Mutant analysis shows that the Ca2+-induced K+ current shuts off one type of excitation in Paramecium.

Saimi, Yoshiro; Hinrichsen, Robert D.; Forte, Michael; Kung, Ching

doi:10.1073/pnas.80.16.5112

Cited by 74 publications

(52 citation statements)

References 39 publications

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“…In Paramecium, the only other organism in which comparable mutants are known, the genetic regulation of Ca2"-dependent K+ currents is complex. For example, mutations of at least two different genes eliminate this current (32,33) and mutations of a third gene enhance the current (34). In other organisms, Ca2+-dependent K+ channels are known to be modulated by cAMP-dependent protein kinases (35,36).…”

Section: Discussionmentioning

confidence: 99%

A Drosophila mutation that eliminates a calcium-dependent potassium current.

Elkins¹,

Ganetzky²,

Wu³

1986

Proc. Natl. Acad. Sci. U.S.A.

214

182

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A mutation of Drosophila, slowpoke (slo), specifically abolishes a Ca2+-dependent K+ current, Ic, from dorsal longitudinal flight muscles of adult flies. Other K+ currents remain normal, providing evidence that Ic is mediated by a molecularly distinguishable set of channels. The pharmacological properties of Ic are similar to those of Ca2+-dependent currents in some vertebrate cells. The muscle action potential was significantly lengthened in slo flies, indicating that Ic plays the major role in its repolarization.In the excitable membranes of neurons and muscles, K+ channels comprise a variety of types as defined pharmacologically and electrophysiologically. These channels play an equal variety of roles in determining the natural signalling properties of excitable cells (1-5). Functions of K+ currents include repolarizing action potentials, setting the frequency ofendogenous pacemaking activity, and delaying the onset of spiking responses evoked by a depolarizing input (6). However, no molecular characterization of these channels has been achieved, primarily because high-affinity ligands for their purification are not yet available.In Drosophila, previous voltage-clamp studies ofthe dorsal longitudinal flight muscles (DLMs) (7,8)

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Section: Discussionmentioning

confidence: 99%

A Drosophila mutation that eliminates a calcium-dependent potassium current.

Elkins¹,

Ganetzky²,

Wu³

1986

Proc. Natl. Acad. Sci. U.S.A.

214

182

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“…It appeared that in the absence of Ca2+ influx (due to these drugs) the Ca2+ channels are nonetheless inactivated by the K+-induced depolarization, leading to the loss of responsiveness. Saimi, Hinrichsen, Forte & Kung (1983) proposed three types of excitation in free-swimming Paramecium. Type I, lasting several milliseconds, begins with Ca2+ activation and ends by the fast, Ca2+-dependent Ca2+-channel inactivation and K+-delayed rectification.…”

Section: Discussionmentioning

confidence: 99%

Slow inactivation of the calcium current of Paramecium is dependent on voltage and not internal calcium.

Hennessey¹,

Kung²

1985

The Journal of Physiology

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SUMMARY1. The isolated Ca2+ current from Paramecium caudatum was examined under voltage clamp with long conditioning depolarizations lasting for up to 5 min.2. The isolated transient Ca2+ current inactivates with tens of milliseconds due to Ca2+-dependent Ca2+-channel inactivation (Brehm & Eckert, 1978). When this fast inactivation was blocked by internally delivered EGTA, a much slower inactivation of the Ca2+ current was discovered. This slow inactivation had time constants of tens of seconds, depending on voltage.3. The development of this slow inactivation was further examined by following the Ca2+ transient after 1 s interruptions of the long depolarization. This development is voltage dependent; the rate of inactivation is higher with a larger depolarization.4. After a long depolarization, the Ca2+ current returns in two clearly separable steps. A portion of the current returns rapidly along an exponential time course with time constants of tens to hundreds of milliseconds. The remainder of the current returns slowly with time constants of tens of seconds. A longer conditioning depolarization generates a larger portion that recovers slowly.5. Internally delivered EGTA, sufficient to prevent most of the fast inactivation, did not change the time course or the extent of either the onset or the removal of the slow inactivation. The compound W-7, which inhibits the Ca2+ current itself, does not block the onset of this slow inactivation during depolarization.6. We conclude that the slow inactivation of the Ca2+ channel is a mechanistically different phenomenon from the fast Ca2+-dependent Ca2+-channel inactivation. The possible physiological and behavioural roles of this slow inactivation are discussed.

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“…Three types of depolarization-induced behaviors have been characterized in ciliates [Saimi et al, 1983]. All three involve ciliary reversal and backward swimming.…”

Section: Introductionmentioning

confidence: 99%

Mutations in genes encoding inner arm dynein heavy chains inTetrahymena thermophila lead to axonemal hypersensitivity to Ca2+

Liu

Hennessey

Rankin

et al. 2005

Cell Motil. Cytoskeleton

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Calcium-dependent ciliary reversals are seen in ciliated protozoans such as Tetrahymena in response to depolarizing stimuli, but the axonemal mechanisms responsible for this response are not well understood. The model is that the outer arm dyneins (OADs) control the beating frequency while the inner arm dyneins (IADs) regulate ciliary waveform. Since ciliary reversal is a type of waveform change, the model would predict that IAD mutations could affect ciliary reversal. We have used gene disruption techniques to generate several behavioral mutants of Tetrahymena with functional disruptions of various IADs. One such mutant, called KO-6, is missing I1 (the two-headed IAD) and is unable to show ciliary reversals in response to any stimuli due to a loss of axonemal Ca2+ sensitivity [Eur J Cell Biol 80 (2001) 486-497; Cell Motil Cytoskeleton 53 (2002) 281-288.]. In contrast, disruption of 3 one-headed IADs [Liu et al., Cell Motil Cytoskeleton 59 (2004), 201-214] produced mutants, which showed over-responsiveness in bioassays measuring either their depolarization-induced avoiding reactions (AR) in Na+ and Ba2+ solutions or their duration of backward swimming (continuous ciliary reversal or CCR) in K+ solutions. Detergent-extracted and reactivated mutants also showed increased probabilities of CCR at lower Ca2+ concentrations suggesting that the behavioral over-responsiveness of these three mutants in vivo is due to increased axonemal Ca2+ sensitivity. Our data suggest the possibility that the one-headed IADs and the two-headed IAD act antagonistically in vivo and that loss of any one of the one-headed IADs leads to behavioral over-responsiveness due to less resistance to I1-induced reversals.

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Mutant analysis shows that the Ca2+-induced K+ current shuts off one type of excitation in Paramecium.

Cited by 74 publications

References 39 publications

A Drosophila mutation that eliminates a calcium-dependent potassium current.

A Drosophila mutation that eliminates a calcium-dependent potassium current.

Slow inactivation of the calcium current of Paramecium is dependent on voltage and not internal calcium.

Mutations in genes encoding inner arm dynein heavy chains inTetrahymena thermophila lead to axonemal hypersensitivity to Ca2+

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