Your search keyword '"Fox, Jonathan H"' showing total 7 results

1. Novel proteomic changes in brain mitochondria provide insights into mitochondrial dysfunction in mouse models of Huntington's disease.

Author

Agrawal, Sonal and Fox, Jonathan H.

Subjects

*HUNTINGTON disease, *PROTEOMICS, *KREBS cycle, *ADENOSINE triphosphatase, *ISOCITRATE dehydrogenase, *MITOCHONDRIAL proteins

Abstract

Huntington's disease (HD) is a progressive ultimately fatal disorder caused by a glutamine-encoding CAG expansion in the huntingtin (HTT) gene that results in degeneration mainly in striatal and cerebro-cortical brain regions. Mitochondrial dysfunction is one important facet of HD pathogenesis. Here we used R6/2 and YAC128 HD mouse models of human HD, that express different HTT transgenes and have different progression rates, to identify HD brain mitochondrial proteomic signatures. Cerebral cortical mitochondrial preparations from HD and wild-type litter mate mice were compared by two-dimensional SDS-PAGE electrophoresis and MALDI-TOF/TOF mass spectrometry. Proteomic analyses inferred 17 and 12 differentially expressed proteins, respectively in 12 week R6/2 and 15 month YAC128 HD mice, compared to controls. Peroxiredoxin 3, stress-70, DJ-1, isocitrate dehydrogenase [NAD] α subunit and ATP synthase subunit D were differentially expressed in both models. Using the PANTHER (Protein ANalysis THrough Evolutionary Relationships) classification system we show that the inferred proteins are involved in oxidative stress defense, oxidative phosphorylation, the citric acid cycle, pyruvate metabolism, apoptosis, protein folding and iron metabolism. Common mitochondrial proteomic changes are significant in mouse models of middle (YAC128) and advanced (R6/2) HD despite differences in the HTT transgenes, age, genetic background and disease stage. The findings identify a proteomic signature of HD mitochondria in mouse models that includes previously unrecognized proteins. • Mitochondria have an important role in the pathogenesis of Huntington's disease (HD). • Brain mitochondria in two mouse models of HD were studied. • Common proteomic changes in mitochondrial redox proteins occurred in both models. [ABSTRACT FROM AUTHOR]

Published

2019

2. Amyloid Precursor Protein Haploinsufficiency Preferentially Mediates Brain Iron Accumulation in Mice Transgenic for The Huntington's Disease Mutation.

Author

Berggren, Kiersten, Agrawal, Sonal, Fox, Julia A., Hildenbrand, Justin, Nelson, Ryan, Bush, Ashley I., and Fox, Jonathan H.

Subjects

PROTEIN precursors, AMYLOID, HUNTINGTON disease, HETEROZYGOSITY, LABORATORY mice

Abstract

Background: Huntington's disease (HD) is an autosomal dominant disorder caused by a CAG expansion in the huntingtin gene that results in expression of mutant huntingtin protein. Iron accumulates inHDbrain neurons. Amyloid precursor protein (APP) promotes neuronal iron export. However, the role of APP in brain iron accumulation in HD is unclear. Objective: To determine the effects of APP insufficiency on HD in YAC128 mice. Methods: We crossed APP hemizygous mice (APP+/-) with YAC128 mice that are transgenic (Tg) for human mutant huntingtin (hmHTT) to generate APP+/+ hmHTT-/-, APP+/- hmHTT-/-, APP+/+ hmHTT+/- and APP+/- hmHTT+/- progeny. Mice were evaluated for behavioral, biochemical and neuropathology HD outcomes at 2-12 months of age. Results: APP heterozygosity decreased cortical APP 25% and 60% in non-Tg and Tg mice, respectively. Cerebral and striatal iron levels were increased by APP knockdown in Tg mice only. Nest-building behavior was decreased in Tg mice; APP knockdown decreased nest building in non-Tg but not Tg mice. Rota-rod endurance was decreased in Tg mice. APP+/- hHTT+/- mice demonstrated additional decreases in rota-rod endurance from 4-10 months of age. Tg mice had smaller striatal volumes and fewer striatal neurons but were not affected by APP knockdown. Conclusions: APP heterozygosity results in greater decreases of cortical APP in Tg versus non-Tg mice. Mutant huntingtin transgenic mice develop brain iron accumulation as a result of greater suppression of APP levels. Elevated brain iron in Tg mice was associated with a decline in motor endurance consistent with a disease promoting effect of iron in the YAC128 model of human HD. [ABSTRACT FROM AUTHOR]

Published

2017

3. Neonatal Iron Supplementation Induces Striatal Atrophy in Female YAC128 Huntington's Disease Mice.

Author

Berggren, Kiersten L., Lu, Zhen, Fox, Julia A., Dudenhoeffer, Megan, Agrawal, Sonal, and Fox, Jonathan H.

Subjects

HUNTINGTON disease, IRON supplements, IRON in the body, NEONATAL diseases, DELAYED onset of disease, IRON

Abstract

Background: Dysregulation of iron homeostasis is implicated in the pathogenesis of Huntington's disease. We have previously shown that increased iron intake in R6/2 HD neonatal mice, but not adult R6/2 HD mice potentiates disease outcomes at 12-weeks of age corresponding to advanced HD [Redox Biol. 2015;4 : 363–74]. However, whether these findings extend to other HD models is unknown. In particular, it is unclear if increased neonatal iron intake can promote neurodegeneration in mouse HD models where disease onset is delayed to mid-adult life. Objective: To determine if increased dietary iron intake in neonatal and adult life-stages potentiates HD in the slowly progressive YAC128 HD mouse model. Methods: Female neonatal mice were supplemented daily from days 10–17 with 120μg/g body weight of carbonyl iron. Adult mice were provided diets containing low (50 ppm), medium (150 ppm) and high (500 ppm) iron concentrations from 2-months of age. HD progression was determined using behavioral, brain morphometric and biochemical approaches. Results: Neonatal-iron supplemented YAC128 HD mice had significantly lower striatal volumes and striatal neuronal cell body volumes as compared to control HD mice at 1-year of age. Neonatal-iron supplementation of HD mice had no effect on rota-rod motor endurance and brain iron or glutathione status. Adult iron intake level had no effect on HD progression. YAC128 HD mice had altered peripheral responses to iron intake compared to iron-matched wild-type controls. Conclusions: Female YAC128 HD mice supplemented with nutritionally-relevant levels of iron as neonates demonstrate increased striatal degeneration 1-year later. [ABSTRACT FROM AUTHOR]

Published

2016

4. Cellular Localization of Kynurenine 3-Monooxygenase in the Brain: Challenging the Dogma.

Author

Sathyasaikumar, Korrapati V., Pérez de la Cruz, Verónica, Pineda, Benjamín, Vázquez Cervantes, Gustavo Ignacio, Ramírez Ortega, Daniela, Donley, David W., Severson, Paul L., West, Brian L., Giorgini, Flaviano, Fox, Jonathan H., and Schwarcz, Robert

Subjects

MICROGLIA, MACROPHAGE colony-stimulating factor, HUNTINGTON disease, KYNURENINE, BRAIN diseases, YOUNG adults

Abstract

Kynurenine 3-monooxygenase (KMO), a key player in the kynurenine pathway (KP) of tryptophan degradation, regulates the synthesis of the neuroactive metabolites 3-hydroxykynurenine (3-HK) and kynurenic acid (KYNA). KMO activity has been implicated in several major brain diseases including Huntington's disease (HD) and schizophrenia. In the brain, KMO is widely believed to be predominantly localized in microglial cells, but verification in vivo has not been provided so far. Here, we examined KP metabolism in the brain after depleting microglial cells pharmacologically with the colony stimulating factor 1 receptor inhibitor PLX5622. Young adult mice were fed PLX5622 for 21 days and were euthanized either on the next day or after receiving normal chow for an additional 21 days. Expression of microglial marker genes was dramatically reduced on day 22 but had fully recovered by day 43. In both groups, PLX5622 treatment failed to affect Kmo expression, KMO activity or tissue levels of 3-HK and KYNA in the brain. In a parallel experiment, PLX5622 treatment also did not reduce KMO activity, 3-HK and KYNA in the brain of R6/2 mice (a model of HD with activated microglia). Finally, using freshly isolated mouse cells ex vivo, we found KMO only in microglia and neurons but not in astrocytes. Taken together, these data unexpectedly revealed that neurons contain a large proportion of functional KMO in the adult mouse brain under both physiological and pathological conditions. [ABSTRACT FROM AUTHOR]

Published

2022

5. Cystamine increasesl-cysteine levels in Huntington's disease transgenic mouse brain and in a PC12 model of polyglutamine aggregation.

Author

Fox, Jonathan H., Barber, David S., Singh, Bhupinder, Zucker, Birgit, Swindell, Mary K., Norflus, Fran, Buzescu, Rodica, Chopra, Raman, Ferrante, Robert J., Kazantsev, Aleksey, and Hersch, Steven M.

Subjects

*GLUTATHIONE, *HUNTINGTON disease, *NEURODEGENERATION, *OXIDATIVE stress, *CHEMICAL inhibitors, *NEUROCHEMISTRY

Abstract

Cystamine, a small disulfide-containing chemical, is neuroprotective in a transgenic mouse and a Drosophila model of Huntington's disease (HD) and decreases huntingtin aggregates in an in vitro model of HD. The mechanism of action of cystamine in these models is widely thought to involve inhibition of transglutaminase mediated cross-linking of mutant huntingtin in the process of aggregate formation/stabilization. In this study we show that cystamine, both in vitro and in a transgenic mouse model of HD (R6/2), increases levels of the cellular antioxidant L-cysteine. Several oxidative stress markers increase in HD brain. We provide further evidence of oxidative stress in mouse HD by demonstrating compensatory responses in R6/2 HD brains. We found age-dependent increases in forebrain glutathione (GSH), and increased levels of transcripts coding for proteins involved in GSH synthesis and detoxification pathways, as revealed by quantitative PCR analysis. Given the general importance of oxidative stress as a mediator of neurodegeneration we propose that an increase in brain L-cysteine levels could be protective in HD. Furthermore, cystamine was dramatically protective against 3-nitropropionic acid-induced striatal injury in mice. We suggest that cystamine's neuroprotective effect in HD transgenic mice results from pleiotropic effects that include transglutaminase inhibition and antioxidant activity. [ABSTRACT FROM AUTHOR]

Published

2004

6. Brain mitochondrial iron accumulates in Huntington's disease, mediates mitochondrial dysfunction, and can be removed pharmacologically.

Author

Agrawal, Sonal, Fox, Julia, Thyagarajan, Baskaran, and Fox, Jonathan H.

Subjects

*MITOCHONDRIAL proteins, *HUNTINGTON'S chorea treatment, *BIOENERGETIC measurements, *NEURODEGENERATION, *IRON-sulfur proteins, *DIAGNOSIS

Abstract

Mitochondrial bioenergetic dysfunction is involved in neurodegeneration in Huntington's disease (HD). Iron is critical for normal mitochondrial bioenergetics but can also contribute to pathogenic oxidation. The accumulation of iron in the brain occurs in mouse models and in human HD. Yet the role of mitochondria-related iron dysregulation as a contributor to bioenergetic pathophysiology in HD is unclear. We demonstrate here that human HD and mouse model HD (12-week R6/2 and 12-month YAC128) brains accumulated mitochondrial iron and showed increased expression of iron uptake protein mitoferrin 2 and decreased iron-sulfur cluster synthesis protein frataxin. Mitochondria-enriched fractions from mouse HD brains had deficits in membrane potential and oxygen uptake and increased lipid peroxidation. In addition, the membrane-permeable iron-selective chelator deferiprone (1 μM) rescued these effects ex-vivo , whereas hydrophilic iron and copper chelators did not. A 10-day oral deferiprone treatment in 9-week R6/2 HD mice indicated that deferiprone removed mitochondrial iron, restored mitochondrial potentials, decreased lipid peroxidation, and improved motor endurance. Neonatal iron supplementation potentiates neurodegeneration in mouse models of HD by unknown mechanisms. We found that neonatal iron supplementation increased brain mitochondrial iron accumulation and potentiated markers of mitochondrial dysfunction in HD mice. Therefore, bi-directional manipulation of mitochondrial iron can potentiate and protect against markers of mouse HD. Our findings thus demonstrate the significance of iron as a mediator of mitochondrial dysfunction and injury in mouse models of human HD and suggest that targeting the iron-mitochondrial pathway may be protective. [ABSTRACT FROM AUTHOR]

Published

2018

7. Altered selenium status in Huntington's disease: Neuroprotection by selenite in the N171-82Q mouse model.

Author

Lu, Zhen, Marks, Eileen, Chen, Jianfang, Moline, Jenna, Barrows, Lorraine, Raisbeck, Merl, Volitakis, Irene, Cherny, Robert A., Chopra, Vanita, Bush, Ashley I., Hersch, Steven, and Fox, Jonathan H.

Subjects

*HUNTINGTON'S chorea treatment, *NEUROPROTECTIVE agents, *SELENITES, *METALS in medicine, *AUTOPSY, *LABORATORY mice

Abstract

Disruption of redox homeostasis is a prominent feature in the pathogenesis of Huntington's disease (HD). Selenium an essential element nutrient that modulates redox pathways and has been reported to provide protection against both acute neurotoxicity (e.g. methamphetamine) and chronic neurodegeneration (e.g. tauopathy) in mice. The objective of our study was to investigate the effect of sodium selenite, an inorganic form of selenium, on behavioral, brain degeneration and biochemical outcomes in the N171-82Q Huntington's disease mouse model. HD mice, which were supplemented with sodium selenite from 6 to 14 weeks of age, demonstrated increased motor endurance, decreased loss of brain weight, decreased mutant huntingtin aggregate burden and decreased brain oxidized glutathione levels. Biochemical studies revealed that selenite treatment reverted HD-associated changes in liver selenium and plasma glutathione in N171-82Q mice and had effects on brain selenoprotein transcript expression. Further, we found decreased brain selenium content in human autopsy brain. Taken together, we demonstrate a decreased selenium phenotype in human and mouse HD and additionally show some protective effects of selenite in N171-82Q HD mice. Modification of selenium metabolism results in beneficial effects in mouse HD and thus may represent a therapeutic strategy. [ABSTRACT FROM AUTHOR]

Published

2014