氨基酸缺乏诱导细胞自噬的哺乳动物雷帕霉素靶蛋白复合体C1信号通路机制研究进展

自噬是机体维持自身稳态的一种重要生理活动,当体内氨基酸或葡萄糖等营养缺乏时,细胞会启动自噬。自噬受到多种信号通路的调节,哺乳动物雷帕霉素靶蛋白复合体C1(m TORC1)信号通路是其中重要的一条,它可以使自噬相关基因13(Atg13)磷酸化,抑制自噬起始。本文将围绕近年来报道的氨基酸缺乏诱导细胞自噬的m TORC1信号通路,包括小G蛋白、腺苷酸活化蛋白激酶(AMPK)、微小RNA(miRNA)、氨基酰-tRNA合成酶在其中的作用等研究进展进行综述。     

Wnt5a介导Wnt/Ca2+通路对BCG诱导牛原代肺泡上皮细胞自噬的调控作用

旨在探讨体外分离培养牛肺泡上皮细胞（bovine alveolar epithelial cells,BAECs）的方法及Wnt5a对牛结核分枝杆菌卡介苗（bacille Calmette-Guérin,BCG）感染BAECs细胞自噬的调控机制。试验选用酶联合消化法和机械刮刷法分离细胞,差速贴壁法纯化BAECs,免疫荧光染色检测上皮细胞标志物角蛋白14（cytokeratin 14,CK14）和角蛋白5（cytokeratin 5,CK5）的表达;BCG感染BAECs,并用Box-5抑制Wnt5a的表达,Western blot和免疫荧光染色检测自噬相关蛋白及非经典Wnt信号通路相关蛋白的表达。结果表明,采用酶联合消化法和机械刮刷法能够成功分离纯度较高的BAECs,细胞经CK14和CK5鉴定为阳性;BCG感染BAECs促进Wnt5a表达,增加细胞自噬,Box-5预处理下调BCG诱导的细胞自噬相关蛋白LC3II、P62、Atg7及Atg5的表达,且抑制非经典Wnt/Ca²⁺信号通路相关蛋白Wnt5a、CaMKII及NFAT的表达。综上,试验成功建立BAECs分离培养方法,BCG感染增加BAECs内Wnt5a表达和细胞自噬,抑制Wnt5a下调BCG诱导的BAECs细胞自噬,且Wnt5a是通过非经典Wnt/Ca²⁺信号通路调控BCG诱导的BAECs细胞自噬。     

Nutrient starvation affects expression of LC3 family at the feto-maternal interface during murine placentation

LC3 − the mammalian homolog of Atg8 − was found as autophagosome membrane binding protein in mammals and widely used as an autophagosomal marker. LC3A, B and C show different expression patterns in each tissue. The aim of this study was to reveal the differences of expression patterns among LC3 families in mouse placenta under normal condition and nutrient starving condition. LC3A and B were highly expressed in decidual cells. LC3A and B were increased in D14 compared with D12 and D16 in mouse placenta, while LC3C was decreased. Starvation induced increase in LC3B expression specifically. Immunohistochemistry showed different expression patterns among LC3A, B and C. LC3A expression in syncytiotrophoblast was vanished by starvation. The results of real time RT-PCR suggested differences between D12 and D16 in autophagic cascade induced by starvation. Taken together, this study suggests that autophagy could play a role in placental invasion system and that nutrient starvation affects LC3B expression.     

SD118-xanthocillin X (1), a novel marine agent extracted from Penicillium commune, induces autophagy through the inhibition of the MEK/ERK pathway

A compound named SD118-xanthocillin X (1) (C(18)H(12)N(2)O(2)), isolated from Penicillium commune in a deep-sea sediment sample, has been shown to inhibit the growth of several cancer cell lines in vitro. In the present study, we employed a growth inhibition assay and apoptotic analysis to identify the biological effect and detailed mechanism of SD118-xanthocillin X (1) in human hepatocellular carcinoma (HepG2) cells. SD118-xanthocillin X (1) demonstrated a concentration-dependent inhibitory effect on the growth of HepG2 cells and caused slight cellular apoptosis and significantly induced autophagy. Autophagy was detected as early as 12 h by the conversion of microtubule-associated protein 1 light chain 3 (LC3-I) to LC3-II, following cleavage and lipid addition to LC3-I. The pharmacological autophagy inhibitor 3-methyladenine largely attenuates the growth inhibition and autophagic effect of SD118-xanthocillin X (1) in HepG2 cells. Our data also indicated that the autophagic effect of SD118-xanthocillin X (1) occurs via the down-regulation of the MEK/ERK signaling pathway and the up-regulated class III PI3K/Beclin 1 signaling pathway.     

SNAT2介导蛋氨酸对牛乳腺上皮细胞增殖与自噬的调节作用

钠离子依赖性中性氨基酸转运体2（SNAT2）是一种氨基酸转运蛋白,可转运中性氨基酸,广泛分布于多种细胞中。氨基酸既可作为蛋白质合成的底物,也是调节细胞新陈代谢的关键信号分子,但SNAT2是否介导氨基酸调节BMECs增殖和自噬尚未见报道。本研究利用CASY细胞计数和Western blotting技术检测SNAT2过表达和siRNA干扰后牛乳腺上皮细胞（BMECs）增殖情况以及SNAT2对自噬标志蛋白LC3-Ⅰ/Ⅱ表达量的影响,并利用免疫荧光检测细胞自噬斑点（LC3-Ⅱ）变化。结果显示,SNAT2过表达时,p-PI3K、p-mTOR和Cyclin D1表达量增加,反之,p-PI3K、p-mTOR和Cyclin D1表达量下降。SNAT2抑制时,LC3-Ⅱ表达量增加,免疫荧光检测自噬斑点增多。添加自噬增强剂海藻糖（trehalose,Tre）和蛋氨酸（methionine,Met）后,与单一添加Tre组相比,Met+Tre组p-mTOR表达量增加,LC3-Ⅱ表达量降低,胞浆内绿色自噬斑点减少;添加Tre和Met并抑制SNAT2时,p-mTOR表达量下降,LC3-Ⅱ表达量增多,胞浆内绿色自噬斑点增加。以上结果表明,SNAT2可介导Met通过调控PI3K-mTOR/Cyclin D1信号通路调节BMECs的增殖与自噬。     

镉对体外培养大鼠肝细胞自噬的影响

选用体外培养原代大鼠肝细胞为模型,醋酸镉处理之后,用Westernblot和免疫荧光法检测了自噬标记分子LC3的表达水平,在此基础上,利用自噬激活剂（雷帕霉素）诱导自噬水平的升高,用MTT法分析了镉对细胞存活率的影响。结果显示,原代大鼠肝细胞在体外培养过程中自噬水平具有缓慢上升的趋势,而镉处理延缓了这种趋势,降低了自噬的水平和细胞存活率;利用激活剂增强自噬后不能减弱镉的损伤,表明镉有可能通过抑制自噬的保护作用,造成对肝细胞的损伤。     

氧化应激与自噬

自噬是细胞依赖溶酶体对蛋白质和细胞器进行降解的过程,能帮助细胞适应各种不良刺激,在维持细胞内环境稳态和实现自我更新中起着重要作用。氧化应激是机体氧化和抗氧化系统之间的稳态被破坏而造成的应激状态。大量研究表明,氧化应激中产生的活性氧能诱导自噬产生,而自噬能缓解氧化应激造成的损伤,从而保护细胞存活。本文主要对自噬的形成过程、氧化应激诱导自噬产生机制以及自噬缓解氧化应激的途径等进行综述,以期为畜牧生产中通过调控自噬缓解氧化应激提供理论依据。     

Dynamics of nitrogen translocation from mature leaves to new shoots and related gene expression during spring shoots development in tea plants (Camellia sinensis L.)

The contribution of N remobilization is crucial for new shoots growth and quality formation during spring tea shoots development. However, the translocation mechanism of N from source leaves to sink young shoots is not well understood. In the present study, ¹⁵N urea was applied to mature tea leaves one week before bud break to track N remobilization in a field experiment. The dynamic changes in plant ¹⁵N abundance, contents of amino acids, and the expression levels of genes related to N metabolism and translocation were followed during the 18‐d development of new spring shoots until three expanding young leaves. The results showed that during the growth of new shoots the amount of ¹⁵N in the shoots increased, whereas the N_dff (N derived from ¹⁵N‐urea) in mature leaves decreased, showing that the foliar‐applied N in mature leaves was readily exported to new shoots. This process was found to be accompanied by decline of chlorophylls. In the mature leaves, expression CsATG18a and CsSAG12 involved in autophagy was dramatically induced (> 4‐fold) at approximately nine days after the bud breaking. The genes involved in the transformation of amino acids, including primarily CsGDH2, CsGDH4, CsGLT3, CsGS1;3, and CsASN2 were upregulated by > 3‐fold after bud breaking. The expression levels of CsATG8A, CsATG9, CsSAG12, CsGS1;1, CsGDH1, and CsAAP6 correlated negatively with the N_dff in mature leaves, but positively with ¹⁵N amount and total N amount in new shoots, suggesting these genes played important roles in N export from mature leaves. In the new shoots, the expression of most genes showed two defined peaks, one on six days and one on 12 days after bud breaking. The expression of CsGS2, CsASN3, CsGLT1, and CsAAP4 positively correlated with the ¹⁵N amount and total N amount in new shoots. These genes might be involved in the transport and re‐assimilation of N from mature leaves. The overall results demonstrated that the translocation of ¹⁵N from mature leaves to new spring shoots was regulated by the genes involved in autophagy, protein degradation, amino acid transformation and transport.