Your search keyword '"Szweda, Luke I."' showing total 68 results

1. Mitochondrial superoxide production and respiratory activity: Biphasic response to ischemic duration

Author

Matsuzaki, Satoshi, Szweda, Luke I., and Humphries, Kenneth M.

Subjects

*SUPEROXIDES, *MITOCHONDRIA, *ISCHEMIA, *ELECTRON transport, *FREE radicals, *NAD(P)H dehydrogenases, *RESPIRATION

Abstract

Abstract: Long bouts of ischemia are associated with electron transport chain deficits and increases in free radical production. In contrast, little is known regarding the effect of brief ischemia on mitochondrial function and free radical production. This study was undertaken to examine the relationship between the duration of ischemia, effects upon electron transport chain activities, and the mitochondrial production of free radicals. Rat hearts were subjected to increasing ischemic durations, mitochondria were isolated, and superoxide production and electron transport chain activities were measured. Results indicate that even brief ischemic durations induced a significant increase in superoxide production. This rate was maintained with ischemic durations less than 15min, and then increased further with longer ischemic times. Mechanistically, brief ischemia was accompanied by an increase in NADH oxidase activity, reflected by a specific increase in complex IV activity. In contrast, longer ischemic durations were accompanied by a decrease in NADH oxidase activity, reflected by deficits in complexes I and IV activities. [Copyright &y& Elsevier]

Published

2009

2. Inhibition of Complex I by Ca2 Reduces Electron Transport Activity and the Rate of Superoxide Anion Production in Cardiac Submitochondrial Particles.

Author

Matsuzaki, Satoshi and Szweda, Luke I.

Subjects

*ELECTRON transport, *LABORATORY rats, *COMPLEX compounds, *CHEMICAL inhibitors, *BIOCHEMISTRY

Abstract

Declines in the rate of mitochondrial electron transport and subsequent increases in the half-life of reduced components of the electron transport chain can stimulate O2·- formation. We have previously shown that, in solubilized cardiac mitochondria, Ca2+ mediates reversible free radical-induced inhibition of complex I. In the study presented here, submitochondrial particles prepared from rat heart were utilized to determine the effects of Ca2+ on specific components of the respiratory chain and on the rates of electron transport and O2·- production. The results indicate that complex I is inactivated when subrnitochondrial particles are treated with Ca2+. Inactivation was specific to complex I with no alterations in the activities of other electron transport chain complexes. Complex I inactivation by Ca2+ resulted in the reduction of NADH-supported electron transport activity. In contrast to the majority of electron transport chain inhibitors, Ca2+ suppressed the rate of O2·- production. In addition, while inhibition of complex III stimulated O2·- production, Ca2+ reduced the relative rate of O2·- production, consistent with the magnitude of complex I inhibition. Evidence indicates that complex I is the primary source of O2·- released from this preparation of submitochondrial particles. Ca2+ therefore inhibits electron transport upstream of site-(s) of free radical production. This may represent a means of limiting O2·- production by a compromised electron transport chain. [ABSTRACT FROM AUTHOR]

Published

2007

3. Preconditioning prevents loss in mitochondrial function and release of cytochrome c during prolonged cardiac ischemia/reperfusion

Author

Lundberg, Kathleen C. and Szweda, Luke I.

Subjects

*ISCHEMIA, *APOPTOSIS, *DEHYDROGENASES, *BLOOD circulation disorders

Abstract

Abstract: Loss in mitochondrial function and induction of mitochondrial-mediated apoptosis occur as a result of cardiac ischemia/reperfusion. Brief and repeated cycles of ischemia/reperfusion, termed ischemic preconditioning, prevent or minimize contractile dysfunction and apoptosis associated with prolonged episodes of cardiac ischemia and reperfusion. The effects of preconditioning on various indices of ischemia/reperfusion-induced alterations in mitochondrial function and structure were therefore explored. Utilizing an in vivo rat model data is provided indicating that preconditioning completely prevents cardiac ischemia/reperfusion-induced: (1) loss in the activity of the redox sensitive Krebs cycle enzyme α-ketoglutarate dehydrogenase; (2) declines in NADH-linked ADP-dependent mitochondrial respiration; (3) insertion of the pro-apoptotic Bcl-2 protein Bax into the mitochondrial membrane; and (4) release of cytochrome c into the cytosol. The results of the current study indicate that preconditioning prevents specific alterations in mitochondrial structure and function that are known to impact cellular viability and provide insight into the collective benefits of preconditioning. [Copyright &y& Elsevier]

Published

2006

4. Mitochondrial protein oxidation and degradation in response to oxidative stress and aging

Author

Bulteau, Anne-Laure, Szweda, Luke I., and Friguet, Bertrand

Subjects

*MITOCHONDRIA, *ORGANELLES, *AGING, *PROTEINS

Abstract

Abstract: Mitochondria are a major source of intracellular reactive oxygen species (ROS), the production of which increases with age. These organelles are also targets of oxidative damage. The deleterious effects of ROS may be responsible for impairment of mitochondrial function observed during various pathophysiological states associated with oxidative stress and aging. An important factor for protein maintenance in the presence of oxidative stress is enzymatic reversal of oxidative modifications and/or protein degradation. Failure of these protein maintenance systems is likely a critical component of the aging process. Mitochondrial matrix proteins are sensitive to oxidative inactivation and oxidized proteins are known to accumulate during aging. The ATP-stimulated mitochondrial Lon protease is a highly conserved protease found in prokaryotes and the mitochondrial compartment of eukaryotes and is believed to play an important role in the degradation of oxidized mitochondrial matrix proteins. Age-dependent declines in the activity and regulation of this proteolytic system may underlie accumulation of oxidatively modified and dysfunctional protein and loss in mitochondrial viability. [Copyright &y& Elsevier]

Published

2006

5. Translocation of δPKC to mitochondria during cardiac reperfusion enhances superoxide anion production and induces loss in mitochondrial function

Author

Churchill, Eric N. and Szweda, Luke I.

Subjects

*PROTOPLASM, *MITOCHONDRIA, *PROTEIN kinase C, *CELL death

Abstract

Abstract: Activation of the δ-isoform of protein kinase C (δPKC) by certain conditions of oxidative stress results in translocation of the kinase to the mitochondria leading to release of cytochrome c and the induction of apoptosis. In the current study, the effects of myocardial reperfusion-induced δPKC translocation on mitochondrial function were assessed. Mitochondria isolated from hearts that had undergone ischemia (30min) followed by reperfusion (15min) exhibited a significant increase in the rate of superoxide anion (O2 − ) generation. This was associated with the translocation of δPKC to the mitochondria within the first 5min of reperfusion. δPKC translocation occurred exclusively during reperfusion and could be mimicked by infusion of intact hearts with H2O2 suggesting redox-dependent activation during reperfusion. Infusion of a peptide inhibitor (δV1-1) specific to the δ-isoform of PKC significantly reduced reperfusion-induced increases in mitochondrial O2 − generation. Finally, the decline in mitochondrial respiratory activity evident upon prolonged reperfusion (120min) was completely prevented by inhibition of δPKC translocation. Thus, δPKC represents a cytosolic redox-sensitive molecule that plays an important role in amplification of O2 − production and subsequent declines in mitochondrial function during reperfusion. [Copyright &y& Elsevier]

Published

2005

6. Initiation of mitochondrial-mediated apoptosis during cardiac reperfusion

Author

Lundberg, Kathleen Corrigan and Szweda, Luke I.

Subjects

*MITOCHONDRIA, *ORGANELLES, *APOPTOSIS, *REPERFUSION injury

Abstract

Reperfusion of myocardial tissue can result in programmed cell death. Nevertheless, relatively little information exists concerning pathways initiated in vivo that ultimately commit cardiac cells to apoptosis during ischemia/reperfusion. The goal of the present study was to determine whether mitochondrial-mediated mechanisms of apoptosis are initiated during in vivo cardiac ischemia/reperfusion. We provide evidence that the content of cytochrome c in the cytosol increases exclusively during reperfusion. Over the same time interval Bax, a pro-apoptotic protein implicated in release of cytochrome c from mitochondria, was found to disappear from cytosolic extracts. This was associated with the appearance of tightly associated Bax in the mitochondrial fraction. Cytochrome c from reperfused cytosolic extracts is present as a high molecular weight oligomer consistent with formation of the apoptosome. In addition, pro-caspase-9 was found to disappear exclusively during reperfusion. Therefore, the results of the current study indicate that the mitochondrial-mediated pathway of apoptosis is initiated as a result of in vivo cardiac ischemia/reperfusion. [Copyright &y& Elsevier]

Published

2004

7. Age-Dependent Declines in Proteasome Activity in the Heart

Author

Bulteau, Anne-Laure, Szweda, Luke I., and Friguet, Bertrand

Subjects

*PROTEINS, HEART aging

Abstract

The proteasome is a major intracellular proteolytic system involved in the removal of oxidized and ubiquitinated protein and the induction of certain stress response pathways. In this study, age-dependent alterations in proteasome function were investigated to gain insight into potential factors which contribute to increased susceptibility to various forms of heart disease during aging. Proteasome activity in cellular extracts prepared from Fisher 344 rat hearts was found to decrease with age. These declines in activity were associated with a decreased 20S proteasome content and loss of specific activities. As determined by two-dimensional gel electrophoresis of purified 20S proteasome, the distribution and silver staining intensities of enzyme subunits were found to vary with age, suggesting that alterations in proteasome subunit composition and/or structure are involved in age-related declines in proteasome activity. In addition, age-dependent increases in the levels of oxidized and ubiquitinated proteins, known substrates of the proteasome, were observed. Thus, loss in proteasome function may impair the ability of myocytes to mount an appropriate response to stress, thereby enhancing the susceptibility of the aging heart to cardiovascular disease. [Copyright &y& Elsevier]

Published

2002

8. Selective Inactivation of alpha-Ketoglutarate Dehydrogenase and Pyruvate Dehydrogenase:...

Author

Humphries, Kenneth M. and Szweda, Luke I.

Subjects

*DEHYDROGENASES, *PYRUVATES

Abstract

Presents information on a study which examines the effects of 4-hydroxyl-2-nonenal (HNE) on purified ketoglutarate dehydrogenase (KGDH) and pyruvate dehydrogenase (PDH). Methods of the study; Importance of determining the selectivity of HNE inactivation; Effects of HNE on mitochondrial enzyme activities; Discussion of the study.

Published

1998

9. Declines in mitochondrial respiration during cardiac reperfusion: Age-dependent inactivation of...

Author

Lucas, David T. and Szweda, Luke I.

Subjects

*MITOCHONDRIA, *REPERFUSION, *ISCHEMIA, *PROTEINS

Abstract

Presents information on a study which identified specific mitochondrial proteins inactivated during ischemia and reperfusion and determined which of these losses in activity are responsible for observed declines in mitochondrial respiration. Materials used; Methods applied; Implication of result.

Published

1999

10. Cardiac reperfusion injury: Aging, lipid peroxidation, and mitochondrial dysfunction.

Author

Lucas, David T. and Szweda, Luke I.

Subjects

*MITOCHONDRIAL pathology

Abstract

Presents information on the findings of a study which suggests that cardiac mitochondria exhibit an age-related increase in susceptibility to reperfusion-induced dysfunction. Materials and methods used to conduct the study; Clarification of the role of free radicals during reperfusion; Results and discussion of the study.

Published

1998

11. Thioredoxin‐1 and its mimetic peptide improve systolic cardiac function and remodeling after myocardial infarction.

Author

Medali, Tania, Couchie, Dominique, Mougenot, Nathalie, Mihoc, Maria, Bergmann, Olaf, Derks, Wouter, Szweda, Luke I., Yacoub, Magdi, Soliman, Saif, Aguib, Yasmine, Wagdy, Kerolos, Ibrahim, Ayman M., Friguet, Bertrand, and Rouis, Mustapha

Abstract

Myocardial infarction (MI) is characterized by a significant loss of cardiomyocytes (CMs), and it is suggested that reactive oxygen species (ROS) are involved in cell cycle arrest, leading to impaired CM renewal. Thioredoxin‐1 (Trx‐1) scavenges ROS and may play a role in restoring CM renewal. However, the truncated form of Trx‐1, Trx‐80, can compromise its efficacy by exerting antagonistic effects. Therefore, a Trx‐1 mimetic peptide called CB3 was tested as an alternative way to restore CMs. This study aimed to investigate the effects of Trx‐1, Trx‐80, and CB3 on mice with experimental MI and study the underlying mechanism of CB3 on CMs. Mouse cardiac parameters were quantified by echocardiography, and infarction size and fibrosis determined using Trichrome and Picro‐Sirius Red staining. The study found that Trx‐1 and CB3 improved mouse cardiac function, reduced the size of cardiac infarct and fibrosis, and decreased the expression of cardiac inflammatory markers. Furthermore, CB3 polarized macrophages into M2 phenotype, reduced apoptosis and oxidative stress after MI, and increased CM proliferation in cell culture and in vivo. CB3 effectively protected against myocardial infarction and could represent a new class of compounds for treating MI. [ABSTRACT FROM AUTHOR]

Published

2024

12. Enhanced cardiac fatty acid utilization induced by high dietary fat: a potential regulatory role for mitochondrial aconitase.

Author

Fernandes, Jolyn, Szweda, Luke I., and Kinter, Michael

Subjects

*FATTY acids, *MITOCHONDRIA

Abstract

An abstract of the article "Enhanced cardiac fatty acid utilization induced by high dietary fat: a potential regulatory role for mitochondrial aconitase," by Jolyn Fernandes, Luke I. Szweda, and Michael Kinter is presented.

Published

2012

13. High-fat Diet Induced Cardiac Oxidative Stress Differentially Modulates Protein Expression and Specific Activity of the Antioxidant Enzyme Catalase

Author

Rindler, Paul M, Szweda, Luke I, and Kinter, Mike

Published

2010

14. The cardiac-enriched microprotein mitolamban regulates mitochondrial respiratory complex assembly and function in mice.

Author

Makarewich, Catherine A., Munir, Amir Z., Bezprozvannaya, Svetlana, Gibson, Aaron M., Soo Young Kim, Martin-Sandoval, Misty S., Mathews, Thomas P., Szweda, Luke I., Bassel-Duby, Rhonda, and Olson, Eric N.

Subjects

*MITOCHONDRIA, *MITOCHONDRIAL membranes, *ELECTRON transport, *COMPARATIVE method, *MEMBRANE proteins, *COMMERCIAL products

Abstract

Emerging evidence indicates that a subset of RNA molecules annotated as noncoding contain short open reading frames that code for small functional proteins called microproteins, which have largely been overlooked due to their small size. To search for cardiac-expressed microproteins, we used a comparative genomics approach and identified mitolamban (Mtlbn) as a highly conserved 47-amino acid transmembrane protein that is abundantly expressed in the heart. Mtlbn localizes specifically to the inner mitochondrial membrane where it interacts with subunits of complex III of the electron transport chain and with mitochondrial respiratory supercomplexes. Genetic deletion of Mtlbn in mice altered complex III assembly dynamics and reduced complex III activity. Unbiased metabolomic analysis of heart tissue from Mtlbn knockout mice further revealed an altered metabolite profile consistent with deficiencies in complex III activity. Cardiac-specific Mtlbn overexpression in transgenic (TG) mice induced cardiomyopathy with histological, biochemical, and ultrastructural pathologic features that contributed to premature death. Metabolomic analysis and biochemical studies indicated that hearts from Mtlbn TG mice exhibited increased oxidative stress and mitochondrial dysfunction. These findings reveal Mtlbn as a cardiac-expressed inner mitochondrial membrane microprotein that contributes to mitochondrial electron transport chain activity through direct association with complex III and the regulation of its assembly and function. [ABSTRACT FROM AUTHOR]

Published

2022

15. High Dietary Fat Selectively Increases Catalase Expression within Cardiac Mitochondria.

Author

Rindler, Paul M., Plafker, Scott M., Szweda, Luke I., and Kinter, Michael

Subjects

*OVERWEIGHT persons, *GLYCERIDES, *OXIDATION-reduction reaction, *LIPEMIA

Abstract

Obesity is a predictor of diabetes and cardiovascular disease. One consequence of obesity is dyslipidemia characterized by high blood triglycerides. It has been proposed that oxidative stress, driven by utilization of lipids for energy, contributes to these diseases. The effects of oxidative stress are mitigated by an endogenous antioxidant enzyme network, but little is known about its response to high fat utilization. Our experiments used a multiplexed quantitative proteomics method to measure antioxidant enzyme expression in heart tissue in a mouse model of diet-induced obesity. This experiment showed a rapid and specific up-regulation of catalase protein, with subsequent assays showing increases in activity and mRNA. Catalase, traditionally considered a peroxisomal protein, was found to be present in cardiac mitochondria and significantly increased in content and activity during high fat feeding. These data, coupled with the fact that fatty acid oxidation enhances mitochondrial H2O2 production, suggest that a localized catalase increase is needed to consume excessive mitochondrial H2O2 produced by increased fat metabolism. To determine whether the catalase-specific response is a common feature of physiological conditions that increase blood triglycerides and fatty acid oxidation, we measured changes in antioxidant expression in fasted versus fed mice. Indeed, a similar specific catalase increase was observed in mice fasted for 24 h. Our findings suggest a fundamental metabolic process in which catalase expression is regulated to prevent damage while preserving an H2O2-mediated sensing of diet composition that appropriately adjusts insulin sensitivity in the short term as needed to prioritize lipid metabolism for complete utilization. [ABSTRACT FROM AUTHOR]

Published

2013

16. α-Ketoglutarate dehydrogenase: A mitochondrial redox sensor.

Author

McLain, Aaron L., Szweda, Pamela A., and Szweda, Luke I.

Subjects

*DEHYDROGENASES, *BIOSENSORS, *MITOCHONDRIA, *OXIDATION-reduction reaction, *KREBS cycle, *ENZYME inhibitors, *LIPOIC acid

Abstract

α-Ketoglutarate dehydrogenase (KGDH), a key regulatory enzyme within the Krebs cycle, is sensitive to mitochondrial redox status. Treatment of mitochondria with H2O2 results in reversible inhibition of KGDH due to glutathionylation of the cofactor, lipoic acid. Upon consumption of H2O2, glutathione is removed by glutaredoxin restoring KGDH activity. Glutathionylation appears to be enzymatically catalysed or require a unique microenvironment. This may represent an antioxidant response, diminishing the flow of electrons to the respiratory chain and protecting sulphydryl residues from oxidative damage. KGDH is, however, also susceptible to oxidative damage. 4-Hydroxy-2-nonenal (HNE), a lipid peroxidation product, reacts with lipoic acid resulting in enzyme inactivation. Evidence indicates that HNE modified lipoic acid is cleaved from KGDH, potentially the first step of a repair process. KGDH is therefore a likely redox sensor, reversibly altering metabolism to reduce oxidative damage and, under severe oxidative stress, acting as a sentinel of mitochondrial viability. [ABSTRACT FROM AUTHOR]

Published

2011

17. Ohr (Organic Hydroperoxide Resistance Protein) Possesses a Previously Undescribed Activity, Lipoyl-dependent Peroxidase.

Author

Cussiol, José R. R., Alegria, Thiago G. P., Szweda, Luke I., and Netto, Luis E. S.

Subjects

*HYDROGEN peroxide, *ENZYME activation, *ENZYMOLOGY, *ESCHERICHIA coli, *THIOREDOXIN, *METALLOENZYMES

Abstract

The Ohr (organic hydroperoxide resistance) family of 15-kDa Cys-based, thiol-dependent peroxidases is central to the bacterial response to stress induced by organic hydroperoxides but not by hydrogen peroxide. Ohr has a unique three- dimensional structure and requires dithiols, but not monothiols, to support its activity. However, the physiological reducing system of Ohr has not yet been identified. Here we show that lipoylated enzymes present in the bacterial extracts of Xylella fastidiosa interacted physically and functionally with this Cys-based peroxidase, whereas thioredoxin and glutathione systems failed to support Ohr peroxidase activity. Furthermore, we could reconstitute in vitro three lipoyl-dependent systems as the Ohr physiological reducing systems. We also showed that OsmC from Escherichia coli, an orthologue of Ohr from Xylella fastidiosa, is specifically reduced by lipoyl-dependent systems. These results represent the first description of a Cys-based peroxidase that is directly reduced by lipoylated enzymes. [ABSTRACT FROM AUTHOR]

Published

2010

18. Regulated production of free radicals by the mitochondrial electron transport chain: Cardiac ischemic preconditioning

Author

Matsuzaki, Satoshi, Szweda, Pamela A., Szweda, Luke I., and Humphries, Kenneth M.

Subjects

*FREE radical pathophysiology, *MITOCHONDRIA, *ELECTRON transport, *ISCHEMIA, *CORONARY disease, *CELLULAR signal transduction, *OXIDATION-reduction reaction, *BIOLOGICAL transport

Abstract

Abstract: Excessive production of free radicals by mitochondria is associated with, and likely contributes to, the progression of numerous pathological conditions. Nevertheless, the production of free radicals by the mitochondria may have important biological functions under normal or stressed conditions by activating or modulating redox-sensitive cellular signaling pathways. This raises the intriguing possibility that regulated mitochondrial free radical production occurs via mechanisms that are distinct from pathologies associated with oxidative damage. Indeed, the capacity of mitochondria to produce free radicals in a limited manner may play a role in ischemic preconditioning, the phenomenon whereby short bouts of ischemia protect from subsequent prolonged ischemia and reperfusion. Ischemic preconditioning can thus serve as an important model system for defining regulatory mechanisms that allow for transient, signal-inducing, production of free radicals by mitochondria. Defining how these mechanism(s) occur will provide insight into therapeutic approaches that minimize oxidative damage without altering normal cellular redox biology. The aim of this review is to present and discuss evidence for the regulated production of superoxide by the electron transport chain within the ischemic preconditioning paradigm of redox regulation. [Copyright &y& Elsevier]

Published

2009

19. Reversible Inhibition of α-Ketoglutarate Dehydrogenase by Hydrogen Peroxide: Glutathionylation and Protection of Lipoic Acid.

Author

Applegate, Milana A. B., Humphries, Kenneth M., and Szweda, Luke I.

Subjects

*MITOCHONDRIA, *ORGANELLES, *HYDROGEN peroxide, *LIPOIC acid, *PEROXIDATION

Abstract

We have previously demonstrated that when cardiac mitochondria were challenged with H2O2, NADH production and oxidative phosphorylation declined. Upon consumption of H2O2, mitochondrial function was restored. These alterations were due, in large part, to reversible glutathionylation and inhibition of the Krebs cycle enzyme α-ketoglutarate dehydrogenase. The current study was undertaken to identify the site and consequences of α-ketoglutarate dehydrogenase glutathionylation. Mitochondria were treated with H2O2 for varying periods of time. Protein sulfhydryls that had undergone H2O2 mediated glutathionylation were specifically derivatized with N-ethylmaleimide-biotin. Subsequent purification of biotin labeled (glutathionylated) protein and Western blot analysis revealed that the E2 subunit of α-ketoglutarate dehydrogenase was reversibly glutathionylated. Further analysis revealed that lipoic acid, a required cofactor covalently attached to the E2 subunit, was the site of glutathionylation. The relative level of glutathionylated lipoic acid closely paralleled the degree of enzyme inhibition and reactivation. Glutathionylation of α-ketoglutarate dehydrogenase protected iipoic acid from modification by the electrophilic lipid peroxidation product 4-hydroxy-2-nonenal. Glutathionylation of α-ketoglutarate dehydrogenase can therefore be viewed as an antioxidant response protecting the enzyme from oxidative damage. [ABSTRACT FROM AUTHOR]

Published

2008

20. Aging: A shift from redox regulation to oxidative damage.

Author

Humphries, Kenneth M., Szweda, Pamela A., and Szweda, Luke I.

Subjects

*PROTEINS, *AGING, *DEVELOPMENTAL biology, *NUCLEIC acids, *LIPIDS, *MACROMOLECULES, *FREE radicals

Abstract

Proteins, nucleic acids, and lipids can undergo various forms of oxidative modification. In numerous instances, these modifications result in irreversible loss of function. The age-dependent accumulation of oxidatively modified and dysfunctional macromolecules provides the basis for the free radical theory of aging. Pro-oxidants, however, are also capable of catalyzing fully reversible modifications to protein. It is increasingly apparent that these reactions participate in redox-dependent regulation of cell metabolism and response to stress. The adventitious use of free radical species adds complexity to the experimental and theoretical manner in which the free radical theory is to be tested and considered. Elucidation of mechanisms by which reversible oxidative processes are controlled, the components involved, and the metabolic consequences and how they are altered with age will provide new insight on the aging process and attempts to delay the inevitable. [ABSTRACT FROM AUTHOR]

Published

2006

21. Decreased complex II respiration and HNE-modified SDH subunit in diabetic heart

Author

Lashin, Ossama M., Szweda, Pamela A., Szweda, Luke I., and Romani, Andrea M.P.

Subjects

*RESPIRATION, *PEOPLE with diabetes, *SUCCINATE dehydrogenase, *SUCCINIC acid

Abstract

Abstract: Several lines of research suggest that mitochondria play a role in the etiopathogenesis of diabetic cardiomyopathy, although the mechanisms involved are still debated. In the present study, we report that State 3 oxygen consumption decreases by ∼35% with glutamate and by ∼30% with succinate in mitochondria from diabetic rat hearts compared to controls. In these mitochondria the enzymatic activities of complex I and complex II are also decreased to a comparable extent. Western blot analysis of mitochondrial protein pattern using antibodies recognizing proteins modified by the lipid peroxidation product 4-hydroxynonenal indicates the FAD-containing subunit of succinate dehydrogenase as one of the targets of this highly reactive aldehyde. In rats diabetic for 6 or 12 weeks, insulin supplementation for 2 weeks decreases the level of protein modified by 4-hydroxynonenal and restores mitochondrial respiration and enzyme activity to control level. Taken together, these results: (1) indicate that 4-hydroxynonenal is endogenously produced within diabetic mitochondria and forms an adduct with selective mitochondrial proteins, (2) identify one of these proteins as a subunit of succinate dehydrogenase, and (3) provide strong evidence that insulin treatment can reverse and ameliorate free radical damage and mitochondrial function under diabetic conditions. [Copyright &y& Elsevier]

Published

2006

22. Inhibition of very long chain acyl-CoA dehydrogenase during cardiac ischemia

Author

Mason, Katherine E., Stofan, Daniel A., and Szweda, Luke I.

Subjects

*DEHYDROGENASES, *RESPIRATION, *FATTY acids, *CORONARY disease, *VITAMIN B complex

Abstract

Abstract: The heart utilizes primarily fatty acids for energy production. During ischemia, however, diminished oxygen supply necessitates a switch from β-oxidation of fatty acids to glucose utilization and glycolysis. Molecular mechanisms responsible for these alterations in metabolism are not fully understood. Mitochondrial acyl-CoA dehydrogenase catalyzes the first committed step in the β-oxidation of fatty acids. In the current study, an in vivo rat model of myocardial ischemia was utilized to determine whether specific acyl-CoA dehydrogenases exhibit ischemia-induced alterations in activity, identify mechanisms responsible for changes in enzyme function, and assess the effects on mitochondrial respiration. Very long chain acyl-CoA dehydrogenase (VLCAD) activity declined 34% during 30min of ischemia. Loss in activity appeared specific to VLCAD as medium chain acyl-CoA dehydrogenase activity remained constant. Loss in VLCAD activity during ischemia was not due to loss in protein content. In addition, activity was restored in the presence of the detergent Triton X-100, suggesting that changes in the interaction between the protein and inner mitochondrial membrane are responsible for ischemia-induced loss in activity. Palmitoyl-carnitine supported ADP-dependent state 3 respiration declined as a result of ischemia. When octanoyl-carnitine was utilized state 3 respiration remained unchanged. State 4 respiration increased during ischemia, an increase that appears specific to fatty acid utilization. Thus, VLCAD represents a likely site for the modulation of substrate utilization during myocardial ischemia. However, the dramatic increase in mitochondrial state 4 respiration would be predicted to accentuate the imbalance between energy production and utilization. [Copyright &y& Elsevier]

Published

2005

23. Modulation of Mitochondrial Complex I Activity by Reversible Ca2+ and NADH Mediated Superoxide Anion Dependent Inhibition.

Author

Sadek, Hesham A., Szweda, Pamela A., and Szweda, Luke I.

Subjects

*MITOCHONDRIAL pathology, *SUPEROXIDES, *ISCHEMIA, *ANTIOXIDANTS, *CHEMICAL inhibitors, *SULFENIC acids

Abstract

Complex I, a key component of the mitochondrial respiratory chain, exhibits diminished activity as a result of cardiac ischemia/reperfusion. Cardiac ischemia/reperfusion is associated with increases in the levels of mitochondrial Ca2+ and pro-oxidants. In the current in vitro study, we sought evidence for a mechanistic link between Ca2+ pro-oxidants, and inhibition of complex I utilizing mitochondria isolated from rat heart. Our results indicate that addition of Ca2+ to solubilized mitochondria results in loss in complex I activity. Ca2+ induced a maximum decrease in complex I activity of approximately 35% at low micromolar concentrations over a narrow physiologically relevant pH range. Loss in activity required reducing equivalents in the form of NADH and was not reversed upon addition of EGTA. The antioxidants N-acetylcysteine and superoxide dismutase, but not catalase, prevented inhibition, indicating the involvement of superoxide anion (O2.-) in the inactivation process. Importantly, the sulfhydryl reducing agent DTT was capable of fully restoring complex I activity implicating the formation of sulfenic acid and/or disulfide derivatives of cysteine in the inactivation process. Finally, complex I can reactivate endogenously upon Ca2+ removal if NADH is present and the enzyme is allowed to turnover catalytically. Thus, the present study provides a mechanistic link between three alterations known to occur during cardiac ischemial reperfusion, mitochondrial Ca2+ accumulation, free radical production, and complex I inhibition. The reversibility of these processes suggests redox regulation of Ca2+ handling. [ABSTRACT FROM AUTHOR]

Published

2004

24. Redox-Dependent Modulation of Aconitase Activity in Intact Mitochondria.

Author

Bulteau, Anne-Laure, Ikeda-Saito, Masao, and Szweda, Luke I.

Subjects

*MITOCHONDRIA, *ORGANELLES, *ENZYMES, *ELECTROPHORESIS, *OXIDIZING agents, *PROTEINS

Abstract

It has previously been reported that exposure of purified mitochondrial or cytoplasmic aconitase to superoxide (O[SUP•][SUB2-]) or hydrogen peroxide (H[SDUB2]O[SUB2]) leads to release of the Fe-α from the enzyme's [4Fe4S]2+ cluster and to inactivation. Nevertheless, little is known regarding the response of aconitase to pro-oxidants within intact mitochondria. In the present study, we provide evidence that aconitase is rapidly inactivated and subsequently reactivated when isolated cardiac mitochondria are treated with H[SUB2]O[SUB2]. Reactivation of the enzyme is dependent on the presence of the enzyme's substrate, citrate. EPR spectroscopic analysis indicates that enzyme inactivation precedes release of the labile Fe-α from the enzyme's [4Fe-4S]2+ cluster. In addition, as judged by isoelectric focusing gel electrophoresis, the relative level of Fe-α release and cluster disassembly does not reflect the magnitude of enzyme inactivation. These observations suggest that some form of posttranslational modification of aconitase other than release of iron is responsible for enzyme inactivation. In support of this conclusion, H[SUB2]O[SUB2] does not exert its inhibitory effects by acting directly on the enzyme, rather inactivation appears to result from interaction(s) between aconitase and a mitochondrial membrane component responsive to H[SUB2]O[SUB2]. Nevertheless, prolonged exposure of mitochondria to steady-state levels of H[SUB2]O[SUB2] or O[SUP•][SUB2-] results in disassembly of the [4Fe-4S][SUP2+] cluster, carbonylation, and protein degradation. Thus, depending on the pro-oxidant species, the level and duration of the oxidative stress, and the metabolic state of the mitochondria, aconitase may undergo reversible modulation in activity or progress to [4Fe-4S][SUP2+] cluster disassembly and proteolytic degradation. [ABSTRACT FROM AUTHOR]

Published

2003

25. Dissociation of Cytochrome c from the Inner Mitochondrial Membrane during Cardiac Ischemia.

Author

Czerski, Lech W., Szweda, Pamela A., and Szweda, Luke I.

Subjects

*CYTOCHROME c, *MITOCHONDRIAL membranes, *ISCHEMIA

Abstract

Mitochondria isolated from ischemic cardiac tissue exhibit diminished rates of respiration and ATP synthesis. The present study was undertaken to determine whether cytochrome c release was responsible for ischemia-induced loss in mitochondrial function. Rat hearts were perfused in Langendorff fashion for 60 min (control) or for 30 min followed by 30 min of no flow ischemia. Mitochondria isolated from ischemic hearts in a buffer containing KCl exhibited depressed rates of maximum respiration and a lower cytochrome c content relative to control mitochondria. The addition of cytochrome c restored maximum rates of respiration, indicating that the release of cytochrome c is responsible for observed declines in function. However, mitochondria isolated in a mannitol/sucrose buffer exhibited no ischemia-induced loss in cytochrome c content, indicating that ischemia does not on its own cause the release of cytochrome c. Nevertheless, state 3 respiratory rates remained depressed, and cytochrome c release was enhanced when mitochondria from ischemic relative to perfused tissue were subsequently placed in a high ionic strength buffer, hypotonic solution, or detergent. Thus, events that occur during ischemia favor detachment of cytochrome c from the inner membrane increasing the pool of cytochrome c available for release. These results provide insight into the sequence of events that leads to release of cytochrome c and loss of mitochondrial respiratory activity during cardiac ischemia/reperfusion. [ABSTRACT FROM AUTHOR]

Published

2003

26. Alterations in mitochondrial function in a mouse model of hypertrophic cardiomyopathy.

Author

Lucas, David T., Aryal, Prafulla, Szweda, Luke I., Koch, Walter J., and Leinwand, Leslie A.

Subjects

*HEART diseases, *MITOCHONDRIA, *HEMODYNAMICS

Abstract

Discusses results of a study investigating alterations of mitochondrial function in a mouse model of hypertrophic cardiomyopathy (HCM). Mitochondrial respiration; Alpha ketoglutarate dehydrogenase activities; Hemodynamic dysfunction in some forms of HCM.

Published

2003

27. Proteolysis, free radicals, and aging1,2 <FN ID="FN1"><NO>1</NO>Guest Editor: Earl Stadtman</FN> <FN ID="FN2"><NO>2</NO>This article is part of a series of reviews on “Oxidatively Modified Proteins in Aging and Disease.” The full list of papers may be found on the homepage of the journal.</FN>

Author

Szweda, Pamela A., Friguet, Bertrand, and Szweda, Luke I.

Subjects

*AGING, *PROTEOLYSIS, *FREE radicals, *LYSOSOMES

Abstract

Aging is accompanied by declines in cellular proteolytic capacity. Proteolytic processing is an important step in numerous cellular processes required for normal metabolic function. These include regulation of protein turnover, degradation of altered forms of protein, signal transduction, protein sorting/trafficking, receptor-mediated endo- and exocytosis, stress/immune responses, and activation of gene transcription. Thus, loss of cellular proteolytic function is likely to contribute to the enhanced fragility of cells from senescent relative to young and adult organisms. Free radicals have been implicated as contributing factors to observed age-dependent declines in proteolytic capacity. The current review offers an overview of the evidence linking free radical events to functional alterations in the lysosomal system and the proteasome, two major pathways by which proteins are degraded within cells. Implications for future investigations in the field are discussed in light of these findings. [Copyright &y& Elsevier]

Published

2002

28. Alterations in renal mitochondrial respiration in response to the reactive oxoaldehyde methylglyoxal.

Author

Rosca, Mariana G., Monnifer, Vincent M., Szweda, Luke I., and Weish, Miriam F.

Subjects

*MITOCHONDRIA, *KIDNEY tubules, *DIABETIC nephropathies

Abstract

Examines the effects of methylglycoxal on renal mitochondrial respiration. Etiological role of mitochondrial damage in renal cellular toxicity; Link between ultrastructural changes in mitochondria and impaired tubular function; Influence of mitochondria in the development of diabetic nephropathy.

Published

2002

29. Inhibitionn of NADH-linked mitochondrial respiration by 4-hydroxy-2-nonenal.

Author

Humphries, Kenneth M., Yoo, Young, and Szweda, Luke I.

Subjects

*MITOCHONDRIAL membrane abnormalities

Abstract

Provides information on a study identifying a potential mechanism by which lipid peroxidation gives rise to mitochondrial dysfunction and provides the basis for investigating the role of this process in certain degenerative events. Methodology used to conduct the study; Results of the study; Discussion on the results.

Published

1998

30. Transcription factor NFYa controls cardiomyocyte metabolism and proliferation during mouse fetal heart development.

Author

Cui, Miao, Bezprozvannaya, Svetlana, Hao, Tian, Elnwasany, Abdallah, Szweda, Luke I., Liu, Ning, Bassel-Duby, Rhonda, and Olson, Eric N.

Subjects

*HEART development, *FETAL heart, *METABOLIC regulation, *TRANSCRIPTION factors, *FETAL development, *FETAL death, *CARDIAC regeneration

Abstract

Cardiomyocytes are highly metabolic cells responsible for generating the contractile force in the heart. During fetal development and regeneration, these cells actively divide but lose their proliferative activity in adulthood. The mechanisms that coordinate their metabolism and proliferation are not fully understood. Here, we study the role of the transcription factor NFYa in developing mouse hearts. Loss of NFYa alters cardiomyocyte composition, causing a decrease in immature regenerative cells and an increase in trabecular and mature cardiomyocytes, as identified by spatial and single-cell transcriptome analyses. NFYa -deleted cardiomyocytes exhibited reduced proliferation and impaired mitochondrial metabolism, leading to cardiac growth defects and embryonic death. NFYa, interacting with cofactor SP2, activates genes linking metabolism and proliferation at the transcription level. Our study identifies a nodal role of NFYa in regulating prenatal cardiac growth and a previously unrecognized transcriptional control mechanism of heart metabolism, highlighting the importance of mitochondrial metabolism during heart development and regeneration. [Display omitted] • Deleting NFYa in cardiomyocytes results in cardiac noncompaction and embryonic death • Fetal cardiomyocyte subtypes identified by multi-modal single-cell transcriptomics • NFYa deletion alters cardiomyocyte composition and mitochondrial metabolism • NFYa, working with SP2, activates metabolic gene transcription In this study, Cui et al. identified a critical role of the nuclear transcription factor Y in regulating mitochondrial metabolism and proliferation in heart muscle cells of the developing mouse heart. [ABSTRACT FROM AUTHOR]

Published

2023

31. Epigenetic Reader BRD4 (Bromodomain-Containing Protein 4) Governs Nucleus-Encoded Mitochondrial Transcriptome to Regulate Cardiac Function.

Author

Kim, Soo Young, Zhang, Xin, Schiattarella, Gabriele G., Altamirano, Francisco, Ramos, Thais A.R., French, Kristin M., Jiang, Nan, Szweda, Pamela A., Evers, Bret M., May, Herman I., Luo, Xiang, Li, Hongliang, Szweda, Luke I., Maracaja-Coutinho, Vinicius, Lavandero, Sergio, Gillette, Thomas G., and Hill, Joseph A.

Subjects

*MITOCHONDRIA, *CARRIER proteins, *EPIGENETICS, *ELECTRON transport, *TRANSCRIPTION factors, *ESTROGEN antagonists, *NUCLEAR receptors (Biochemistry), *CARDIAC contraction, *LONG QT syndrome diagnosis, *AMBULATORY electrocardiography, *EXERCISE tests, *BROMODOMAIN-containing proteins, *RESEARCH, *PREDICTIVE tests, *RESEARCH methodology, *GENETIC testing, *ATHLETES, *LONG QT syndrome, *RETROSPECTIVE studies, *EVALUATION research, *COMPARATIVE studies, *HEART beat, *ACTION potentials, *EXERCISE, *DISEASE susceptibility, *DIAGNOSTIC errors, *PHENOTYPES

Abstract

Background: BET (bromodomain and extraterminal) epigenetic reader proteins, in particular BRD4 (bromodomain-containing protein 4), have emerged as potential therapeutic targets in a number of pathological conditions, including cancer and cardiovascular disease. Small-molecule BET protein inhibitors such as JQ1 have demonstrated efficacy in reversing cardiac hypertrophy and heart failure in preclinical models. Yet, genetic studies elucidating the biology of BET proteins in the heart have not been conducted to validate pharmacological findings and to unveil potential pharmacological side effects.Methods: By engineering a cardiomyocyte-specific BRD4 knockout mouse, we investigated the role of BRD4 in cardiac pathophysiology. We performed functional, transcriptomic, and mitochondrial analyses to evaluate BRD4 function in developing and mature hearts.Results: Unlike pharmacological inhibition, loss of BRD4 protein triggered progressive declines in myocardial function, culminating in dilated cardiomyopathy. Transcriptome analysis of BRD4 knockout mouse heart tissue identified early and specific disruption of genes essential to mitochondrial energy production and homeostasis. Functional analysis of isolated mitochondria from these hearts confirmed that BRD4 ablation triggered significant changes in mitochondrial electron transport chain protein expression and activity. Computational analysis identified candidate transcription factors participating in the BRD4-regulated transcriptome. In particular, estrogen-related receptor α, a key nuclear receptor in metabolic gene regulation, was enriched in promoters of BRD4-regulated mitochondrial genes.Conclusions: In aggregate, we describe a previously unrecognized role for BRD4 in regulating cardiomyocyte mitochondrial homeostasis, observing that its function is indispensable to the maintenance of normal cardiac function. [ABSTRACT FROM AUTHOR]

Published

2020

32. Mitochondrial fatty acid utilization increases chromatin oxidative stress in cardiomyocytes.

Author

Menendez-Montes, Ivan, Abdisalaam, Salim, Feng Xiao, Lam, Nicholas T., Mukherjee, Shibani, Szweda, Luke I., Asaithamby, Aroumougame, and Sadek, Hesham A.

Subjects

*MITOCHONDRIA, *CHROMATIN, *OXIDATIVE stress, *FATTY acids, *HEART failure, *VEGETABLE oils, *COMMERCIAL products

Abstract

The inability of adult mammalian cardiomyocytes to proliferate underpins the development of heart failure following myocardial injury. Although the newborn mammalian heart can spontaneously regenerate for a short period of time after birth, this ability is lost within the first week after birth in mice, partly due to increased mitochondrial reactive oxygen species (ROS) production which results in oxidative DNA damage and activation of DNA damage response. This increase in ROS levels coincides with a postnatal switch from anaerobic glycolysis to fatty acid (FA) oxidation by cardiac mitochondria. However, to date, a direct link between mitochondrial substrate utilization and oxidative DNA damage is lacking. Here, we generated ROS-sensitive fluorescent sensors targeted to different subnuclear compartments (chromatin, heterochromatin, telomeres, and nuclear lamin) in neonatal rat ventricular cardiomyocytes, which allowed us to determine the spatial localization of ROS in cardiomyocyte nuclei upon manipulation of mitochondrial respiration. Our results demonstrate that FA utilization by the mitochondria induces a significant increase in ROS detection at the chromatin level compared to other nuclear compartments. These results indicate that mitochondrial metabolic perturbations directly alter the nuclear redox status and that the chromatin appears to be particularly sensitive to the prooxidant effect of FA utilization by the mitochondria. [ABSTRACT FROM AUTHOR]

Published

2021

33. Enhancing cardiac glycolysis causes an increase in PDK4 content in response to short-term high-fat diet.

Author

Newhardt, Maria F., Batushansky, Albert, Satoshi Matsuzaki, Young, Zachary T., West, Melinda, Ngun Cer Chin, Szweda, Luke I., Kinter, Michael, and Humphries, Kenneth M.

Subjects

*HIGH-fat diet, *PYRUVATE dehydrogenase kinase, *GLYCOLYSIS, *METABOLIC profile tests, *FRUCTOSE, *HEART metabolism, *FATTY acids

Abstract

The healthy heart has a dynamic capacity to respond and adapt to changes in nutrient availability. Metabolic inflexibility, such as occurs with diabetes, increases cardiac reliance on fatty acids to meet energetic demands, and this results in deleterious effects, including mitochondrial dysfunction, that contribute to pathophysiology. Enhancing glucose usage may mitigate metabolic inflexibility and be advantageous under such conditions. Here, we sought to identify how mitochondrial function and cardiac metabolism are affected in a transgenic mouse model of enhanced cardiac glycolysis (GlycoHi) basally and following a short-term (7-day) high-fat diet (HFD). GlycoHi mice constitutively express an active form of phosphofructokinase-2, resulting in elevated levels of the PFK-1 allosteric activator fructose 2,6-bisphosphate. We report that basally GlycoHi mitochondria exhibit augmented pyruvate-supported respiration relative to fatty acids. Nevertheless, both WT and GlycoHi mitochondria had a similar shift toward increased rates offattyacid-supportedrespirationfollowing HFD. Metabolic profiling by GC-MS revealed distinct features based on both genotype and diet, with a unique increase in branched-chain amino acids in the GlycoHi HFD group. Targeted quantitative proteomics analysis also supported both genotype- and diet-dependent changes in protein expression and uncovered an enhanced expression of pyruvate dehydrogenase kinase 4 (PDK4) in the GlycoHi HFD group. These results support a newly identified mechanism whereby the levels of fructose 2,6-bisphosphate promote mitochondrial PDK4 levels and identify a secondary adaptive response that prevents excessive mitochondrial pyruvate oxidation when glycolysis is sustained after a high-fat dietary challenge. [ABSTRACT FROM AUTHOR]

Published

2019

34. High-Phosphate Diet Induces Exercise Intolerance and Impairs Fatty Acid Metabolism in Mice.

Author

Peri-Okonny, Poghni, Baskin, Kedryn K., Iwamoto, Gary, Mitchell, Jere H., Smith, Scott A., Kim, Han Kyul, Szweda, Luke I., Bassel-Duby, Rhonda, Fujikawa, Teppei, Castorena, Carlos M., Richardson, James, Shelton, John M., Ayers, Colby, Berry, Jarett D., Malladi, Venkat S., Hu, Ming-Chang, Moe, Orson W., Scherer, Philipp E., and Vongpatanasin, Wanpen

Subjects

*FREE fatty acids, *FATTY acids, *AEROBIC capacity, *PHYSICAL activity, *SEDENTARY behavior, *OMEGA-6 fatty acids, *INORGANIC compounds, *PHYSIOLOGICAL effects of phosphates

Abstract

Background: Inorganic phosphate (Pi) is used extensively as a preservative and a flavor enhancer in the Western diet. Physical inactivity, a common feature of Western societies, is associated with increased cardiovascular morbidity and mortality. It is unknown whether dietary Pi excess contributes to exercise intolerance and physical inactivity.Methods: To determine an association between Pi excess and physical activity in humans, we assessed the relationship between serum Pi and actigraphy-determined physical activity level, as well as left ventricular function by cardiac magnetic resonance imaging, in DHS-2 (Dallas Heart Study phase 2) participants after adjusting for relevant variables. To determine direct effects of dietary Pi on exercise capacity, oxygen uptake, serum nonesterified fatty acid, and glucose were measured during exercise treadmill test in C57/BL6 mice fed either a high-Pi (2%) or normal-Pi (0.6%) diet for 12 weeks. To determine the direct effect of Pi on muscle metabolism and expression of genes involved in fatty acid metabolism, additional studies in differentiated C2C12 myotubes were conducted after subjecting to media containing 1 to 3 mmol/L Pi (pH 7.0) to simulate in vivo phosphate conditions.Results: In participants of the DHS-2 (n=1603), higher serum Pi was independently associated with reduced time spent in moderate to vigorous physical activity ( P=0.01) and increased sedentary time ( P=0.004). There was no association between serum Pi and left ventricular ejection fraction or volumes. In animal studies, compared with the control diet, consumption of high-Pi diet for 12 weeks did not alter body weight or left ventricular function but reduced maximal oxygen uptake, treadmill duration, spontaneous locomotor activity, fat oxidation, and fatty acid levels and led to downregulation of genes involved in fatty acid synthesis, release, and oxidation, including Fabp4, Hsl, Fasn, and Pparγ, in muscle. Similar results were recapitulated in vitro by incubating C2C12 myotubes with high-Pi media.Conclusions: Our data demonstrate a detrimental effect of dietary Pi excess on skeletal muscle fatty acid metabolism and exercise capacity that is independent of obesity and cardiac contractile function. Dietary Pi may represent a novel and modifiable target to reduce physical inactivity associated with the Western diet. [ABSTRACT FROM AUTHOR]

Published

2019

35. Coenzyme A-mediated degradation of pyruvate dehydrogenase kinase 4 promotes cardiac metabolic flexibility after high-fat feeding in mice.

Author

Schafer, Christopher, Young, Zachary T., Makarewich, Catherine A., Elnwasany, Abdallah, Kinter, Caroline, Kinter, Michael, and Szweda, Luke I.

Subjects

*COENZYME A, *PYRUVATE dehydrogenase kinase, *HIGH-fat diet, *FATTY acid oxidation, *OXIDATION of glucose, *LABORATORY mice

Abstract

Cardiac energy is produced primarily by oxidation of fatty acids and glucose, with the relative contributions of each nutrient being sensitive to changes in substrate availability and energetic demand. A major contributor to cardiac metabolic flexibility is pyruvate dehydrogenase (PDH), which converts glucose-derived pyruvate to acetyl-CoA within the mitochondria. PDH is inhibited by phosphorylation dependent on the competing activities of pyruvate dehydrogenase kinases (PDK1-4) and phosphatases (PDP1-2). A single high-fat meal increases cardiac PDK4 content and subsequently inhibits PDH activity, reducing pyruvate utilization when abundant fatty acids are available. In this study, we demonstrate that dietinduced increases in PDK4 are reversible and characterize a novel pathway that regulates PDK4 degradation in response to the cardiac metabolic environment. We found that PDK4 degradation is promoted by CoA (CoASH), the levels of which declined in mice fed a high-fat diet and normalized following transition to a control diet. We conclude that CoASH functions as a metabolic sensor linking the rate of PDK4 degradation to fatty acid availability in the heart. However, prolonged high-fat feeding followed by return to a low-fat diet resulted in persistent in vitro sensitivity of PDH to fatty acid-induced inhibition despite reductions in PDK4 content. Moreover, increases in the levels of proteins responsible for-oxidation and rates of palmitate oxidation by isolated cardiac mitochondria following longterm consumption of high dietary fat persisted after transition to the control diet. We propose that these changes prime PDH for inhibition upon reintroduction of fatty acids. [ABSTRACT FROM AUTHOR]

Published

2018

36. PPARα is essential for retinal lipid metabolism and neuronal survival.

Author

Pearsall, Elizabeth A., Rui Cheng, Kelu Zhou, Yusuke Takahashi, Matlock, H. Greg, Vadvalkar, Shraddha S., Younghwa Shin, Fredrick, Thomas W., Gantner, Marin L., Meng, Steven, Zhongjie Fu, Yan Gong, Kinter, Michael, Humphries, Kenneth M., Szweda, Luke I., Smith, Lois E. H., and Jian-xing Ma

Subjects

*PEROXISOME proliferator-activated receptors, *LIPID metabolism, *NEURONS, *MITOCHONDRIA, *CELL membranes

Abstract

Background: Peroxisome proliferator activated receptor-alpha (PPARα) is a ubiquitously expressed nuclear receptor. The role of endogenous PPARα in retinal neuronal homeostasis is unknown. Retinal photoreceptors are the highest energy-consuming cells in the body, requiring abundant energy substrates. PPARα is a known regulator of lipid metabolism, and we hypothesized that it may regulate lipid use for oxidative phosphorylation in energetically demanding retinal neurons. Results: We found that endogenous PPARα is essential for the maintenance and survival of retinal neurons, with Pparα-/- mice developing retinal degeneration first detected at 8 weeks of age. Using extracellular flux analysis, we identified that PPARα mediates retinal utilization of lipids as an energy substrate, and that ablation of PPARα ultimately results in retinal bioenergetic deficiency and neurodegeneration. This may be due to PPARα regulation of lipid transporters, which facilitate the internalization of fatty acids into cell membranes and mitochondria for oxidation and ATP production. Conclusion: We identify an endogenous role for PPARα in retinal neuronal survival and lipid metabolism and furthermore underscore the importance of fatty acid oxidation in photoreceptor survival. We also suggest PPARα as a putative therapeutic target for age-related macular degeneration, which may be due in part to decreased mitochondrial efficiency and subsequent energetic deficits. [ABSTRACT FROM AUTHOR]

Published

2017

37. PPARα is essential for retinal lipid metabolism and neuronal survival.

Author

Pearsall, Elizabeth A., Rui Cheng, Kelu Zhou, Yusuke Takahashi, Matlock, H. Greg, Vadvalkar, Shraddha S., Younghwa Shin, Fredrick, Thomas W., Gantner, Marin L., Meng, Steven, Zhongjie Fu, Yan Gong, Kinter, Michael, Humphries, Kenneth M., Szweda, Luke I., Smith, Lois E. H., and Jian-xing Ma

Abstract

Background: Peroxisome proliferator activated receptor-alpha (PPARα) is a ubiquitously expressed nuclear receptor. The role of endogenous PPARα in retinal neuronal homeostasis is unknown. Retinal photoreceptors are the highest energy-consuming cells in the body, requiring abundant energy substrates. PPARα is a known regulator of lipid metabolism, and we hypothesized that it may regulate lipid use for oxidative phosphorylation in energetically demanding retinal neurons. Results: We found that endogenous PPARα is essential for the maintenance and survival of retinal neurons, with Pparα-/- mice developing retinal degeneration first detected at 8 weeks of age. Using extracellular flux analysis, we identified that PPARα mediates retinal utilization of lipids as an energy substrate, and that ablation of PPARα ultimately results in retinal bioenergetic deficiency and neurodegeneration. This may be due to PPARα regulation of lipid transporters, which facilitate the internalization of fatty acids into cell membranes and mitochondria for oxidation and ATP production. Conclusion: We identify an endogenous role for PPARα in retinal neuronal survival and lipid metabolism, and furthermore underscore the importance of fatty acid oxidation in photoreceptor survival. We also suggest PPARα as a putative therapeutic target for age-related macular degeneration, which may be due in part to decreased mitochondrial efficiency and subsequent energetic deficits. [ABSTRACT FROM AUTHOR]

Published

2017

38. Glucose availability controls adipogenesis in mouse 3T3-L1 adipocytes via up-regulation of nicotinamide metabolism.

Author

Jackson, Robert M., Griesel, Beth A., Gurley, Jami M., Szweda, Luke I., and Olson, Ann Louise

Subjects

*GLUCOSE, *ADIPOGENESIS, *NICOTINAMIDE, *OBESITY, *HYPERTROPHY, *ADIPONECTIN

Abstract

Expansion of adipose tissue in response to a positive energy balance underlies obesity and occurs through both hypertrophy of existing cells and increased differentiation of adipocyte precursors (hyperplasia). To better understand the nutrient signals that promote adipocyte differentiation, we investigated the role of glucose availability in regulating adipocyte differentiation and maturation. 3T3-L1 preadipocytes were grown and differentiated in medium containing a standard differentiation hormone mixture and either 4 or 25 mM glucose. Adipocyte maturation at day 9 post-differentiation was determined by key adipocyte markers, including glucose transporter 4 (GLUT4) and adiponectin expression and Oil Red O staining of neutral lipids. We found that adipocyte differentiation and maturation required a pulse of 25mM glucose only during the first 3 days of differentiation. Importantly, fatty acids were unable to substitute for the 25 mM glucose pulse during this period. The 25 mM glucose pulse increased adiponectin and GLUT4 expression and accumulation of neutral lipids via distinct mechanisms. Adiponectin expression and other early markers of differentiation required an increase in the intracellular pool of total NAD/P. In contrast, GLUT4 protein expression was only partially restored by increased NAD/P levels. Furthermore, GLUT4 mRNA expression was mediated by glucose-dependent activation of GLUT4 gene transcription through the cis-acting GLUT4-liver X receptor element (LXRE) promoter element. In summary, this study supports the conclusion that high glucose promotes adipocyte differentiation via distinct metabolic pathways and independently of fatty acids. This may partly explain the mechanism underlying adipocyte hyperplasia that occurs much later than adipocyte hypertrophy in the development of obesity. [ABSTRACT FROM AUTHOR]

Published

2017

39. Regulation of Pyruvate Dehydrogenase Kinase 4 in the Heart through Degradation by the Lon Protease in Response to Mitochondrial Substrate Availability.

Author

Crewe, Clair, Schafer, Christopher, Irene Lee, Kinter, Michael, and Szweda, Luke I.

Subjects

*PYRUVATE dehydrogenase kinase, *HEART proteins, *HEART metabolism, *PHOSPHORYLATION, *MITOCHONDRIAL proteins, *PROTEOLYSIS

Abstract

Cardiac metabolic inflexibility is driven by robust up-regulation of pyruvate dehydrogenase kinase 4 (PDK4) and phosphorylation- dependent inhibition of pyruvate dehydrogenase (PDH) within a single day of feeding mice a high fat diet. In the current study, we have discovered that PDK4 is a short lived protein (t1/2 ~ 1 h) and is specifically degraded by the mitochondrial protease Lon. Lon does not rapidly degrade PDK1 and -2, indicating specificity toward the PDK isoform that is a potent modulator of metabolic flexibility. Moreover, PDK4 degradation appears regulated by dissociation from the PDH complex dependent on the respiratory state and energetic substrate availability of mouse heart mitochondria. Finally, we demonstrate that pharmacologic inhibition of PDK4 promotes PDK4 degradation in vitro and in vivo. These findings reveal a novel strategy to manipulate PDH activity by selectively targeting PDK4 content through dissociation and proteolysis. [ABSTRACT FROM AUTHOR]

Published

2017

40. Catalase-dependent H2O2 consumption by cardiac mitochondria and redox-mediated loss in insulin signaling.

Author

Rindler, Paul M., Cacciola, Angela, Kinter, Michael, and Szweda, Luke I.

Abstract

We have recently demonstrated that catalase content in mouse cardiac mitochondria is selectively elevated in response to high dietary fat, a nutritional state associated with oxidative stress and loss in insulin signaling. Catalase and various isoforms of glutathione peroxidase and peroxiredoxin each catalyze the consumption of H2O2 Catalase, located primarily within peroxisomes and to a lesser extent mitochondria, has a low binding affinity for H2O2 relative to glutathione peroxidase and peroxiredoxin. As such, the contribution of catalase to mitochondrial H2O2 consumption is not well understood. In the current study, using highly purified cardiac mitochondria challenged with micromolar concentrations of H2O2, we found that catalase contributes significantly to mitochondrial H2O2 consumption. In addition, catalase is solely responsible for removal of H2O2 in nonrespiring or structurally disrupted mitochondria. Finally, in mice fed a high-fat diet, mitochondrial-derived H2O2 is responsible for diminished insulin signaling in the heart as evidenced by reduced insulin-stimulated Akt phosphorylation. While elevated mitochondrial catalase content (∼50%) enhanced the capacity of mitochondria to consume H2O2 in response to high dietary fat, the selective increase in catalase did not prevent H2O2-induced loss in cardiac insulin signaling. Taken together, our results indicate that mitochondrial catalase likely functions to preclude the formation of high levels of H2O2 without perturbing redox-dependent signaling. [ABSTRACT FROM AUTHOR]

Published

2016

41. Nutrient sensing and utilization: Getting to the heart of metabolic flexibility.

Author

Griffin, Timothy M., Humphries, Kenneth M., Kinter, Michael, Lim, Hui-Ying, and Szweda, Luke I.

Subjects

*HEART metabolism disorders, *METABOLIC syndrome, *OBESITY complications, *PATHOLOGICAL physiology, *PEROXISOMES

Abstract

A central feature of obesity-related cardiometabolic diseases is the impaired ability to transition between fatty acid and glucose metabolism. This impairment, referred to as “metabolic inflexibility”, occurs in a number of tissues, including the heart. Although the heart normally prefers to metabolize fatty acids over glucose, the inability to upregulate glucose metabolism under energetically demanding conditions contributes to a pathological state involving energy imbalance, impaired contractility, and post-translational protein modifications. This review discusses pathophysiologic processes that contribute to cardiac metabolic inflexibility and speculates on the potential physiologic origins that lead to the current state of cardiometabolic disease in an obesogenic environment. [ABSTRACT FROM AUTHOR]

Published

2016

42. Lysine Acetylation Activates Mitochondrial Aconitase in the Heart.

Author

Fernandes, Jolyn, Weddle, Alexis, Kinter, Caroline S., Humphries, Kenneth M., Mather, Timothy, Szweda, Luke I., and Kinter, Michael

Subjects

*ACONITATE hydratase genetics, *ACETYLATION, *LYSINE biotechnology, *PROTEOMICS, *MITOCHONDRIAL proteins, *ACETIC anhydride

Abstract

High-throughput proteomics studies have identified several thousand acetylation sites on more than 1000 proteins. Mitochondrial aconitase, the Krebs cycle enzyme that converts citrate to isocitrate, has been identified in many of these reports. Acetylated mitochondrial aconitase has also been identified as a target for sirtuin 3 (SIRT3)-catalyzed deacetylation. However, the functional significance of mitochondrial aconitase acetylation has not been determined. Using in vitro strategies, mass spectrometric analyses, and an in vivo mouse model of obesity, we found a significant acetylation-dependent activation of aconitase. Isolated heart mitochondria subjected to in vitro chemical acetylation with either acetic anhydride or acetyl-coenzyme A resulted in increased aconitase activity that was reversed with SIRT3 treatment. Quantitative mass spectrometry was used to measure acetylation at 21 lysine residues and revealed significant increases with both in vitro treatments. A high-fat diet (60% of kilocalories from fat) was used as an in vivo model and also showed significantly increased mitochondrial aconitase activity without changes in protein level. The high-fat diet also produced an increased level of aconitase acetylation at multiple sites as measured by the quantitative mass spectrometry assays. Treatment of isolated mitochondria from these mice with SIRT3 abolished the high-fat diet-induced activation of aconitase and reduced acetylation. Finally, kinetic analyses found that the increase in activity was a result of increased maximal velocity, and molecular modeling suggests the potential for acetylation at K144 to perturb the tertiary structure of the enzyme. The results of this study reveal a novel activation of mitochondrial aconitase by acetylation. [ABSTRACT FROM AUTHOR]

Published

2015

43. Deficiency in adipocyte chemokine receptor CXCR4 exacerbates obesity and compromises thermoregulatory responses of brown adipose tissue in a mouse model of diet-induced obesity.

Author

Longbiao Yao, Heuser-Baker, Janet, Herlea-Pana, Oana, Nan Zhang, Szweda, Luke I., Griffin, Timothy M., and Barlic-Dicen, Jana

Subjects

*CHEMOKINE receptors, *CYTOKINE receptors, *BODY temperature regulation, *ADIPOSE tissues, *ADIPONECTIN

Abstract

The chemokine receptor CXCR4 is expressed on adipocytes and macrophages in adipose tissue, but its role in this tissue remains unknown. We evaluated whether deficiency in either adipocyte or myeloid leukocyte CXCR4 affects body weight (BW) and adiposity in a mouse model of high-fat-diet (HFD)-induced obesity. We found that ablation of adipocyte, but not myeloid leukocyte, CXCR4 exacerbated obesity. The HFD-fed adipocyte-specific CXCR4-knockout (AdCXCR4ko) mice, compared to wild-type C57BL/6 control mice, had increased BW (average: 52.0 g vs. 35.5 g), adiposity (average: 49.3 vs. 21.0% of total BW), and inflammatory leukocyte content in white adipose tissue (WAT), despite comparable food intake. As previously reported, HFD feeding increased uncoupling protein 1 (UCP1) expression (fold increase: 3.5) in brown adipose tissue (BAT) of the C57BL/6 control mice. However, no HFD-induced increase in UCP1 expression was observed in the AdCXCR4ko mice, which were cold sensitive. Thus, our study suggests that adipocyte CXCR4 limits development of obesity by preventing excessive inflammatory cell recruitment into WAT and by supporting thermogenic activity of BAT. Since CXCR4 is conserved between mouse and human, the newfound role of CXCR4 in mouse adipose tissue may parallel the role of this chemokine receptor in human adipose tissue. [ABSTRACT FROM AUTHOR]

Published

2014

44. Rapid Inhibition of Pyruvate Dehydrogenase: An Initiating Event in High Dietary Fat-Induced Loss of Metabolic Flexibility in the Heart.

Author

Crewe, Clair, Kinter, Michael, and Szweda, Luke I.

Subjects

*PYRUVATE dehydrogenase complex, *HIGH-fat diet, *HEART physiology, *HEART metabolism, *OXIDATION of glucose, *FATTY acid oxidation, *PHYSIOLOGICAL stress

Abstract

Cardiac function depends on the ability to switch between fatty acid and glucose oxidation for energy production in response to changes in substrate availability and energetic stress. In obese and diabetic individuals, increased reliance on fatty acids and reduced metabolic flexibility are thought to contribute to the development of cardiovascular disease. Mechanisms by which cardiac mitochondria contribute to diet-induced metabolic inflexibility were investigated. Mice were fed a high fat or low fat diet for 1 d, 1 wk, and 20 wk. Cardiac mitochondria isolated from mice fed a high fat diet displayed a diminished ability to utilize the glycolytically derived substrate pyruvate. This response was rapid, occurring within the first day on the diet, and persisted for up to 20 wk. A selective increase in the expression of pyruvate dehydrogenase kinase 4 and inhibition of pyruvate dehydrogenase are responsible for the rapid suppression of pyruvate utilization. An important consequence is that pyruvate dehydrogenase is sensitized to inhibition when mitochondria respire in the presence of fatty acids. Additionally, increased expression of pyruvate dehydrogenase kinase 4 preceded any observed diet-induced reductions in the levels of glucose transporter type 4 and glycolytic enzymes and, as judged by Akt phosphorylation, insulin signaling. Importantly, diminished insulin signaling evident at 1 wk on the high fat diet did not occur in pyruvate dehydrogenase kinase 4 knockout mice. Dietary intervention leads to a rapid decline in pyruvate dehydrogenase kinase 4 levels and recovery of pyruvate dehydrogenase activity indicating an additional form of regulation. Finally, an overnight fast elicits a metabolic response similar to that induced by high dietary fat obscuring diet-induced metabolic changes. Thus, our data indicate that diet-induced inhibition of pyruvate dehydrogenase may be an initiating event in decreased oxidation of glucose and increased reliance of the heart on fatty acids for energy production. [ABSTRACT FROM AUTHOR]

Published

2013

45. Redox regulation of insulin sensitivity due to enhanced fatty acid utilization in the mitochondria.

Author

Rindler, Paul M., Crewe, Clair L., Fernandes, Jolyn, Kinter, Michael, and Szweda, Luke I.

Abstract

Obesity enhances the risk for the development of type 2 diabetes and cardiovascular disease. Loss in insulin sensitivity and diminished ability of muscle to take up and use glucose are characteristics of type 2 diabetes. Paradoxically, regulatory mechanisms that promote utilization of fatty acids appear to initiate diet-induced insulin insensitivity. In this review, we discuss recent findings implicating increased mitochondrial production of the prooxidant H2O2 due to enhanced utilization of fatty acids, as a signal to diminish reliance on glucose and its metabolites for energy. In the short term, the ability to preferentially use fatty acids may be beneficial, promoting a metabolic shift that ensures use of available fat by skeletal muscle and heart while preventing intracellular glucose accumulation and toxicity. However, with prolonged consumption of high dietary fat and ensuing obesity, the near exclusive dependence on fatty acid oxidation for production of energy by the mitochondria drives insulin resistance, diabetes, and cardiovascular disease. [ABSTRACT FROM AUTHOR]

Published

2013

46. Glutathionylation of α-ketoglutarate dehydrogenase: The chemical nature and relative susceptibility of the cofactor lipoic acid to modification.

Author

McLain, Aaron L., Cormier, Peter J., Kinter, Michael, and Szweda, Luke I.

Subjects

*GLUTATHIONE, *KETOGLUTARATE dehydrogenase, *DISEASE susceptibility, *COFACTORS (Biochemistry), *LIPOIC acid, *LABORATORY rats

Abstract

Abstract: α-Ketoglutarate dehydrogenase (KGDH) is reversibly inhibited when rat heart mitochondria are exposed to hydrogen peroxide (H2O2). H2O2-induced inhibition occurs through the formation of a mixed disulfide between a protein sulfhydryl and glutathione. Upon consumption of H2O2, glutaredoxin can rapidly remove glutathione, resulting in regeneration of enzyme activity. KGDH is a key regulatory site within the Krebs cycle. Glutathionylation of the enzyme may therefore represent an important means to control mitochondrial function in response to oxidative stress. We have previously provided indirect evidence that glutathionylation occurs on lipoic acid, a cofactor covalently bound to the E2 subunit of KGDH. However, lipoic acid contains two vicinal sulfhydryls and rapid disulfide exchange might be predicted to preclude stable glutathionylation. The current study sought conclusive identification of the site and chemistry of KGDH glutathionylation and factors that control the degree and rate of enzyme inhibition. We present evidence that, upon reaction of free lipoic acid with oxidized glutathione in solution, disulfide exchange occurs rapidly, producing oxidized lipoic acid and reduced glutathione. This prevents the stable formation of a glutathione–lipoic acid adduct. Nevertheless, 1:1 lipoic acid–glutathione adducts are formed on KGDH because the second sulfhydryl on lipoic acid is unable to participate in disulfide exchange in the enzyme's native conformation. The maximum degree of KGDH inhibition that can be achieved by treatment of mitochondria with H2O2 is 50%. Results indicate that this is not due to glutathionylation of a subpopulation of the enzyme but, rather, the unique susceptibility of lipoic acid on a subset of E2 subunits within each enzyme complex. Calcium enhances the rate of glutathionylation by increasing the half-life of reduced lipoic acid during enzyme catalysis. This does not, however, alter the maximal level of inhibition, providing further evidence that specific lipoic acid residues within the E2 complex are susceptible to glutathionylation. These findings offer chemical information necessary for the identification of mechanisms and physiological implications of KGDH glutathionylation. [Copyright &y& Elsevier]

Published

2013

47. A Quantitative Proteomic Profile of the Nrf2-Mediated Antioxidant Response of Macrophages to Oxidized LDL Determined by Multiplexed Selected Reaction Monitoring.

Author

Kinter, Caroline S., Lundie, Jillian M., Patel, Halee, Rindler, Paul M., Szweda, Luke I., and Kinter, Michael

Subjects

*GLYCOPROTEINS, *INFECTION, *CRYSTALLOGRAPHY, *SALT, *ELECTROSTATICS, *MOLECULAR dynamics

Abstract

The loading of macrophages with oxidized low density lipoprotein (LDL) is a key part of the initiation and progression of atherosclerosis. Oxidized LDL contains a wide ranging set of toxic species, yet the molecular events that allow macrophages to withstand loading with these toxic species are not completely characterized. The transcription factor nuclear factor (erythroid-derived 2)-like 2 (Nrf2) is a master regulator of the cellular stress response. However, the specific parts of the Nrf2-dependent stress response are diverse, with both tissue- and treatment-dependent components. The goal of these experiments was to develop and use a quantitative proteomic approach to characterize the Nrf2-dependent response in macrophages to oxidized LDL. Cultured mouse macrophages, the J774 macrophage-like cell line, were treated with a combination of oxidized LDL, the Nrf2-stabilizing reagent tert- butylhydroquinone (tBHQ), and/or Nrf2 siRNA. Protein expression was determined using a quantitative proteomics assay based on selected reaction monitoring. The assay was multiplexed to monitor a set of 28 antioxidant and stress response proteins, 6 housekeeping proteins, and 1 non-endogenous standard protein. The results have two components. The first component is the validation of the multiplexed, quantitative proteomics assay. The assay is shown to be fundamentally quantitative, precise, and accurate. The second component is the characterization of the Nrf2-mediated stress response. Treatment with tBHQ and/or Nrf2 siRNA gave statistically significant changes in the expression of a subset of 11 proteins. Treatment with oxidized LDL gave statistically significant increases in the expression of 7 of those 11 proteins plus one additional protein. All of the oxLDL-mediated increases were attenuated by Nrf2 siRNA. These results reveal a specific, multifaceted response of the foam cells to the incoming toxic oxidized LDL. [ABSTRACT FROM AUTHOR]

Published

2012

48. α-Ketoglutarate Dehydrogenase: A Mitochondrial Redox Sensor

Author

McLain, Aaron L., Kinter, Michael, and Szweda, Luke I.

Published

2010

49. Hydroxynonenal-generated crosslinking fluorophore accumulation in Alzheimer disease reveals a dichotomy of protein turnover

Author

Zhu, Xiongwei, Castellani, Rudy J., Moreira, Paula I., Aliev, Gjumrakch, Shenk, Justin C., Siedlak, Sandra L., Harris, Peggy L.R., Fujioka, Hisashi, Sayre, Lawrence M., Szweda, Pamela A., Szweda, Luke I., Smith, Mark A., and Perry, George

Subjects

*ALZHEIMER'S disease, *LIPID peroxidation (Biology), *ALDEHYDES, *AMINO acids, *OXIDATIVE stress, *PROTEIN crosslinking, *LIPOFUSCINS

Abstract

Abstract: Lipid peroxidation generates reactive aldehydes, most notably hydroxynonenal (HNE), which covalently bind amino acid residue side chains leading to protein inactivation and insolubility. Specific adducts of lipid peroxidation have been demonstrated in intimate association with the pathological lesions of Alzheimer disease (AD), suggesting that oxidative stress is a major component of AD pathogenesis. Some HNE-protein products result in protein crosslinking through a fluorescent compound similar to lipofuscin, linking lipid peroxidation and the lipofuscin accumulation that commonly occurs in post-mitotic cells such as neurons. In this study, brain tissue from AD and control patients was examined by immunocytochemistry and immunoelectron microscopy for evidence of HNE-crosslinking modifications of the type that should accumulate in the lipofuscin pathway. Strong labeling of granulovacuolar degeneration (GVD) and Hirano bodies was noted but lipofuscin did not contain this specific HNE-fluorophore. These findings directly implicate lipid crosslinking peroxidation products as accumulating not in the lesions or the lipofuscin pathways, but instead in a distinct pathway, GVD, that accumulates cytosolic proteins. [Copyright &y& Elsevier]

Published

2012

50. Proteasome alterations during adipose differentiation and aging: links to impaired adipocyte differentiation and development of oxidative stress

Author

Dasuri, Kalavathi, Zhang, Le, Ebenezer, Philip, Fernandez-Kim, Sun Ok, Bruce-Keller, Annadora J., Szweda, Luke I., and Keller, Jeffrey N.

Subjects

*PROTEOLYSIS, *FAT cells, *CELL differentiation, *CELLULAR aging, *OXIDATIVE stress, *INSULIN resistance, *FREE radicals, *OBESITY

Abstract

Abstract: Intracellular proteins are degraded by a number of proteases, including the ubiquitin–proteasome pathway (UPP). Impairments in the UPP occur during the aging of a variety of tissues, although little is known in regards to age-related alterations to the UPP during the aging of adipose tissue. The UPP is known to be involved in regulating the differentiation of a variety of cell types, although the potential changes in the UPP during adipose differentiation have not been fully elucidated. How the UPP is altered in aging adipose tissue and adipocyte differentiation and the effects of proteasome inhibition on adipocyte homeostasis and differentiation are critical issues to elucidate experimentally. Adipogenesis continues throughout the life of adipose tissue, with continual differentiation of preadipocytes essential to maintaining tissue function during aging, and UPP alterations in mature adipocytes are likely to directly modulate adipose function during aging. In this study we demonstrate that aging induces alterations in the activity and expression of principal components of the UPP. Additionally, we show that multiple changes in the UPP occur during the differentiation of 3T3-L1 cells into adipocytes. In vitro data link observed UPP alterations to increased levels of oxidative stress and altered adipose biology relevant to both aging and differentiation. Taken together, these data demonstrate that changes in the UPP occur in response to adipose aging and adipogenesis and strongly suggest that proteasome inhibition is sufficient to decrease adipose differentiation, as well as increasing oxidative stress in mature adipocytes, both of which probably promote deleterious effects on adipose aging. [Copyright &y& Elsevier]

Published

2011