl4-induced acute liver injury.Conclusions:PDK4 may contribute to the protection from apoptotic injury in mouse liver.