Your search keyword '"Elsje G. Otten"' showing total 7 results

1. Autophagy promotes cell survival by maintaining NAD levels

Author

Tetsushi Kataura, Lucia Sedlackova, Elsje G. Otten, Ruchika Kumari, David Shapira, Filippo Scialo, Rhoda Stefanatos, Kei-ichi Ishikawa, George Kelly, Elena Seranova, Congxin Sun, Dorothea Maetzel, Niall Kenneth, Sergey Trushin, Tong Zhang, Eugenia Trushina, Charles C. Bascom, Ryan Tasseff, Robert J. Isfort, John E. Oblong, Satomi Miwa, Michael Lazarou, Rudolf Jaenisch, Masaya Imoto, Shinji Saiki, Manolis Papamichos-Chronakis, Ravi Manjithaya, Oliver D.K. Maddocks, Alberto Sanz, Sovan Sarkar, Viktor I. Korolchuk, Kataura, T., Sedlackova, L., Otten, E. G., Kumari, R., Shapira, D., Scialo, F., Stefanatos, R., Ishikawa, K. -I., Kelly, G., Seranova, E., Sun, C., Maetzel, D., Kenneth, N., Trushin, S., Zhang, T., Trushina, E., Bascom, C. C., Tasseff, R., Isfort, R. J., Oblong, J. E., Miwa, S., Lazarou, M., Jaenisch, R., Imoto, M., Saiki, S., Papamichos-Chronakis, M., Manjithaya, R., Maddocks, O. D. K., Sanz, A., Sarkar, S., and Korolchuk, V. I.

Subjects

Cell Death, Cell Survival, Cell Biology, Saccharomyces cerevisiae, NAD, General Biochemistry, Genetics and Molecular Biology, PARP, mitochondria, Mice, mitophagy, ageing, Autophagy, DNA damage, Sirtuins, Animals, Humans, Molecular Biology, metabolism, Developmental Biology

Abstract

Autophagy is an essential catabolic process that promotes the clearance of surplus or damaged intracellular components. Loss of autophagy in age-related human pathologies contributes to tissue degeneration through a poorly understood mechanism. Here, we identify an evolutionarily conserved role of autophagy from yeast to humans in the preservation of nicotinamide adenine dinucleotide (NAD) levels, which are critical for cell survival. In respiring mouse fibroblasts with autophagy deficiency, loss of mitochondrial quality control was found to trigger hyperactivation of stress responses mediated by NADases of PARP and Sirtuin families. Uncontrolled depletion of the NAD(H) pool by these enzymes ultimately contributed to mitochondrial membrane depolarization and cell death. Pharmacological and genetic interventions targeting several key elements of this cascade improved the survival of autophagy-deficient yeast, mouse fibroblasts, and human neurons. Our study provides a mechanistic link between autophagy and NAD metabolism and identifies targets for interventions in human diseases associated with autophagic, lysosomal, and mitochondrial dysfunction.

Published

2022

2. Ubiquitylation of lipopolysaccharide by RNF213 during bacterial infection

Author

Keith B. Boyle, Elsje G. Otten, Ana Crespillo-Casado, Felix Randow, Balaji Santhanam, Claudio Pathe, Emma I. Werner, and Vimisha Dharamdasani

Subjects

Lipopolysaccharides, Salmonella typhimurium, Lipopolysaccharide, Ubiquitin-Protein Ligases, Cell Line, Lipid A, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, Ubiquitin, Autophagy, Animals, Humans, 030304 developmental biology, Adenosine Triphosphatases, 0303 health sciences, Multidisciplinary, Innate immune system, biology, Ubiquitination, Ubiquitin ligase, Cell biology, Cytosol, chemistry, Salmonella Infections, biology.protein, RING Finger Domains, 030217 neurology & neurosurgery, Ring Finger Protein 213, HeLa Cells

Abstract

Ubiquitylation is a widespread post-translational protein modification in eukaryotes and marks bacteria that invade the cytosol as cargo for antibacterial autophagy1–3. The identity of the ubiquitylated substrate on bacteria is unknown. Here we show that the ubiquitin coat on Salmonella that invade the cytosol is formed through the ubiquitylation of a non-proteinaceous substrate, the lipid A moiety of bacterial lipopolysaccharide (LPS), by the E3 ubiquitin ligase ring finger protein 213 (RNF213). RNF213 is a risk factor for moyamoya disease4,5, which is a progressive stenosis of the supraclinoid internal carotid artery that causes stroke (especially in children)6,7. RNF213 restricts the proliferation of cytosolic Salmonella and is essential for the generation of the bacterial ubiquitin coat, both directly (through the ubiquitylation of LPS) and indirectly (through the recruitment of LUBAC, which is a downstream E3 ligase that adds M1-linked ubiquitin chains onto pre-existing ubiquitin coats8). In cells that lack RNF213, bacteria do not attract ubiquitin-dependent autophagy receptors or induce antibacterial autophagy. The ubiquitylation of LPS on Salmonella that invade the cytosol requires the dynein-like core of RNF213, but not its RING domain. Instead, ubiquitylation of LPS relies on an RZ finger in the E3 shell. We conclude that ubiquitylation extends beyond protein substrates and that ubiquitylation of LPS triggers cell-autonomous immunity, and we postulate that non-proteinaceous substances other than LPS may also become ubiquitylated. Upon Salmonella invasion of the mammalian cytosol, ubiquitylation of a non-proteinaceous substrate—the lipid A moiety of bacterial lipopolysaccharide—by the E3 ubiquitin ligase RNF213 marks the bacteria as cargo for antibacterial autophagy.

Published

2020

3. Oxidation of p62 as an evolutionary adaptation to promote autophagy in stress conditions

Author

Bernadette Carroll, Rhoda Stefanatos, Elsje G. Otten, and Viktor I. Korolchuk

Subjects

Cancer Research, Physiology, Cell Survival, Cell, ved/biology.organism_classification_rank.species, lcsh:Medicine, Oxidative phosphorylation, Biology, Biochemistry, Genetics and Molecular Biology (miscellaneous), Article, Sequestosome-1 Protein, medicine, Autophagy, Animals, Humans, Amino Acid Sequence, Model organism, lcsh:QH301-705.5, Cells, Cultured, chemistry.chemical_classification, Mice, Knockout, reactive oxygen species, Reactive oxygen species, Sequence Homology, Amino Acid, ved/biology, Mechanism (biology), Neurodegeneration, Amyotrophic Lateral Sclerosis, lcsh:R, Hydrogen Peroxide, medicine.disease, Microreview, Oxidants, Cell biology, medicine.anatomical_structure, Drosophila melanogaster, HEK293 Cells, chemistry, lcsh:Biology (General), Ageing, Proteostasis, Molecular Medicine, Oxidation-Reduction, HeLa Cells

Abstract

Cellular homoeostatic pathways such as macroautophagy (hereinafter autophagy) are regulated by basic mechanisms that are conserved throughout the eukaryotic kingdom. However, it remains poorly understood how these mechanisms further evolved in higher organisms. Here we describe a modification in the autophagy pathway in vertebrates, which promotes its activity in response to oxidative stress. We have identified two oxidation-sensitive cysteine residues in a prototypic autophagy receptor SQSTM1/p62, which allow activation of pro-survival autophagy in stress conditions. The Drosophila p62 homologue, Ref(2)P, lacks these oxidation-sensitive cysteine residues and their introduction into the protein increases protein turnover and stress resistance of flies, whereas perturbation of p62 oxidation in humans may result in age-related pathology. We propose that the redox-sensitivity of p62 may have evolved in vertebrates as a mechanism that allows activation of autophagy in response to oxidative stress to maintain cellular homoeostasis and increase cell survival., The cellular mechanisms underlying autophagy are conserved; however it is unclear how they evolved in higher organisms. Here the authors identify two oxidation-sensitive cysteine residues in the autophagy receptor SQSTM1/p62 in vertebrates which allow activation of pro-survival autophagy in stress conditions.

Published

2019

4. mTORC1 as the main gateway to autophagy

Author

Viktor I. Korolchuk, Yoana Rabanal-Ruiz, and Elsje G. Otten

Subjects

0301 basic medicine, autophagy, Anabolism, medicine.medical_treatment, mTORC1, Nutrient sensing, Review Article, Biology, Mechanistic Target of Rapamycin Complex 1, Biochemistry, 03 medical and health sciences, Lysosome, medicine, Animals, Humans, Molecular Biology, Review Articles, PI3K/AKT/mTOR pathway, amino acids, Catabolism, Growth factor, Autophagy, Cell biology, 030104 developmental biology, medicine.anatomical_structure, lysosome, mTOR, biological phenomena, cell phenomena, and immunity, Lysosomes, Signal Transduction

Abstract

Cells and organisms must coordinate their metabolic activity with changes in their environment to ensure their growth only when conditions are favourable. In order to maintain cellular homoeostasis, a tight regulation between the synthesis and degradation of cellular components is essential. At the epicentre of the cellular nutrient sensing is the mechanistic target of rapamycin complex 1 (mTORC1) which connects environmental cues, including nutrient and growth factor availability as well as stress, to metabolic processes in order to preserve cellular homoeostasis. Under nutrient-rich conditions mTORC1 promotes cell growth by stimulating biosynthetic pathways, including synthesis of proteins, lipids and nucleotides, and by inhibiting cellular catabolism through repression of the autophagic pathway. Its close signalling interplay with the energy sensor AMP-activated protein kinase (AMPK) dictates whether the cell actively favours anabolic or catabolic processes. Underlining the role of mTORC1 in the coordination of cellular metabolism, its deregulation is linked to numerous human diseases ranging from metabolic disorders to many cancers. Although mTORC1 can be modulated by a number of different inputs, amino acids represent primordial cues that cannot be compensated for by any other stimuli. The understanding of how amino acids signal to mTORC1 has increased considerably in the last years; however this area of research remains a hot topic in biomedical sciences. The current ideas and models proposed to explain the interrelationship between amino acid sensing, mTORC1 signalling and autophagy is the subject of the present review.

Published

2017

5. An Induced Pluripotent Stem Cell Patient Specific Model of Complement Factor H (Y402H) Polymorphism Displays Characteristic Features of Age-Related Macular Degeneration and Indicates a Beneficial Role for UV Light Exposure

Author

Dean, Hallam, Joseph, Collin, Sanja, Bojic, Valeria, Chichagova, Adriana, Buskin, Yaobo, Xu, Lucia, Lafage, Elsje G, Otten, George, Anyfantis, Carla, Mellough, Stefan, Przyborski, Sameer, Alharthi, Viktor, Korolchuk, Andrew, Lotery, Gabriele, Saretzki, Martin, McKibbin, Lyle, Armstrong, David, Steel, David, Kavanagh, and Majlinda, Lako

Subjects

Macular Degeneration, Mice, Errata, Ultraviolet Rays, Complement Factor H, Induced Pluripotent Stem Cells, Animals, Humans, Ultraviolet Therapy, Mice, SCID, Aged

Abstract

Age-related macular degeneration (AMD) is the most common cause of blindness, accounting for 8.7% of all blindness globally. Vision loss is caused ultimately by apoptosis of the retinal pigment epithelium (RPE) and overlying photoreceptors. Treatments are evolving for the wet form of the disease; however, these do not exist for the dry form. Complement factor H polymorphism in exon 9 (Y402H) has shown a strong association with susceptibility to AMD resulting in complement activation, recruitment of phagocytes, RPE damage, and visual decline. We have derived and characterized induced pluripotent stem cell (iPSC) lines from two subjects without AMD and low-risk genotype and two patients with advanced AMD and high-risk genotype and generated RPE cells that show local secretion of several proteins involved in the complement pathway including factor H, factor I, and factor H-like protein 1. The iPSC RPE cells derived from high-risk patients mimic several key features of AMD including increased inflammation and cellular stress, accumulation of lipid droplets, impaired autophagy, and deposition of "drüsen"-like deposits. The low- and high-risk RPE cells respond differently to intermittent exposure to UV light, which leads to an improvement in cellular and functional phenotype only in the high-risk AMD-RPE cells. Taken together, our data indicate that the patient specific iPSC model provides a robust platform for understanding the role of complement activation in AMD, evaluating new therapies based on complement modulation and drug testing. Stem Cells 2017;35:2305-2320.

Published

2017

6. Autophagy, lipophagy and lysosomal lipid storage disorders

Author

Carl, Ward, Nuria, Martinez-Lopez, Elsje G, Otten, Bernadette, Carroll, Dorothea, Maetzel, Rajat, Singh, Sovan, Sarkar, and Viktor I, Korolchuk

Subjects

Fatty Liver, Lysosomal Storage Diseases, Multiprotein Complexes, TOR Serine-Threonine Kinases, Autophagy, Animals, Humans, Mechanistic Target of Rapamycin Complex 1, Lipid Metabolism, Lysosomes, Lipid Metabolism, Inborn Errors, Signal Transduction

Abstract

Autophagy is a catabolic process with an essential function in the maintenance of cellular and tissue homeostasis. It is primarily recognised for its role in the degradation of dysfunctional proteins and unwanted organelles, however in recent years the range of autophagy substrates has also been extended to lipids. Degradation of lipids via autophagy is termed lipophagy. The ability of autophagy to contribute to the maintenance of lipo-homeostasis becomes particularly relevant in the context of genetic lysosomal storage disorders where perturbations of autophagic flux have been suggested to contribute to the disease aetiology. Here we review recent discoveries of the molecular mechanisms mediating lipid turnover by the autophagy pathways. We further focus on the relevance of autophagy, and specifically lipophagy, to the disease mechanisms. Moreover, autophagy is also discussed as a potential therapeutic target in several key lysosomal storage disorders.

Published

2015

7. Dynamic Modelling of Pathways to Cellular Senescence Reveals Strategies for Targeted Interventions

Author

Piero Dalle Pezze, Elsje G. Otten, Thomas B. L. Kirkwood, Viktor I. Korolchuk, Thomas von Zglinicki, Daryl P. Shanley, and Glyn Nelson

Subjects

Mitochondrion, Biochemistry, Cell Signaling, Mitophagy, lcsh:QH301-705.5, Cellular Senescence, Energy-Producing Organelles, Cellular Stress Responses, Ecology, Systems Biology, TOR Serine-Threonine Kinases, Signaling Cascades, Mitochondria, Cell biology, Computational Theory and Mathematics, Cell Aging, Cell Processes, Modeling and Simulation, Mitochondrial fission, Cellular Structures and Organelles, Cell aging, Network Analysis, Signal Transduction, Research Article, Senescence, Cell Physiology, Computer and Information Sciences, DNA damage, Systems biology, Bioenergetics, Biology, Models, Biological, Stress Signaling Cascade, Cell Line, Metabolic Networks, Cellular and Molecular Neuroscience, Genetics, Humans, Computer Simulation, Molecular Biology, Ecology, Evolution, Behavior and Systematics, PI3K/AKT/mTOR pathway, Biology and Life Sciences, Computational Biology, Cell Biology, Cell Metabolism, Oxidative Stress, lcsh:Biology (General), Reactive Oxygen Species, DNA Damage, Transcription Factors

Abstract

Cellular senescence, a state of irreversible cell cycle arrest, is thought to help protect an organism from cancer, yet also contributes to ageing. The changes which occur in senescence are controlled by networks of multiple signalling and feedback pathways at the cellular level, and the interplay between these is difficult to predict and understand. To unravel the intrinsic challenges of understanding such a highly networked system, we have taken a systems biology approach to cellular senescence. We report a detailed analysis of senescence signalling via DNA damage, insulin-TOR, FoxO3a transcription factors, oxidative stress response, mitochondrial regulation and mitophagy. We show in silico and in vitro that inhibition of reactive oxygen species can prevent loss of mitochondrial membrane potential, whilst inhibition of mTOR shows a partial rescue of mitochondrial mass changes during establishment of senescence. Dual inhibition of ROS and mTOR in vitro confirmed computational model predictions that it was possible to further reduce senescence-induced mitochondrial dysfunction and DNA double-strand breaks. However, these interventions were unable to abrogate the senescence-induced mitochondrial dysfunction completely, and we identified decreased mitochondrial fission as the potential driving force for increased mitochondrial mass via prevention of mitophagy. Dynamic sensitivity analysis of the model showed the network stabilised at a new late state of cellular senescence. This was characterised by poor network sensitivity, high signalling noise, low cellular energy, high inflammation and permanent cell cycle arrest suggesting an unsatisfactory outcome for treatments aiming to delay or reverse cellular senescence at late time points. Combinatorial targeted interventions are therefore possible for intervening in the cellular pathway to senescence, but in the cases identified here, are only capable of delaying senescence onset., Author Summary Ageing is characterised by a gradual loss of homeostasis within organs, which is known to be driven by the accumulation of senescent cells. Cellular senescence helps prevent cells from becoming cancerous, but their detrimental effect on organ function becomes debilitating once they accumulate. These cells are particularly difficult for the body to remove, and therefore understanding what controls their survival and interactions within the organ is important to combat age-related disease. We present a mathematical model for cellular senescence. This model is used for predicting drug interventions for restoring function in cellular senescence. Whilst these interventions were predicted and tested in vitro, showing improved function and phenotype, none was able to restore cells to a pre-senescent state. Our model includes mitochondria, the power-plants of the cell, and we identify impairment of their turnover coupled with increased mitochondrial biogenesis as a mechanism which explained the long-term failure in drug intervention. Finally, we predict that the system dynamics stabilise in a new late-senescence state, characterised by limited network response to treatment and increased system vulnerability. This study shows formally for the first time the dynamics of cellular senescence as a system network and proves the requirement of early intervention in order to delay cellular senescence.

Published

2014