Mutation of the calcium channel gene Cacna1f disrupts calcium signaling, synaptic transmission and cellular organization in mouse retina

Fiona Mansergh; Noelle C. Orton; John P. Vessey; Melanie R. Lalonde; William K. Stell; Francois Tremblay; Steven Barnes; Derrick E. Rancourt; N. Torben Bech-Hansen

doi:10.1093/hmg/ddi336

Mutation of the calcium channel gene Cacna1f disrupts calcium signaling, synaptic transmission and cellular organization in mouse retina

Fiona Mansergh, Noelle C. Orton, John P. Vessey, Melanie R. Lalonde, William K. Stell, Francois Tremblay, Steven Barnes, Derrick E. Rancourt, N. Torben Bech-Hansen

Medicine

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229 Citations (Scopus)

Résumé

Retinal neural transmission represents a key function of the eye. Identifying the molecular components of this vital process is helped by studies of selected human genetic eye disorders. For example, mutations in the calcium channel subunit gene CACNA1F cause incomplete X-linked congenital stationary night blindness (CSNB2 or iCSNB), a human retinal disorder with abnormal electrophysiological response and visual impairments consistent with a retinal neurotransmission defect. To understand the subcellular basis of this retinal disorder, we generated a mouse with a loss-of-function mutation by inserting a self-excising Cre-lox-neo cassette into exon 7 of the murine orthologue, Cacna1f. Electroretinography of the mutant mouse revealed a scotopic a-wave of marginally reduced amplitude compared with the wild-type mouse and absence of the post-receptoral b-wave and oscillatory potentials. Cone ERG responses together with visual evoked potentials and multi-unit activity in the superior colliculus were also absent. Calcium imaging in Fluo-4 loaded retinal slices depolarized with KCl showed 90% less peak signal in the photoreceptor synapses of the Cacna1f mutant than in wild-type mice. The absence of post-receptoral ERG responses and the diminished photoreceptor calcium signals are consistent with a loss of Ca2+ channel function in photoreceptors. Immunocytochemistry showed no detectable Ca_v1.4 protein in the outer plexiform layer of Cacna1f mutant mice, profound loss of photoreceptor synapses, and abnormal dendritic sprouting of second-order neurons in the photoreceptor layer. Together, these findings in the Cacna1f-mutant mouse reveal that the Ca_v1.4 calcium channel is vital for the functional assembly and or maintenance and synaptic functions of photoreceptor ribbon synapses. Moreover, the outcome of this study provides critical clues to the pathophysiology of the human retinal channelopathy of X-linked incomplete CSNB.

Langue d'origine	English
Pages (de-à)	3035-3046
Nombre de pages	12
Journal	Human Molecular Genetics
Volume	14
Numéro de publication	20
DOI	https://doi.org/10.1093/hmg/ddi336
Statut de publication	Published - oct. 2005

Note bibliographique

Funding Information:
We thank Drs Catherine Morgans (OHSU), Robert Molday (UBC) and Shigetada Nakanishi (Kyoto University) for the antibodies used in these studies, Rose Tobias for the mouse genotyping, Artee Karkhanis and Wei Dong for EM and Brenda Carson and Eileen Rattner for expert assistance in establishing the mutant mouse. This research was supported in part by the Foundation Fighting Blindness-Canada (N.T.B.H.), Canadian Institutes for Health Research (MT-10968 to S.B., MOP-15660 to N.T.B.H.), NSHRF and CIHR-RPP grants (F.T.); Dalhousie Medical Research Foundation (S.B.); E.A. Baker/CIHR studentship award to M.R.L.; FFB-C studentship to N.C.O., NSERC (W.K.S.). N.T.B.H. is the Roy and Joan Allen Professor in Sight Research at the University of Calgary.

ASJC Scopus Subject Areas

Molecular Biology
Genetics
Genetics(clinical)

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10.1093/hmg/ddi336

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title = "Mutation of the calcium channel gene Cacna1f disrupts calcium signaling, synaptic transmission and cellular organization in mouse retina",

abstract = "Retinal neural transmission represents a key function of the eye. Identifying the molecular components of this vital process is helped by studies of selected human genetic eye disorders. For example, mutations in the calcium channel subunit gene CACNA1F cause incomplete X-linked congenital stationary night blindness (CSNB2 or iCSNB), a human retinal disorder with abnormal electrophysiological response and visual impairments consistent with a retinal neurotransmission defect. To understand the subcellular basis of this retinal disorder, we generated a mouse with a loss-of-function mutation by inserting a self-excising Cre-lox-neo cassette into exon 7 of the murine orthologue, Cacna1f. Electroretinography of the mutant mouse revealed a scotopic a-wave of marginally reduced amplitude compared with the wild-type mouse and absence of the post-receptoral b-wave and oscillatory potentials. Cone ERG responses together with visual evoked potentials and multi-unit activity in the superior colliculus were also absent. Calcium imaging in Fluo-4 loaded retinal slices depolarized with KCl showed 90% less peak signal in the photoreceptor synapses of the Cacna1f mutant than in wild-type mice. The absence of post-receptoral ERG responses and the diminished photoreceptor calcium signals are consistent with a loss of Ca2+ channel function in photoreceptors. Immunocytochemistry showed no detectable Cav1.4 protein in the outer plexiform layer of Cacna1f mutant mice, profound loss of photoreceptor synapses, and abnormal dendritic sprouting of second-order neurons in the photoreceptor layer. Together, these findings in the Cacna1f-mutant mouse reveal that the Cav1.4 calcium channel is vital for the functional assembly and or maintenance and synaptic functions of photoreceptor ribbon synapses. Moreover, the outcome of this study provides critical clues to the pathophysiology of the human retinal channelopathy of X-linked incomplete CSNB.",

author = "Fiona Mansergh and Orton, {Noelle C.} and Vessey, {John P.} and Lalonde, {Melanie R.} and Stell, {William K.} and Francois Tremblay and Steven Barnes and Rancourt, {Derrick E.} and Bech-Hansen, {N. Torben}",

note = "Funding Information: We thank Drs Catherine Morgans (OHSU), Robert Molday (UBC) and Shigetada Nakanishi (Kyoto University) for the antibodies used in these studies, Rose Tobias for the mouse genotyping, Artee Karkhanis and Wei Dong for EM and Brenda Carson and Eileen Rattner for expert assistance in establishing the mutant mouse. This research was supported in part by the Foundation Fighting Blindness-Canada (N.T.B.H.), Canadian Institutes for Health Research (MT-10968 to S.B., MOP-15660 to N.T.B.H.), NSHRF and CIHR-RPP grants (F.T.); Dalhousie Medical Research Foundation (S.B.); E.A. Baker/CIHR studentship award to M.R.L.; FFB-C studentship to N.C.O., NSERC (W.K.S.). N.T.B.H. is the Roy and Joan Allen Professor in Sight Research at the University of Calgary.",

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AU - Mansergh, Fiona

AU - Orton, Noelle C.

AU - Vessey, John P.

AU - Lalonde, Melanie R.

AU - Stell, William K.

AU - Tremblay, Francois

AU - Barnes, Steven

AU - Rancourt, Derrick E.

AU - Bech-Hansen, N. Torben

N1 - Funding Information: We thank Drs Catherine Morgans (OHSU), Robert Molday (UBC) and Shigetada Nakanishi (Kyoto University) for the antibodies used in these studies, Rose Tobias for the mouse genotyping, Artee Karkhanis and Wei Dong for EM and Brenda Carson and Eileen Rattner for expert assistance in establishing the mutant mouse. This research was supported in part by the Foundation Fighting Blindness-Canada (N.T.B.H.), Canadian Institutes for Health Research (MT-10968 to S.B., MOP-15660 to N.T.B.H.), NSHRF and CIHR-RPP grants (F.T.); Dalhousie Medical Research Foundation (S.B.); E.A. Baker/CIHR studentship award to M.R.L.; FFB-C studentship to N.C.O., NSERC (W.K.S.). N.T.B.H. is the Roy and Joan Allen Professor in Sight Research at the University of Calgary.

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N2 - Retinal neural transmission represents a key function of the eye. Identifying the molecular components of this vital process is helped by studies of selected human genetic eye disorders. For example, mutations in the calcium channel subunit gene CACNA1F cause incomplete X-linked congenital stationary night blindness (CSNB2 or iCSNB), a human retinal disorder with abnormal electrophysiological response and visual impairments consistent with a retinal neurotransmission defect. To understand the subcellular basis of this retinal disorder, we generated a mouse with a loss-of-function mutation by inserting a self-excising Cre-lox-neo cassette into exon 7 of the murine orthologue, Cacna1f. Electroretinography of the mutant mouse revealed a scotopic a-wave of marginally reduced amplitude compared with the wild-type mouse and absence of the post-receptoral b-wave and oscillatory potentials. Cone ERG responses together with visual evoked potentials and multi-unit activity in the superior colliculus were also absent. Calcium imaging in Fluo-4 loaded retinal slices depolarized with KCl showed 90% less peak signal in the photoreceptor synapses of the Cacna1f mutant than in wild-type mice. The absence of post-receptoral ERG responses and the diminished photoreceptor calcium signals are consistent with a loss of Ca2+ channel function in photoreceptors. Immunocytochemistry showed no detectable Cav1.4 protein in the outer plexiform layer of Cacna1f mutant mice, profound loss of photoreceptor synapses, and abnormal dendritic sprouting of second-order neurons in the photoreceptor layer. Together, these findings in the Cacna1f-mutant mouse reveal that the Cav1.4 calcium channel is vital for the functional assembly and or maintenance and synaptic functions of photoreceptor ribbon synapses. Moreover, the outcome of this study provides critical clues to the pathophysiology of the human retinal channelopathy of X-linked incomplete CSNB.

AB - Retinal neural transmission represents a key function of the eye. Identifying the molecular components of this vital process is helped by studies of selected human genetic eye disorders. For example, mutations in the calcium channel subunit gene CACNA1F cause incomplete X-linked congenital stationary night blindness (CSNB2 or iCSNB), a human retinal disorder with abnormal electrophysiological response and visual impairments consistent with a retinal neurotransmission defect. To understand the subcellular basis of this retinal disorder, we generated a mouse with a loss-of-function mutation by inserting a self-excising Cre-lox-neo cassette into exon 7 of the murine orthologue, Cacna1f. Electroretinography of the mutant mouse revealed a scotopic a-wave of marginally reduced amplitude compared with the wild-type mouse and absence of the post-receptoral b-wave and oscillatory potentials. Cone ERG responses together with visual evoked potentials and multi-unit activity in the superior colliculus were also absent. Calcium imaging in Fluo-4 loaded retinal slices depolarized with KCl showed 90% less peak signal in the photoreceptor synapses of the Cacna1f mutant than in wild-type mice. The absence of post-receptoral ERG responses and the diminished photoreceptor calcium signals are consistent with a loss of Ca2+ channel function in photoreceptors. Immunocytochemistry showed no detectable Cav1.4 protein in the outer plexiform layer of Cacna1f mutant mice, profound loss of photoreceptor synapses, and abnormal dendritic sprouting of second-order neurons in the photoreceptor layer. Together, these findings in the Cacna1f-mutant mouse reveal that the Cav1.4 calcium channel is vital for the functional assembly and or maintenance and synaptic functions of photoreceptor ribbon synapses. Moreover, the outcome of this study provides critical clues to the pathophysiology of the human retinal channelopathy of X-linked incomplete CSNB.

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Mutation of the calcium channel gene Cacna1f disrupts calcium signaling, synaptic transmission and cellular organization in mouse retina

Résumé

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ASJC Scopus Subject Areas

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