Mitochondrial nucleoids maintain genetic autonomy but allow for functional complementation

Mitochondrial DNA (mtDNA) is packaged into DNA-protein assemblies called nucleoids, but the mode of mtDNA propagation via the nucleoid remains controversial. Two mechanisms have been proposed: nucleoids may consistently maintain their mtDNA content faithfully, or nucleoids may exchange mtDNAs dynamically. To test these models directly, two cell lines were fused, each homoplasmic for a partially deleted mtDNA in which the deletions were nonoverlapping and each deficient in mitochondrial protein synthesis, thus allowing the first unequivocal visualization of two mtDNAs at the nucleoid level. The two mtDNAs transcomplemented to restore mitochondrial protein synthesis but were consistently maintained in discrete nucleoids that did not intermix stably. These results indicate that mitochondrial nucleoids tightly regulate their genetic content rather than freely exchanging mtDNAs. This genetic autonomy provides a molecular mechanism to explain patterns of mitochondrial genetic inheritance, in addition to facilitating therapeutic methods to eliminate deleterious mtDNA mutations.     

Characterization of the structure and DNA complexity of mung bean mitochondrial nucleoids

Electron microscopic images of mitochondrial nucleoids isolated from mung bean seedlings revealed a relatively homogeneous population of particles, each consisting of a chromatin-like structure associated with a membrane component. Association of F-actin with mitochondrial nucleoids was also observed. The mitochondrial nucleoid structure identified in situ showed heterogeneous genomic organization. After pulsed-field gel electrophoresis (PFGE), a large proportion of the mitochondrial nucleoid DNA remained in the well, whereas the rest migrated as a 50–200 kb smear zone. This PFGE migration pattern was not affected by high salt, topoisomerase I or latrunculin B treatments; however, the mobility of a fraction of the fastmoving DNA decreased conspicuously following an in-gel ethidium-enhanced UV-irradiation treatment, suggesting that molecules with intricately compact structures were present in the 50-200 kb region. Approximately 70% of the mitochondrial nucleoid DNA molecules examined via electron microscopy were open circles, supercoils, complex forms, and linear molecules with interspersed sigma-shaped structures and/or loops. Increased sensitivity of mtDNA to DNase I was found after mitochondrial nucleoids were pretreated with high salt. This result indicates that some loosely bound or peripheral DNA binding proteins protected the mtDNA from DNase I degradation.     

The mitochondrial genome. The nucleoid

Mitochondrial DNA (mtDNA) in cells is organized in nucleoids containing DNA and various proteins. This review discusses questions of organization and structural dynamics of nucleoids as well as their protein components. The structures of mt-nucleoid from different organisms are compared. The currently accepted model of nucleoid organization is described and questions needing answers for better understanding of the fine mechanisms of the mitochondrial genetic apparatus functioning are discussed.     

Evidence for a two membrane-spanning autonomous mitochondrial DNA replisome

The unit of inheritance for mitochondrial DNA (mtDNA) is a complex nucleoprotein structure termed the nucleoid. The organization of the nucleoid as well as its role in mtDNA replication remain largely unknown. Here, we show in Saccharomyces cerevisiae that at least two populations of nucleoids exist within the same mitochondrion and can be distinguished by their association with a discrete proteinaceous structure that spans the outer and inner mitochondrial membranes. Surprisingly, this two membrane-spanning structure (TMS) persists and self-replicates in the absence of mtDNA. We tested whether TMS functions to direct the replication of mtDNA. By monitoring BrdU incorporation, we observed that actively replicating nucleoids are associated exclusively with TMS. Consistent with TMS's role in mtDNA replication, we found that Mip1, the mtDNA polymerase, is also a stable component of TMS. Taken together, our observations reveal the existence of an autonomous two membrane-spanning mitochondrial replisome as well as provide a mechanism for how mtDNA replication and inheritance may be physically linked.     

The numbers of individual mitochondrial DNA molecules and mitochondrial DNA nucleoids in yeast are co-regulated by the general amino acid control pathway

Mitochondrial DNA (mtDNA) is inherited as a protein-DNA complex (the nucleoid). We show that activation of the general amino acid response pathway in rho(+) and rho(-) petite cells results in an increased number of nucleoids without an increase in mtDNA copy number. In rho(-) cells, activation of the general amino acid response pathway results in increased intramolecular recombination between tandemly repeated sequences of rho(-) mtDNA to produce small, circular oligomers that are packaged into individual nucleoids, resulting in an approximately 10-fold increase in nucleoid number. The parsing of mtDNA into nucleoids due to general amino acid control requires Ilv5p, a mitochondrial protein that also functions in branched chain amino acid biosynthesis, and one or more factors required for mtDNA recombination. Two additional proteins known to function in mtDNA recombination, Abf2p and Mgt1p, are also required for parsing mtDNA into a larger number of nucleoids, although expression of these proteins is not under general amino acid control. Increased nucleoid number leads to increased mtDNA transmission, suggesting a mechanism to enhance mtDNA inheritance under amino acid starvation conditions.     

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.     

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.     

Whole Cell Formaldehyde Cross-Linking Simplifies Purification of Mitochondrial Nucleoids and Associated Proteins Involved in Mitochondrial Gene Expression

Mitochondrial DNA/protein complexes (nucleoids) appear as discrete entities inside the mitochondrial network when observed by live-cell imaging and immunofluorescence. This somewhat trivial observation in recent years has spurred research towards isolation of these complexes and the identification of nucleoid-associated proteins. Here we show that whole cell formaldehyde crosslinking combined with affinity purification and tandem mass-spectrometry provides a simple and reproducible method to identify potential nucleoid associated proteins. The method avoids spurious mitochondrial isolation and subsequent multifarious nucleoid enrichment protocols and can be implemented to allow for label-free quantification (LFQ) by mass-spectrometry. Using expression of a Flag-tagged Twinkle helicase and appropriate controls we show that this method identifies many previously identified nucleoid associated proteins. Using LFQ to compare HEK293 cells with and without mtDNA, but both expressing Twinkle-FLAG, identifies many proteins that are reduced or absent in the absence of mtDNA. This set not only includes established mtDNA maintenance proteins but also many proteins involved in mitochondrial RNA metabolism and translation and therefore represents what can be considered an mtDNA gene expression proteome. Our data provides a very valuable resource for both basic mitochondrial researchers as well as clinical geneticists working to identify novel disease genes on the basis of exome sequence data.     

Evolutionary tinkering with mitochondrial nucleoids

Mitochondrial DNA (mtDNA) is organized in nucleoprotein particles called nucleoids. Each nucleoid, which is considered a heritable unit of mtDNA, might contain several copies of the mitochondrial genome and several different proteins. Some nucleoid-associated proteins, such as the high mobility group (HMG) box family, have well defined functions in mtDNA maintenance and packaging; others, such as Aco1 and IIv5, are bifunctional, fulfilling their roles in nucleoids in addition to well established metabolic functions. The fact that the HMG box mtDNA packaging proteins are of eukaryotic rather than bacterial origin and also that every organism seems to have a unique set of nucleoid-associated proteins suggests that evolutionary tinkering occurred to reinvent mitochondrial nucleoprotein during the evolution of mitochondrial genomes.     

Mgm101p is a novel component of the mitochondrial nucleoid that binds DNA and is required for the repair of oxidatively damaged mitochondrial DNA

Maintenance of mitochondrial DNA (mtDNA) during cell division is required for progeny to be respiratory competent. Maintenance involves the replication, repair, assembly, segregation, and partitioning of the mitochondrial nucleoid. MGM101 has been identified as a gene essential for mtDNA maintenance in S. cerevisiae, but its role is unknown. Using liquid chromatography coupled with tandem mass spectrometry, we identified Mgm101p as a component of highly enriched nucleoids, suggesting that it plays a nucleoid-specific role in maintenance. Subcellular fractionation, indirect immunofluorescence and GFP tagging show that Mgm101p is exclusively associated with the mitochondrial nucleoid structure in cells. Furthermore, DNA affinity chromatography of nucleoid extracts indicates that Mgm101p binds to DNA, suggesting that its nucleoid localization is in part due to this activity. Phenotypic analysis of cells containing a temperature sensitive mgm101 allele suggests that Mgm101p is not involved in mtDNA packaging, segregation, partitioning or required for ongoing mtDNA replication. We examined Mgm101p's role in mtDNA repair. As compared with wild-type cells, mgm101 cells were more sensitive to mtDNA damage induced by UV irradiation and were hypersensitive to mtDNA damage induced by gamma rays and H2O2 treatment. Thus, we propose that Mgm101p performs an essential function in the repair of oxidatively damaged mtDNA that is required for the maintenance of the mitochondrial genome.     

Analysis of mitochondrial DNA nucleoids in wild-type and a mutant strain of Saccharomyces cerevisiae that lacks the mitochondrial HMG box protein Abf2p.

DNA-protein complexes (nucleoids) are believed to be the segregating unit of mitochondrial DNA (mtDNA) in Saccharomyces cerevisiae. A mitochondrial HMG box protein, Abf2p, is needed for maintenance of mtDNA in cells grown on rich dextrose medium, but is dispensible in glycerol grown cells. As visualized by 4',6'-diamino-2-phenylindole staining, mtDNA nucleoids in mutant cells lacking Abf2p ( delta abf2) are diffuse compared with those in wild-type cells. We have isolated mtDNA nucleoids and characterized two mtDNA-protein complexes, termed NCLDp-2 and NCLDs-2, containing distinct but overlapping sets of polypeptides. This protocol yields similar nucleoid complexes from the delta abf2 mutant, although several proteins appear lacking from NCLDs-2. Segments of mtDNA detected with probes to COXII, VAR1 and ori5 sequences are equally sensitive to DNase I digestion in NCLDs-2 and NCLDp-2 from wild-type cells and from the delta abf2 mutant. However, COXII and VAR1 sequences are 4-to 5-fold more sensitive to DNase I digestion of mtDNA in toluene-permeabilized mitochondria from the delta abf2 mutant than from wild-type cells, but no difference in DNase I sensitivity was detected with the ori5 probe. These results provide a first indication that Abf2p influences differential organization of mtDNA sequences.     

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

The high susceptibility of mitochondrial DNA to reactive oxygen species and other damaging agents has been supposed to result from the absence of histones. Here we show that DNA-binding proteins of mitochondrial nucleoids can shield mtDNA from X-ray radiation and hydrogen peroxide just as nuclear histones do. Mitochondria, mitochondrial nucleoid proteins, and histones were isolated from mouse liver and assessed for mtDNA protection by the yield of PCR products. In vitro, mtDNA in complex either with nucleoid proteins or with nuclear histones proved to be much less damaged than naked mtDNA, with little difference in protective efficacy. Most probably, in mitochondria the nucleoid proteins also protect mtDNA against reactive oxygen species and thus attenuate the oxidative damage.     

线粒体拟核结构及相关疾病研究进展

线粒体DNA(mitochondrial DNA,mtDNA)与一系列蛋白质相互作用形成核蛋白复合体,并包装折叠成类似原核生物拟核的结构,称为线粒体拟核(mitochondrial nucleoid)。参与线粒体拟核组成的相关蛋白包括线粒体转录因子、线粒体单链DNA结合蛋白以及多种参与线粒体中代谢途径的多功能蛋白。线粒体拟核结构的阐明对于进一步研究线粒体形态与功能以及mtDNA的遗传模式、基因表达调控具有重要意义。本文综述了线粒体拟核结构的最新研究进展,着重介绍组成拟核结构的重要蛋白,以及这些蛋白如何将mtDNA与柠檬酸循环等线粒体重要代谢途径相联系。同时,拟核相关蛋白(nucleoid-associated protein)的异常涉及多种人类疾病,这为研究线粒体相关疾病提供了新的思路。