The Role of Mitochondrial Dysfunction in Neurodegenerative Proteinopathies and Aging.

Ocampo, Alejandro

13 January 2012

Age-related neurodegenerative proteinophaties, including polyglutamine (polyQ) diseases such as Huntington’s disease, are a group of disorders in which a single protein or a set of proteins misfold and aggregate resulting in a progressive and selective loss of anatomically or physiologically related neuronal systems. Despite evidence showing a clear relationship between mitochondrial dysfunction, aging and neurodegenerative proteinophaties, the extent of the mitochondrial respiratory chain deficits, the involvement of mitochondrial dysfunction and the mechanisms responsible for these processes are largely unknown. Using yeast models of cellular aging and polyQ disorders we show that mitochondrial dysfunction is an important contributor to the process of aging and age-related neurodegenerative diseases. Preserving mitochondrial function is essential for standard wild-type aging. Enhancement of mitochondrial biogenesis ameliorates polyQ cytotoxicity and is a required component of interventions that retard the aging process.

Mitochondrial Respiration

Yeast Models

Neurodegeneration

Aging

The Effect of Cocoa Flavanols on β-Cell Mass and Function

Rowley, Thomas John

01 August 2017

A hallmark of type 2 diabetes (T2D) is β-cell dysfunction and the eventual loss of functional β-cell mass. Therefore, mechanisms that improve or preserve β-cell function could be used to improve the quality of life of individuals with T2D. Studies have shown that monomeric, oligomeric and polymeric cocoa flavanols have different effects on obesity, insulin resistance and glucose tolerance. We hypothesized that these cocoa flavanols may have beneficial effects on β-cell function. INS-1 832/13 derived β-cells and primary rat islets cultured with a monomeric catechin-rich cocoa flavanol fraction demonstrated enhanced glucose-stimulated insulin secretion, while cells cultured with total cocoa extract, oligomeric, or polymeric procyanidin-rich fractions demonstrated no improvement. The increased glucose-stimulated insulin secretion in the presence of the monomeric catechin-rich fraction corresponded with enhanced mitochondrial respiration, suggesting improvements in β-cell fuel utilization. Mitochondrial complex III, IV and V components were upregulated after culture with the monomer-rich fraction, corresponding with increased cellular ATP production. The monomer-rich fraction improved cellular redox state and increased glutathione concentration, which corresponds with Nrf2 nuclear localization and expression of Nrf2 target genes, including NRF-1 and GABPA, essential genes for increasing mitochondrial function. We propose a model by which monomeric cocoa catechins improve the cellular redox state, resulting in Nrf2 nuclear migration and upregulation of genes critical for mitochondrial respiration, and, ultimately, enhanced glucose-stimulated insulin secretion and β-cell function. These results suggest a mechanism by which monomeric cocoa catechins exert their effects as an effective complementary strategy to benefit T2D patients.

Nutrition

Osteocyte secreted factors regulate muscle function and metabolism

Huang, Tim

09 February 2022

Muscle and bone are two tightly connected systems on both an anatomic and functional level. Bone and muscle diseases like osteoporosis and sarcopenia have been found to show an association with each other. These two organs form a complex musculoskeletal system and have been found to secrete hormone-like factors called myokines and osteokines that can influence and affect each other. Indeed, the crosstalk between bone and muscle plays an important role during development and aging. For example, myostatin, also known as growth differentiation factor 8 (GDF-8), a cytokine secreted by muscle cells, is a negative regulator of muscle and bone mass. Over expression or loss of function mutations of myostatin in mice have led to muscle atrophy and hypertrophy respectively. Interleukin-6 (IL-6) is expressed abundantly in muscle and is released during exercise and muscle contraction. It has been shown to increase osteoclast (bone cells that break down bone) formation. In the bone, osteocytes make up the majority of all cells and are terminally differentiated osteoblasts. Osteocytes control the balance between bone resorption by osteoclasts and bone formation by osteoblasts. Osteocytes are also known to express receptors for various hormones, including parathyroid hormone (PTH) receptor. As osteocytes comprise more than 90% of all bone cells in adult bone, we hypothesize that osteocytes might secrete factors capable of controlling muscle cells and that PTH might control the expression of these factors. To test this hypothesis, we used an osteocytic cell line Ocy454-12H as well as C2C12 cells, which are a well-accepted model of myocyte differentiation. To investigate the effects of osteocyte-derived factors on myocytes, C2C12 cells were treated with conditioned medium (CM) from osteocytes during specific times. We found that during C2C12 proliferation, when compared to the αMEM control, mRNA expression of MSS51 was decreased for both cells that were treated with CM of osteocytes treated with PTH (PTH CM, p=0.00570) and cells that were treated with CM of osteocytes treated with vehicle only (CM control, p=0.0178). During C2C12 differentiation, mRNA expression of myostatin was significantly (p=0.0387) decreased in cells that were treated with PTH CM compared to cells that were treated with CM control. Considering the importance of mitochondrial respiration in cells, we next analyzed oxygen consumption and metabolism in C2C12 myocytes treated with CM from Ocy454-12H using a Seahorse XF Cell Mito Stress Test. Metabolic analysis revealed that during proliferation, PTH CM led to higher basal respiration, ATP production, and coupling efficiency in C2C12 cells while lowering spare respiratory capacity. In differentiation, there was a trend in which CM control would cause a decrease across all parameters compared to the control group and the PTH CM group. Interestingly, PTH CM-treated C2C12 cells were shown to have a higher oxygen consumption rate (OCR) than the CM-control treated group and would have similar values to that of the control group (C2C12 not treated with CM). Taken together these results suggest that osteocytes might control muscle cells differentiation and metabolism via a PTH-mediated signaling pathway.

Biology

C2C12

Gene expression

Mitochondrial respiration

Musculoskeletal

Osteocytes

PTH

Dietary Selenium Supplementation: Effects on Neurodegeneration Following Traumatic Brain and Spinal Cord Injury

Crowdus Meyer, Carolyn A.

01 January 2015

Traumatic brain and spinal cord injury continue to be substantial clinical problems with few available treatment strategies. Individuals who are at a greater risk for sustaining a central nervous system (CNS) injury, such as professional athletes and military personnel, may benefit from a prophylactic supplement that would intervene in the neurodegenerative pathways immediately following injury. The high demand for selenium within the central nervous system, as well as the synthesis of selenoproteins by neurons and astrocytes suggests a critical role of selenium within the brain and spinal cord. Studies were designed to test the efficacy of enriched dietary selenium status in providing neuroprotective benefits in rodent models of spinal cord and traumatic brain injury. Levels of selenium storage within the CNS are increased relative to the amount of selenium present in the diet, indicating that selenium compounds effectively cross the blood brain barrier. In a model of moderate severity spinal cord contusion injury, dietary selenium supplementation reduced the number of days until recovery of independent bladder function following injury. These benefits did not translate to improvements in locomotor function during open field testing or reduction in overall lesion volume in the injured animal groups. Examination of gene expression changes 24 hours after spinal cord injury revealed that dietary selenium enrichment increased expression of genes involved in DNA repair, mitochondrial respiration, and transcriptional regulation. By expanding the scope of these studies to include models of traumatic brain injury, these data show the importance of selenium in the cortex as well. In particular, when compared to diets deficient in selenium, higher levels of dietary selenium improve spatial memory performance and mitochondrial respiration. The results of this dietary study show modest improvements following both traumatic brain and spinal cord injury and suggest that while selenium enrichment may not have a profound effect on the secondary injury cascade immediately following injury, the presence of adequate dietary selenium is critical for mitochondrial respiration. Together the results of these studies suggest that dietary supplementation may play a subtle role in injury mechanisms within the CNS and warrant further investigation.

Brain Injury

Spinal Cord Injury

Selenium

Gene Expression

Mitochondrial Respiration

Nervous System Diseases

The Relationship between Chlorophyll a Fluorescence and the Lower Oxygen Limit in Higher Plants

Wright, Harrison

09 June 2011

The lower oxygen limit (LOL) in plants marks the oxygen (O2) level where the metabolism shifts from being predominantly aerobic to anaerobic; recent work has shown that respiratory-based indicators of this metabolic shift are well-correlated with changes in chlorophyll a fluorescence signals. The physiological and biochemical changes at the root of this relationship have not been well-described in the literature. The processes involved are spatially separated: chlorophyll fluorescence is associated with the lightdependent reactions and emanates from the chloroplasts whereas aerobic respiration and fermentation occurs in the mitochondria and cytosol, respectively. Evidences outlined in this thesis are used to suggest the mechanistic link between these three regions of the cell is a fluid exchange of cellular reductant. When mitochondrial respiration is inhibited as a result of inadequate O2, used as a terminal electron acceptor, glycolytic reductant in the form of NADH accumulates in the cytosol. Reductant imbalances between the cytosol and organelles can be adjusted indirectly using translocators. Excess chloroplastic reductant is used to reduce the plastoquinone (PQ) pool via NADPH-dehydrogenase, a component of the chlororespiratory pathway, effectively decreasing the photochemical quenching (qP) capacity thereby inducing a switch from minimum fluorescence (Fo) to a higher relative fluorescence (F) value where qP < 1. Subjecting dark-adapted photosystems to low-intensity light increased Fo to a slightly higher F value due to a lightinduced reduction of the oxidized PQ pool when the O2 was above the LOL, but decreased F as a result of a PSI-driven oxidation of the already over-reduced PQ pool when the O2 was below the LOL. Low O2 was also shown to increase violaxanthin deepoxidation and non-photochemical quenching (qN), likely a reflection of the overreduced state of the photosystems and associated pH decrease. Dynamic controlled atmosphere (DCA) is a fluorescence-based controlled atmosphere (CA) system that sets the optimum atmosphere for fruits and vegetables based on a product’s fluorescence response. Experiments in this thesis on the relationship between O2, temperature, light, metabolism, pigmentation and chlorophyll fluorescence were used to interpret the physiology behind fluorescence changes, suggest improved DCA techniques and outline potentially profitable avenues for future research.

Chlororespiration

Fermentation

Xanthophyll cycle

Lower oxygen limit

Chlorophyll fluorescence

Chlorofermentation

Chlorophyll fluorescence

Mitochondrial respiration

Reductant

Estudo dos efeitos da radioterapia no tecido cardíaco e sua associação com o metabolismo energético / Study of the effects of radiation therapy in cardiac tissue and its association with energy metabolism

Raquel Gomes Siqueira

28 October 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Durante o tratamento radioterápico para tumores localizados na região torácica, parte do coração frequentemente é incluída no campo de tratamento e pode receber doses de radiação ionizante, significativas em relação à terapêutica. A irradiação do coração é capaz de causar importantes complicações cardíacas ao paciente, caracterizadas por alterações funcionais progressivas cerca de 10 a 20 anos após a exposição do órgão. Devido ao seu alto grau de contração e grande consumo energético, o tecido cardíaco é altamente dependente do metabolismo oxidativo que ocorre nas mitocôndrias. Danos as estas organelas podem levar ao decréscimo da produção de energia, tendo um impacto direto sobre a performance cardíaca. Ainda, ao interagir com as células, a radiação ionizante pode gerar uma série de eventos bioquímicos que conduzem a uma resposta celular complexa, em que muitas proteínas parecem estar envolvidas. Tendo em vista tais conhecimentos, o objetivo do estudo foi avaliar o aspecto ultraestrutural do tecido cardíaco, a bioenergética mitocondrial e a expressão diferencial de proteínas após irradiação. Os ensaios foram realizados em amostras de tecido cardíaco de ratos Wistar irradiados com dose única de 20 Gy direcionada ao coração. As análise tiveram início 4 e 32 semanas após irradiação. A análise ultraestrutural foi realizada através de microscopia eletrônica de transmissão. A respiração mitocondrial foi mensurada em oxígrafo, a partir das taxas de consumo de oxigênio pelas fibras cardíacas. A identificação de proteínas diferencialmente expressas foi investigada através de duas técnicas proteômicas: 2D-DIGE (2-D Fluorescence Difference Gel Electrophoresis) e uma abordagem label-free seguida de espectrometria de massas. Os resultados mostraram que os efeitos tardios da radiação incluem a degeneração das mitocôndrias e das unidades contráteis do tecido cardíaco, disfunções na cadeia respiratória mitocondrial e expressão diferencial de proteínas envolvidas no metabolismo energético de carboidratos, lipídeos e da fosfocreatina. De forma geral, o estudo mostrou que a irradiação cardíaca prejudica o processo de síntese energética, conduzindo a um déficit da taxa respiratória mitocondrial como efeito tardio. Tal evento pode culminar em disfunções mecânicas no coração, caracterizando o desenvolvimento de doenças cardíacas radioinduzidas. / During radiotherapy for tumors located at toracic region, part of the heart is often included in the treatment field and may receive a significant ionizing radiation dose comparing to the therapeutics. Heart irradiation is able to cause substantial cardiac complications to patient, characterized by functional progressive changes from 10 to 20 years after the exposure of the organ. Because of its high level of contraction and large energetic consumption, cardiac tissue is highly depending on oxidative metabolism which happens at mitochondrias. Damage to these organelles can lead to decreased energy production, having a direct impact on cardiac performance. Even when interacting with cells, ionizing radiation can generate a series of biochemical events that lead to a complex cellular response, in many proteins seem to be involved. Given this knowledge, the aim of the study was to evaluate the ultrastructural appearance of cardiac tissue, mitochondrial bioenergetics and differential expression of proteins after irradiation. The tests were performed on samples of cardiac tissue of rats irradiated with single dose of 20 Gy directed to the heart. The analysis started 4 to 32 weeks after irradiation. The ultrastructural analysis was performed by transmission electron microscopy. Mitochondrial respiration was measured in oxigraph from rates of oxygen consumption by cardiac fibers. The identification of differentially expressed proteins was investigated using two proteomic techniques: 2D-DIGE (2-D Fluorescence Difference Gel Electrophoresis) and a label-free approach followed by mass spectrometry. The results showed that the late effects of radiation include degeneration of mitochondria and contractile units of cardiac tissue, dysfunction in the mitochondrial respiratory chain and differential expression of proteins involved in energy metabolism of carbohydrates, lipids and phosphocreatine. In general, the study showed that the cardiac irradiation damages the process of synthesis energy, leading to a deficit in mitochondrial respiratory rate as late effect. Such event may result in mechanical dysfunction in the heart, characterizing the development of radiation-induced heart disease.

Doença cardíaca radioinduzida

Radioterapia

Respiração mitocondrial

Proteoma

Radiotherapy

Radioinduced cardiac disease

Mitochondrial respiration

Proteome

BIOFISICA

Estudo dos efeitos da radioterapia no tecido cardíaco e sua associação com o metabolismo energético / Study of the effects of radiation therapy in cardiac tissue and its association with energy metabolism

Raquel Gomes Siqueira

28 October 2013

Coordenação de Aperfeiçoamento de Pessoal de Nível Superior / Durante o tratamento radioterápico para tumores localizados na região torácica, parte do coração frequentemente é incluída no campo de tratamento e pode receber doses de radiação ionizante, significativas em relação à terapêutica. A irradiação do coração é capaz de causar importantes complicações cardíacas ao paciente, caracterizadas por alterações funcionais progressivas cerca de 10 a 20 anos após a exposição do órgão. Devido ao seu alto grau de contração e grande consumo energético, o tecido cardíaco é altamente dependente do metabolismo oxidativo que ocorre nas mitocôndrias. Danos as estas organelas podem levar ao decréscimo da produção de energia, tendo um impacto direto sobre a performance cardíaca. Ainda, ao interagir com as células, a radiação ionizante pode gerar uma série de eventos bioquímicos que conduzem a uma resposta celular complexa, em que muitas proteínas parecem estar envolvidas. Tendo em vista tais conhecimentos, o objetivo do estudo foi avaliar o aspecto ultraestrutural do tecido cardíaco, a bioenergética mitocondrial e a expressão diferencial de proteínas após irradiação. Os ensaios foram realizados em amostras de tecido cardíaco de ratos Wistar irradiados com dose única de 20 Gy direcionada ao coração. As análise tiveram início 4 e 32 semanas após irradiação. A análise ultraestrutural foi realizada através de microscopia eletrônica de transmissão. A respiração mitocondrial foi mensurada em oxígrafo, a partir das taxas de consumo de oxigênio pelas fibras cardíacas. A identificação de proteínas diferencialmente expressas foi investigada através de duas técnicas proteômicas: 2D-DIGE (2-D Fluorescence Difference Gel Electrophoresis) e uma abordagem label-free seguida de espectrometria de massas. Os resultados mostraram que os efeitos tardios da radiação incluem a degeneração das mitocôndrias e das unidades contráteis do tecido cardíaco, disfunções na cadeia respiratória mitocondrial e expressão diferencial de proteínas envolvidas no metabolismo energético de carboidratos, lipídeos e da fosfocreatina. De forma geral, o estudo mostrou que a irradiação cardíaca prejudica o processo de síntese energética, conduzindo a um déficit da taxa respiratória mitocondrial como efeito tardio. Tal evento pode culminar em disfunções mecânicas no coração, caracterizando o desenvolvimento de doenças cardíacas radioinduzidas. / During radiotherapy for tumors located at toracic region, part of the heart is often included in the treatment field and may receive a significant ionizing radiation dose comparing to the therapeutics. Heart irradiation is able to cause substantial cardiac complications to patient, characterized by functional progressive changes from 10 to 20 years after the exposure of the organ. Because of its high level of contraction and large energetic consumption, cardiac tissue is highly depending on oxidative metabolism which happens at mitochondrias. Damage to these organelles can lead to decreased energy production, having a direct impact on cardiac performance. Even when interacting with cells, ionizing radiation can generate a series of biochemical events that lead to a complex cellular response, in many proteins seem to be involved. Given this knowledge, the aim of the study was to evaluate the ultrastructural appearance of cardiac tissue, mitochondrial bioenergetics and differential expression of proteins after irradiation. The tests were performed on samples of cardiac tissue of rats irradiated with single dose of 20 Gy directed to the heart. The analysis started 4 to 32 weeks after irradiation. The ultrastructural analysis was performed by transmission electron microscopy. Mitochondrial respiration was measured in oxigraph from rates of oxygen consumption by cardiac fibers. The identification of differentially expressed proteins was investigated using two proteomic techniques: 2D-DIGE (2-D Fluorescence Difference Gel Electrophoresis) and a label-free approach followed by mass spectrometry. The results showed that the late effects of radiation include degeneration of mitochondria and contractile units of cardiac tissue, dysfunction in the mitochondrial respiratory chain and differential expression of proteins involved in energy metabolism of carbohydrates, lipids and phosphocreatine. In general, the study showed that the cardiac irradiation damages the process of synthesis energy, leading to a deficit in mitochondrial respiratory rate as late effect. Such event may result in mechanical dysfunction in the heart, characterizing the development of radiation-induced heart disease.

Doença cardíaca radioinduzida

Radioterapia

Respiração mitocondrial

Proteoma

Radiotherapy

Radioinduced cardiac disease

Mitochondrial respiration

Proteome

BIOFISICA

Analysis of mutants impaired for respiratory growth in the model photosynthetic alga, Chlamydomonas reinhardtii

Castonguay, Andrew David

01 October 2021

No description available.

Genetics

Biology

Biochemistry

Microbiology

Deep-Tissue Heating as a Therapeutic Intervention to Prevent Skeletal Muscle Atrophy in Humans

Hafen, Paul S

01 July 2018

Skeletal muscle is a highly adaptable tissue that comprises approximately 40% of total body weight while accounting for up to 90% of whole-body oxygen consumption and energy expenditure during exercise. The loss of skeletal muscle protein and subsequent decrease in muscle mass (atrophy) that accompanies disuse results primarily from a decrease in intracellular protein synthesis combined with an increase in proteolytic activity. Interestingly, these processes of skeletal muscle atrophy are amplified by changes in mitochondrial capacity, with evidence suggesting that the maintenance of mitochondria during periods of disuse protects skeletal muscle against atrophy. Remarkably, rodents with denervated muscle are protected against muscle atrophy following whole-body heat stress. The mechanism of protection appears to be tied to the observed increases in heat shock protein (HSP) and PGC-1α, which accompany the heat stress. Without any published observations as to whether such heat-induced protection against muscle atrophy would translate to human muscle, the aim of this project was to determine the extent to which deep tissue heating (via pulsed shortwave diathermy) might provide protection against skeletal muscle atrophy.

muscle atrophy

human skeletal muscle

immobilization

heat stress

heat shock

mitochondrial respiration

Life Sciences

HIF-1α in the Heart: Remodeling Nucleotide Metabolism

Wu, Joe, Bond, Cherie, Chen, Ping, Chen, Minghua, Li, Ying, Shohet, Ralph V., Wright, Gary

01 May 2015

These studies have examined the effect of hypoxia inducible factor 1α (HIF-1α) on nucleotide metabolism in the ischemic heart using a genetic mouse model with heart-specific and regulated expression of a stable form of HIF-1α. We find that AMP deaminase (AMPD), the entry point of the purine nucleotide cycle (PNC), is induced by HIF-1α at the level of mRNA, protein, and activity. AMP that accumulates during ischemia can be metabolized to adenosine by 5'-nucleotidase or to IMP by AMPD. Consistent with the finding of AMPD induction, adenosine accumulation during ischemia was much attenuated in HIF-1α-expressing hearts. Further investigation of nucleotide salvage enzymes found that hypoxanthine phosphoribosyl transferase (HPRT) is also upregulated in HIF-1α-expressing hearts. Treatment of hearts with an inhibitor of the PNC, hadacidin, hastens the fall of the adenylate energy charge during ischemia and the accumulation of AMP. The results provide new insight into the role of the PNC in the heart, especially as it relates to ischemia, and indicate that HIF-1α regulates nucleotide metabolism as a compensatory response to hypoxia.

cardioprotection

mitochondrial respiration

nucleotide salvage

purine nucleotide cycle

Biomedical Sciences

Environmental Health