Cytoplasmically determined human cell mutants defective in mitochondrial ribosome assembly

Complementation of mutant and wild-type human mitochondrial DNAs coexisting since the mutation event and lack of complementation of DNAs introduced separately into a cell within distinct organelles

The rules that govern complementation of mutant and wild-type mitochondrial genomes in human cells were investigated under different experimental conditions. Among mitochondrial transformants derived from an individual affected by the MERRF (myoclonus epilepsy associated with ragged red fibers) encephalomyopathy and carrying in heteroplasmic form the mitochondrial tRNA(Lys) mutation associated with that syndrome, normal protein synthesis and respiration was observed when the wild-type mitochondrial DNA exceeded 10% of the total complement. In these transformants, the protective effect of wild-type mitochondrial DNA was shown to involve interactions of the mutant and wild-type gene products. Very different results were obtained in experiments in which two mitochondrial DNAs carrying nonallelic disease-causing mutations were sequentially introduced within distinct organelles into the same human mitochondrial DNA-less (rho 0) cell. In transformants exhibiting different ratios of the two genomes, no evidence of cooperation between their products was observed, even 3 months after the introduction of the second mutation. These results pointed to the phenotypic independence of the two genomes. A similar conclusion was reached in experiments in which mitochondria carrying a chloramphenicol resistance-inducing mitochondrial DNA mutation were introduced into chloramphenicol-sensitive cells. A plausible interpretation of the different results obtained in the latter two sets of experiments, compared with the complementation behavior observed in the heteroplasmic MERRF transformants, is that in the latter, the mutant and wild-type genomes coexisted in the same organelles from the time of the mutation. This would imply that the way in which mitochondrial DNA is sorted among different organelles plays a fundamental role in determining the oxidative-phosphorylation phenotype in mammalian cells. These results have significant implications for mitochondrial genetics and for studies on the transmission and therapy of mitochondrial DNA-linked diseases.

Complementation of mutant and wild-type human mitochondrial DNAs coexisting since the mutation event and lack of complementation of DNAs introduced separately into a cell within distinct organelles

The rules that govern complementation of mutant and wild-type mitochondrial genomes in human cells were investigated under different experimental conditions. Among mitochondrial transformants derived from an individual affected by the MERRF (myoclonus epilepsy associated with ragged red fibers) encephalomyopathy and carrying in heteroplasmic form the mitochondrial tRNA(Lys) mutation associated with that syndrome, normal protein synthesis and respiration was observed when the wild-type mitochondrial DNA exceeded 10% of the total complement. In these transformants, the protective effect of wild-type mitochondrial DNA was shown to involve interactions of the mutant and wild-type gene products. Very different results were obtained in experiments in which two mitochondrial DNAs carrying nonallelic disease-causing mutations were sequentially introduced within distinct organelles into the same human mitochondrial DNA-less (rho 0) cell. In transformants exhibiting different ratios of the two genomes, no evidence of cooperation between their products was observed, even 3 months after the introduction of the second mutation. These results pointed to the phenotypic independence of the two genomes. A similar conclusion was reached in experiments in which mitochondria carrying a chloramphenicol resistance-inducing mitochondrial DNA mutation were introduced into chloramphenicol-sensitive cells. A plausible interpretation of the different results obtained in the latter two sets of experiments, compared with the complementation behavior observed in the heteroplasmic MERRF transformants, is that in the latter, the mutant and wild-type genomes coexisted in the same organelles from the time of the mutation. This would imply that the way in which mitochondrial DNA is sorted among different organelles plays a fundamental role in determining the oxidative-phosphorylation phenotype in mammalian cells. These results have significant implications for mitochondrial genetics and for studies on the transmission and therapy of mitochondrial DNA-linked diseases.

In vitro genetic transfer of protein synthesis and respiration defects to mitochondrial DNA-less cells with myopathy-patient mitochondria

A severe mitochondrial protein synthesis defect in myoblasts from a patient with mitochondrial myopathy was transferred with myoblast mitochondria into two genetically unrelated mitochondrial DNA (mtDNA)-less human cell lines, pointing to an mtDNA alteration as being responsible and sufficient for causing the disease. The transfer of the defect correlated with marked deficiencies in respiration and cytochrome c oxidase activity of the transformants and the presence in their mitochondria of mtDNA carrying a tRNA(Lys) mutation. Furthermore, apparently complete segregation of the defective genotype and phenotype was observed in the transformants derived from the heterogeneous proband myoblast population, suggesting that the mtDNA heteroplasmy in this population was to a large extent intercellular. The present work thus establishes a direct link between mtDNA alteration and a biochemical defect.

In vitro genetic transfer of protein synthesis and respiration defects to mitochondrial DNA-less cells with myopathy-patient mitochondria

A severe mitochondrial protein synthesis defect in myoblasts from a patient with mitochondrial myopathy was transferred with myoblast mitochondria into two genetically unrelated mitochondrial DNA (mtDNA)-less human cell lines, pointing to an mtDNA alteration as being responsible and sufficient for causing the disease. The transfer of the defect correlated with marked deficiencies in respiration and cytochrome c oxidase activity of the transformants and the presence in their mitochondria of mtDNA carrying a tRNA(Lys) mutation. Furthermore, apparently complete segregation of the defective genotype and phenotype was observed in the transformants derived from the heterogeneous proband myoblast population, suggesting that the mtDNA heteroplasmy in this population was to a large extent intercellular. The present work thus establishes a direct link between mtDNA alteration and a biochemical defect.

Human cells lacking mtDNA: repopulation with exogenous mitochondria by complementation

Two human cell lines (termed rho 0), which had been completely depleted of mitochondrial DNA (mtDNA) by long-term exposure to ethidium bromide, were found to be dependent on uridine and pyruvate for growth because of the absence of a functional respiratory chain. Loss of either of these two metabolic requirements was used as a selectable marker for the repopulation of rho 0 cells with exogenous mitochondria by complementation. Transformants obtained with various mitochondrial donors exhibited a respiratory phenotype that was in most cases distinct from that of the rho 0 parent or the donor, indicating that the genotypes of the mitochondrial and nuclear genomes as well as their specific interactions play a role in the respiratory competence of a cell.

Human cell variants resistant to methylglyoxal-bis(guanylhydrazone) display increased sensitivity to chloramphenicol

Four variants of the cultured human cell line VA2 have been isolated which are resistant to the antiproliferative and antimitochondrial effects of methylglyoxal-bis(guanylhydrazone) (MGBG). Each of the four variants is two- to fivefold more sensitive to the mitochondrial protein synthesis inhibitor chloramphenicol (CAP) than wild type when grown in the absence of MGBG, and five- to tenfold more sensitive to CAP when grown in the presence of MGBG. Uptake studies demonstrate that each MGBG-resistant variant cell line is freely permeable to CAP. The in vivo rates of mitochondrial protein synthesis are significantly reduced in each of the variants whether pregrown and labeled in the presence or absence of MGBG. When cytoplasts from a cytoplasmically inherited CAP-resistant mutant are fused to an MGBG-resistant recipient cell line, cybrid clones can be isolated which are functionally resistant to low levels of CAP. With continued growth, the levels of resistance to CAP do not, however, approach the levels of resistance of the CAP-resistant donor cell line. When CAP resistance is subsequently transferred from a CAP/MGBG-resistant cybrid by enucleation and fusion to other human cell lines, then CAP-resistant cybrids can be readily selected in high levels of CAP. It is possible that the substantial decrease in mitochondrial protein synthesis observed in the variants fully accounts for their increased sensitivity to CAP, although the basis for this decreased rate of mitochondrial protein synthesis is not understood.