A CACNA1F mutation identified in an X-linked retinal disorder shifts the voltage dependence of Ca sub(v)1.4 channel activation

A CACNA1F mutation identified in an X-linked retinal disorder shifts the voltage dependence of Ca sub(v)1.4 channel activation

Light stimuli produce graded hyperpolarizations of the photoreceptor plasma membrane and an associated decrease in a voltage gated calcium channel conductance that mediates release of glutamate neurotransmitter. The Ca sub(v)1.4 channel is thought to be involved in this process. The CACNA1F gene enc...

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Veröffentlicht in:Proceedings of the National Academy of Sciences - PNAS 2005-05, Vol.102 (21), p.7553-7558
Hauptverfasser: Hemara-Wahanui, Ariana, Berjukow, Stanislav, Hope, Carolyn I, Dearden, Peter K, Wu, Shu-Biao, Wilson-Wheeler, Jane, Sharp, Dianne M, Lundon-Treweek, Patricia, Clover, Gillian M, Hoda, Jean-Charles, Striessnig, Joerg, Marksteiner, Rainer, Hering, Steffen, Maw, Marion A
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container_title Proceedings of the National Academy of Sciences - PNAS
container_volume 102
creator Hemara-Wahanui, Ariana
Berjukow, Stanislav
Hope, Carolyn I
Dearden, Peter K
Wu, Shu-Biao
Wilson-Wheeler, Jane
Sharp, Dianne M
Lundon-Treweek, Patricia
Clover, Gillian M
Hoda, Jean-Charles
Striessnig, Joerg
Marksteiner, Rainer
Hering, Steffen
Maw, Marion A
description Light stimuli produce graded hyperpolarizations of the photoreceptor plasma membrane and an associated decrease in a voltage gated calcium channel conductance that mediates release of glutamate neurotransmitter. The Ca sub(v)1.4 channel is thought to be involved in this process. The CACNA1F gene encodes the poreforming subunit of the Ca sub(v)1.4 channel and various mutations in CACNA1F cause X-linked incomplete congenital stationary night blindness (CSNB2). The molecular mechanism of the pathology underlying the CSNB2 phenotype remains to be established. Recent clinical investigations of a New Zealand family found a severe visual disorder that has some clinical similarities to, but is clearly distinct from, CSNB2. Here, we report investigations into the molecular mechanism of the pathology of this condition. Molecular genetic analyses identified a previously undescribed nucleotide substitution in CACNA1F that is predicted to encode an isoleucine to threonine substitution at CACNA1F residue 745. The I745T CACNA1F allele produced a remarkable approximately -30-mV shift in the voltage dependence of Ca sub(v)1.4 channel activation and significantly slower inactivation kinetics in an expression system. These findings imply that substitution of this wild-type residue in transmembrane segment IIS6 may have decreased the energy required to open the channel. Collectively, these findings suggest that a gain-of-function mechanism involving increased Ca sub(v)1.4 channel activity is likely to cause the unusual phenotype.
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The I745T CACNA1F allele produced a remarkable approximately -30-mV shift in the voltage dependence of Ca sub(v)1.4 channel activation and significantly slower inactivation kinetics in an expression system. These findings imply that substitution of this wild-type residue in transmembrane segment IIS6 may have decreased the energy required to open the channel. 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The I745T CACNA1F allele produced a remarkable approximately -30-mV shift in the voltage dependence of Ca sub(v)1.4 channel activation and significantly slower inactivation kinetics in an expression system. These findings imply that substitution of this wild-type residue in transmembrane segment IIS6 may have decreased the energy required to open the channel. Collectively, these findings suggest that a gain-of-function mechanism involving increased Ca sub(v)1.4 channel activity is likely to cause the unusual phenotype.</abstract></addata></record>
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title A CACNA1F mutation identified in an X-linked retinal disorder shifts the voltage dependence of Ca sub(v)1.4 channel activation
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