Anti-Ca
 2+
 channel antibody attenuates Ca
 2+
 currents and mimics cerebellar ataxia
 in vivo

Liao, Yaping Joyce; Safa, Parsa; Chen, Yiren; Sobel, Raymond A.; Boyden, Edward S.; Tsien, Richard W.

doi:10.1073/pnas.0710771105

Cited by 55 publications

(51 citation statements)

References 41 publications

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“…Furthermore NESOpAb has proved useful in studies of native channels, demonstrating an involvement of neonatal Na V 1.5 in the enhancement of invasive behaviour of breast cancer cells, a result confirmed using RNA interference [18]. A further example is the D-III polyclonal antibody, which was developed as a blocker of P/Q-type voltage-gated Ca 2+ channels in cerebellar granule cells [17]. D-III was used to demonstrate a direct link between voltage-gated Ca 2+ channel antibodies and the pathogenesis of para-neoplastic cerebellar ataxia, suggesting that normal channel function and neurophysiology could be restored in patients by removal of damaging antibodies directed against these channels [17].…”

Section: E3 Targeted Antibodies: Principles and Examplesmentioning

confidence: 97%

“…The first study used polyclonal antibodies targeted to the voltagegated K + channels K V 1.2 and K V 3.1 which inhibited whole cell currents and helped establish that K V 1.2 is functional in neuronal cells [14]. Polyclonal antibodies also proved successful as inhibitors of the voltage gated sodium channel Na V 1.5 [13,16], and of N-and P/Q-type voltage-gated Ca 2+ channels [17]. NESOpAb is a polyclonal antibody designed to recognise the 'neonatal' splice variant form of Na V 1.5, and is an efficient blocker of current conducted by the channel [16].…”

Section: E3 Targeted Antibodies: Principles and Examplesmentioning

confidence: 99%

“…A further example is the D-III polyclonal antibody, which was developed as a blocker of P/Q-type voltage-gated Ca 2+ channels in cerebellar granule cells [17]. D-III was used to demonstrate a direct link between voltage-gated Ca 2+ channel antibodies and the pathogenesis of para-neoplastic cerebellar ataxia, suggesting that normal channel function and neurophysiology could be restored in patients by removal of damaging antibodies directed against these channels [17].…”

Section: E3 Targeted Antibodies: Principles and Examplesmentioning

confidence: 99%

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Extracellular Ion Channel Inhibitor Antibodies

Naylor¹,

Beech

2009

TODDISJ

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For many ion channels there are no specific pharmacological agents and this impedes searches for the physiological and pathological functions of the ion channels in native systems and restricts opportunity for therapeutic drug development. Antibodies can display high specificity for their target proteins and are routinely engineered to recognise proteins in many experimental procedures and increasingly as therapeutic agents. The unlimited diversity and potential for high specificity make antibodies attractive as biological tools and drugs, although they are not without problems. Along with other investigators we have explored targeting of the E3 extracellular loop (or turret) as an approach for the generation of antibodies with the potential to block certain types of ion channel with isoform specificity. The approach has led to success with nine ion channels and effective use in vitro and in vivo. Here we review current knowledge and experience of channel-blocking antibodies, focusing particularly but not exclusively on E3-targeting.

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Section: E3 Targeted Antibodies: Principles and Examplesmentioning

confidence: 97%

Section: E3 Targeted Antibodies: Principles and Examplesmentioning

confidence: 99%

Section: E3 Targeted Antibodies: Principles and Examplesmentioning

confidence: 99%

See 1 more Smart Citation

Extracellular Ion Channel Inhibitor Antibodies

Naylor¹,

Beech

2009

TODDISJ

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“…When tested at neuromuscular junctions, this antibody attenuated excitatory postsynaptic currents. Moreover, cerebellum infusion caused cerebellar ataxia in mice, establishing a link between anti-voltage-gated calcium channel antibodies and pathogenesis [19] . Besides regulating neural excitability, some E3-targeted antibodies could modulate store-operated or agonist-evoked Ca 2+ entry [20][21][22][23][24][25] , oligodendrocyte proliferation and migration [26] , and tumor growth [27,28] .…”

Section: Development Of Active Antibodiesmentioning

confidence: 99%

Antibody therapeutics targeting ion channels: are we there yet?

Sun

2013

Acta Pharmacol Sin

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The combination of technological advances, genomic sequences and market success is catalyzing rapid development of antibodybased therapeutics. Cell surface receptors and ion channel proteins are well known drug targets, but the latter has seen less success. The availability of crystal structures, better understanding of gating biophysics and validation of physiological roles now form an excellent foundation to pursue antibody-based therapeutics targeting ion channels to treat a variety of diseases.

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“…Furthermore, silencing of small-conductance calcium-activated potassium channels, regulators of firing frequency, in the CNS has proved that a purely electrical alteration is sufficient to cause cerebellar ataxia [11]. Even an anti-Ca 2+ channel antibody was sufficient to inhibit voltage-gated Ca 2+ channels, alter cerebellar synaptic transmission, and confer the phenotype of cerebellar ataxia [12].…”

mentioning

confidence: 99%

PTPRR, Cerebellum, and Motor Coordination

Schmitt

Bitoun

Manto³

2009

Cerebellum

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Tyrosine phosphorylation is a powerful mechanism of modulation for proliferation, differentiation, and functioning of neurons. The protein products of the neuronal mouse gene PTPRR are physiological regulators of mitogen-activated protein kinase (MAPK) activities. PTPRR −/− mice display deficits of motor coordination and balance skills. PTPRR gene orthologues are found in many vertebrates. Recent observations suggest that the human episodic ataxia 2 (EA2) and spinocerebellar ataxia types 6 (SCA6), 12 (SCA12), and 14 (SCA14) might be associated with impaired phosphorylation levels of cerebellum calcium channels and receptors. The concept that MAPK signaling is a key process in tuning synaptic plasticity in cerebellar circuits is now emerging, with numerous implications for understanding cerebellar functions and cerebellar disorders.

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Anti-Ca ²⁺ channel antibody attenuates Ca ²⁺ currents and mimics cerebellar ataxia in vivo

Cited by 55 publications

References 41 publications

Extracellular Ion Channel Inhibitor Antibodies

Extracellular Ion Channel Inhibitor Antibodies

Antibody therapeutics targeting ion channels: are we there yet?

PTPRR, Cerebellum, and Motor Coordination

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Anti-Ca 2+ channel antibody attenuates Ca 2+ currents and mimics cerebellar ataxia in vivo

Cited by 55 publications

References 41 publications

Extracellular Ion Channel Inhibitor Antibodies

Extracellular Ion Channel Inhibitor Antibodies

Antibody therapeutics targeting ion channels: are we there yet?

PTPRR, Cerebellum, and Motor Coordination

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Product

Resources

About

Anti-Ca ²⁺ channel antibody attenuates Ca ²⁺ currents and mimics cerebellar ataxia in vivo