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Query: UMLS:C0153640 (
Cerebellum
)
1,777
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Several human neurological disorders have been associated with mutations in the gene coding for the alpha1 subunit of the P/Q type
voltage-gated calcium channel
(alpha1A/Ca(v)2.1). Mutations in this gene also occur in a number of neurologically affected mouse strains, including leaner (tg(la)/tg(la)). Because the P-type calcium current is very prominent in cerebellar Purkinje neurons, these cells from mice with alpha1 subunit mutations make excellent models for the investigation of the functional consequences of native mutations in a
voltage-gated calcium channel
of mammalian central nervous system. In this review, we describe the impact of altered channel function on cellular calcium homeostasis and signaling. Remarkably, calcium buffering functions of the endoplasmic reticulum and calcium-binding proteins appear to be regulated in order to compensate for altered calcium influx through the mutant channels. Although this compensation may serve to maintain calcium signaling functions, such as calcium-induced calcium release, it remains uncertain whether such compensation alleviates or contributes to the behavioral phenotype.
Cerebellum
2002 Apr
PMID:Homeostatic compensation maintains Ca2+ signaling functions in Purkinje neurons in the leaner mutant mouse. 1288 61
Low threshold voltage-gated T-type calcium channels have long been implicated in the electrical excitability and calcium signaling of cerebellar Purkinje neurons although the molecular composition, localization, and modulation of T-type channels within Purkinje cells have only recently been addressed. The specific functional roles that T-type channels play in local synaptic integration within Purkinje spines are also currently being unraveled. Overall, Purkinje neurons represent a powerful model system to explore the potential roles of postsynaptic T-type channels throughout the nervous system. In this review, we present an overview of T-type calcium channel biophysical, pharmacological, and physiological characteristics that provides a foundation for understanding T-type channels within Purkinje neurons. We also describe the biophysical properties of T-type channels in context of other
voltage-gated calcium channel
currents found within Purkinje cells. The data thus far suggest that one specific T-type isoform, Ca(v)3.1, is highly expressed within Purkinje spines and both physically and functionally couples to mGluR1 and other effectors within putative signaling microdomains. Finally, we discuss how the selective potentiation of Ca(v)3.1 channels via activation of mGluR1 by parallel fiber inputs affects local synaptic integration and how this interaction may relate to the overall excitability of Purkinje neuron dendrites.
Cerebellum
2012 Sep
PMID:Contributions of T-type voltage-gated calcium channels to postsynaptic calcium signaling within Purkinje neurons. 2073 77
