Parkinson’s disease is associated with altered expression of CaV1 channels and calcium-binding proteins

In Parkinson's disease oxidative stress and calcium-induced excitotoxicity have been considered important mechanisms leading to cell death for decades, but the factors that make some neurons vulnerable to neurodegeneration while others remain resistant are not fully understood. Studies of the d...

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Published inBrain (London, England : 1878) Vol. 136; no. 7; pp. 2077 - 2097
Main Authors Hurley, Michael J., Brandon, Bianca, Gentleman, Steve M., Dexter, David T.
Format Journal Article
LanguageEnglish
Published Oxford Oxford University Press 01.07.2013
Subjects
Aged
Aged, 80 and over
Analysis of Variance
Biological and medical sciences
Brain - pathology
Calcium Channels, L-Type - metabolism
Calcium-Binding Proteins - metabolism
Cell Count
Degenerative and inherited degenerative diseases of the nervous system. Leukodystrophies. Prion diseases
Densitometry
DNA-Binding Proteins - metabolism
Female
Humans
Male
Medical sciences
Microfilament Proteins
Middle Aged
Nerve Tissue Proteins - metabolism
Neurology
Neurons - metabolism
Parkinson Disease - metabolism
Parkinson Disease - pathology
Spinal Cord - metabolism
Spinal Cord - pathology
Stereotaxic Techniques
calcium channel
Nervous system diseases
Parkinson's disease
Calcium
Parkinson disease
calcium-binding proteins
Involuntary movement
Cerebral disorder
Binding protein
dihydropyridines
Central nervous system disease
Degenerative disease
Neurological disorder
Extrapyramidal syndrome
Dyskinesia
dyskinesia
Parkinson’s disease
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Abstract In Parkinson's disease oxidative stress and calcium-induced excitotoxicity have been considered important mechanisms leading to cell death for decades, but the factors that make some neurons vulnerable to neurodegeneration while others remain resistant are not fully understood. Studies of the disorder in animal models suggest that the voltage-gated calcium channel subtype Ca(V)1.3 has a role in making neurons susceptible to neurodegeneration and support earlier work in post-mortem human brain that suggested loss of calcium buffering capacity in neurons correlated with areas of neuronal loss in the substantia nigra of parkinsonian brain. This study examined expression of Ca(V)1 subtypes and the calcium-binding proteins calbindin, calmodulin and calreticulin in areas vulnerable and resistant to neurodegeneration in Parkinson's disease, in brain from neurologically normal individuals and patients with Parkinson's disease. In control brain the expression of a specific Ca(V)1 subtype or distribution of each calcium-binding protein did not associate with those regions prone to neurodegeneration in Parkinson's disease. Whereas, alterations in the amount of both Ca(V)1 subtypes and the calcium-binding proteins were found throughout the brain in Parkinson's disease. Some changes reflected the cell loss seen in Parkinson's disease, whereas others represented altered levels of cellular expression, which as they occurred in the absence of cell loss could not be explained as solely compensatory to the neurodegeneration. The finding of increased Ca(V)1.3 subtype expression in the cerebral cortex of early stage Parkinson's disease, before the appearance of pathological changes, supports the view that disturbed calcium homeostasis is an early feature of Parkinson's disease and not just a compensatory consequence to the neurodegenerative process. This interpretation is supported further by the finding that the ratio of Ca(V)1 subtypes differed throughout the brain in patients with Parkinson's disease compared with control subjects, in favour of an increased use of Ca(V)1.3, which would add to the metabolic burden for cells that rely on this Ca(V)1 subtype for electrical activity and could therefore render specific neuronal populations more vulnerable to neurodegeneration.
AbstractList In Parkinson's disease oxidative stress and calcium-induced excitotoxicity have been considered important mechanisms leading to cell death for decades, but the factors that make some neurons vulnerable to neurodegeneration while others remain resistant are not fully understood. Studies of the disorder in animal models suggest that the voltage-gated calcium channel subtype Ca(V)1.3 has a role in making neurons susceptible to neurodegeneration and support earlier work in post-mortem human brain that suggested loss of calcium buffering capacity in neurons correlated with areas of neuronal loss in the substantia nigra of parkinsonian brain. This study examined expression of Ca(V)1 subtypes and the calcium-binding proteins calbindin, calmodulin and calreticulin in areas vulnerable and resistant to neurodegeneration in Parkinson's disease, in brain from neurologically normal individuals and patients with Parkinson's disease. In control brain the expression of a specific Ca(V)1 subtype or distribution of each calcium-binding protein did not associate with those regions prone to neurodegeneration in Parkinson's disease. Whereas, alterations in the amount of both Ca(V)1 subtypes and the calcium-binding proteins were found throughout the brain in Parkinson's disease. Some changes reflected the cell loss seen in Parkinson's disease, whereas others represented altered levels of cellular expression, which as they occurred in the absence of cell loss could not be explained as solely compensatory to the neurodegeneration. The finding of increased Ca(V)1.3 subtype expression in the cerebral cortex of early stage Parkinson's disease, before the appearance of pathological changes, supports the view that disturbed calcium homeostasis is an early feature of Parkinson's disease and not just a compensatory consequence to the neurodegenerative process. This interpretation is supported further by the finding that the ratio of Ca(V)1 subtypes differed throughout the brain in patients with Parkinson's disease compared with control subjects, in favour of an increased use of Ca(V)1.3, which would add to the metabolic burden for cells that rely on this Ca(V)1 subtype for electrical activity and could therefore render specific neuronal populations more vulnerable to neurodegeneration.In Parkinson's disease oxidative stress and calcium-induced excitotoxicity have been considered important mechanisms leading to cell death for decades, but the factors that make some neurons vulnerable to neurodegeneration while others remain resistant are not fully understood. Studies of the disorder in animal models suggest that the voltage-gated calcium channel subtype Ca(V)1.3 has a role in making neurons susceptible to neurodegeneration and support earlier work in post-mortem human brain that suggested loss of calcium buffering capacity in neurons correlated with areas of neuronal loss in the substantia nigra of parkinsonian brain. This study examined expression of Ca(V)1 subtypes and the calcium-binding proteins calbindin, calmodulin and calreticulin in areas vulnerable and resistant to neurodegeneration in Parkinson's disease, in brain from neurologically normal individuals and patients with Parkinson's disease. In control brain the expression of a specific Ca(V)1 subtype or distribution of each calcium-binding protein did not associate with those regions prone to neurodegeneration in Parkinson's disease. Whereas, alterations in the amount of both Ca(V)1 subtypes and the calcium-binding proteins were found throughout the brain in Parkinson's disease. Some changes reflected the cell loss seen in Parkinson's disease, whereas others represented altered levels of cellular expression, which as they occurred in the absence of cell loss could not be explained as solely compensatory to the neurodegeneration. The finding of increased Ca(V)1.3 subtype expression in the cerebral cortex of early stage Parkinson's disease, before the appearance of pathological changes, supports the view that disturbed calcium homeostasis is an early feature of Parkinson's disease and not just a compensatory consequence to the neurodegenerative process. This interpretation is supported further by the finding that the ratio of Ca(V)1 subtypes differed throughout the brain in patients with Parkinson's disease compared with control subjects, in favour of an increased use of Ca(V)1.3, which would add to the metabolic burden for cells that rely on this Ca(V)1 subtype for electrical activity and could therefore render specific neuronal populations more vulnerable to neurodegeneration.
In Parkinson's disease oxidative stress and calcium-induced excitotoxicity have been considered important mechanisms leading to cell death for decades, but the factors that make some neurons vulnerable to neurodegeneration while others remain resistant are not fully understood. Studies of the disorder in animal models suggest that the voltage-gated calcium channel subtype Ca(V)1.3 has a role in making neurons susceptible to neurodegeneration and support earlier work in post-mortem human brain that suggested loss of calcium buffering capacity in neurons correlated with areas of neuronal loss in the substantia nigra of parkinsonian brain. This study examined expression of Ca(V)1 subtypes and the calcium-binding proteins calbindin, calmodulin and calreticulin in areas vulnerable and resistant to neurodegeneration in Parkinson's disease, in brain from neurologically normal individuals and patients with Parkinson's disease. In control brain the expression of a specific Ca(V)1 subtype or distribution of each calcium-binding protein did not associate with those regions prone to neurodegeneration in Parkinson's disease. Whereas, alterations in the amount of both Ca(V)1 subtypes and the calcium-binding proteins were found throughout the brain in Parkinson's disease. Some changes reflected the cell loss seen in Parkinson's disease, whereas others represented altered levels of cellular expression, which as they occurred in the absence of cell loss could not be explained as solely compensatory to the neurodegeneration. The finding of increased Ca(V)1.3 subtype expression in the cerebral cortex of early stage Parkinson's disease, before the appearance of pathological changes, supports the view that disturbed calcium homeostasis is an early feature of Parkinson's disease and not just a compensatory consequence to the neurodegenerative process. This interpretation is supported further by the finding that the ratio of Ca(V)1 subtypes differed throughout the brain in patients with Parkinson's disease compared with control subjects, in favour of an increased use of Ca(V)1.3, which would add to the metabolic burden for cells that rely on this Ca(V)1 subtype for electrical activity and could therefore render specific neuronal populations more vulnerable to neurodegeneration.
Author Brandon, Bianca
Gentleman, Steve M.
Dexter, David T.
Hurley, Michael J.
Author_xml – sequence: 1
  givenname: Michael J.
  surname: Hurley
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  surname: Gentleman
  fullname: Gentleman, Steve M.
– sequence: 4
  givenname: David T.
  surname: Dexter
  fullname: Dexter, David T.
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ISSN 0006-8950
1460-2156
IngestDate Fri Jul 11 07:27:22 EDT 2025
Mon Jul 21 06:05:07 EDT 2025
Mon Jul 21 09:17:29 EDT 2025
Tue Jul 01 00:46:06 EDT 2025
Thu Apr 24 23:11:15 EDT 2025
IsDoiOpenAccess false
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Issue 7
Keywords calcium channel
Nervous system diseases
Parkinson's disease
Calcium
Parkinson disease
calcium-binding proteins
Involuntary movement
Cerebral disorder
Binding protein
dihydropyridines
Central nervous system disease
Degenerative disease
Neurological disorder
Extrapyramidal syndrome
Dyskinesia
dyskinesia
Parkinson’s disease
Language English
License CC BY 4.0
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crossref_citationtrail_10_1093_brain_awt134
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  year: 2013
  text: 2013-Jul
PublicationDecade 2010
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PublicationTitle Brain (London, England : 1878)
PublicationTitleAlternate Brain
PublicationYear 2013
Publisher Oxford University Press
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Snippet In Parkinson's disease oxidative stress and calcium-induced excitotoxicity have been considered important mechanisms leading to cell death for decades, but the...
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StartPage 2077
SubjectTerms Aged
Aged, 80 and over
Analysis of Variance
Biological and medical sciences
Brain - pathology
Calcium Channels, L-Type - metabolism
Calcium-Binding Proteins - metabolism
Cell Count
Degenerative and inherited degenerative diseases of the nervous system. Leukodystrophies. Prion diseases
Densitometry
DNA-Binding Proteins - metabolism
Female
Humans
Male
Medical sciences
Microfilament Proteins
Middle Aged
Nerve Tissue Proteins - metabolism
Neurology
Neurons - metabolism
Parkinson Disease - metabolism
Parkinson Disease - pathology
Spinal Cord - metabolism
Spinal Cord - pathology
Stereotaxic Techniques
Title Parkinson’s disease is associated with altered expression of CaV1 channels and calcium-binding proteins
URI https://www.ncbi.nlm.nih.gov/pubmed/23771339
https://www.proquest.com/docview/1372695287
Volume 136
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