A chemical enucleation method for the transfer of mitochondrial DNA to ro cells (original) (raw)
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A chemical enucleation method for the transfer of mitochondrial DNA to cells
Nucleic Acids Research, 2003
The study of pathogenic mitochondrial DNA mutations has, in most cases, relied on the production of transmitochondrial cybrids. Although the procedure to produce such cybrids is well established, it is laborious and cumbersome. Moreover, the mechanical enucleation procedure is inef®cient and different techniques have to be used depending on the adherence properties of the cell. To circumvent these dif®culties, we developed a chemical enucleation method that can have wide applicability for the production of transmitochondrial cybrids. The method is based on the use of actinomycin D to render the nuclear genome transcription/replication inactive and unable to recover after treatment. Such treated cells are fused to cells devoid of mitochondrial DNA and selected for the presence of a functional oxidative phosphorylation system. Our results showed that 95% of the clones recovered by this procedure are true transmitochondrial cybrids. This method greatly facilitates the production of transmitochondrial cybrids, thereby increasing the number of mtDNA mutations and the recipient cell types that can be studied by this system.
Production of transmitochondrial cybrids containing naturally occurring pathogenic mtDNA variants
Nucleic Acids Research, 2006
The human mitochondrial genome (mtDNA) encodes polypeptides that are critical for coupling oxidative phosphorylation. Our detailed understanding of the molecular processes that mediate mitochondrial gene expression and the structurefunction relationships of the OXPHOS components could be greatly improved if we were able to transfect mitochondria and manipulate mtDNA in vivo. Increasing our knowledge of this process is not merely of fundamental importance, as mutations of the mitochondrial genome are known to cause a spectrum of clinical disorders and have been implicated in more common neurodegenerative disease and the ageing process. In organellar or in vitro reconstitution studies have identified many factors central to the mechanisms of mitochondrial gene expression, but being able to investigate the molecular aetiology of a limited number of cell lines from patients harbouring mutated mtDNA has been enormously beneficial. In the absence of a mechanism for manipulating mtDNA, a much larger pool of pathogenic mtDNA mutations would increase our knowledge of mitochondrial gene expression. Colonic crypts from ageing individuals harbour mutated mtDNA. Here we show that by generating cytoplasts from colonocytes, standard fusion techniques can be used to transfer mtDNA into rapidly dividing immortalized cells and, thereby, respiratory-deficient transmitochondrial cybrids can be isolated. A simple screen identified clones that carried putative pathogenic mutations in MTRNR1, MTRNR2, MTCOI and MTND2, MTND4 and MTND6. This method can therefore be exploited to produce a library of cell lines carrying pathogenic human mtDNA for further study.
Methods for Efficient Elimination of Mitochondrial DNA from Cultured Cells
PloS one, 2016
Here, we document that persistent mitochondria DNA (mtDNA) damage due to mitochondrial overexpression of the Y147A mutant uracil-N-glycosylase as well as mitochondrial overexpression of bacterial Exonuclease III or Herpes Simplex Virus protein UL12.5M185 can induce a complete loss of mtDNA (ρ0 phenotype) without compromising the viability of cells cultured in media supplemented with uridine and pyruvate. Furthermore, we use these observations to develop rapid, sequence-independent methods for the elimination of mtDNA, and demonstrate utility of these methods for generating ρ0 cells of human, mouse and rat origin. We also demonstrate that ρ0 cells generated by each of these three methods can serve as recipients of mtDNA in fusions with enucleated cells.
Elimination of Mitochondrial DNA from Mammalian Cells
Current protocols in cell biology, 2018
To cope with DNA damage, mitochondria developed a pathway by which severely damaged or unrepairable mtDNA molecules are abandoned and degraded, and new molecules are resynthesized using intact templates, if available. In this unit, we describe a method that harnesses this pathway to completely eliminate mtDNA from mammalian cells by transiently overexpressing the Y147A mutant of human uracil-N-glycosylase (mUNG1). We also provide an alternate protocol for mtDNA depletion using combined treatment with ethidium bromide (EtBr) and dideoxycytidine (ddC). Support protocols detail approaches for 1) genotyping ρ 0 cells of human, mouse and rat origin by PCR; 2) quantitation of mtDNA by qPCR; and 3) preparation of calibrator plasmids for mtDNA quantitation.
Somatic Cell and Molecular Genetics, 1996
LMTK cells with the toxic mitochondrial dye rhodamine 6G (R-6G) at 2.5 I~g/nzljbr 7 days prevented cell g~owth while maintaining viabili~, with less than 10-6 cells recovering to form cvlonies. Pre-treatment of LMTK-cells with R-6G was followed by fusion with enucleated mouse 501-,.1 cells harbonng a hom~>ptasmic point mutation in the mitochondrial DNA (mtDNA) 16S rRNA gene ,::onfi~rring chloramphenicot resistance (CAPa). Cybrids and any surviving unfused LMTK cells" wets' selected in BrdU with or without CAP and their mtDNAs screened for the p~z~sence ~:~f the CAP ~ market: Aptnz)ximatety l colony per 2 • 10 5 LMTK-cells appeared b~ the,[hsion plates selecwd both with and without CAP. Most clones investigated were confirmed to be cybrids t~y showing the presence of the generally homoplasmic CAP R mutation, whether or not C)tP selection was used. Hence, R-6G pre-treatment permits" construction of transmitochondrial cybrid cell lines carrying a variety of mtDNAs, without the need for po cell lines.
Molecular biology of the cell, 2000
Large-scale rearrangements of mitochondrial DNA (mtDNA; i.e., partial duplications [dup-mtDNAs] and deletions [Delta-mtDNAs]) coexist in tissues in a subset of patients with sporadic mitochondrial disorders. In order to study the dynamic relationship among rearranged and wild-type mtDNA (wt-mtDNA) species, we created transmitochondrial cell lines harboring various proportions of wt-, Delta-, and dup-mtDNAs from two patients. After prolonged culture in nonselective media, cells that contained initially 100% dup-mtDNAs became heteroplasmic, containing both wild-type and rearranged mtDNAs, likely generated via intramolecular recombination events. However, in cells that contained initially a mixture of both wt- and Delta-mtDNAs, we did not observe any dup-mtDNAs or other new forms of rearranged mtDNAs, perhaps because the two species were physically separated and were therefore unable to recombine. The ratio of wt-mtDNA to Delta-mtDNAs remained stable in all cells examined, suggesting t...
Mitochondrial DNA Replacement Techniques to Prevent Human Mitochondrial Diseases
International Journal of Molecular Sciences, 2021
Background: Mitochondrial DNA (mtDNA) diseases are a group of maternally inherited genetic disorders caused by a lack of energy production. Currently, mtDNA diseases have a poor prognosis and no known cure. The chance to have unaffected offspring with a genetic link is important for the affected families, and mitochondrial replacement techniques (MRTs) allow them to do so. MRTs consist of transferring the nuclear DNA from an oocyte with pathogenic mtDNA to an enucleated donor oocyte without pathogenic mtDNA. This paper aims to determine the efficacy, associated risks, and main ethical and legal issues related to MRTs. Methods: A bibliographic review was performed on the MEDLINE and Web of Science databases, along with searches for related clinical trials and news. Results: A total of 48 publications were included for review. Five MRT procedures were identified and their efficacy was compared. Three main risks associated with MRTs were discussed, and the ethical views and legal posit...
The maintenance of mitochondrial DNA integrity--critical analysis and update
Cold Spring Harbor perspectives in biology, 2013
DNA molecules in mitochondria, just like those in the nucleus of eukaryotic cells, are constantly damaged by noxious agents. Eukaryotic cells have developed efficient mechanisms to deal with this assault. The process of DNA repair in mitochondria, initially believed nonexistent, has now evolved into a mature area of research. In recent years, it has become increasingly appreciated that mitochondria possess many of the same DNA repair pathways that the nucleus does. Moreover, a unique pathway that is enabled by high redundancy of the mitochondrial DNA and allows for the disposal of damaged DNA molecules operates in this organelle. In this review, we attempt to present a unified view of our current understanding of the process of DNA repair in mitochondria with an emphasis on issues that appear controversial.
Progress and prospects: gene therapy for mitochondrial DNA disease
Gene Therapy, 2008
Defects of the mitochondrial genome cause a wide variety of clinical disorders. Except for rare cases where surgery or transplant is indicated, there is no effective treatment for patients. Genetic-based therapies are consequently being considered. On account of the difficulties associated with mitochondrial (mt) transfection, alternative approaches whereby mitochondrial genes can be engineered and introduced into the nucleus (allotopic expression) are being attempted with some success, at least in cultured cells. Defects in the activities of multi-subunit complexes of the oxidative phosphorylation apparatus have been circumvented by the targeted expression of simple single subunit enzymes from other species (xenotopic expression). Although far from the clinic, these approaches show promise. Similarly, nuclear transfection with genes encoding restriction endonucleases or sequence-specific zinc finger-binding proteins destined for mitochondria has also proved successful in targeting mtDNA-borne pathogenic mutations. This is particularly important, as mutated mtDNA is often found in cells that also contain normal copies of the genome, a situation termed heteroplasmy. Shifting the levels of heteroplasmy towards the normal mtDNA has become the goal of a variety of invasive and non-invasive methods, which are also highlighted in this review.