盘基网柄菌细胞分化和凋亡中酸性磷酸酶的定位

利用电镜酶细胞化学方法,观察盘基网柄菌细胞分化和凋亡过程中酸性磷酸酶的变化。在细胞丘阶段,酶反应颗粒出现在线粒体内自噬空泡内,随着内自噬空泡的逐渐增大,线粒体内的酶反应颗粒逐渐增多,线粒体内嵴结构不断破坏,直至遍布整个空泡化的线粒体内;当细胞发育至前孢子细胞时,由于嵴结构被完全破坏,酶反应颗粒主要集中在前孢子细胞空泡的单层膜上,空泡化的线粒体内酶反应颗粒逐渐消失。在凋亡的柄细胞中,自噬泡内酶反应强烈,凋亡中期的前柄细胞的细胞核中出现酶反应颗粒,均匀分布在细胞核中,直至细胞核与自噬泡融合。在孢子细胞外被与质膜间也观察到非溶酶体酸性磷酸酶。所得结果证实:线粒体内自噬小泡具有消化功能;自噬泡内酶活性与细胞器消亡有关;细胞核中的酸性磷酸酶可能作为一种非溶酶体酸性磷酸酶参与细胞核中核蛋白的脱磷酸化过程,与发育相关基因表达有关     

盘基网柄菌细胞分化和凋亡的形态特征

本文用透射电镜和DAPI荧光染色法研究了盘基网柄菌(Dictyosteliumdiscoideum)细胞分化和柄细胞的凋亡特征,结果显示:细胞丘中绝大部分细胞的线粒体内出现一小空泡,随着发育进程,空泡逐渐增大,线粒体的嵴随之变少,直至线粒体完全空泡化,最后形成单层膜的空泡。据此我们推测前孢子细胞特有的空泡来源于线粒体,并且这种细胞器水平上的内自噬现象与前孢子细胞分化密切相关。在前柄细胞分化阶段,前柄细胞中出现数个自噬泡,最初吞噬的线粒体嵴结构完整;随着前柄细胞进一步分化,部分线粒体内出现类似于前孢子细胞中的内自噬现象,并且自噬泡只吞噬这种线粒体。在凋亡后期,细胞核内核仁消失,染色体固缩形成高电子密度斑块,自噬泡采用与细胞核膜融合的方式来完成核的清除,最后柄细胞完全空泡化且包被一层纤维素壁。作者认为前柄细胞凋亡过程实质上是一种分化过程,所以有其鲜明特点:细胞出现自噬泡,标志着凋亡开始,用自噬而不是凋亡小体来清除胞内各种细胞器,直到分化最后阶段才清除细胞核和形成纤维素壁。这些特点不仅是前柄细胞凋亡的形态学指标,也和细胞发育和分化相关。     

簇生岐柄菌的超微形态学研究

为揭示网柄细胞状黏菌的超微结构特征,对簇生岐柄菌Cavenderia fasciculata生活史过程中的孢子、黏变形体和柄细胞3种类型的细胞超微结构进行系统观察,并与目前仅知的3种网柄细胞状黏菌的超微结构进行比较。结果表明：簇生岐柄菌C. fasciculata的孢子、黏变形体和柄细胞内均有线粒体结构,随着细胞分化,线粒体内部结构逐渐破坏,并被自噬泡吞噬;孢子表面具有线状纹饰。     

细胞色素c在盘基网柄菌细胞凋亡中的作用

细胞色素c在细胞凋亡中发挥着重要的作用,其作用机理在高等真核生物及低等真核生物酵母中已经比较清楚,但在盘基网柄菌(Dictyostelium discoideum)中的作用却没有相关报道.所以我们用western blot和实时荧光定量PCR的方法分别测定了盘基网柄菌前柄细胞和前孢子细胞中细胞色素c的含量及表达量的变化...     

PKA在盘基网柄菌(Dictyostelium discoideum)多细胞发育中的作用

在盘基网柄菌(Dictyosteliumdiscoideum)多细胞发育中,蛋白激酶A(proteinkinaseA,PKA)发挥多重作用.细胞聚集阶段,PKA调节腺苷酰环化酶的活性,中转cAMP,诱导dut、pdi等一些发育早期的基因表达;参与启动聚集后的细胞分化和形态构成,增强GBF活性,激活前孢子细胞特有基因的表达;它还精密调控前柄细胞特有基因ecmB的表达,准确启动拔顶发育,诱导孢柄和孢子的成熟.子实体形成后,PKA又是维持孢子休眠和保证孢子有效萌发的必需因子.在PKA调控下,盘基网柄菌有条不紊地完成整个发育过程.     

盘基网柄菌中分化诱导因子信号与细胞命运决定

对盘基网柄菌发育过程中分化诱导因子(DIF)的作用及其机制进行了综述,包括DIF对盘基网柄菌前柄细胞、柄细胞分化的作用以及DIF的生物合成、DIF的诱导、降解失活、DIF对细胞命运和细胞比例的调节及其作用机制等。     

抑制自噬促进冬凌草甲素诱导的多发性骨髓瘤细胞凋亡涉及胞内ROS产生

目的本实验主要研究冬凌草甲素诱导多发性骨髓瘤发生自噬、凋亡,两者之间的关系以及所涉及的相关机制。方法利用MTT比色法检测冬凌草甲素对多发性骨髓瘤RPMI8226细胞的增殖活性影响;透视电镜观察细胞内凋亡和自噬的形态学改变;TUNEL检测细胞凋亡;分别利用以下技术检测处理后的细胞内的自噬变化:使用QDs605nm-Anti-LC3荧光探针以及免疫荧光技术定位细胞胞内LC3Ⅰ和LC3Ⅱ蛋白,利用western blot免疫印记技术检测Beclin 1蛋白表达水平;利用DCFH-DA探针以及流式细胞术检测细胞胞内ROS水平。结果冬凌草甲素能明显抑制RPMI8226细胞增殖,其抑制作用呈时间、剂量依赖性;冬凌草甲素能同时诱发细胞凋亡、自噬和胞内ROS产生;NAC完全抑制胞内ROS产生后冬凌草甲素诱导的细胞凋亡消失;3-MA抑制自噬后,冬凌草甲素诱导的胞内ROS产生进一步增多,凋亡增多。结论冬凌草甲素能明显抑制RPMI8226细胞增殖;冬凌草甲素同时诱发细胞凋亡和自噬;胞内ROS产生介导冬凌草甲素诱导的凋亡;凋亡为细胞死亡的主要途径,而自噬通过下调胞内ROS产生抑制凋亡。     

盘基网柄菌细胞黏附分子cadA/DdCAD-1在细胞分化及细胞命运决定中的作用

盘基网柄菌细胞黏附分子DdCAD-1是在细胞发育过程中最先表达的黏附分子,为了研究DdCAD-1在盘基网柄菌细胞发育中的作用,将cadA基因的突变株cadA-细胞用中性红染料染色,发育成的蛞蝓体显示cadA-细胞的前柄细胞/前孢子细胞的分化出现明显的障碍,外源表达的重组蛋白His6-DdCAD-1与cadA-细胞作用一段时间后,这种现象得到了改善。另外,cadA-细胞的孢子产率也有所降低,外源重组蛋白也可以拯救该表现型。表达DdCAD-1的细胞与cadA-细胞共同发育所形成的嵌合体显示表达DdCAD-1的细胞占据在拔顶期结构的顶端及尾部,而这些结构都在非孢子区,最终会死亡。提示DdCAD-1对于细胞分化及细胞命运决定有重要意义。     

盘基网柄菌发育中的细胞粘附分子及其信号转导

在盘基网柄菌发育早期,DdCAD-1和csA调节了变形虫细胞间的粘着,调控该过程的机制类似于胚胎发育中上皮细胞层的闭合。完成网柄菌发育的一个必需分子是gpl50异嗜性粘附分子。盘基网柄菌β-连环蛋白同源物Aardvark(Aar)的缺乏使细胞间失去粘着连接,Aar也有信号转导功能,调控了前孢子细胞基因的表达。因此,细胞间的粘着是盘基网柄菌发育的一个重要组成部分,并与调控形态发生过程的信号转导有密切相互作用关系。     

将盘基网柄菌用于本科细胞生物学综合性实验教学初探——电穿孔转化绿色荧光蛋白

盘基网柄菌(Dictyostelium discoideum)是一个应用广泛的模式生物,非常适合用来研究胞质分裂、细胞运动、吞噬作用、趋化性、趋电性、信号转导以及个体发育过程中的细胞分化。该实验主要介绍电穿孔技术转化绿色荧光蛋白标记肌动蛋白基因质粒(Lifeact-GFP)进入盘基网柄菌活细胞中,抗性筛选(潮霉素B)获得阳性克隆子,最后借助荧光显微镜观察绿色荧光蛋白标记的微丝在盘基网柄菌的分布情况。综合性实验训练可提高学生的学习兴趣和综合运用理论知识的能力,进而可培养学生的科学研究思维。     

Ultrastructure of mitochondria apparatus of cardiomyocytes in apoptosis induced by long-term anoxia in rats

Apoptosis in cardiomyocytes was induced by incubation of pieces of cardiac tissues under condition of anoxia. Electronmicroscopic investigation detected previously unknown changes in mitochondrial ultrastructure. The mitochondrial population was characterized by morphological heterogeneity. In addition to a mitochondrial population characterized with irrigated cleared matrix, anoxia induced the appearance of an atypical and previously unknown population of small electron-dense cardiomyocyte mitochondria. They were characterized by unusual localization inside electron-light mitochondria ("mitochondria inside mitochondria"). The most part of mitochondria with the irrigated matrix are commonly characterized by unusual types of rearrangements of the inner mitochondrial membrane. Under anoxic conditions, the inner mitochondrial membrane formed electron-dense ordered structures. This is a spongy structure with cells of equal size. Results of our study are discussed in terms of conception of changes in mitochondrial reticulum ultrastructure during apoptosis.     

Evolution of urate-degrading enzymes in animal peroxisomes

The end product of purine metabolism varies from species to species. The degradation of purines to urate is common to all animal species, but the degradation of urate is much less complete in higher animals. The comparison of subcellular distribution, intraperoxisomal localization forms, molecular structures, and some other properties of urate-degrading enzymes (urate oxidase, allantoinase, and allantoicase) among animals is described. Liver urate oxidase (uricase) is located in the peroxisomes in all animals with urate oxidase. On the basis of the comparison of intraperoxisomal localization forms, mol wt, and solubility of liver urate oxidase among animals, it is suggested that amphibian urate oxidase is a transition form in the evolution of aquatic animals to land animals. Allantoinase and allantoicase are different proteins in fish liver, but the two enzymes form a complex in amphibian liver. The subcellular localization of allantoinase and allantoicase varies among fishes. Hepatic allantoinase is located both in the peroxisomes and in the cytosol in saltwater fishes, and only in the cytosol in freshwater fishes. Hepatic allantoicase is located on the outer surface of the, peroxisomal membrane in the mackerel group and in the peroxisomal matrix in the sardine group. Amphibian hepatic allantoinase-allantoicase complex is probably located in the mitochondria. On the basis of previous data, changes of allantoinase and allantoicase in molecular structure and intracellular localization during animal evolution may be as follows: Fish liver allantoinase is a single peptide with a mol wt of 54,000, and is located both in the peroxisomes and in the cytosol, or only in the cytosol. Fish liver allantoicase consists of two identical subunits with a mol wt of 48,000, and is located in the peroxisomal matrix or on the outer surface of the peroxisomal membrane. The evolution of fishes to amphibia resulted in the dissociation of allantoicase into subunits, and in the association of allantoinase with the subunit of allantoicase. This amphibian enzyme was lost by further evolution.     

Staying alive: bacterial inhibition of apoptosis during infection

The ability of bacterial pathogens to inhibit apoptosis in eukaryotic cells during infection is an emerging theme in the study of bacterial pathogenesis. Prevention of apoptosis provides a survival advantage because it enables the bacteria to replicate inside host cells. Bacterial pathogens have evolved several ways to prevent apoptosis by protecting the mitochondria and preventing cytochrome c release, by activating cell survival pathways, or by preventing caspase activation. This review summarizes the most recent work on bacterial anti-apoptotic strategies and suggests new research that is necessary to advance the field.     

Apoptotic role of TGF-β mediated by Smad4 mitochondria translocation and cytochrome c oxidase subunit II interaction

Smad4, originally isolated from the human chromosome 18q21, is a key factor in transducing the signals of the TGF-β superfamily of growth hormones and plays a pivotal role in mediating antimitogenic and proapoptotic effects of TGF-β, but the mechanisms by which Smad4 induces apoptosis are elusive. Here we report that Smad4 directly translocates to the mitochondria of apoptotic cells. Smad4 gene silencing by siRNA inhibits TGF-β-induced apoptosis in Hep3B cells and UV-induced apoptosis in PANC-1 cells. Cell fractionation assays demonstrated that a fraction of Smad4 translocates to mitochondria after long time TGF-β treatment or UV exposure, during which the cells were under apoptosis. Smad4 mitochondria translocation during apoptosis was also confirmed by fluorescence observation of Smad4 colocalization with MitoTracker Red. We searched for mitochondria proteins that have physical interactions with Smad4 using yeast two-hybrid screening approach. DNA sequence analysis identified 34 positive clones, five of which encoded subunits in mitochondria complex IV, i.e., one clone encoded cytochrome c oxidase COXII, three clones encoded COXIII and one clone encoded COXVb. Strong interaction between Smad4 with COXII, an important apoptosis regulator, was verified in yeast by β-gal activity assays and in mammalian cells by immunoprecipitation assays. Further, mitochondrial portion of cells was isolated and the interaction between COXII and Smad4 in mitochondria upon TGF-β treatment or UV exposure was confirmed. Importantly, targeting Smad4 to mitochondria using import leader fusions enhanced TGF-β-induced apoptosis. Collectively, the results suggest that Smad4 promote apoptosis of the cells through its mitochondrial translocation and association with mitochondria protein COXII.     

Bcl-2 prevents abnormal mitochondrial proliferation during etoposide-induced apoptosis

At the late stage of etoposide-induced apoptosis in HL-60 cells, marked by condensation of chromatin, mitochondria increase in numbers. There is also a drastic increase in mitochondrial DNA content. This increase in mitochondrial numbers and DNA content is an indicator of mitochondrial proliferation during apoptosis. These proliferating mitochondria exhibit abnormal morphology and are impaired, which is demonstrated by decrease in mitochondrial membrane potential and ATP content. The described apoptosis-induced abnormal mitochondrial proliferation was inhibited by overexpression of Bcl-2 protein, which also diminishes mitochondrial impairment. The increase in mitochondrial DNA levels correlated with elevated expression of one of the regulators of mitochondrial DNA replication, mtSSB. Our data suggest that proliferation of mitochondria may be an integral part of a cascade of apoptotic events.     

Apoptotic microtubule network organization and maintenance depend on high cellular ATP levels and energized mitochondria

Microtubule cytoskeleton is reformed during apoptosis, forming a cortical structure beneath plasma membrane, which plays an important role in preserving cell morphology and plasma membrane integrity. However, the maintenance of the apoptotic microtubule network (AMN) during apoptosis is not understood. In the present study, we examined apoptosis induced by camptothecin (CPT), a topoisomerase I inhibitor, in human H460 and porcine LLCPK-1α cells. We demonstrate that AMN was organized in apoptotic cells with high ATP levels and hyperpolarized mitochondria and, on the contrary, was dismantled in apoptotic cells with low ATP levels and mitochondrial depolarization. AMN disorganization after mitochondrial depolarization was associated with increased plasma membrane permeability assessed by enhancing LDH release and increased intracellular calcium levels. Living cell imaging monitoring of both, microtubule dynamics and mitochondrial membrane potential, showed that AMN persists during apoptosis coinciding with cycles of mitochondrial hyperpolarization. Eventually, AMN was disorganized when mitochondria suffered a large depolarization and cell underwent secondary necrosis. AMN stabilization by taxol prevented LDH release and calcium influx even though mitochondria were depolarized, suggesting that AMN is essential for plasma membrane integrity. Furthermore, high ATP levels and mitochondria polarization collapse after oligomycin treatment in apoptotic cells suggest that ATP synthase works in “reverse” mode during apoptosis. These data provide new explanations for the role of AMN and mitochondria during apoptosis.     

Fragmented mitochondria are sensitized to Bax insertion and activation during apoptosis

Recent studies have shown mitochondrial fragmentation during cell stress and have suggested a role for the morphological change in mitochondrial injury and ensuing apoptosis. However, the underlying mechanism remains elusive. Here we demonstrate that mitochondrial fragmentation facilitates Bax insertion and activation in mitochondria, resulting in the release of apoptogenic factors. In HeLa cells, overexpression of mitofusins attenuated mitochondrial fragmentation during cisplatin- and azide-induced cell injury, which was accompanied by less apoptosis and less cytochrome c release from mitochondria. Similar effects were shown by inhibiting the mitochondrial fission protein Drp1 with a dominant negative mutant (dn-Drp1). Mitofusins and dn-Drp1 did not seem to significantly affect Bax translocation/accumulation to mitochondria; however, they blocked Bax insertion and activation in mitochondrial membrane. Consistently, in rat kidney proximal tubular cells, small interfering RNA knockdown of Drp1 prevented mitochondrial fragmentation during azide-induced ATP depletion, which was accompanied by less Bax activation, insertion, and oligomerization in mitochondria. These cells released less cytochrome c and AIF from mitochondria and showed significantly lower apoptosis. Finally, mitofusin-null mouse embryonic fibroblasts (MEF) had fragmented mitochondria. These MEFs were more sensitive to cisplatin-induced Bax activation, release of cytochrome c, and apoptosis. Together, this study provides further support for a role of mitochondrial fragmentation in mitochondrial injury and apoptosis. Mechanistically, mitochondrial fragmentation may sensitize the cells to Bax insertion and activation in mitochondria, facilitating the release of apoptogenic factors and consequent apoptosis.     

Laser micro-irradiation of mitochondria: is there an amplified mitochondrial death signal in neural cells?

Several mitochondrial proteins, such as cytochrome c, are directly involved in the pathway for caspase activation following induction of apoptosis. Release of mitochondrial cytochrome c early in apoptosis is rapid and almost complete. Microinjection of cytochrome c into resting cells induces apoptosis, but the amount needed approaches the total cellular content. These observations suggest that mitochondrial protein release is an all-or-nothing process inside the cell and not an amplifiable apoptotic signal. To test this hypothesis, laser micro-irradiation was used to rupture membranes of individual mitochondria within living rat neural cells. Laser micro-irradiation caused swelling, fragmentation, depolarization, and cytochrome c depletion in targeted mitochondria. These effects were explained by correlative electron microscopic analysis showing local rupture of outer and inner membranes at the site of irradiation. In all cases, there were no detectable changes in the structure, membrane potential, or cytochrome c content of neighboring, non-irradiated organelles. Furthermore, irradiation of up to 15% of the mitochondria in a cell did not induce apoptosis. The results from these laser micro-irradiation experiments prove that local release of mitochondrial proteins does not constitute an amplifiable apoptotic signal in resting neural cells.