Your search keyword '"Rapaport, Doron"' showing total 24 results

1. Human Dopaminergic Neurons Lacking PINK1 Exhibit Disrupted Dopamine Metabolism Related to Vitamin B6 Co-Factors.

Author

Bus, Christine, Zizmare, Laimdota, Feldkaemper, Marita, Geisler, Sven, Zarani, Maria, Schaedler, Anna, Klose, Franziska, Admard, Jakob, Mageean, Craig J., Arena, Giuseppe, Fallier-Becker, Petra, Ugun-Klusek, Aslihan, Maruszczak, Klaudia K., Kapolou, Konstantina, Schmid, Benjamin, Rapaport, Doron, Ueffing, Marius, Casadei, Nicolas, Krüger, Rejko, Gasser, Thomas, Vogt Weisenhorn, Daniela M., Kahle, Philipp J., Trautwein, Christoph, Gloeckner, Christian J., Fitzgerald, Julia C., Bus, Christine, Zizmare, Laimdota, Feldkaemper, Marita, Geisler, Sven, Zarani, Maria, Schaedler, Anna, Klose, Franziska, Admard, Jakob, Mageean, Craig J., Arena, Giuseppe, Fallier-Becker, Petra, Ugun-Klusek, Aslihan, Maruszczak, Klaudia K., Kapolou, Konstantina, Schmid, Benjamin, Rapaport, Doron, Ueffing, Marius, Casadei, Nicolas, Krüger, Rejko, Gasser, Thomas, Vogt Weisenhorn, Daniela M., Kahle, Philipp J., Trautwein, Christoph, Gloeckner, Christian J., and Fitzgerald, Julia C.

Abstract

PINK1 loss-of-function mutations cause early onset Parkinson disease. PINK1-Parkin mediated mitophagy has been well studied, but the relevance of the endogenous process in the brain is debated. Here, the absence of PINK1 in human dopaminergic neurons inhibits ionophore-induced mitophagy and reduces mitochondrial membrane potential. Compensatory, mitochondrial renewal maintains mitochondrial morphology and protects the respiratory chain. This is paralleled by metabolic changes, including inhibition of the TCA cycle enzyme mAconitase, accumulation of NAD(+), and metabolite depletion. Loss of PINK1 disrupts dopamine metabolism by critically affecting its synthesis and uptake. The mechanism involves steering of key amino acids toward energy production rather than neurotransmitter metabolism and involves cofactors related to the vitamin B6 salvage pathway identified using unbiased multi-omics approaches. We propose that reduction of mitochondrial membrane potential that cannot be controlled by PINK1 signaling initiates metabolic compensation that has neurometabolic consequences relevant to Parkinson disease.

Published

2020

2. Human Dopaminergic Neurons Lacking PINK1 Exhibit Disrupted Dopamine Metabolism Related to Vitamin B6 Co-Factors.

Author

Bus, Christine, Zizmare, Laimdota, Feldkaemper, Marita, Geisler, Sven, Zarani, Maria, Schaedler, Anna, Klose, Franziska, Admard, Jakob, Mageean, Craig J., Arena, Giuseppe, Fallier-Becker, Petra, Ugun-Klusek, Aslihan, Maruszczak, Klaudia K., Kapolou, Konstantina, Schmid, Benjamin, Rapaport, Doron, Ueffing, Marius, Casadei, Nicolas, Krüger, Rejko, Gasser, Thomas, Vogt Weisenhorn, Daniela M., Kahle, Philipp J., Trautwein, Christoph, Gloeckner, Christian J., Fitzgerald, Julia C., Bus, Christine, Zizmare, Laimdota, Feldkaemper, Marita, Geisler, Sven, Zarani, Maria, Schaedler, Anna, Klose, Franziska, Admard, Jakob, Mageean, Craig J., Arena, Giuseppe, Fallier-Becker, Petra, Ugun-Klusek, Aslihan, Maruszczak, Klaudia K., Kapolou, Konstantina, Schmid, Benjamin, Rapaport, Doron, Ueffing, Marius, Casadei, Nicolas, Krüger, Rejko, Gasser, Thomas, Vogt Weisenhorn, Daniela M., Kahle, Philipp J., Trautwein, Christoph, Gloeckner, Christian J., and Fitzgerald, Julia C.

Abstract

PINK1 loss-of-function mutations cause early onset Parkinson disease. PINK1-Parkin mediated mitophagy has been well studied, but the relevance of the endogenous process in the brain is debated. Here, the absence of PINK1 in human dopaminergic neurons inhibits ionophore-induced mitophagy and reduces mitochondrial membrane potential. Compensatory, mitochondrial renewal maintains mitochondrial morphology and protects the respiratory chain. This is paralleled by metabolic changes, including inhibition of the TCA cycle enzyme mAconitase, accumulation of NAD(+), and metabolite depletion. Loss of PINK1 disrupts dopamine metabolism by critically affecting its synthesis and uptake. The mechanism involves steering of key amino acids toward energy production rather than neurotransmitter metabolism and involves cofactors related to the vitamin B6 salvage pathway identified using unbiased multi-omics approaches. We propose that reduction of mitochondrial membrane potential that cannot be controlled by PINK1 signaling initiates metabolic compensation that has neurometabolic consequences relevant to Parkinson disease.

Published

2020

3. Structural basis of client specificity in mitochondrial membrane-protein chaperones

Author

Sučec, Iva, Wang, Yong, Dakhlaoui, Ons, Weinhäupl, Katharina, Jores, Tobias, Costa, Doriane, Hessel, Audrey, Brennich, Martha, Rapaport, Doron, Lindorff-Larsen, Kresten, Bersch, Beate, Schanda, Paul, Sučec, Iva, Wang, Yong, Dakhlaoui, Ons, Weinhäupl, Katharina, Jores, Tobias, Costa, Doriane, Hessel, Audrey, Brennich, Martha, Rapaport, Doron, Lindorff-Larsen, Kresten, Bersch, Beate, and Schanda, Paul

Abstract

Chaperones are essential for assisting protein folding and for transferring poorly soluble proteins to their functional locations within cells. Hydrophobic interactions drive promiscuous chaperone-client binding, but our understanding of how additional interactions enable client specificity is sparse. Here, we decipher what determines binding of two chaperones (TIM8 center dot 13 and TIM9 center dot 10) to different integral membrane proteins, the all-transmembrane mitochondrial carrier Ggc1 and Tim23, which has an additional disordered hydrophilic domain. Combining NMR, SAXS, and molecular dynamics simulations, we determine the structures of Tim23/TIM8 center dot 13 and Tim23/TIM9 center dot 10 complexes. TIM8 center dot 13 uses transient salt bridges to interact with the hydrophilic part of its client, but its interactions to the transmembrane part are weaker than in TIM9 center dot 10. Consequently, TIM9 center dot 10 outcompetes TIM8 center dot 13 in binding hydrophobic clients, while TIM8 center dot 13 is tuned to few clients with both hydrophilic and hydrophobic parts. Our study exemplifies how chaperones fine-tune the balance of promiscuity versus specificity.

Published

2020

4. Structural basis of client specificity in mitochondrial membrane-protein chaperones

Author

Sučec, Iva, Wang, Yong, Dakhlaoui, Ons, Weinhäupl, Katharina, Jores, Tobias, Costa, Doriane, Hessel, Audrey, Brennich, Martha, Rapaport, Doron, Lindorff-Larsen, Kresten, Bersch, Beate, Schanda, Paul, Sučec, Iva, Wang, Yong, Dakhlaoui, Ons, Weinhäupl, Katharina, Jores, Tobias, Costa, Doriane, Hessel, Audrey, Brennich, Martha, Rapaport, Doron, Lindorff-Larsen, Kresten, Bersch, Beate, and Schanda, Paul

Abstract

Chaperones are essential for assisting protein folding and for transferring poorly soluble proteins to their functional locations within cells. Hydrophobic interactions drive promiscuous chaperone-client binding, but our understanding of how additional interactions enable client specificity is sparse. Here, we decipher what determines binding of two chaperones (TIM8 center dot 13 and TIM9 center dot 10) to different integral membrane proteins, the all-transmembrane mitochondrial carrier Ggc1 and Tim23, which has an additional disordered hydrophilic domain. Combining NMR, SAXS, and molecular dynamics simulations, we determine the structures of Tim23/TIM8 center dot 13 and Tim23/TIM9 center dot 10 complexes. TIM8 center dot 13 uses transient salt bridges to interact with the hydrophilic part of its client, but its interactions to the transmembrane part are weaker than in TIM9 center dot 10. Consequently, TIM9 center dot 10 outcompetes TIM8 center dot 13 in binding hydrophobic clients, while TIM8 center dot 13 is tuned to few clients with both hydrophilic and hydrophobic parts. Our study exemplifies how chaperones fine-tune the balance of promiscuity versus specificity.

Published

2020

5. Mutations in RHOT1 disrupt ER-mitochondria contact sites interfering with calcium homeostasis and mitochondrial dynamics in Parkinson's disease.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, Krüger, Rejko, Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, and Krüger, Rejko

Abstract

OBJECTIVE: The outer mitochondrial membrane protein Miro1 is a crucial player in mitochondrial dynamics and calcium homeostasis. Recent evidence indicated that Miro1 mediates calcium-induced mitochondrial shape transition (MiST), which is a prerequisite for the initiation of mitophagy. Moreover, altered Miro1 protein levels have emerged as a shared feature of monogenic and sporadic Parkinson's disease (PD), but, so far, no disease-associated variants in RHOT1 have been identified. RESULTS: Here, for the first time, we describe heterozygous RHOT1 mutations in two PD patients (het c.815G>A; het c.1348C>T) and identified mitochondrial phenotypes with reduced mitochondrial mass in patient-derived cellular models. Both mutations lead to decreased ER-mitochondrial contact sites and calcium dyshomeostasis. As a consequence, energy metabolism was impaired, which in turn lead to increased mitophagy. CONCLUSION: In summary, our data support the role of Miro1 in maintaining calcium homeostasis and mitochondrial quality control in PD.

Published

2019

6. Mutations in RHOT1 disrupt ER-mitochondria contact sites interfering with calcium homeostasis and mitochondrial dynamics in Parkinson's disease.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, Krüger, Rejko, Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, and Krüger, Rejko

Abstract

OBJECTIVE: The outer mitochondrial membrane protein Miro1 is a crucial player in mitochondrial dynamics and calcium homeostasis. Recent evidence indicated that Miro1 mediates calcium-induced mitochondrial shape transition (MiST), which is a prerequisite for the initiation of mitophagy. Moreover, altered Miro1 protein levels have emerged as a shared feature of monogenic and sporadic Parkinson's disease (PD), but, so far, no disease-associated variants in RHOT1 have been identified. RESULTS: Here, for the first time, we describe heterozygous RHOT1 mutations in two PD patients (het c.815G>A; het c.1348C>T) and identified mitochondrial phenotypes with reduced mitochondrial mass in patient-derived cellular models. Both mutations lead to decreased ER-mitochondrial contact sites and calcium dyshomeostasis. As a consequence, energy metabolism was impaired, which in turn lead to increased mitophagy. CONCLUSION: In summary, our data support the role of Miro1 in maintaining calcium homeostasis and mitochondrial quality control in PD.

Published

2019

7. Mutations in RHOT1 disrupt ER-mitochondria contact sites interfering with calcium homeostasis and mitochondrial dynamics in Parkinson's disease.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, Krüger, Rejko, Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, and Krüger, Rejko

Abstract

OBJECTIVE: The outer mitochondrial membrane protein Miro1 is a crucial player in mitochondrial dynamics and calcium homeostasis. Recent evidence indicated that Miro1 mediates calcium-induced mitochondrial shape transition (MiST), which is a prerequisite for the initiation of mitophagy. Moreover, altered Miro1 protein levels have emerged as a shared feature of monogenic and sporadic Parkinson's disease (PD), but, so far, no disease-associated variants in RHOT1 have been identified. RESULTS: Here, for the first time, we describe heterozygous RHOT1 mutations in two PD patients (het c.815G>A; het c.1348C>T) and identified mitochondrial phenotypes with reduced mitochondrial mass in patient-derived cellular models. Both mutations lead to decreased ER-mitochondrial contact sites and calcium dyshomeostasis. As a consequence, energy metabolism was impaired, which in turn lead to increased mitophagy. CONCLUSION: In summary, our data support the role of Miro1 in maintaining calcium homeostasis and mitochondrial quality control in PD.

Published

2019

8. Mutations in RHOT1 disrupt ER-mitochondria contact sites interfering with calcium homeostasis and mitochondrial dynamics in Parkinson's disease.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, Krüger, Rejko, Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Integrative Cell Signalling (Skupin Group) [research center], FNR: PEARL (P13/6682797/Krüger), MiRisk-PD (MiRisk‐PD, C17/BM/11676395), CASCAD (7975668), INTER/BMBF/13/04, NCER-PD, FNR9631103. [sponsor], DFG: KR2119/8‐1, DI 1386/2‐1, FOR2488 [sponsor], NIH: P41 GM103426 [sponsor], BMBF: Mito‐PD 031 A 430 A [sponsor], JPND Courage-PD [sponsor], Grossmann, Dajana, Berenguer, Clara, Bellet, Marie Estelle, Scheibner, David, Bohler, Jill, Massart, François, Rapaport, Doron, Skupin, Alexander, Fouquier d'Hérouël, Aymeric, Sharma, Manu, Ghelfi, Jenny, Rakovic, Aleksandar, Lichtner, Peter, Antony, Paul, Glaab, Enrico, May, Patrick, Dimmer, Kai Stefan, Fitzgerald, Julia Catherine, Grünewald, Anne, and Krüger, Rejko

Abstract

OBJECTIVE: The outer mitochondrial membrane protein Miro1 is a crucial player in mitochondrial dynamics and calcium homeostasis. Recent evidence indicated that Miro1 mediates calcium-induced mitochondrial shape transition (MiST), which is a prerequisite for the initiation of mitophagy. Moreover, altered Miro1 protein levels have emerged as a shared feature of monogenic and sporadic Parkinson's disease (PD), but, so far, no disease-associated variants in RHOT1 have been identified. RESULTS: Here, for the first time, we describe heterozygous RHOT1 mutations in two PD patients (het c.815G>A; het c.1348C>T) and identified mitochondrial phenotypes with reduced mitochondrial mass in patient-derived cellular models. Both mutations lead to decreased ER-mitochondrial contact sites and calcium dyshomeostasis. As a consequence, energy metabolism was impaired, which in turn lead to increased mitophagy. CONCLUSION: In summary, our data support the role of Miro1 in maintaining calcium homeostasis and mitochondrial quality control in PD.

Published

2019

9. The GET pathway can increase the risk of mitochondrial outer membrane proteins to be mistargeted to the ER

Author

Vitali, Daniela G., Sinzel, Monika, Bulthuis, E.P., Kolb, Antonia, Zabel, Susanne, Mehlhorn, Dietmar G., Borgese, Nica, Rapaport, Doron, Vitali, Daniela G., Sinzel, Monika, Bulthuis, E.P., Kolb, Antonia, Zabel, Susanne, Mehlhorn, Dietmar G., Borgese, Nica, and Rapaport, Doron

Abstract

Item does not contain fulltext

Published

2018

10. The GET pathway can increase the risk of mitochondrial outer membrane proteins to be mistargeted to the ER

Author

Vitali, Daniela G., Sinzel, Monika, Bulthuis, E.P., Kolb, Antonia, Zabel, Susanne, Mehlhorn, Dietmar G., Borgese, Nica, Rapaport, Doron, Vitali, Daniela G., Sinzel, Monika, Bulthuis, E.P., Kolb, Antonia, Zabel, Susanne, Mehlhorn, Dietmar G., Borgese, Nica, and Rapaport, Doron

Abstract

Item does not contain fulltext

Published

2018

11. The GET pathway can increase the risk of mitochondrial outer membrane proteins to be mistargeted to the ER

Author

Vitali, Daniela G., Sinzel, Monika, Bulthuis, E.P., Kolb, Antonia, Zabel, Susanne, Mehlhorn, Dietmar G., Borgese, Nica, Rapaport, Doron, Vitali, Daniela G., Sinzel, Monika, Bulthuis, E.P., Kolb, Antonia, Zabel, Susanne, Mehlhorn, Dietmar G., Borgese, Nica, and Rapaport, Doron

Abstract

Item does not contain fulltext

Published

2018

12. Structural Basis of Membrane Protein Chaperoning through the Mitochondrial Intermembrane Space

Author

Weinhaupl, Katharina, Lindau, Caroline, Hessel, Audrey, Wang, Yong, Schültze, Conny, Jores, Tobias, Melchionda, Laura, Schönfisch, Birgit, Kalbacher, Hubert, Bersch, Beate, Rapaport, Doron, Brennich, Martha, Lindorff-Larsen, Kresten, Wiedemann, Nils, Schanda, Paul, Weinhaupl, Katharina, Lindau, Caroline, Hessel, Audrey, Wang, Yong, Schültze, Conny, Jores, Tobias, Melchionda, Laura, Schönfisch, Birgit, Kalbacher, Hubert, Bersch, Beate, Rapaport, Doron, Brennich, Martha, Lindorff-Larsen, Kresten, Wiedemann, Nils, and Schanda, Paul

Published

2018

13. Structural Basis of Membrane Protein Chaperoning through the Mitochondrial Intermembrane Space

Author

Weinhaupl, Katharina, Lindau, Caroline, Hessel, Audrey, Wang, Yong, Schültze, Conny, Jores, Tobias, Melchionda, Laura, Schönfisch, Birgit, Kalbacher, Hubert, Bersch, Beate, Rapaport, Doron, Brennich, Martha, Lindorff-Larsen, Kresten, Wiedemann, Nils, Schanda, Paul, Weinhaupl, Katharina, Lindau, Caroline, Hessel, Audrey, Wang, Yong, Schültze, Conny, Jores, Tobias, Melchionda, Laura, Schönfisch, Birgit, Kalbacher, Hubert, Bersch, Beate, Rapaport, Doron, Brennich, Martha, Lindorff-Larsen, Kresten, Wiedemann, Nils, and Schanda, Paul

Published

2018

14. Mitochondrial Defects and Neurodegeneration in Mice Overexpressing Wild Type or G399S Mutant HtrA2

Author

University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, Fitzgerald, Julia, University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, and Fitzgerald, Julia

Abstract

The protease HtrA2 has a protective role inside mitochondria, but promotes apoptosis under stress. We previously identified the G399S HtrA2 mutation in Parkinson's disease (PD) patients and reported mitochondrial dysfunction in vitro. Mitochondrial dysfunction is a common feature of PD and related to neurodegeneration. Complete loss of HtrA2 has been shown to cause neurodegeneration in mice. However, the full impact of HtrA2 overexpression or the G399S mutation is still to be determined in vivo. Here, we report the first HtrA2 G399S transgenic mouse model. Our data suggest that the mutation has a dominant-negative effect. We also describe a toxic effect of wild-type (WT) HtrA2 overexpression. Only low overexpression of the G399S mutation allowed viable animals and we suggest that the mutant protein is likely unstable. This is accompanied by reduced mitochondrial respiratory capacity and sensitivity to apoptotic cell death. Mice overexpressing WT HtrA2 were viable, yet these animals have inhibited mitochondrial respiration and significant induction of apoptosis in the brain leading to motor dysfunction, highlighting the opposing roles of HtrA2. Our data further underscore the importance of HtrA2 as a key mediator of mitochondrial function and its fine regulatory role in cell fate. The location and abundance of HtrA2 is tightly controlled and, therefore, human mutations leading to gain- or loss of function could provide significant risk for PD-related neurodegeneration.

Published

2016

15. Mitochondrial Defects and Neurodegeneration in Mice Overexpressing Wild Type or G399S Mutant HtrA2

Author

University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, Fitzgerald, Julia, University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, and Fitzgerald, Julia

Abstract

The protease HtrA2 has a protective role inside mitochondria, but promotes apoptosis under stress. We previously identified the G399S HtrA2 mutation in Parkinson's disease (PD) patients and reported mitochondrial dysfunction in vitro. Mitochondrial dysfunction is a common feature of PD and related to neurodegeneration. Complete loss of HtrA2 has been shown to cause neurodegeneration in mice. However, the full impact of HtrA2 overexpression or the G399S mutation is still to be determined in vivo. Here, we report the first HtrA2 G399S transgenic mouse model. Our data suggest that the mutation has a dominant-negative effect. We also describe a toxic effect of wild-type (WT) HtrA2 overexpression. Only low overexpression of the G399S mutation allowed viable animals and we suggest that the mutant protein is likely unstable. This is accompanied by reduced mitochondrial respiratory capacity and sensitivity to apoptotic cell death. Mice overexpressing WT HtrA2 were viable, yet these animals have inhibited mitochondrial respiration and significant induction of apoptosis in the brain leading to motor dysfunction, highlighting the opposing roles of HtrA2. Our data further underscore the importance of HtrA2 as a key mediator of mitochondrial function and its fine regulatory role in cell fate. The location and abundance of HtrA2 is tightly controlled and, therefore, human mutations leading to gain- or loss of function could provide significant risk for PD-related neurodegeneration.

Published

2016

16. Mitochondrial Defects and Neurodegeneration in Mice Overexpressing Wild Type or G399S Mutant HtrA2

Author

University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, Fitzgerald, Julia, University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, and Fitzgerald, Julia

Abstract

The protease HtrA2 has a protective role inside mitochondria, but promotes apoptosis under stress. We previously identified the G399S HtrA2 mutation in Parkinson's disease (PD) patients and reported mitochondrial dysfunction in vitro. Mitochondrial dysfunction is a common feature of PD and related to neurodegeneration. Complete loss of HtrA2 has been shown to cause neurodegeneration in mice. However, the full impact of HtrA2 overexpression or the G399S mutation is still to be determined in vivo. Here, we report the first HtrA2 G399S transgenic mouse model. Our data suggest that the mutation has a dominant-negative effect. We also describe a toxic effect of wild-type (WT) HtrA2 overexpression. Only low overexpression of the G399S mutation allowed viable animals and we suggest that the mutant protein is likely unstable. This is accompanied by reduced mitochondrial respiratory capacity and sensitivity to apoptotic cell death. Mice overexpressing WT HtrA2 were viable, yet these animals have inhibited mitochondrial respiration and significant induction of apoptosis in the brain leading to motor dysfunction, highlighting the opposing roles of HtrA2. Our data further underscore the importance of HtrA2 as a key mediator of mitochondrial function and its fine regulatory role in cell fate. The location and abundance of HtrA2 is tightly controlled and, therefore, human mutations leading to gain- or loss of function could provide significant risk for PD-related neurodegeneration.

Published

2016

17. Mitochondrial Defects and Neurodegeneration in Mice Overexpressing Wild Type or G399S Mutant HtrA2

Author

University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, Fitzgerald, Julia, University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, and Fitzgerald, Julia

Abstract

The protease HtrA2 has a protective role inside mitochondria, but promotes apoptosis under stress. We previously identified the G399S HtrA2 mutation in Parkinson's disease (PD) patients and reported mitochondrial dysfunction in vitro. Mitochondrial dysfunction is a common feature of PD and related to neurodegeneration. Complete loss of HtrA2 has been shown to cause neurodegeneration in mice. However, the full impact of HtrA2 overexpression or the G399S mutation is still to be determined in vivo. Here, we report the first HtrA2 G399S transgenic mouse model. Our data suggest that the mutation has a dominant-negative effect. We also describe a toxic effect of wild-type (WT) HtrA2 overexpression. Only low overexpression of the G399S mutation allowed viable animals and we suggest that the mutant protein is likely unstable. This is accompanied by reduced mitochondrial respiratory capacity and sensitivity to apoptotic cell death. Mice overexpressing WT HtrA2 were viable, yet these animals have inhibited mitochondrial respiration and significant induction of apoptosis in the brain leading to motor dysfunction, highlighting the opposing roles of HtrA2. Our data further underscore the importance of HtrA2 as a key mediator of mitochondrial function and its fine regulatory role in cell fate. The location and abundance of HtrA2 is tightly controlled and, therefore, human mutations leading to gain- or loss of function could provide significant risk for PD-related neurodegeneration.

Published

2016

18. Mitochondrial Defects and Neurodegeneration in Mice Overexpressing Wild Type or G399S Mutant HtrA2

Author

University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, Fitzgerald, Julia, University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, and Fitzgerald, Julia

Abstract

The protease HtrA2 has a protective role inside mitochondria, but promotes apoptosis under stress. We previously identified the G399S HtrA2 mutation in Parkinson's disease (PD) patients and reported mitochondrial dysfunction in vitro. Mitochondrial dysfunction is a common feature of PD and related to neurodegeneration. Complete loss of HtrA2 has been shown to cause neurodegeneration in mice. However, the full impact of HtrA2 overexpression or the G399S mutation is still to be determined in vivo. Here, we report the first HtrA2 G399S transgenic mouse model. Our data suggest that the mutation has a dominant-negative effect. We also describe a toxic effect of wild-type (WT) HtrA2 overexpression. Only low overexpression of the G399S mutation allowed viable animals and we suggest that the mutant protein is likely unstable. This is accompanied by reduced mitochondrial respiratory capacity and sensitivity to apoptotic cell death. Mice overexpressing WT HtrA2 were viable, yet these animals have inhibited mitochondrial respiration and significant induction of apoptosis in the brain leading to motor dysfunction, highlighting the opposing roles of HtrA2. Our data further underscore the importance of HtrA2 as a key mediator of mitochondrial function and its fine regulatory role in cell fate. The location and abundance of HtrA2 is tightly controlled and, therefore, human mutations leading to gain- or loss of function could provide significant risk for PD-related neurodegeneration.

Published

2016

19. Mitochondrial Defects and Neurodegeneration in Mice Overexpressing Wild Type or G399S Mutant HtrA2

Author

University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, Fitzgerald, Julia, University of Luxembourg: High Performance Computing - ULHPC [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Biomedical Data Science (Glaab Group) [research center], Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Casadei, Nicolas, Sood, Poonan, Ulrich, Thomas, Kieper, Nicole, Helling, Stefan, May, Caroline, Glaab, Enrico, Chen, Jing, Nuber, Silke, Marcus, Katrin, Rapaport, Doron, Ott, Thomas, Riess, O., Krüger, Rejko, and Fitzgerald, Julia

Abstract

The protease HtrA2 has a protective role inside mitochondria, but promotes apoptosis under stress. We previously identified the G399S HtrA2 mutation in Parkinson's disease (PD) patients and reported mitochondrial dysfunction in vitro. Mitochondrial dysfunction is a common feature of PD and related to neurodegeneration. Complete loss of HtrA2 has been shown to cause neurodegeneration in mice. However, the full impact of HtrA2 overexpression or the G399S mutation is still to be determined in vivo. Here, we report the first HtrA2 G399S transgenic mouse model. Our data suggest that the mutation has a dominant-negative effect. We also describe a toxic effect of wild-type (WT) HtrA2 overexpression. Only low overexpression of the G399S mutation allowed viable animals and we suggest that the mutant protein is likely unstable. This is accompanied by reduced mitochondrial respiratory capacity and sensitivity to apoptotic cell death. Mice overexpressing WT HtrA2 were viable, yet these animals have inhibited mitochondrial respiration and significant induction of apoptosis in the brain leading to motor dysfunction, highlighting the opposing roles of HtrA2. Our data further underscore the importance of HtrA2 as a key mediator of mitochondrial function and its fine regulatory role in cell fate. The location and abundance of HtrA2 is tightly controlled and, therefore, human mutations leading to gain- or loss of function could provide significant risk for PD-related neurodegeneration.

Published

2016

20. A novel heterozygous OPA3 mutation located in the mitochondrial target sequence results in altered steady-state levels and fragmented mitochondrial network.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Grau, Tanja, Burbulla, Lena F., Engl, Gertraud, Delettre, Cecile, Delprat, Benjamin, Oexle, Konrad, Leo-Kottler, Beate, Roscioli, Tony, Krüger, Rejko, Rapaport, Doron, Wissinger, Bernd, Schimpf-Linzenbold, Simone, Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Grau, Tanja, Burbulla, Lena F., Engl, Gertraud, Delettre, Cecile, Delprat, Benjamin, Oexle, Konrad, Leo-Kottler, Beate, Roscioli, Tony, Krüger, Rejko, Rapaport, Doron, Wissinger, Bernd, and Schimpf-Linzenbold, Simone

Abstract

BACKGROUND: Mutations in OPA3 have been reported in patients with autosomal dominant optic atrophy plus cataract and Costeff syndrome. Here, we report the results of a comprehensive study on OPA3 mutations, including the mutation spectrum and its prevalence in a large cohort of OPA1-negative autosomal dominant optic atrophy (ADOA) patients, the associated clinical phenotype and the functional characterisation of a newly identified OPA3 mutant. METHODS: Mutation analysis was carried out in a patient cohort of 121 independent ADOA patients. To characterise a novel OPA3 mutation, we analysed the mitochondrial import, steady-state levels and the mitochondrial localisation of the mutated protein in patients' fibroblasts. Furthermore, the morphology of mitochondria harbouring the mutated OPA3 was monitored. RESULTS: We identified four independent cases (representing families with multiple affected members) with OPA3 mutations. Besides the known p.Q105E mutation, we observed a novel insertion, c.10_11insCGCCCG/p.V3_G4insAP which is located in the mitochondrial presequence. Detailed functional analysis of mitochondria harbouring this novel mutation demonstrates a fragmented mitochondrial network with a decreased mitochondrial mass in patient fibroblasts. In addition, quantification of the OPA3 protein reveals decreased steady-state levels of the mutant protein compared with the native one. Comparison of the clinical phenotypes suggests that OPA3 mutations can additionally evoke hearing loss and by that extend the clinical manifestation of OPA3-associated optic atrophy. This finding is supported by expression analysis of OPA3 in murine cochlear tissue. CONCLUSIONS: In summary, our study provides new insights into the clinical spectrum and the pathogenesis of dominant optic atrophy caused by mutations in the OPA3 gene.

Published

2013

21. Alterations in expression levels of deafness dystonia protein 1 affect mitochondrial morphology

Author

Engl, Gertraud, Florian, Stefan, Tranebjærg, Lisbeth, Rapaport, Doron, Engl, Gertraud, Florian, Stefan, Tranebjærg, Lisbeth, and Rapaport, Doron

Abstract

Deafness-Dystonia-Optic Neuropathy (DDON) Syndrome is a rare X-linked progressive neurodegenerative disorder resulting from mutations in the TIMM8A gene encoding for the deafness dystonia protein 1 (DDP1). Despite important progress in identifying and characterizing novel mutations in this gene, little is known about the underlying pathomechanisms. Deficiencies in the biogenesis of hTim23 and consecutive alterations in biogenesis of inner membrane and matrix proteins have been proposed to serve as one possible mechanistic explanation. To shed new light on the role of DDP1 in the biogenesis of mammalian mitochondria, we investigated the effects of reduced or elevated DDP1 levels on mitochondrial dynamics and function. Our results show a reduction in the import of ß-barrel proteins into mitochondria from cells overexpressing DDP1. This effect was not observed when the DDON-related mutant form DDP1-C66W was overexpressed. Live cell microscopy of primary fibroblasts derived from DDON patients and of DDP1 downregulated HeLa cells displayed alterations of mitochondrial morphology with notable extensions in the length of mitochondrial tubules, whereas overexpression of DDP1 induced the formation of hollow spherical mitochondria. Of note, knockdown of the TIMM8A gene by RNA interference did not show an influence on the oxygen respiration rate and the mitochondrial membrane potential. Taken together, these results suggest that alterations in the levels of DDP1 can affect the morphology of mitochondria and thus shed new light on the pathogenic mechanisms of DDON.

Published

2012

22. Alterations in expression levels of deafness dystonia protein 1 affect mitochondrial morphology

Author

Engl, Gertraud, Florian, Stefan, Tranebjærg, Lisbeth, Rapaport, Doron, Engl, Gertraud, Florian, Stefan, Tranebjærg, Lisbeth, and Rapaport, Doron

Abstract

Deafness-Dystonia-Optic Neuropathy (DDON) Syndrome is a rare X-linked progressive neurodegenerative disorder resulting from mutations in the TIMM8A gene encoding for the deafness dystonia protein 1 (DDP1). Despite important progress in identifying and characterizing novel mutations in this gene, little is known about the underlying pathomechanisms. Deficiencies in the biogenesis of hTim23 and consecutive alterations in biogenesis of inner membrane and matrix proteins have been proposed to serve as one possible mechanistic explanation. To shed new light on the role of DDP1 in the biogenesis of mammalian mitochondria, we investigated the effects of reduced or elevated DDP1 levels on mitochondrial dynamics and function. Our results show a reduction in the import of ß-barrel proteins into mitochondria from cells overexpressing DDP1. This effect was not observed when the DDON-related mutant form DDP1-C66W was overexpressed. Live cell microscopy of primary fibroblasts derived from DDON patients and of DDP1 downregulated HeLa cells displayed alterations of mitochondrial morphology with notable extensions in the length of mitochondrial tubules, whereas overexpression of DDP1 induced the formation of hollow spherical mitochondria. Of note, knockdown of the TIMM8A gene by RNA interference did not show an influence on the oxygen respiration rate and the mitochondrial membrane potential. Taken together, these results suggest that alterations in the levels of DDP1 can affect the morphology of mitochondria and thus shed new light on the pathogenic mechanisms of DDON.

Published

2012

23. Dissecting the role of the mitochondrial chaperone mortalin in Parkinson's disease: functional impact of disease-related variants on mitochondrial homeostasis.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Burbulla, Lena F., Schelling, Carina, Kato, Hiroki, Rapaport, Doron, Woitalla, Dirk, Schiesling, Carola, Schulte, Claudia, Sharma, Manu, Illig, Thomas, Bauer, Peter, Jung, Stephan, Nordheim, Alfred, Schols, Ludger, Riess, Olaf, Krüger, Rejko, Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Burbulla, Lena F., Schelling, Carina, Kato, Hiroki, Rapaport, Doron, Woitalla, Dirk, Schiesling, Carola, Schulte, Claudia, Sharma, Manu, Illig, Thomas, Bauer, Peter, Jung, Stephan, Nordheim, Alfred, Schols, Ludger, Riess, Olaf, and Krüger, Rejko

Abstract

The mitochondrial chaperone mortalin has been linked to neurodegeneration in Parkinson's disease (PD) based on reduced protein levels in affected brain regions of PD patients and its interaction with the PD-associated protein DJ-1. Recently, two amino acid exchanges in the ATPase domain (R126W) and the substrate-binding domain (P509S) of mortalin were identified in Spanish PD patients. Here, we identified a separate and novel variant (A476T) in the substrate-binding domain of mortalin in German PD patients. To define a potential role as a susceptibility factor in PD, we characterized the functions of all three variants in different cellular models. In vitro import assays revealed normal targeting of all mortalin variants. In neuronal and non-neuronal human cell lines, the disease-associated variants caused a mitochondrial phenotype of increased reactive oxygen species and reduced mitochondrial membrane potential, which were exacerbated upon proteolytic stress. These functional impairments correspond with characteristic alterations of the mitochondrial network in cells overexpressing mutant mortalin compared with wild-type (wt), which were confirmed in fibroblasts from a carrier of the A476T variant. In line with a loss of function hypothesis, knockdown of mortalin in human cells caused impaired mitochondrial function that was rescued by wt mortalin, but not by the variants. Our genetic and functional studies of novel disease-associated variants in the mortalin gene define a loss of mortalin function, which causes impaired mitochondrial function and dynamics. Our results support the role of this mitochondrial chaperone in neurodegeneration and underscore the concept of impaired mitochondrial protein quality control in PD.

Published

2010

24. Dissecting the role of the mitochondrial chaperone mortalin in Parkinson's disease: functional impact of disease-related variants on mitochondrial homeostasis.

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Burbulla, Lena F., Schelling, Carina, Kato, Hiroki, Rapaport, Doron, Woitalla, Dirk, Schiesling, Carola, Schulte, Claudia, Sharma, Manu, Illig, Thomas, Bauer, Peter, Jung, Stephan, Nordheim, Alfred, Schols, Ludger, Riess, Olaf, Krüger, Rejko, Luxembourg Centre for Systems Biomedicine (LCSB): Clinical & Experimental Neuroscience (Krüger Group) [research center], Burbulla, Lena F., Schelling, Carina, Kato, Hiroki, Rapaport, Doron, Woitalla, Dirk, Schiesling, Carola, Schulte, Claudia, Sharma, Manu, Illig, Thomas, Bauer, Peter, Jung, Stephan, Nordheim, Alfred, Schols, Ludger, Riess, Olaf, and Krüger, Rejko

Abstract

The mitochondrial chaperone mortalin has been linked to neurodegeneration in Parkinson's disease (PD) based on reduced protein levels in affected brain regions of PD patients and its interaction with the PD-associated protein DJ-1. Recently, two amino acid exchanges in the ATPase domain (R126W) and the substrate-binding domain (P509S) of mortalin were identified in Spanish PD patients. Here, we identified a separate and novel variant (A476T) in the substrate-binding domain of mortalin in German PD patients. To define a potential role as a susceptibility factor in PD, we characterized the functions of all three variants in different cellular models. In vitro import assays revealed normal targeting of all mortalin variants. In neuronal and non-neuronal human cell lines, the disease-associated variants caused a mitochondrial phenotype of increased reactive oxygen species and reduced mitochondrial membrane potential, which were exacerbated upon proteolytic stress. These functional impairments correspond with characteristic alterations of the mitochondrial network in cells overexpressing mutant mortalin compared with wild-type (wt), which were confirmed in fibroblasts from a carrier of the A476T variant. In line with a loss of function hypothesis, knockdown of mortalin in human cells caused impaired mitochondrial function that was rescued by wt mortalin, but not by the variants. Our genetic and functional studies of novel disease-associated variants in the mortalin gene define a loss of mortalin function, which causes impaired mitochondrial function and dynamics. Our results support the role of this mitochondrial chaperone in neurodegeneration and underscore the concept of impaired mitochondrial protein quality control in PD.

Published

2010