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Gene/Protein
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Target Concepts:
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Query: UMLS:C0016632 (
Fox
)
1,461
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
CaV1.2
voltage-gated calcium channels play critical roles in the control of membrane excitability, gene expression, and muscle contraction. These channels show diverse functional properties generated by alternative splicing at multiple sites within the
CaV1.2
pre-mRNA. The molecular mechanisms controlling this splicing are not understood. We find that two exons in the
CaV1.2
channel are controlled in part by members of the
Fox
family of splicing regulators. Exons 9* and 33 confer distinct electrophysiological properties on the channel and show opposite patterns of regulation during cortical development, with exon 9* progressively decreasing its inclusion in the
CaV1.2
mRNA over time and exon 33 progressively increasing. Both exons contain
Fox
protein binding elements within their adjacent introns, and
Fox
protein expression is induced in cortical neurons in parallel with the changes in
CaV1.2
splicing. We show that knocking down expression of
Fox
proteins in tissue culture cells has opposite effects on exons 9* and 33. The loss of
Fox
protein increases exon 9* splicing and decreases exon 33, as predicted by the positions of the
Fox
binding elements and by the pattern of splicing in development. Conversely, overexpression of Fox1 and Fox2 proteins represses exon 9* and enhances exon 33 splicing in the endogenous
CaV1.2
mRNA. These effects of
Fox
proteins on exons 9* and 33 can be recapitulated in transfected minigene reporters. Both the repressive and the enhancing effects of
Fox
proteins are dependent on the
Fox
binding elements within and adjacent to the target exons, indicating that the
Fox
proteins are directly regulating both exons. These results demonstrate that the
Fox
protein family is playing a key role in tuning the properties of
CaV1.2
calcium channels during neuronal development.
...
PMID:Developmental control of CaV1.2 L-type calcium channel splicing by Fox proteins. 1956 22
