Shankar J. Chinta scite author profile

SUMMARYExposure to the herbicide paraquat (PQ) is associated with an increased risk of idiopathic Parkinson’s disease (PD). Therapies based on PQ’s presumed mechanisms of action have not, however, yielded effective disease therapies. Cellular senescence is an anticancer mechanism that arrests proliferation of replication-competent cells and results in a pro-inflammatory senescence-associated secretory phenotype (SASP) capable of damaging neighboring tissues. Here, we demonstrate that senescent cell markers are preferentially present within astrocytes in PD brain tissues. Additionally, PQ was found to induce astrocytic senescence and an SASP in vitro and in vivo, and senescent cell depletion in the latter protects against PQ-induced neuropathology. Our data suggest that exposure to certain environmental toxins promotes accumulation of senescent cells in the aging brain, which can contribute to dopaminergic neurodegeneration. Therapies that target senescent cells may constitute a strategy for treatment of sporadic PD, for which environmental exposure is a major risk factor.

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Mitochondrial alpha-synuclein accumulation impairs complex I function in dopaminergic neurons and results in increased mitophagy in vivo

Chinta

Mallajosyula

Rane

et al. 2010

Neuroscience Letters

360

307

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Alpha-synuclein is the major protein component of Lewy bodies, a cardinal pathological feature of the degenerating Parkinsonian brain. Alpha-synuclein has been reported to be able to intercalate into membranes via formation of an alpha-helical structure at its N-terminal end. Recent in vitro studies from various laboratories have demonstrated that alpha-synuclein can physically associate with mitochondria and interfere with mitochondrial function. α-Syn predominantly associates with the inner mitochondrial membrane, where it can apparently interact with complex I resulting in reduced mitochondrial complex I activity and increased free radical production. However, the effect of in vivo alpha-synuclein accumulation within dopaminergic neurons on mitochondrial function has not been thoroughly studied. Examination of transgenic animals which overexpress the familial mutant A53T form of the protein selectively within dopaminergic neurons reveals that A53T localizes to the mitochondrial membranes as monomers and oligomers particularly under conditions of proteasomal inhibitory stress, and that this localization coincides with a selective age-related mitochondrial complex I inhibition and decreased substrate-specific respiration along with increases in mitochondrial autophagy (mitophagy). KeywordsAlpha-synuclein (α-syn); mitochondria; oligomers; Parkinson's disease; proteasomal inhibition; mitochondrial complex I (CI) activity; mitophagy Parkinson's disease (PD) is a progressive neurodegenerative disorder characterized by preferential loss of dopaminergic neurons in the substantia nigra pars compacta (SNpc) [20]. PD is also accompanied by the hallmark formation of intracytoplasmic protein aggregates termed "Lewy bodies" which include alpha-synuclein (α-syn) as a major protein component [29]. Monomeric α-syn is a 14 kD presynaptic protein with as yet enigmatic cellular function. Due to the presence of six imperfect 11-amino acid repeat sequences within its Nterminus, this results in formation of an alpha helical structure which mediates the protein's binding to phospholipid vesicles. α-syn can also aggregate into higher molecular weight oligomers. It has been proposed that oligomerization results in induction of a beta-pleated Address correspondence to: Professor Julie K. Andersen, Ph.D, 8001 Redwood Blvd, Novato, CA 94945, Ph: (415) 209-2070, Fax: (415) 209-2231, jandersen@buckinstitute.org. Conflict of interestThe authors report no conflicts of interest.Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. sheet structure within the protein that aids in its further aggregat...

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MAO-B Elevation in Mouse Brain Astrocytes Results in Parkinson's Pathology

et al. 2008

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Age-related increases in monoamine oxidase B (MAO-B) may contribute to neurodegeneration associated with Parkinson's disease (PD). The MAO-B inhibitor deprenyl, a long-standing antiparkinsonian therapy, is currently used clinically in concert with the dopamine precursor L-DOPA. Clinical studies suggesting that deprenyl treatment alone is not protective against PD associated mortality were targeted to symptomatic patients. However, dopamine loss is at least 60% by the time PD is symptomatically detectable, therefore lack of effect of MAO-B inhibition in these patients does not negate a role for MAO-B in pre-symptomatic dopaminergic loss. In order to directly evaluate the role of age-related elevations in astroglial MAO-B in the early initiation or progression of PD, we created genetically engineered transgenic mice in which MAO-B levels could be specifically induced within astroglia in adult animals. Elevated astrocytic MAO-B mimicking age related increase resulted in specific, selective and progressive loss of dopaminergic neurons in the substantia nigra (SN), the same subset of neurons primarily impacted in the human condition. This was accompanied by other PD-related alterations including selective decreases in mitochondrial complex I activity and increased mitochondrial oxidative stress. Along with a global astrogliosis, we observed local microglial activation within the SN. These pathologies correlated with decreased locomotor activity. Importantly, these events occurred even in the absence of the PD-inducing neurotoxin MPTP. Our data demonstrates that elevation of murine astrocytic MAO-B by itself can induce several phenotypes of PD, signifying that MAO-B could be directly involved in multiple aspects of disease neuropathology. Mechanistically this may involve increases in membrane permeant H2O2 which can oxidize dopamine within dopaminergic neurons to dopaminochrome which, via interaction with mitochondrial complex I, can result in increased mitochondrial superoxide. Our inducible astrocytic MAO-B transgenic provides a novel model for exploring pathways involved in initiation and progression of several key features associated with PD pathology and for therapeutic drug testing.

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Redox imbalance in Parkinson's disease

Chinta¹,

Andersen²

2008

Biochimica et Biophysica Acta (BBA) - General Subjects

245

194

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Parkinson's disease (PD) is an adult-onset neurodegenerative disorder characterized by preferential loss of dopaminergic neurons in an area of the midbrain called the substantia nigra (SN) along with occurrence of intraneuronal inclusions called Lewy bodies. The majority of cases of PD are sporadic in nature with late onset (95% of patients); however a few PD cases (5%) are seen in familial clusters with generally earlier onset. Although PD has been heavily researched, so far the exact cause of the rather selective cell death is unknown. Multiple lines of evidence suggest an important role for oxidative stress. Dopaminergic neurons (DA) are particularly prone to oxidative stress due to DA metabolism and auto-oxidation combined with increased iron, decreased total glutathione levels and mitochondrial complex I inhibition-induced ROS production in the SN which can lead to cell death by exceeding the oxidative capacity of DA-containing cells in the region. Enhancing antioxidant capabilities and chelating labile iron pools in this region therefore constitutes a rational approach to prevent or slow ongoing damage of DA neurons. In this review, we summarize the various sources of reactive oxygen species that may cause redox imbalance in PD as well as potential therapeutic targets for attenuation of oxidative stress associated with PD.

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Cellular senescence and the aging brain

Chinta

Woods

Rane

et al. 2015

Experimental Gerontology

219

162

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Cellular senescence is a potent anti-cancer mechanism that arrests the proliferation of mitotically competent cells to prevent malignant transformation. Senescent cells accumulate with age in a variety of human and mouse tissues where they express a complex ‘senescence-associated secretory phenotype’ (SASP). The SASP includes many pro-inflammatory cytokines, chemokines, growth factors and proteases that have the potential to cause or exacerbate age-related pathology, both degenerative and hyperplastic. While cellular senescence in peripheral tissues has recently been linked to a number of age-related pathologies, its involvement in brain aging is just beginning to be explored. Recent data generated by several laboratories suggest both aging and age-related neurodegenerative diseases are accompanied by an increase in SASP-expressing senescent cells of non-neuronal origin in the brain. Moreover, this increase correlates with neurodegeneration. Senescent cells in the brain could therefore constitute novel therapeutic targets for treating age-related neuropathologies.

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Dopaminergic neurons

Chinta

Andersen

2005

The International Journal of Biochemistry & Cell Biology

272

157

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Selective binding of nuclear alpha-synuclein to the PGC1alpha promoter under conditions of oxidative stress may contribute to losses in mitochondrial function: Implications for Parkinson’s disease

Siddiqui

Chinta

Mallajosyula

et al. 2012

Free Radical Biology and Medicine

156

151

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Alpha-synuclein has been reported to be present in the nucleus and levels enhanced by oxidative stress. Herein, we sought to investigate the mechanistic role of nuclear alpha-synuclein. We found that alpha-synuclein nuclear localization coincided with enhanced chromatin binding both in an in vitro and a corresponding in vivo brain oxidative stress model previously characterized by our laboratory as well as in PD brain tissues. Genome-wide chromatin immunoprecipitation (ChIP)-on-chip analysis of alpha-synuclein:promoter binding in response to oxidative stress in vitro revealed that binding occurs at several promoters belonging to a range of functional categories including transcriptional regulation. Interestingly, given the important role of mitochondrial dysfunction in PD, this included binding to the promoter for the master mitochondrial transcription activator, PGC1alpha in vitro, in vivo, and in human brain tissue with age and PD. To test the possible mechanistic impact of alpha-synuclein PGC1alpha promotor binding, we assessed PGC1alpha promoter activity, mRNA, and protein levels and expression of candidate PGC1alpha-target genes in our in vitro model. All were found to be reduced in conjunction with increased levels of aberrant mitochondrial morphology and impaired mitochondrial function. Exogenous PGC1alpha expression was found to attenuate alpha-synuclein-mediated mitochondrial dysfunction and subsequent neurotoxicity in vitro. Our data suggests that nuclear alpha-synuclein localization under conditions of oxidative stress may impact on mitochondrial function in part via the protein’s capacity to act as a transcriptional modulator of PGC1alpha. This represents a novel role for alpha-synuclein as it relates to mitochondrial dysfunction in PD.

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Increased murine neonatal iron intake results in Parkinson-like neurodegeneration with age

Kaur

Peng

Chinta

et al. 2007

Neurobiology of Aging

126

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Shankar J. Chinta

Cellular Senescence Is Induced by the Environmental Neurotoxin Paraquat and Contributes to Neuropathology Linked to Parkinson’s Disease

Mitochondrial alpha-synuclein accumulation impairs complex I function in dopaminergic neurons and results in increased mitophagy in vivo

MAO-B Elevation in Mouse Brain Astrocytes Results in Parkinson's Pathology

Redox imbalance in Parkinson's disease

Cellular senescence and the aging brain

Dopaminergic neurons

Selective binding of nuclear alpha-synuclein to the PGC1alpha promoter under conditions of oxidative stress may contribute to losses in mitochondrial function: Implications for Parkinson’s disease

Increased murine neonatal iron intake results in Parkinson-like neurodegeneration with age

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