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E, Dmgm1 and OXPHOS-deficient cells. Dashed line: proportion of fusion in wild-type cells. doi:10.1371/journal.pone.0049639.gDiscussionIn this work, we demonstrate that MedChemExpress SIS3 Mitochondrial fusion is inhibited in cells with genetic OXPHOS defects. Fusion inhibition is not complete, as in cells MedChemExpress Docosahexaenoyl ethanolamide lacking core components of the fusion machinery, but partial. Interestingly, the fusion defect was similar in cells with a single pathogenic point mutation in ATP6 and in cells lacking mitochondrial genes or the entire mtDNA. Remarkably, fusion inhibition was observed under fermentative conditions, when glycolysis provides ATP for mitochondrial biogenesisMitochondrial DNA Mutations Mitochondrial FusionFigure 4. OXPHOS defects inhibit fusion with wild-type mitochondria in trans. Wild-type and mutant cells expressing matrix-targeted mtGFP or mtRFP were conjugated and mitochondrial fusion was analyzed by fluorescence microscopy after the indicated times (A, B) or after 4 hours (C). A: Kinetics of Total (T), Partial (P) and No fusion (N). B, C: Comparison of total fusion as a function of time (B) or of Total, Partial and No fusion after 4 hours (C). Dashed line: proportion of fusion in wild-type cells. doi:10.1371/journal.pone.0049639.gMitochondrial DNA Mutations Mitochondrial FusionFigure 5. Outer membrane fusion is not affected by OXPHOS defects. Wild-type and mutant cells expressing fluorescent proteins targeted to the outer membrane (GFPOM, RFPOM) were conjugated and mitochondrial outer membrane fusion was analyzed by fluorescence microscopy after the indicated times (A, B) or after 4 hours (C). A: Kinetics of Total (T), Partial (P) and No fusion (N). B, C: Comparison of total fusion as a function of time (B) or of Total, Partial and No fusion after 4 hours (C). The dashed line indicates the proportion in wild-type cells. Dashed line: proportion of total fusion in wild-type cells. doi:10.1371/journal.pone.0049639.gFigure 6. Pattern of Mgm1-isoforms in yeast cells with different OXPHOS defects. Yeast cells of the indicated genotypes were maintained for 6 hours in glucose-containing medium (A, B) or galactose-containing medium (C). In A, cells were treated, or not, with valinomycin (VM). Cells were then analyzed by Western-blot with Mgm1-antibodies and the relative amounts of l-Mgm1 and s-Mgm1 quantified by densitometry. doi:10.1371/journal.pone.0049639.gand growth. The dominant inhibition of fusion in heterogenic crosses demonstrated that the fusion defects of OXPHOS deficient mitochondria cannot be compensated, in trans, by functional mitochondria.Fusion assays with fluorescently labeled outer membranes demonstrated that OXPHOS defects selectively inhibit inner membrane fusion. Electron microscopy revealed that fusion inhibition was associated to the presence of elongated, 1527786 unfused inner membranes that were connected to boundary membranes. These ultrastructural features are reminiscent of those observed upon inhibition of inner membrane fusion with ionophores (this work and [14]) or in Mgm1-mutant strains [15,33]. The selective inhibition of inner membrane fusion in OXPHOS-deficient cells confirms that outer and inner membrane fusions are catalyzed by machineries that can function separately and have differentMitochondrial DNA Mutations Mitochondrial FusionTable 3. Frequency of inner membrane septae* in yeast mitochondria.Strains wild-type Datpnumber of observed mitochondria 50 49 33 32 57 11number of observed inner membrane septae* 0 37 38 1 31 3#.E, Dmgm1 and OXPHOS-deficient cells. Dashed line: proportion of fusion in wild-type cells. doi:10.1371/journal.pone.0049639.gDiscussionIn this work, we demonstrate that mitochondrial fusion is inhibited in cells with genetic OXPHOS defects. Fusion inhibition is not complete, as in cells lacking core components of the fusion machinery, but partial. Interestingly, the fusion defect was similar in cells with a single pathogenic point mutation in ATP6 and in cells lacking mitochondrial genes or the entire mtDNA. Remarkably, fusion inhibition was observed under fermentative conditions, when glycolysis provides ATP for mitochondrial biogenesisMitochondrial DNA Mutations Mitochondrial FusionFigure 4. OXPHOS defects inhibit fusion with wild-type mitochondria in trans. Wild-type and mutant cells expressing matrix-targeted mtGFP or mtRFP were conjugated and mitochondrial fusion was analyzed by fluorescence microscopy after the indicated times (A, B) or after 4 hours (C). A: Kinetics of Total (T), Partial (P) and No fusion (N). B, C: Comparison of total fusion as a function of time (B) or of Total, Partial and No fusion after 4 hours (C). Dashed line: proportion of fusion in wild-type cells. doi:10.1371/journal.pone.0049639.gMitochondrial DNA Mutations Mitochondrial FusionFigure 5. Outer membrane fusion is not affected by OXPHOS defects. Wild-type and mutant cells expressing fluorescent proteins targeted to the outer membrane (GFPOM, RFPOM) were conjugated and mitochondrial outer membrane fusion was analyzed by fluorescence microscopy after the indicated times (A, B) or after 4 hours (C). A: Kinetics of Total (T), Partial (P) and No fusion (N). B, C: Comparison of total fusion as a function of time (B) or of Total, Partial and No fusion after 4 hours (C). The dashed line indicates the proportion in wild-type cells. Dashed line: proportion of total fusion in wild-type cells. doi:10.1371/journal.pone.0049639.gFigure 6. Pattern of Mgm1-isoforms in yeast cells with different OXPHOS defects. Yeast cells of the indicated genotypes were maintained for 6 hours in glucose-containing medium (A, B) or galactose-containing medium (C). In A, cells were treated, or not, with valinomycin (VM). Cells were then analyzed by Western-blot with Mgm1-antibodies and the relative amounts of l-Mgm1 and s-Mgm1 quantified by densitometry. doi:10.1371/journal.pone.0049639.gand growth. The dominant inhibition of fusion in heterogenic crosses demonstrated that the fusion defects of OXPHOS deficient mitochondria cannot be compensated, in trans, by functional mitochondria.Fusion assays with fluorescently labeled outer membranes demonstrated that OXPHOS defects selectively inhibit inner membrane fusion. Electron microscopy revealed that fusion inhibition was associated to the presence of elongated, 1527786 unfused inner membranes that were connected to boundary membranes. These ultrastructural features are reminiscent of those observed upon inhibition of inner membrane fusion with ionophores (this work and [14]) or in Mgm1-mutant strains [15,33]. The selective inhibition of inner membrane fusion in OXPHOS-deficient cells confirms that outer and inner membrane fusions are catalyzed by machineries that can function separately and have differentMitochondrial DNA Mutations Mitochondrial FusionTable 3. Frequency of inner membrane septae* in yeast mitochondria.Strains wild-type Datpnumber of observed mitochondria 50 49 33 32 57 11number of observed inner membrane septae* 0 37 38 1 31 3#.

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