拟核结合蛋白调控链霉菌形态分化和次级代谢的作用和机制

链霉菌具有独特而复杂的形态分化周期,涉及到染色体复制、浓缩和分离等多个步骤,并伴随着菌丝的分隔和片段化。拟核结合蛋白作为染色体高级结构的重要组成成分,在调控链霉菌的形态分化中发挥了重要作用,调控许多与DNA相关的过程,包括基因表达、DNA保护、重组/修复和拟核的形成与维持等。此外,拟核结合蛋白作为细菌重要的全局性调控因子,也广泛参与了链霉菌次级代谢的调控。本文总结了链霉菌拟核结合蛋白的结构和功能,特别是调控形态分化和次级代谢的最新研究成果。     

线粒体DNA异常与肿瘤

能量代谢重编程是肿瘤细胞一个重要的标志特征,而由线粒体DNA(mitochondrial DNA,mtDNA)结构及功能异常引起的线粒体功能障碍是其机制之一。人类mtDNA为位于线粒体基质中由16569bp组成的双链闭合环状分子,编码与氧化磷酸化电子传递链相关的13种多肽以及与线粒体蛋白合成相关的22种tRNA和2种rRNA。近年来,人们发现多种肿瘤组织及细胞中存在mtDNA序列的多类型突变或拷贝数的变异,且mtDNA的这些异常与肿瘤的发生发展、早期诊断及放化疗监测等密切相关。异常的mtDNA因削弱线粒体产能、增加细胞内活性氧(reactive oxygen species,ROS)水平、打破Ca2+稳态,从而赋予肿瘤细胞代谢重编程、凋亡抵抗等侵袭性进程。针对mtDNA异常在肿瘤发生发展中的作用及机制研究,将为肿瘤的早期诊断及靶向治疗提供新的策略。     

哺乳动物线粒体蛋白质翻译及其调控机制

线粒体是真核细胞内参与能量生成和物质代谢的重要细胞器。线粒体核糖体(mitochondrial ribosome, MR)作为细胞器中的翻译机器,用于表达线粒体DNA(mitochondrial DNA, mtDNA)编码的基因。近年来,随着研究的不断深入,人们对参与哺乳动物线粒体蛋白质翻译的蛋白质因子及其翻译的基本过程有了越来越清晰的认识,这对阐明线粒体蛋白质翻译的调控机制及研究人类线粒体疾病等方面具有重要的意义。线粒体蛋白质的翻译过程分为起始、延伸、终止和回收四个阶段。本文综述哺乳动物线粒体核糖体的结构与功能,以及线粒体蛋白质翻译因子的性质与功能,并进一步探讨翻译激活因子、微小RNA、线粒体COX翻译调控组装中间体(mt-translation regulation assembly intermediate of COX, MITRAC)以及核糖体的翻译后修饰对线粒体蛋白质翻译的调控及其机制,展望其对人类线粒体相关疾病研究的应用前景。     

线粒体DNA异质性

线粒体 DNA（mitochondrial DNA,mtDNA）是线粒体内最重要的遗传物质。mtDNA 突变普 遍存在,突变型 mtDNA 与野生型 mtDNA 共存的现象被称为 mtDNA 异质性。mtDNA 异质性与衰老和多种疾病密切相关。mtDNA异质性特性、mtDNA 异质性与衰老和疾病相关性以及线粒体疾病的治疗等都是近年来遗传学研究的热点。本文从 mtDNA 异质性的动态变化、组织特异性、mtDNA 异质性与疾病以及线粒体疾病的治疗等方面对 mtDNA 异质性进行综述。     

线粒体DNA与DNA甲基化的关系

线粒体DNA（mitochondrial DNA,mtDNA）遗传信息量虽小,却控制着线粒体一些最基本的性质,对细胞及其功能有着重要影响。mtDNA的损伤与衰老、肿瘤等疾病的发生有关。DNA甲基化是调节基因表达的重要方式之一。mtDNA基因的表达受核DNA（nuclear DNA,nDNA）的调控,mtDNA和nDNA协同作用参与机体代谢调节和发病。本文就近年来mtDNA与DNA甲基化的关系作一综述。     

拟核结合蛋白与细菌基因的表达调控

拟核结合蛋白是细菌遗传物质组织和基因表达调控的关键. 细菌基因组压缩为致密的拟核必需有拟核结合蛋白的支撑. 拟核结合蛋白、DNA超螺旋和大分子簇在拟核的结构形成中起到重要作用,其中拟核结合蛋白最重要.拟核结合蛋白还影响细菌DNA的复制、重组、转录和修复等多个重要生理过程.作为全局调控因子,拟核结合蛋白是调控细菌适应环境变化所需基因表达的关键. 本文总结拟核结合蛋白的结构、功能和调控,特别是其在致病与非致病分枝杆菌中的差别,为寻找新药物靶标提供线索.     

线粒体DNA与DNA甲基化

线粒体是除细胞核之外唯一携带遗传物质的细胞器,其线粒体DNA（mitochondrial DNA,mtDNA）控制着线粒体一些最基本的性质,对细胞功能有着重要影响.DNA甲基化是调节基因表达的重要方式之一.研究表明mtDNA存在CpG位点的低甲基化,并且mtDNA基因的表达受核DNA（nuclear DNA,nDNA）及线粒体自身DNA甲基化的调控,mtDNA和nDNA协同作用参与机体代谢调节和疾病发生发展过程.就近年来mtDNA与DNA甲基化的关系作一综述.     

线粒体功能障碍机制及其相关疾病研究进展

线粒体是真核细胞重要的细胞器,与多种疾病的发生发展密切相关。线粒体膜受到破坏、呼吸链受到抑制、酶活性降低、线粒体DNA(mitochondrial DNA,mtDNA)的损伤等都会引起线粒体功能障碍,可直接或间接地影响整个细胞的正常功能。现就线粒体功能障碍与其相关疾病的关系作一综述。     

线粒体功能障碍与慢性肝病

线粒体不仅作为细胞能量的代谢中心,而且在参与物质代谢中发挥重要作用。线粒体含有多种限速酶用于嘧啶和血红素合成、氧化磷酸化、自由基生成和解毒、胆固醇和神经递质代谢,以及凋亡程序的执行。线粒体功能障碍主要表现在线粒体形态结构的改变、ATP合成减少、活性氧物种的过度产生、动力学失衡和mtDNA损伤。因功能受损参与多种疾病,包括神经系统疾病、心血管系统疾病、肝脏疾病、肾脏疾病、糖尿病以及DNA损伤反应相关的癌症的发生与发展。本文就近年来关于线粒体功能障碍与慢性肝病关系的研究作一综述,旨在为靶向线粒体治疗肝脏相关疾病提供研究思路。     

人线粒体DNA复制控制区与疾病和衰老的关系

线粒体DNA(mitochondrial DNA,mtDNA)复制控制区(又称D-环区)是线粒体非编码区中较为重要的区域,参与并调节线粒体DNA的复制与转录。然而,与核基因组不同的是,线粒体DNA的复制与转录并不是相互独立的,而是存在着密切的联系。从目前的研究看来,复制控制区的某些变化很可能会引起mtDNA复制、转录的变化,从而导致线粒体功能的变化,最终引起线粒体疾病或衰老的发生。     

TFAM knockdown-triggered mtDNA-nucleoid aggregation and a decrease in mtDNA copy number induce the reorganization of nucleoid populations and mitochondria-associated ER-membrane contacts

The correct organization of mitochondrial DNA (mtDNA) in nucleoids and the contacts of mitochondria with the ER play an important role in maintaining the mitochondrial genome distribution within the cell. Mitochondria-associated ER membranes (MAMs) consist of interacting proteins and lipids located in the outer mitochondrial membrane and ER membrane, forming a platform for the mitochondrial inner membrane-associated genome replication factory as well as connecting the nucleoids with the mitochondrial division machinery. We show here that knockdown of a core component of mitochondrial nucleoids, TFAM, causes changes in the mitochondrial nucleoid populations, which subsequently impact ER-mitochondria membrane contacts. Knockdown of TFAM causes a significant decrease in the copy number of mtDNA as well as aggregation of mtDNA nucleoids. At the same time, it causes significant upregulation of the replicative TWNK helicase in the membrane-associated nucleoid fraction. This is accompanied by a transient elevation of MAM proteins, indicating a rearrangement of the linkage between ER and mitochondria triggered by changes in mitochondrial nucleoids. Reciprocal knockdown of the mitochondrial replicative helicase TWNK causes a decrease in mtDNA copy number and modifies mtDNA membrane association, however, it does not cause nucleoid aggregation and considerable alterations of MAM proteins in the membrane-associated fraction. Our explanation is that the aggregation of mitochondrial nucleoids resulting from TFAM knockdown triggers a compensatory mechanism involving the reorganization of both mitochondrial nucleoids and MAM. These results could provide an important insight into pathological conditions associated with impaired nucleoid organization or defects of mtDNA distribution.     

Proteins associated with mitochondrial DNA protect it against the action of X-rays and hydrogen peroxide

It has been suggested in a number of investigations that the high vulnerability of mitochondrial DNA to reactive oxygen species and other damaging agents is due to the absence in mitochondria of histones complexed with DNA. In the present study it was shown that DNA-binding proteins of mitochondrial nucleoids were able to shield mitochondrial DNA from X-ray radiation and hydrogen peroxide, as nuclear histones did. Mitochondria, mitochondrial nucleoid proteins, and histones were isolated from mouse liver cells. The degree of damage to or protection of mitochondrial DNA was assessed from the yield of its PCR amplification product. The in vitro experiments demonstrated that mouse mitochondrial DNA, when in complex with mitochondrial nucleoids or nuclear histones, was damaged much less by radiation and/or hydrogen peroxide than in the absence of these proteins and histones. No significant difference between mitochondrial nucleoid proteins and nuclear histones was revealed in their efficiency to protect mitochondrial DNA from the damaging effect of radiation and hydrogen peroxide. It is likely that the nucleoid proteins in the mitochondria shield mitochondrial DNA against the attack of reactive oxygen species, thus significantly decreasing the level of the oxidative damage to mitochondrial DNA.     

Effects of Fcj1-Mos1 and mitochondrial division on aggregation of mitochondrial DNA nucleoids and organelle morphology

Mitochondrial DNA (mtDNA) is packaged into DNA–protein complexes called nucleoids, which are distributed as many small foci in mitochondria. Nucleoids are crucial for the biogenesis and function of mtDNA. Here, using a yeast genetic screen for components that control nucleoid distribution and size, we identify Fcj1 and Mos1, two evolutionarily conserved mitochondrial proteins that maintain the connection between the cristae and boundary membranes. These two proteins are also important for establishing tubular morphology of mitochondria, as mitochondria lacking Fcj1 and Mos1 form lamellar sheets. We find that nucleoids aggregate, increase in size, and decrease in number in fcj1∆ and mos1∆ cells. In addition, Fcj1 form punctate structures and localized adjacent to nucleoids. Moreover, connecting mitochondria by deleting the DNM1 gene required for organelle division enhances aggregation of mtDNA nucleoids in fcj1∆ and mos1∆ cells, whereas single deletion of DNM1 does not affect nucleoids. Conversely, deleting F1Fo-ATP synthase dimerization factors generates concentric ring-like cristae, restores tubular mitochondrial morphology, and suppresses nucleoid aggregation in these mutants. Our findings suggest an unexpected role of Fcj1-Mos1 and organelle division in maintaining the distribution and size of mtDNA nucleoids.     

Mitochondrial nucleoid interacting proteins support mitochondrial protein synthesis

Mitochondrial ribosomes and translation factors co-purify with mitochondrial nucleoids of human cells, based on affinity protein purification of tagged mitochondrial DNA binding proteins. Among the most frequently identified proteins were ATAD3 and prohibitin, which have been identified previously as nucleoid components, using a variety of methods. Both proteins are demonstrated to be required for mitochondrial protein synthesis in human cultured cells, and the major binding partner of ATAD3 is the mitochondrial ribosome. Altered ATAD3 expression also perturbs mtDNA maintenance and replication. These findings suggest an intimate association between nucleoids and the machinery of protein synthesis in mitochondria. ATAD3 and prohibitin are tightly associated with the mitochondrial membranes and so we propose that they support nucleic acid complexes at the inner membrane of the mitochondrion.     

Visualizing,quantifying, and manipulating mitochondrial DNA in vivo

Mitochondrial DNA (mtDNA) encodes proteins and RNAs that support the functions of mitochondria and thereby numerous physiological processes. Mutations of mtDNA can cause mitochondrial diseases and are implicated in aging. The mtDNA within cells is organized into nucleoids within the mitochondrial matrix, but how mtDNA nucleoids are formed and regulated within cells remains incompletely resolved. Visualization of mtDNA within cells is a powerful means by which mechanistic insight can be gained. Manipulation of the amount and sequence of mtDNA within cells is important experimentally and for developing therapeutic interventions to treat mitochondrial disease. This review details recent developments and opportunities for improvements in the experimental tools and techniques that can be used to visualize, quantify, and manipulate the properties of mtDNA within cells.     

Superresolution fluorescence imaging of mitochondrial nucleoids reveals their spatial range, limits, and membrane interaction

A fundamental objective in molecular biology is to understand how DNA is organized in concert with various proteins, RNA, and biological membranes. Mitochondria maintain and express their own DNA (mtDNA), which is arranged within structures called nucleoids. Their functions, dimensions, composition, and precise locations relative to other mitochondrial structures are poorly defined. Superresolution fluorescence microscopy techniques that exceed the previous limits of imaging within the small and highly compartmentalized mitochondria have been recently developed. We have improved and employed both two- and three-dimensional applications of photoactivated localization microscopy (PALM and iPALM, respectively) to visualize the core dimensions and relative locations of mitochondrial nucleoids at an unprecedented resolution. PALM reveals that nucleoids differ greatly in size and shape. Three-dimensional volumetric analysis indicates that, on average, the mtDNA within ellipsoidal nucleoids is extraordinarily condensed. Two-color PALM shows that the freely diffusible mitochondrial matrix protein is largely excluded from the nucleoid. In contrast, nucleoids are closely associated with the inner membrane and often appear to be wrapped around cristae or crista-like inner membrane invaginations. Determinations revealing high packing density, separation from the matrix, and tight association with the inner membrane underscore the role of mechanisms that regulate access to mtDNA and that remain largely unknown.     

Effects of ethidium bromide and chloramphenicol on the mitochondrial nucleoids in Euglena gracilis

The effects of ethidium bromide (EB) at 0.13 m M and of chloramphenicol (CAP) at 46 m M on the mitochondria and mitochondrial nucleoids in Euglena gracilis . Z strain, were examined by fluorescence microscopy and by electron microscopy. Ethidium bromide stopped the multiplication of cells and decreased their respiratory activity by 55% after treatment for 10 days. Most of the mitochondria became slender with few cristae and some became cup-shaped with stacked cristac. Mitochondrial nucleoids decreased markedly in number after treatment with EB for more than 2 days. After treatment for 3 days with EB, mitochondrial nucleoids could not be detected in about half of all cells examined. Treatment with CAP for 10 days reduced the respiratory activity by 47%. Chloramphenicol did not decrease the number of mitochondrial nucleoids but it increased the number of cristae and the volume of mitochondria.     

Mdm31 and Mdm32 are inner membrane proteins required for maintenance of mitochondrial shape and stability of mitochondrial DNA nucleoids in yeast

The MDM31 and MDM32 genes are required for normal distribution and morphology of mitochondria in the yeast Saccharomyces cerevisiae. They encode two related proteins located in distinct protein complexes in the mitochondrial inner membrane. Cells lacking Mdm31 and Mdm32 harbor giant spherical mitochondria with highly aberrant internal structure. Mitochondrial DNA (mtDNA) is instable in the mutants, mtDNA nucleoids are disorganized, and their association with Mmm1-containing complexes in the outer membrane is abolished. Mutant mitochondria are largely immotile, resulting in a mitochondrial inheritance defect. Deletion of either one of the MDM31 and MDM32 genes is synthetically lethal with deletion of either one of the MMM1, MMM2, MDM10, and MDM12 genes, which encode outer membrane proteins involved in mitochondrial morphogenesis and mtDNA inheritance. We propose that Mdm31 and Mdm32 cooperate with Mmm1, Mmm2, Mdm10, and Mdm12 in maintenance of mitochondrial morphology and mtDNA.     

Human prohibitin 1 maintains the organization and stability of the mitochondrial nucleoids

Mitochondrial prohibitin (PHB) proteins have diverse functions, such as the regulation of apoptosis and the maintenance of mitochondrial morphology. In this study, we clarified a novel mitochondrial function of PHB1 that regulates the organization and maintenance of mitochondrial DNA (mtDNA). In PHB1-knockdown cells, we found that mtDNA is not stained by fluorescent dyes, such as ethidium bromide and PicoGreen, although the mitochondrial membrane potential still maintains. We also demonstrated that mtDNA, which is predominantly found in the NP-40-insoluble fraction when isolated from normal mitochondria, is partially released into the soluble fraction when isolated from PHB1-knockdown cells, indicating that the organization of the mitochondrial nucleoids has been altered. Furthermore, we found that PHB1 regulates copy number of mtDNA by stabilizing TFAM protein, a known protein component of the mitochondrial nucleoids. However, TFAM does not affect the organization of mtDNA as observed in PHB1-knockdown cells. Taken together, these results demonstrate that PHB1 maintains the organization and copy number of the mtDNA through both TFAM-independent and -dependent pathways.