S. Akhtar scite author profile

Episodic ataxia type 1 (EA-1) is a neurological disorder arising from mutations in the Kv1.1 potassium channel ␣-subunit. EA-1 patients exhibit substantial phenotypic variability resulting from at least 14 distinct EA-1 point mutations. We found that EA-1 missense mutations generate mutant Kv1.1 subunits with folding and intracellular trafficking properties indistinguishable from wild-type Kv1.1. However, the single identified EA-1 nonsense mutation exhibits intracellular aggregation and detergent insolubility. This phenotype can be transferred to co-assembled Kv1 ␣-and Kv␤-subunits associated with Kv1.1 in neurons. These results suggest that as in many neurodegenerative disorders, intracellular aggregation of misfolded Kv1.1-containing channels may contribute to the pathophysiology of EA-1.

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Characteristics of Brain Kv1 Channels Tailored to Mimic Native Counterparts by Tandem Linkage of α Subunits

Akhtar

Shamotienko

Papakosta

et al. 2002

Journal of Biological Chemistry

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Modification of rat brain Kv1.4 channel gating by association with accessory Kvβ1.1 and β2.1 subunits

McIntosh

Southan

Akhtar

et al. 1997

Pfl�gers Archiv European Journal of Physiology

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We have examined the effects of co-expression of Kvbeta1.1 and Kvbeta2.1 subunits on the gating of rat brain Kv1.4 channels, expressed in Xenopus oocytes. Expression of Kv1.4 subunits alone produced a rapidly inactivating "A" type current, which activated at potentials beyond -60 mV in a solution containing high levels of rubidium. Current activation curves obtained from tail current measurements were fitted with a Boltzmann function, with V1/2 = -47 mV and k = 10 mV. Neither the Kvbeta1.1 nor Kvbeta2.1 subunits altered the voltage dependence of activation. Both subunits accelerated the activation time constant of Kv1.4, without affecting its voltage dependence. Surprisingly, the Kvbeta2.1 subunit, which lacks an N-terminal inactivation domain, was almost as effective as the Kvbeta1.1 subunit in speeding up Kv1.4. Steady-state inactivation of Kv1.4 was unchanged upon co-expression with either Kvbeta1.1 or Kvbeta2.1 subunits. Kv1.4 recovered from inactivation with two time constants; apart from an approximately 50% lengthening of the slow time constant with a high Kvbeta2.1 injection ratio, neither time constant was altered by either the Kvbeta1.1 or Kvbeta2.1 subunits, suggesting little interaction with recovery from C-type inactivation. Clearly, beta subunits have the potential to modify the gating of Kv1.4 channels in the brain more subtly than has been suggested previously.

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Recreation of Neuronal Kv1 Channel Oligomers by Expression in Mammalian Cells Using Semliki Forest Virus

et al. 1999

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The multiple roles of voltage-sensitive K(+) channels (Kv1 subfamily) in brain are served by subtypes containing pore-forming alpha (1.1-1.6) and auxiliary beta subunits, usually in an (alpha)(4)(beta)(4) stoichiometry. To facilitate structure/activity analysis, combinations that are prevalent in neurones and susceptible to alpha-dendrotoxin (alphaDTX) were reproduced in mammalian cells, using Semliki Forest virus. Infected Chinese hamster ovary cells expressed N-glycosylated Kv1.1 and 1.2 alpha subunits (M(r) approximately 60 and 62 K) that assembled and bound [(125)I]-alphaDTX with high affinity; an appreciable proportion appeared on the cell surface, with Kv1.2 showing a 5-fold enrichment in a plasma membrane fraction. To obtain 'native-like' alpha/beta complexes, beta1.1 or 2.1 (M(r) approximately 42 and 39 K, respectively) was co-expressed with Kv1.1 or 1.2. This slightly enhanced N-glycosylation and toxin binding, most notable with beta2. 1 and Kv1.2. Solubilization of membranes from cells infected with Kv. 1.2 and beta2.1, followed by Ni(2+) chromatography, gave a purified alpha1.2/beta2.1 complex with a size of approximately 405 K and S(20, W) = 15.8 S. Importantly, these values indicate that four alpha and beta subunits co-assembled as in neurones, a conclusion supported by the size ( approximately 260 K) of the homo-tetramer formed by Kv1.2 alone. Thus, an authentic K(+) channel octomer has been reconstructed; oligomeric species were also found in plasma membranes. To create 'authentic-like' hetero-oligomeric channels, Kv1.1 and 1.2 were co-expressed and shown to have assembled by the precipitation of both with IgGs specific for either. Consistently, confocal microscopy of cells labeled with these antibodies showed that the relatively low surface content of Kv1.1 was increased by Kv1.2. [(125)I]-alphaDTX binding to these complexes was antagonized by DTX(k), a probe selective for Kv1.1, in a manner that mimicks the pattern observed for the Kv1.1/1.2-containing channels in neuronal membranes.

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A Functional Spliced-Variant of β2 Subunit of Kv1 Channels in C6 Glioma Cells and Reactive Astrocytes from Rat Lesioned Cerebellum

et al. 1999

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Voltage-gated K(+) channels (Kv1) are important in glia, being required for cell proliferation. Herein, reactive astrocytes from a rat cerebellar lesion were shown to contain Kv1.1, -1.2, -1.3, -1.4, and -1.6 alpha plus beta1.1 subunits, as well as an unusual beta2.1 constituent; the latter was also found in a glioblastoma C6 cell line, together with Kv1.1, -1.3, and -1.6 and beta1.1 subunits. Reverse transcriptase-polymerase chain reaction revealed a novel product of the beta2 gene in C6 cells and reactive astrocytes, but not in cultured astrocytes or rat normal brain. Its cloning identified a variant, Kvbeta2.1A, alternatively spliced between I24 and Y39. Despite this 14 residue deletion, Kvbeta2.1A assembled cotranslationally with Kv1.1 or -1.2 and, when coexpressed with Kv1. 4 in oocytes, increased the inactivation rate of this K(+) current. Whereas the full-length beta2.1 gave a large increase in the amplitude of the Kv1.1 current in oocytes, the effect of beta2.1A varied from a modest elevation of the current to a slight suppression in some cases. In summary, this is the first report of the existence of an alternatively spliced product of the Kvbeta2.1 gene in C6 cells and reactive astrocytes, and supports the involvement of its core region (residues 39 onward) in assembly with alpha subunits while excluding a contribution of the adjacent 14 residues to accelerating the inactivation of Kv1.4.

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S. Akhtar

Episodic Ataxia Type-1 Mutations in the Kv1.1 Potassium Channel Display Distinct Folding and Intracellular Trafficking Properties

Characteristics of Brain Kv1 Channels Tailored to Mimic Native Counterparts by Tandem Linkage of α Subunits

Modification of rat brain Kv1.4 channel gating by association with accessory Kvβ1.1 and β2.1 subunits

Recreation of Neuronal Kv1 Channel Oligomers by Expression in Mammalian Cells Using Semliki Forest Virus

A Functional Spliced-Variant of β2 Subunit of Kv1 Channels in C6 Glioma Cells and Reactive Astrocytes from Rat Lesioned Cerebellum

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