Characterization of C-terminal Splice Variants of Cav1.4 Ca2+ Channels in Human Retina

Haeseleer, Françoise; Williams, Brittany; Lee, Amy

doi:10.1074/jbc.m116.731737

Cited by 30 publications

(50 citation statements)

References 58 publications

(105 reference statements)

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“…When co-transfected with the full length Cav1.4 and the axillary subunits (Cav1.4 + β2 + α2δ1), RS1 significantly enhanced the Cav1.4-LTCC current density (Figure 3 ) and the voltage-dependent activation (Figure 3B ). Unlike Cav1.2- or Cav1.3-LTCCs, full length Cav1.4 without a deletion of exon 47 shows no discernable CDI (Baumann et al, 2004 ) and displays unusually slow voltage-dependent inactivation (McRory et al, 2004 ; Haeseleer et al, 2016 ). Co-transfection with RS1 and functional Cav1.4-LTCC did not alter the CDI property of Cav1.4-LTCCs (Figure 3C ).…”

Section: Resultsmentioning

confidence: 99%

Retinoschisin Facilitates the Function of L-Type Voltage-Gated Calcium Channels

Shi

2017

Front. Cell. Neurosci.

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Modulation of ion channels by extracellular proteins plays critical roles in shaping synaptic plasticity. Retinoschisin (RS1) is an extracellular adhesive protein secreted from photoreceptors and bipolar cells, and it plays an important role during retinal development, as well as in maintaining the stability of retinal layers. RS1 is known to form homologous octamers and interact with molecules on the plasma membrane including phosphatidylserine, sodium-potassium exchanger complex, and L-type voltage-gated calcium channels (LTCCs). However, how this physical interaction between RS1 and ion channels might affect the channel gating properties is unclear. In retinal photoreceptors, two major LTCCs are Cav1.3 (α1D) and Cav1.4 (α1F) with distinct biophysical properties, functions and distributions. Cav1.3 is distributed from the inner segment (IS) to the synaptic terminal and is responsible for calcium influx to the photoreceptors and overall calcium homeostasis. Cav1.4 is only expressed at the synaptic terminal and is responsible for neurotransmitter release. Mutations of the gene encoding Cav1.4 cause X-linked incomplete congenital stationary night blindness type 2 (CSNB2), while null mutations of Cav1.3 cause a mild decrease of retinal light responses in mice. Even though RS1 is known to maintain retinal architecture, in this study, we present that RS1 interacts with both Cav1.3 and Cav1.4 and regulates their activations. RS1 was able to co-immunoprecipitate with Cav1.3 and Cav1.4 from porcine retinas, and it increased the LTCC currents and facilitated voltage-dependent activation in HEK cells co-transfected with RS1 and Cav1.3 or Cav1.4, thus providing evidence of a functional interaction between RS1 and LTCCs. The interaction between RS1 and Cav1.3 did not change the calcium-dependent inactivation of Cav1.3. In mice lacking RS1, the expression of Cav1.3 and Cav1.4 in the retina decreased, while in mice with Cav1.4 deletion, the retinal level of RS1 decreased. These results provide important evidence that RS1 is not only an adhesive protein promoting cell-cell adhesion, it is essential for anchoring other membrane proteins including ion channels and enhancing their function in the retina.

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Section: Resultsmentioning

confidence: 99%

Retinoschisin Facilitates the Function of L-Type Voltage-Gated Calcium Channels

Shi

2017

Front. Cell. Neurosci.

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“…L‐type calcium channels (LTCCs) mediate a voltage‐dependent and depolarization‐induced calcium influx and regulate diverse biological processes such as contraction, secretion, neurotransmission, differentiation, and gene expression in many different cell types (Barnes & Kelly, ; Benitah et al., ; Catterall & Few, ; Catterall, Perez‐Reyes, Snutch, & Striessnig, ; Dolphin, , ; Joiner & Lee, ; Thorneloe & Nelson, ). There are three major LTCCs expressed in the vertebrate retina: Cav1.2, Cav1.3, and Cav1.4 (Ahlijanian, Westenbroek, & Catterall, ; Barnes & Kelly, ; Cristofanilli, Mizuno, & Akopian, ; Firth, Morgan, Boelen, & Morgans, ; Haeseleer, Williams, & Lee, ; Haeseleer et al., ; Kersten et al., ; Knoflach et al., ; Ko et al., ; Lee et al., ; Liu et al., ; Mizuno, Barabas, Krizaj, & Akopian, ; Morgans, ; Morgans et al., ; Shi, Chang, Yu, Ko, & Ko, ; Strom et al., ; Wu, Marmorstein, Striessnig, & Peachey, ; Xing, Akopian, & Krizaj, ; Xu, Zhao, & Yang, ; Zou, Lee, & Yang, ). In photoreceptors, Cav1.4 is exclusively expressed at the synaptic terminals and responsible for the tonic release of glutamate in the dark as a result of depolarization‐evoked activation of LTCCs (Haeseleer et al., , ; Knoflach et al., ; Morgans, ).…”

Section: Circadian Oscillation In the Photoreceptorsmentioning

confidence: 99%

“…There are three major LTCCs expressed in the vertebrate retina: Cav1.2, Cav1.3, and Cav1.4 (Ahlijanian, Westenbroek, & Catterall, ; Barnes & Kelly, ; Cristofanilli, Mizuno, & Akopian, ; Firth, Morgan, Boelen, & Morgans, ; Haeseleer, Williams, & Lee, ; Haeseleer et al., ; Kersten et al., ; Knoflach et al., ; Ko et al., ; Lee et al., ; Liu et al., ; Mizuno, Barabas, Krizaj, & Akopian, ; Morgans, ; Morgans et al., ; Shi, Chang, Yu, Ko, & Ko, ; Strom et al., ; Wu, Marmorstein, Striessnig, & Peachey, ; Xing, Akopian, & Krizaj, ; Xu, Zhao, & Yang, ; Zou, Lee, & Yang, ). In photoreceptors, Cav1.4 is exclusively expressed at the synaptic terminals and responsible for the tonic release of glutamate in the dark as a result of depolarization‐evoked activation of LTCCs (Haeseleer et al., , ; Knoflach et al., ; Morgans, ). Cav1.3 is also detected at the synaptic terminal (Firth et al., ; Shi, Chiang, et al., ), but it might not be as essential for mediating neurotransmitter release as Cav1.4 (Shi, Ko, & Ko, ; Shi, Chang, et al., ).…”

Section: Circadian Oscillation In the Photoreceptorsmentioning

confidence: 99%

Circadian regulation in the retina: From molecules to network

2018

Eur J of Neuroscience

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The mammalian retina is the most unique tissue among those that display robust circadian/diurnal oscillations. The retina is not only a light sensing tissue that relays light information to the brain, it has its own circadian “system” independent from any influence from other circadian oscillators. While all retinal cells and retinal pigment epithelium (RPE) possess circadian oscillators, these oscillators integrate by means of neural synapses, electrical coupling (gap junctions), and released neurochemicals (such as dopamine, melatonin, adenosine, and ATP), so the whole retina functions as an integrated circadian system. Dysregulation of retinal clocks not only causes retinal or ocular diseases, it also impacts the circadian rhythm of the whole body, as the light information transmitted from the retina entrains the brain clock that governs the body circadian rhythms. In this review, how circadian oscillations in various retinal cells are integrated, and how retinal diseases affect daily rhythms.

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“…While heterologous systems are valuable for determining basic kinetic properties of Ca V 1.4, none of them has yet captured fully the complexities of the photoreceptor calcium current. In vivo, retinal photoreceptors express simultaneously several splice isoforms of Ca V 1.4 with different kinetics [ 48 , 49 ] and associate with unique modulatory subunits (discussed below: Ca V 1.4 Subunit Composition ) [ 17 ]. Additional factors, including physiological temperature (37°C) [ 50 ], calmodulin (CaM) coexpression [ 51 – 53 ], and calcium-binding protein 4 (CaBP4) coexpression [ 54 , 55 ], also significantly modulate biophysical parameters of the channel.…”

Section: The Complexity Of the Photoreceptor Calcium Current And Cmentioning

confidence: 99%

“…Over 20 splice isoforms of CACNA1F have been identified, several of which have significantly disparate dynamics [ 48 , 49 ]. Most remarkably, several splice variants exist in which the C-terminus is truncated or otherwise disrupted.…”

Section: The Complexity Of the Photoreceptor Calcium Current And Cmentioning

confidence: 99%

Channeling Vision: Ca_V1.4—A Critical Link in Retinal Signal Transmission

Waldner

Bech-Hansen

Stell

2018

BioMed Research International

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Voltage-gated calcium channels (VGCC) are key to many biological functions. Entry of Ca2+ into cells is essential for initiating or modulating important processes such as secretion, cell motility, and gene transcription. In the retina and other neural tissues, one of the major roles of Ca2+-entry is to stimulate or regulate exocytosis of synaptic vesicles, without which synaptic transmission is impaired. This review will address the special properties of one L-type VGCC, CaV1.4, with particular emphasis on its role in transmission of visual signals from rod and cone photoreceptors (hereafter called “photoreceptors,” to the exclusion of intrinsically photoreceptive retinal ganglion cells) to the second-order retinal neurons, and the pathological effects of mutations in the CACNA1F gene which codes for the pore-forming α1F subunit of CaV1.4.

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Characterization of C-terminal Splice Variants of Cav1.4 Ca2+ Channels in Human Retina

Cited by 30 publications

References 58 publications

Retinoschisin Facilitates the Function of L-Type Voltage-Gated Calcium Channels

Retinoschisin Facilitates the Function of L-Type Voltage-Gated Calcium Channels

Circadian regulation in the retina: From molecules to network

Channeling Vision: Ca_V1.4—A Critical Link in Retinal Signal Transmission

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Characterization of C-terminal Splice Variants of Cav1.4 Ca2+ Channels in Human Retina

Cited by 30 publications

References 58 publications

Retinoschisin Facilitates the Function of L-Type Voltage-Gated Calcium Channels

Retinoschisin Facilitates the Function of L-Type Voltage-Gated Calcium Channels

Circadian regulation in the retina: From molecules to network

Channeling Vision: CaV1.4—A Critical Link in Retinal Signal Transmission

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Product

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Channeling Vision: Ca_V1.4—A Critical Link in Retinal Signal Transmission