Your search keyword '"Anand, Ruchika"' showing total 14 results

1. Mitochondrial apolipoprotein MIC26 is a metabolic rheostat regulating central cellular fuel pathways.

Author

Damiecki, Melissa, Naha, Ritam, Schaumkessel, Yulia, Westhoff, Philipp, Atanelov, Nika, Stefanski, Anja, Petzsch, Patrick, Stühler, Kai, Köhrer, Karl, Weber, Andreas P. M., Anand, Ruchika, Reichert, Andreas S., and Kondadi, Arun Kumar

Published

2024

2. Cristae dynamics is modulated in bioenergetically compromised mitochondria.

Author

Golombek, Mathias, Tsigaras, Thanos, Schaumkessel, Yulia, Hänsch, Sebastian, Weidtkamp-Peters, Stefanie, Anand, Ruchika, Reichert, Andreas S., and Kondadi, Arun Kumar

Published

2024

3. A X‐linked nonsense APOO/MIC26 variant causes a lethal mitochondrial disease with progeria‐like phenotypes.

Author

Peifer‐Weiß, Leon, Kurban, Mazen, David, Céline, Lubeck, Melissa, Kondadi, Arun Kumar, Nemer, Georges, Reichert, Andreas S., and Anand, Ruchika

Subjects

AGENESIS of corpus callosum, NONSENSE mutation, MITOCHONDRIA, PHENOTYPES, GENETIC variation

Abstract

APOO/MIC26 is a subunit of the MICOS complex required for mitochondrial cristae morphology and function. Here, we report a novel variant of the APOO/MIC26 gene that causes a severe mitochondrial disease with overall progeria‐like phenotypes in two patients. Both patients developed partial agenesis of the corpus callosum, bilateral congenital cataract, hypothyroidism, and severe immune deficiencies. The patients died at an early age of 12 or 18 months. Exome sequencing revealed a mutation (NM_024122.5): c.532G>T (p.E178*) in the APOO/MIC26 gene that causes a nonsense mutation leading to the loss of 20 C‐terminal amino acids. This mutation resulted in a highly unstable and degradation prone MIC26 protein, yet the remaining minute amounts of mutant MIC26 correctly localized to mitochondria and interacted physically with other MICOS subunits. MIC26 KO cells expressing MIC26 harboring the respective APOO/MIC26 mutation showed mitochondria with perturbed cristae architecture and fragmented morphology resembling MIC26 KO cells. We conclude that the novel mutation found in the APOO/MIC26 gene is a loss‐of‐function mutation impairing mitochondrial morphology and cristae morphogenesis. [ABSTRACT FROM AUTHOR]

Published

2023

4. Molecular and cellular evidence for the impact of a hypertrophic cardiomyopathy-associated RAF1 variant on the structure and function of contractile machinery in bioartificial cardiac tissues.

Author

Nakhaei-Rad, Saeideh, Haghighi, Fereshteh, Bazgir, Farhad, Dahlmann, Julia, Busley, Alexandra Viktoria, Buchholzer, Marcel, Kleemann, Karolin, Schänzer, Anne, Borchardt, Andrea, Hahn, Andreas, Kötter, Sebastian, Schanze, Denny, Anand, Ruchika, Funk, Florian, Kronenbitter, Annette Vera, Scheller, Jürgen, Piekorz, Roland P., Reichert, Andreas S., Volleth, Marianne, and Wolf, Matthew J.

Subjects

INDUCED pluripotent stem cells, NOONAN syndrome, SUDDEN death, HYPERTROPHIC cardiomyopathy, GENETIC variation

Abstract

Noonan syndrome (NS), the most common among RASopathies, is caused by germline variants in genes encoding components of the RAS-MAPK pathway. Distinct variants, including the recurrent Ser257Leu substitution in RAF1, are associated with severe hypertrophic cardiomyopathy (HCM). Here, we investigated the elusive mechanistic link between NS-associated RAF1S257L and HCM using three-dimensional cardiac bodies and bioartificial cardiac tissues generated from patient-derived induced pluripotent stem cells (iPSCs) harboring the pathogenic RAF1 c.770 C > T missense change. We characterize the molecular, structural, and functional consequences of aberrant RAF1–associated signaling on the cardiac models. Ultrastructural assessment of the sarcomere revealed a shortening of the I-bands along the Z disc area in both iPSC-derived RAF1S257L cardiomyocytes and myocardial tissue biopsies. The aforementioned changes correlated with the isoform shift of titin from a longer (N2BA) to a shorter isoform (N2B) that also affected the active force generation and contractile tensions. The genotype-phenotype correlation was confirmed using cardiomyocyte progeny of an isogenic gene-corrected RAF1S257L-iPSC line and was mainly reversed by MEK inhibition. Collectively, our findings uncovered a direct link between a RASopathy gene variant and the abnormal sarcomere structure resulting in a cardiac dysfunction that remarkably recapitulates the human disease. Studies on 3D bioartificial cardiac tissues reveal the impacts of hypertrophic cardiomyopathy-associated RAF1 mutations on sarcomere structure, contractile behavior, Ca2+ handling, and intracellular signaling. [ABSTRACT FROM AUTHOR]

Published

2023

5. MIC26 and MIC27 are bona fide subunits of the MICOS complex in mitochondria and do not exist as glycosylated apolipoproteins.

Author

Lubeck, Melissa, Derkum, Nick H., Naha, Ritam, Strohm, Rebecca, Driessen, Marc D., Belgardt, Bengt-Frederik, Roden, Michael, Stühler, Kai, Anand, Ruchika, Reichert, Andreas S., and Kondadi, Arun Kumar

Subjects

APOLIPOPROTEINS, MEMBRANE proteins, MITOCHONDRIA, MITOCHONDRIAL membranes, MASS spectrometry

Abstract

Impairments of mitochondrial functions are linked to human ageing and pathologies such as cancer, cardiomyopathy, neurodegeneration and diabetes. Specifically, aberrations in ultrastructure of mitochondrial inner membrane (IM) and factors regulating them are linked to diabetes. The development of diabetes is connected to the 'Mitochondrial Contact Site and Cristae Organising System' (MICOS) complex which is a large membrane protein complex defining the IM architecture. MIC26 and MIC27 are homologous apolipoproteins of the MICOS complex. MIC26 has been reported as a 22 kDa mitochondrial and a 55 kDa glycosylated and secreted protein. The molecular and functional relationship between these MIC26 isoforms has not been investigated. In order to understand their molecular roles, we depleted MIC26 using siRNA and further generated MIC26 and MIC27 knockouts (KOs) in four different human cell lines. In these KOs, we used four anti-MIC26 antibodies and consistently detected the loss of mitochondrial MIC26 (22 kDa) and MIC27 (30 kDa) but not the loss of intracellular or secreted 55 kDa protein. Thus, the protein assigned earlier as 55 kDa MIC26 is nonspecific. We further excluded the presence of a glycosylated, high-molecular weight MIC27 protein. Next, we probed GFP- and myc-tagged variants of MIC26 with antibodies against GFP and myc respectively. Again, only the mitochondrial versions of these tagged proteins were detected but not the corresponding high-molecular weight MIC26, suggesting that MIC26 is indeed not post-translationally modified. Mutagenesis of predicted glycosylation sites in MIC26 also did not affect the detection of the 55 kDa protein band. Mass spectrometry of a band excised from an SDS gel around 55 kDa could not confirm the presence of any peptides derived from MIC26. Taken together, we conclude that both MIC26 and MIC27 are exclusively localized in mitochondria and that the observed phenotypes reported previously are exclusively due to their mitochondrial function. [ABSTRACT FROM AUTHOR]

Published

2023

6. Mesenchymal stem cells improve redox homeostasis and mitochondrial respiration in fibroblast cell lines with pathogenic MT-ND3 and MT-ND6 variants.

Author

Navaratnarajah, Tharsini, Bellmann, Marlen, Seibt, Annette, Anand, Ruchika, Degistirici, Özer, Meisel, Roland, Mayatepek, Ertan, Reichert, Andreas, Baertling, Fabian, and Distelmaier, Felix

Subjects

CELL respiration, MITOCHONDRIAL DNA, CELL lines, MITOCHONDRIA, HUMAN stem cells, HEME oxygenase, MESENCHYMAL stem cells, HOMEOSTASIS

Abstract

The most frequent biochemical defect of inherited mitochondrial disease is isolated complex I deficiency. There is no cure for this disorder, and treatment is mainly supportive. In this study, we investigated the effects of human mesenchymal stem cells (MSCs) on skin fibroblast derived from three individuals with complex I deficiency carrying different pathogenic variants in mitochondrial DNA-encoded subunits (MT-ND3, MT-ND6). Complex I-deficient fibroblasts were transiently co-cultured with bone marrow-derived MSCs. Mitochondrial transfer was analysed by fluorescence labelling and validated by Sanger sequencing. Levels of reactive oxygen species (ROS) were measured using MitoSOX Red. Moreover, mitochondrial respiration was analysed by Seahorse XFe96 Extracellular Flux Analyzer. Levels of antioxidant proteins were investigated via immunoblotting. Co-culturing of complex I-deficient fibroblast with MSCs lowered cellular ROS levels. The effect on ROS production was more sustained compared to treatment of patient fibroblasts with culture medium derived from MSC cultures. Investigation of cellular antioxidant defence systems revealed an upregulation of SOD2 (superoxide dismutase 2, mitochondrial) and HO-1 (heme oxygenase 1) in patient-derived cell lines. This adaptive response was normalised upon MSC treatment. Moreover, Seahorse experiments revealed a significant improvement of mitochondrial respiration, indicating a mitigation of the oxidative phosphorylation defect. Experiments with repetitive MSC co-culture at two consecutive time points enhanced this effect. Our study indicates that MSC-based treatment approaches might constitute an interesting option for patients with mitochondrial DNA-encoded mitochondrial diseases. We suggest that this strategy may prove more promising for defects caused by mitochondrial DNA variants compared to nuclear-encoded defects. [ABSTRACT FROM AUTHOR]

Published

2022

7. High-throughput screening for natural compound-based autophagy modulators reveals novel chemotherapeutic mode of action for arzanol.

Author

Deitersen, Jana, Berning, Lena, Stuhldreier, Fabian, Ceccacci, Sara, Schlütermann, David, Friedrich, Annabelle, Wu, Wenxian, Sun, Yadong, Böhler, Philip, Berleth, Niklas, Mendiburo, María José, Seggewiß, Sabine, Anand, Ruchika, Reichert, Andreas S., Monti, Maria Chiara, Proksch, Peter, and Stork, Björn

Published

2021

8. Cristae undergo continuous cycles of membrane remodelling in a MICOS‐dependent manner.

Author

Kondadi, Arun Kumar, Anand, Ruchika, Hänsch, Sebastian, Urbach, Jennifer, Zobel, Thomas, Wolf, Dane M, Segawa, Mayuko, Liesa, Marc, Shirihai, Orian S, Weidtkamp‐Peters, Stefanie, and Reichert, Andreas S

Abstract

The mitochondrial inner membrane can reshape under different physiological conditions. How, at which frequency this occurs in living cells, and the molecular players involved are unknown. Here, we show using state‐of‐the‐art live‐cell stimulated emission depletion (STED) super‐resolution nanoscopy that neighbouring crista junctions (CJs) dynamically appose and separate from each other in a reversible and balanced manner in human cells. Staining of cristae membranes (CM), using various protein markers or two lipophilic inner membrane‐specific dyes, further revealed that cristae undergo continuous cycles of membrane remodelling. These events are accompanied by fluctuations of the membrane potential within distinct cristae over time. Both CJ and CM dynamics depended on MIC13 and occurred at similar timescales in the range of seconds. Our data further suggest that MIC60 acts as a docking platform promoting CJ and contact site formation. Overall, by employing advanced imaging techniques including fluorescence recovery after photobleaching (FRAP), single‐particle tracking (SPT), live‐cell STED and high‐resolution Airyscan microscopy, we propose a model of CJ dynamics being mechanistically linked to CM remodelling representing cristae membrane fission and fusion events occurring within individual mitochondria. Synopsis: Mitochondrial crista junctions and cristae membranes undergo continuous remodelling events in a MICOS‐dependent manner. These findings, based on live‐STED nanoscopy and complementary approaches, change the dogma of cristae being static invaginations of the inner membrane and open a novel, highly dynamic view on the internal structure of mitochondria. Crista junctions (CJs) and cristae membranes (CM) undergo dynamic remodelling at a time‐scale of seconds in a reversible, balanced, and MICOS‐dependent manner.MIC60 is the primary docking site for formation of the MICOS complex to ensure CJ formation in mammalian cells.The mitochondrial membrane potential is shown to dynamically fluctuate in distinct cristae, which is correlated to CM remodelling events.We propose a model of CJ‐dynamics being mechanistically linked to CM remodelling representing cristae membrane fission and fusion events occurring within individual mitochondria. [ABSTRACT FROM AUTHOR]

Published

2020

9. Mic13 Is Essential for Formation of Crista Junctions in Mammalian Cells.

Author

Anand, Ruchika, Strecker, Valentina, Urbach, Jennifer, Wittig, Ilka, and Reichert, Andreas S.

Subjects

MITOCHONDRIA, CELL junctions, CELL membranes, CELL morphology, MEMBRANE proteins, CRISPRS

Abstract

Mitochondrial cristae are connected to the inner boundary membrane via crista junctions which are implicated in the regulation of oxidative phosphorylation, apoptosis, and import of lipids and proteins. The MICOS complex determines formation of crista junctions. We performed complexome profiling and identified Mic13, also termed Qil1, as a subunit of the MICOS complex. We show that MIC13 is an inner membrane protein physically interacting with MIC60, a central subunit of the MICOS complex. Using the CRISPR/Cas method we generated the first cell line deleted for MIC13. These knockout cells show a complete loss of crista junctions demonstrating that MIC13 is strictly required for the formation of crista junctions. MIC13 is required for the assembly of MIC10, MIC26, and MIC27 into the MICOS complex. However, it is not needed for the formation of the MIC60/MIC19/MIC25 subcomplex suggesting that the latter is not sufficient for crista junction formation. MIC13 is also dispensable for assembly of respiratory chain complexes and for maintaining mitochondrial network morphology. Still, lack of MIC13 resulted in a moderate reduction of mitochondrial respiration. In summary, we show that MIC13 has a fundamental role in crista junction formation and that assembly of respiratory chain supercomplexes is independent of mitochondrial cristae shape. [ABSTRACT FROM AUTHOR]

Published

2016

10. Stress-induced OMA1 activation and autocatalytic turnover regulate OPA1-dependent mitochondrial dynamics.

Author

Baker, Michael J, Lampe, Philipp A, Stojanovski, Diana, Korwitz, Anne, Anand, Ruchika, Tatsuta, Takashi, and Langer, Thomas

Subjects

AUTOCATALYSIS, MITOCHONDRIA, PHYSIOLOGICAL stress, CELL fusion, EUKARYOTES, CELL membranes

Abstract

The dynamic network of mitochondria fragments under stress allowing the segregation of damaged mitochondria and, in case of persistent damage, their selective removal by mitophagy. Mitochondrial fragmentation upon depolarisation of mitochondria is brought about by the degradation of central components of the mitochondrial fusion machinery. The OMA1 peptidase mediates the degradation of long isoforms of the dynamin-like GTPase OPA1 in the inner membrane. Here, we demonstrate that OMA1-mediated degradation of OPA1 is a general cellular stress response. OMA1 is constitutively active but displays strongly enhanced activity in response to various stress insults. We identify an amino terminal stress-sensor domain of OMA1, which is only present in homologues of higher eukaryotes and which modulates OMA1 proteolysis and activation. OMA1 activation is associated with its autocatalyic degradation, which initiates from both termini of OMA1 and results in complete OMA1 turnover. Autocatalytic proteolysis of OMA1 ensures the reversibility of the response and allows OPA1-mediated mitochondrial fusion to resume upon alleviation of stress. This differentiated stress response maintains the functional integrity of mitochondria and contributes to cell survival. [ABSTRACT FROM AUTHOR]

Published

2014

11. Emerging Roles of the MICOS Complex in Cristae Dynamics and Biogenesis.

Author

Anand, Ruchika, Reichert, Andreas S., and Kondadi, Arun Kumar

Subjects

ORIGIN of life, ADENOSINE triphosphatase, MOLECULAR shapes, PATHOLOGICAL physiology, MEMBRANE fusion, PLANT mitochondria

Abstract

Simple Summary: Mitochondria possess an outer and inner membrane. The part of the inner membrane parallel to the outer membrane is termed the inner boundary membrane, while the cristae membrane folds towards the mitochondrial matrix and houses the respiratory chain complexes. Crista junctions are located at the interface of the inner boundary membrane and the cristae membrane and contain the important 'mitochondrial contact site and cristae organizing system' complex. Despite the growing evidence that the mitochondrial inner membrane could remodel, cristae membranes were largely considered static for nearly seventy years, as the observations were mostly based on electron microscopy and tomography. Recently, using fluorescence super-resolution techniques, several studies showed that cristae membranes undergo dynamic remodeling in living cells, and probably even fission and fusion of the inner membrane. In this review, we discuss the important recent literature conveying the emerging role of the MICOS complex in cristae dynamics and its relation to cristae biogenesis. As the aberrant inner membrane architecture is connected to various pathologies such as cardiomyopathies, neurodegeneration and diabetes, understanding the roles of various molecules connected with cristae biogenesis and dynamics would shed light on the pathophysiology, probably leading to therapeutics in the near future. Mitochondria are double membrane-enclosed organelles performing important cellular and metabolic functions such as ATP generation, heme biogenesis, apoptosis, ROS production and calcium buffering. The mitochondrial inner membrane (IM) is folded into cristae membranes (CMs) of variable shapes using molecular players including the 'mitochondrial contact site and cristae organizing system' (MICOS) complex, the dynamin-like GTPase OPA1, the F1FO ATP synthase and cardiolipin. Aberrant cristae structures are associated with different disorders such as diabetes, neurodegeneration, cancer and hepato-encephalopathy. In this review, we provide an updated view on cristae biogenesis by focusing on novel roles of the MICOS complex in cristae dynamics and shaping of cristae. For over seven decades, cristae were considered as static structures. It was recently shown that cristae constantly undergo rapid dynamic remodeling events. Several studies have re-oriented our perception on the dynamic internal ambience of mitochondrial compartments. In addition, we discuss the recent literature which sheds light on the still poorly understood aspect of cristae biogenesis, focusing on the role of MICOS and its subunits. Overall, we provide an integrated and updated view on the relation between the biogenesis of cristae and the novel aspect of cristae dynamics. [ABSTRACT FROM AUTHOR]

Published

2021

12. Individual cristae within the same mitochondrion display different membrane potentials and are functionally independent.

Author

Wolf, Dane M, Segawa, Mayuko, Kondadi, Arun Kumar, Anand, Ruchika, Bailey, Sean T, Reichert, Andreas S, Bliek, Alexander M, Shackelford, David B, Liesa, Marc, and Shirihai, Orian S

Subjects

MEMBRANE potential, MITOCHONDRIA, ELECTRIC insulators & insulation, OXIDATIVE phosphorylation, MITOCHONDRIAL membranes, PLANT mitochondria

Abstract

The mitochondrial membrane potential (ΔΨm) is the main driver of oxidative phosphorylation (OXPHOS). The inner mitochondrial membrane (IMM), consisting of cristae and inner boundary membranes (IBM), is considered to carry a uniform ΔΨm. However, sequestration of OXPHOS components in cristae membranes necessitates a re‐examination of the equipotential representation of the IMM. We developed an approach to monitor ΔΨm at the resolution of individual cristae. We found that the IMM was divided into segments with distinct ΔΨm, corresponding to cristae and IBM. ΔΨm was higher at cristae compared to IBM. Treatment with oligomycin increased, whereas FCCP decreased, ΔΨm heterogeneity along the IMM. Impairment of cristae structure through deletion of MICOS‐complex components or Opa1 diminished this intramitochondrial heterogeneity of ΔΨm. Lastly, we determined that different cristae within the individual mitochondrion can have disparate membrane potentials and that interventions causing acute depolarization may affect some cristae while sparing others. Altogether, our data support a new model in which cristae within the same mitochondrion behave as independent bioenergetic units, preventing the failure of specific cristae from spreading dysfunction to the rest. Synopsis: Mitochondrial membrane potential (ΔΨm) is the main driving force for ATP synthesis at the folds of the inner mitochondrial membrane, the cristae. Measurement of ΔΨm in individual cristae reveals that crista junctions provide electrical insulation and sustain polarization of individual mitochondrial cristae within a single mitochondrion even when neighbouring cristae are damaged. Cristae have higher ΔΨ compared to their adjoining inner mitochondrial membranes.Cristae are electrically insulated, allowing individual cristae within any given mitochondrion to have different membrane potentials.Cristae can remain polarized despite depolarization of neighbouring ones.Disruption of crista junctions impairs the electrical insulation of cristae, equilibrating their ΔΨ with those of inner mitochondrial membranes. [ABSTRACT FROM AUTHOR]

Published

2019

13. Functional Interplay between Cristae Biogenesis, Mitochondrial Dynamics and Mitochondrial DNA Integrity.

Author

Kondadi, Arun Kumar, Anand, Ruchika, and Reichert, Andreas S.

Abstract

Mitochondria are vital cellular organelles involved in a plethora of cellular processes such as energy conversion, calcium homeostasis, heme biogenesis, regulation of apoptosis and ROS reactive oxygen species (ROS) production. Although they are frequently depicted as static bean-shaped structures, our view has markedly changed over the past few decades as many studies have revealed a remarkable dynamicity of mitochondrial shapes and sizes both at the cellular and intra-mitochondrial levels. Aberrant changes in mitochondrial dynamics and cristae structure are associated with ageing and numerous human diseases (e.g., cancer, diabetes, various neurodegenerative diseases, types of neuro- and myopathies). Another unique feature of mitochondria is that they harbor their own genome, the mitochondrial DNA (mtDNA). MtDNA exists in several hundreds to thousands of copies per cell and is arranged and packaged in the mitochondrial matrix in structures termed mt-nucleoids. Many human diseases are mechanistically linked to mitochondrial dysfunction and alteration of the number and/or the integrity of mtDNA. In particular, several recent studies identified remarkable and partly unexpected links between mitochondrial structure, fusion and fission dynamics, and mtDNA. In this review, we will provide an overview about these recent insights and aim to clarify how mitochondrial dynamics, cristae ultrastructure and mtDNA structure influence each other and determine mitochondrial functions. [ABSTRACT FROM AUTHOR]

Published

2019

14. The mycotoxin phomoxanthone A disturbs the form and function of the inner mitochondrial membrane.

Author

Böhler, Philip, Stuhldreier, Fabian, Anand, Ruchika, Kondadi, Arun Kumar, Schlütermann, David, Berleth, Niklas, Deitersen, Jana, Wallot-Hieke, Nora, Wu, Wenxian, Frank, Marian, Niemann, Hendrik, Wesbuer, Elisabeth, Barbian, Andreas, Luyten, Tomas, Parys, Jan B., Weidtkamp-Peters, Stefanie, Borchardt, Andrea, Reichert, Andreas S., Peña-Blanco, Aida, and García-Sáez, Ana J.

Published

2018