Selective Neuron Vulnerability in Common and Rare Diseases—Mitochondria in the Focus

Mitochondrial dysfunction is a central feature of neurodegeneration within the central and peripheral nervous system, highlighting a strong dependence on proper mitochondrial function of neurons with especially high energy consumptions. The fitness of mitochondria critically depends on preservation of distinct processes, including the maintenance of their own genome, mitochondrial dynamics, quality control, and Ca2+ handling. These processes appear to be differently affected in common neurodegenerative diseases, such as Alzheimer’s and Parkinson’s disease, as well as in rare neurological disorders, including Huntington’s disease, Amyotrophic Lateral Sclerosis and peripheral neuropathies. Strikingly, particular neuron populations of different morphology and function perish in these diseases, suggesting that cell-type specific factors contribute to the vulnerability to distinct mitochondrial defects. Here we review the disruption of mitochondrial processes in common as well as in rare neurological disorders and its impact on selective neurodegeneration. Understanding discrepancies and commonalities regarding mitochondrial dysfunction as well as individual neuronal demands will help to design new targets and to make use of already established treatments in order to improve treatment of these diseases.

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Critical requirement of SOS1 RAS-GEF function for mitochondrial dynamics, metabolism, and redox homeostasis

Oncogene ◽

10.1038/s41388-021-01886-3 ◽

2021 ◽

Author(s):

Rósula García-Navas ◽

Pilar Liceras-Boillos ◽

Carmela Gómez ◽

Fernando C. Baltanás ◽

Nuria Calzada ◽

...

Keyword(s):

Mitochondrial Dynamics ◽

Redox Homeostasis ◽

Atp Production ◽

Oxidative Energy Metabolism ◽

Ras Activation ◽

Mitochondrial Defects ◽

Critical Requirement ◽

Dynamics And Function ◽

And Function ◽

And Control

AbstractSOS1 ablation causes specific defective phenotypes in MEFs including increased levels of intracellular ROS. We showed that the mitochondria-targeted antioxidant MitoTEMPO restores normal endogenous ROS levels, suggesting predominant involvement of mitochondria in generation of this defective SOS1-dependent phenotype. The absence of SOS1 caused specific alterations of mitochondrial shape, mass, and dynamics accompanied by higher percentage of dysfunctional mitochondria and lower rates of electron transport in comparison to WT or SOS2-KO counterparts. SOS1-deficient MEFs also exhibited specific alterations of respiratory complexes and their assembly into mitochondrial supercomplexes and consistently reduced rates of respiration, glycolysis, and ATP production, together with distinctive patterns of substrate preference for oxidative energy metabolism and dependence on glucose for survival. RASless cells showed defective respiratory/metabolic phenotypes reminiscent of those of SOS1-deficient MEFs, suggesting that the mitochondrial defects of these cells are mechanistically linked to the absence of SOS1-GEF activity on cellular RAS targets. Our observations provide a direct mechanistic link between SOS1 and control of cellular oxidative stress and suggest that SOS1-mediated RAS activation is required for correct mitochondrial dynamics and function.

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Mitochondrial dysfunction and energy deprivation in the mechanism of neurodegeneration

Turkish Journal of Biochemistry ◽

10.1515/tjb-2019-0255 ◽

2019 ◽

Vol 44 (6) ◽

pp. 723-729 ◽

Cited By ~ 2

Author(s):

Andrey Y. Abramov ◽

Plamena R. Angelova

Keyword(s):

Mitochondrial Dysfunction ◽

Mitochondrial Dynamics ◽

Neuronal Loss ◽

High Energy ◽

Neuronal Function ◽

Cellular Functions ◽

Energy Demands ◽

Mitochondrial Toxins ◽

Energy Deprivation ◽

Species Production

Abstract Energy-producing organelles mitochondria are involved in a number of cellular functions. Deregulation of mitochondrial function due to mutations or effects of mitochondrial toxins is proven to be a trigger for diverse pathologies, including neurodegenerative disorders. Despite the extensive research done in the last decades, the mechanisms by which mitochondrial dysfunction leads to neuronal deregulation and cell death have not yet been fully elucidated. Brain cells are specifically dependent on mitochondria due to their high energy demands to maintain neuronal ion gradients and signal transduction, and also, to mediate neuronal health through the processes of mitochondrial calcium homeostasis, mitophagy, mitochondrial reactive oxygen species production and mitochondrial dynamics. Some of these processes have been independently implicated in the mechanism of neuronal loss in neurodegeneration. Moreover, it is increasingly recognised that these processes are interdependent and interact within the mitochondria to ensure proper neuronal function and survival.

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The Role of the Antioxidant Response in Mitochondrial Dysfunction in Degenerative Diseases: Cross-Talk between Antioxidant Defense, Autophagy, and Apoptosis

Oxidative Medicine and Cellular Longevity ◽

10.1155/2019/6392763 ◽

2019 ◽

Vol 2019 ◽

pp. 1-26 ◽

Cited By ~ 30

Author(s):

Michael L.-H. Huang ◽

Shannon Chiang ◽

Danuta S. Kalinowski ◽

Dong-Hun Bae ◽

Sumit Sahni ◽

...

Keyword(s):

Oxidative Stress ◽

Mitochondrial Dysfunction ◽

Mitochondrial Dynamics ◽

Signal Transmission ◽

Antioxidant Response ◽

High Energy ◽

Stress Factors ◽

Degenerative Diseases ◽

Energy Demands ◽

Stress Energy

The mitochondrion is an essential organelle important for the generation of ATP for cellular function. This is especially critical for cells with high energy demands, such as neurons for signal transmission and cardiomyocytes for the continuous mechanical work of the heart. However, deleterious reactive oxygen species are generated as a result of mitochondrial electron transport, requiring a rigorous activation of antioxidative defense in order to maintain homeostatic mitochondrial function. Indeed, recent studies have demonstrated that the dysregulation of antioxidant response leads to mitochondrial dysfunction in human degenerative diseases affecting the nervous system and the heart. In this review, we outline and discuss the mitochondrial and oxidative stress factors causing degenerative diseases, such as Alzheimer’s disease, Parkinson’s disease, amyotrophic lateral sclerosis, Huntington’s disease, and Friedreich’s ataxia. In particular, the pathological involvement of mitochondrial dysfunction in relation to oxidative stress, energy metabolism, mitochondrial dynamics, and cell death will be explored. Understanding the pathology and the development of these diseases has highlighted novel regulators in the homeostatic maintenance of mitochondria. Importantly, this offers potential therapeutic targets in the development of future treatments for these degenerative diseases.

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Molecular Basis for the Therapeutic Effects of Exercise on Mitochondrial Defects

Frontiers in Physiology ◽

10.3389/fphys.2020.615038 ◽

2021 ◽

Vol 11 ◽

Author(s):

Jonathan M. Memme ◽

David A. Hood

Keyword(s):

Skeletal Muscle ◽

Mitochondrial Dysfunction ◽

Muscle Pathology ◽

Therapeutic Effects ◽

Atp Production ◽

Muscle Aging ◽

Mitochondrial Defects ◽

Aging Muscle ◽

Skeletal Muscle Aging ◽

And Function

Mitochondrial dysfunction is common to many organ system disorders, including skeletal muscle. Aging muscle and diseases of muscle are often accompanied by defective mitochondrial ATP production. This manuscript will focus on the pre-clinical evidence supporting the use of regular exercise to improve defective mitochondrial metabolism and function in skeletal muscle, through the stimulation of mitochondrial turnover. Examples from aging muscle, muscle-specific mutations and cancer cachexia will be discussed. We will also examine the effects of exercise on the important mitochondrial regulators PGC-1α, and Parkin, and summarize the effects of exercise to reverse mitochondrial dysfunction (e.g., ROS production, apoptotic susceptibility, cardiolipin synthesis) in muscle pathology. This paper will illustrate the breadth and benefits of exercise to serve as “mitochondrial medicine” with age and disease.

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Genetic Neuropathy Due to Impairments in Mitochondrial Dynamics

Biology ◽

10.3390/biology10040268 ◽

2021 ◽

Vol 10 (4) ◽

pp. 268

Author(s):

Govinda Sharma ◽

Gerald Pfeffer ◽

Timothy E. Shutt

Keyword(s):

Peripheral Neuropathy ◽

Mitochondrial Dysfunction ◽

Energy Demand ◽

Mitochondrial Dynamics ◽

High Energy ◽

Morphological Properties ◽

Peripheral Neurons ◽

Pathogenic Variants ◽

Mitochondrial Motility ◽

Prevailing View

Mitochondria are dynamic organelles capable of fusing, dividing, and moving about the cell. These properties are especially important in neurons, which in addition to high energy demand, have unique morphological properties with long axons. Notably, mitochondrial dysfunction causes a variety of neurological disorders including peripheral neuropathy, which is linked to impaired mitochondrial dynamics. Nonetheless, exactly why peripheral neurons are especially sensitive to impaired mitochondrial dynamics remains somewhat enigmatic. Although the prevailing view is that longer peripheral nerves are more sensitive to the loss of mitochondrial motility, this explanation is insufficient. Here, we review pathogenic variants in proteins mediating mitochondrial fusion, fission and transport that cause peripheral neuropathy. In addition to highlighting other dynamic processes that are impacted in peripheral neuropathies, we focus on impaired mitochondrial quality control as a potential unifying theme for why mitochondrial dysfunction and impairments in mitochondrial dynamics in particular cause peripheral neuropathy.

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Mitochondrial dysfunction in the pathophysiology of renal diseases

AJP Renal Physiology ◽

10.1152/ajprenal.00571.2013 ◽

2014 ◽

Vol 306 (4) ◽

pp. F367-F378 ◽

Cited By ~ 183

Author(s):

Ruochen Che ◽

Yanggang Yuan ◽

Songming Huang ◽

Aihua Zhang

Keyword(s):

Mitochondrial Dna ◽

Mitochondrial Dysfunction ◽

Nuclear Dna ◽

Kidney Diseases ◽

Mitochondrial Dynamics ◽

Critical Role ◽

Kidney Injury ◽

High Energy ◽

Renal Diseases ◽

Glomerular Diseases

Mitochondrial dysfunction has gained recognition as a contributing factor in many diseases. The kidney is a kind of organ with high energy demand, rich in mitochondria. As such, mitochondrial dysfunction in the kidney plays a critical role in the pathogenesis of kidney diseases. Despite the recognized importance mitochondria play in the pathogenesis of the diseases, there is limited understanding of various aspects of mitochondrial biology. This review examines the physiology and pathophysiology of mitochondria. It begins by discussing mitochondrial structure, mitochondrial DNA, mitochondrial reactive oxygen species production, mitochondrial dynamics, and mitophagy, before turning to inherited mitochondrial cytopathies in kidneys (inherited or sporadic mitochondrial DNA or nuclear DNA mutations in genes that affect mitochondrial function). Glomerular diseases, tubular defects, and other renal diseases are then discussed. Next, acquired mitochondrial dysfunction in kidney diseases is discussed, emphasizing the role of mitochondrial dysfunction in the pathogenesis of chronic kidney disease and acute kidney injury, as their prevalence is increasing. Finally, it summarizes the possible beneficial effects of mitochondrial-targeted therapeutic agents for treatment of mitochondrial dysfunction-mediated kidney injury-genetic therapies, antioxidants, thiazolidinediones, sirtuins, and resveratrol-as mitochondrial-based drugs may offer potential treatments for renal diseases.

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From Exosome Glycobiology to Exosome Glycotechnology, the Role of Natural Occurring Polysaccharides

Polysaccharides ◽

10.3390/polysaccharides2020021 ◽

2021 ◽

Vol 2 (2) ◽

pp. 311-338

Author(s):

Giulia Della Rosa ◽

Clarissa Ruggeri ◽

Alessandra Aloisi

Keyword(s):

State Of The Art ◽

Cell Communication ◽

Pathological Conditions ◽

New Findings ◽

Cell Type Specific ◽

New Perspective ◽

And Function ◽

And Personalized Medicine ◽

Innate Ability

Exosomes (EXOs) are nano-sized informative shuttles acting as endogenous mediators of cell-to-cell communication. Their innate ability to target specific cells and deliver functional cargo is recently claimed as a promising theranostic strategy. The glycan profile, actively involved in the EXO biogenesis, release, sorting and function, is highly cell type-specific and frequently altered in pathological conditions. Therefore, the modulation of EXO glyco-composition has recently been considered an attractive tool in the design of novel therapeutics. In addition to the available approaches involving conventional glyco-engineering, soft technology is becoming more and more attractive for better exploiting EXO glycan tasks and optimizing EXO delivery platforms. This review, first, explores the main functions of EXO glycans and associates the potential implications of the reported new findings across the nanomedicine applications. The state-of-the-art of the last decade concerning the role of natural polysaccharides—as targeting molecules and in 3D soft structure manufacture matrices—is then analysed and highlighted, as an advancing EXO biofunction toolkit. The promising results, integrating the biopolymers area to the EXO-based bio-nanofabrication and bio-nanotechnology field, lay the foundation for further investigation and offer a new perspective in drug delivery and personalized medicine progress.

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Molecular Mechanisms behind Inherited Neurodegeneration of the Optic Nerve

Biomolecules ◽

10.3390/biom11040496 ◽

2021 ◽

Vol 11 (4) ◽

pp. 496

Author(s):

Alessandra Maresca ◽

Valerio Carelli

Keyword(s):

Optic Nerve ◽

Mitochondrial Dysfunction ◽

Molecular Mechanisms ◽

Ganglion Cells ◽

Mitochondrial Dynamics ◽

Unmet Need ◽

Deep Understanding ◽

Genetic Landscape ◽

Innovative Therapies ◽

Energy Dependent

Inherited neurodegeneration of the optic nerve is a paradigm in neurology, as many forms of isolated or syndromic optic atrophy are encountered in clinical practice. The retinal ganglion cells originate the axons that form the optic nerve. They are particularly vulnerable to mitochondrial dysfunction, as they present a peculiar cellular architecture, with axons that are not myelinated for a long intra-retinal segment, thus, very energy dependent. The genetic landscape of causative mutations and genes greatly enlarged in the last decade, pointing to common pathways. These mostly imply mitochondrial dysfunction, which leads to a similar outcome in terms of neurodegeneration. We here critically review these pathways, which include (1) complex I-related oxidative phosphorylation (OXPHOS) dysfunction, (2) mitochondrial dynamics, and (3) endoplasmic reticulum-mitochondrial inter-organellar crosstalk. These major pathogenic mechanisms are in turn interconnected and represent the target for therapeutic strategies. Thus, their deep understanding is the basis to set and test new effective therapies, an urgent unmet need for these patients. New tools are now available to capture all interlinked mechanistic intricacies for the pathogenesis of optic nerve neurodegeneration, casting hope for innovative therapies to be rapidly transferred into the clinic and effectively cure inherited optic neuropathies.

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The Interplay between Mitochondrial Morphology and Myomitokines in Aging Sarcopenia

International Journal of Molecular Sciences ◽

10.3390/ijms22010091 ◽

2020 ◽

Vol 22 (1) ◽

pp. 91

Author(s):

Vanina Romanello

Keyword(s):

Mitochondrial Dysfunction ◽

Poor Quality ◽

Whole Body ◽

Fibroblast Growth Factor 21 ◽

Mitochondrial Morphology ◽

Mass Force ◽

Major Mechanism ◽

Muscle Aging ◽

And Function

Sarcopenia is a chronic disease characterized by the progressive loss of skeletal muscle mass, force, and function during aging. It is an emerging public problem associated with poor quality of life, disability, frailty, and high mortality. A decline in mitochondria quality control pathways constitutes a major mechanism driving aging sarcopenia, causing abnormal organelle accumulation over a lifetime. The resulting mitochondrial dysfunction in sarcopenic muscles feedbacks systemically by releasing the myomitokines fibroblast growth factor 21 (FGF21) and growth and differentiation factor 15 (GDF15), influencing the whole-body homeostasis and dictating healthy or unhealthy aging. This review describes the principal pathways controlling mitochondrial quality, many of which are potential therapeutic targets against muscle aging, and the connection between mitochondrial dysfunction and the myomitokines FGF21 and GDF15 in the pathogenesis of aging sarcopenia.

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Impact of Aldosterone on the Failing Myocardium: Insights from Mitochondria and Adrenergic Receptors Signaling and Function

Cells ◽

10.3390/cells10061552 ◽

2021 ◽

Vol 10 (6) ◽

pp. 1552

Author(s):

Mariona Guitart-Mampel ◽

Pedro Urquiza ◽

Jordana I. Borges ◽

Anastasios Lymperopoulos ◽

Maria E. Solesio

Keyword(s):

Mitochondrial Dysfunction ◽

G Protein ◽

Adrenergic Receptor ◽

Cellular Level ◽

Cardiac Physiology ◽

Failing Heart ◽

Receptor Kinases ◽

And Function ◽

The Impact ◽

G Protein Coupled

The mineralocorticoid aldosterone regulates electrolyte and blood volume homeostasis, but it also adversely modulates the structure and function of the chronically failing heart, through its elevated production in chronic human post-myocardial infarction (MI) heart failure (HF). By activating the mineralocorticoid receptor (MR), a ligand-regulated transcription factor, aldosterone promotes inflammation and fibrosis of the heart, while increasing oxidative stress, ultimately induding mitochondrial dysfunction in the failing myocardium. To reduce morbidity and mortality in advanced stage HF, MR antagonist drugs, such as spironolactone and eplerenone, are used. In addition to the MR, aldosterone can bind and stimulate other receptors, such as the plasma membrane-residing G protein-coupled estrogen receptor (GPER), further complicating it signaling properties in the myocardium. Given the salient role that adrenergic receptor (ARs)—particularly βARs—play in cardiac physiology and pathology, unsurprisingly, that part of the impact of aldosterone on the failing heart is mediated by its effects on the signaling and function of these receptors. Aldosterone can significantly precipitate the well-documented derangement of cardiac AR signaling and impairment of AR function, critically underlying chronic human HF. One of the main consequences of HF in mammalian models at the cellular level is the presence of mitochondrial dysfunction. As such, preventing mitochondrial dysfunction could be a valid pharmacological target in this condition. This review summarizes the current experimental evidence for this aldosterone/AR crosstalk in both the healthy and failing heart, and the impact of mitochondrial dysfunction in HF. Recent findings from signaling studies focusing on MR and AR crosstalk via non-conventional signaling of molecules that normally terminate the signaling of ARs in the heart, i.e., the G protein-coupled receptor-kinases (GRKs), are also highlighted.

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