Richard W. Tsien scite author profile

How many types of calcium channels exist in neurones? This question is fundamental to understanding how calcium entry contributes to diverse neuronal functions such as transmitter release, neurite extension, spike initiation and rhythmic firing. There is considerable evidence for the presence of more than one type of Ca conductance in neurones and other cells. However, little is known about single-channel properties of diverse neuronal Ca channels, or their responsiveness to dihydropyridines, compounds widely used as labels in Ca channel purification. Here we report evidence for the coexistence of three types of Ca channel in sensory neurones of the chick dorsal root ganglion. In addition to a large conductance channel that contributes long-lasting current at strong depolarizations (L), and a relatively tiny conductance that underlies a transient current activated at weak depolarizations (T), we find a third type of unitary activity (N) that is neither T nor L. N-type Ca channels require strongly negative potentials for complete removal of inactivation (unlike L) and strong depolarizations for activation (unlike T). The dihydropyridine Ca agonist Bay K 8644 strongly increases the opening probability of L-, but not T- or N-type channels.

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Different modes of Ca channel gating behaviour favoured by dihydropyridine Ca agonists and antagonists

Hess

Lansman

Tsien

1984

Nature

1,278

808

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Single cardiac transmembranous Ca channels have three modes of gating behaviour in the absence of drugs, expressed as current records with brief openings (mode 1), with no openings because of channel unavailability (mode 0 or null mode) and with long-lasting openings and very brief closings that appear only rarely (mode 2). The dihydropyridine Ca agonist Bay K 8644 enhances Ca channel current by promoting mode 2, while the Ca antagonists nitrendipine and nimodipine inhibit the current by favouring mode 0.

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CREB Phosphorylation and Dephosphorylation: A Ca2+- and Stimulus Duration–Dependent Switch for Hippocampal Gene Expression

Bito

Deisseroth

Tsien

1996

Cell

1,046

812

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While changes in gene expression are critical for many brain functions, including long-term memory, little is known about the cellular processes that mediate stimulus-transcription coupling at central synapses. In studying the signaling pathways by which synaptic inputs control the phosphorylation state of cyclic AMP-responsive element binding protein (CREB) and determine expression of CRE-regulated genes, we found two important Ca2+/calmodulin (CaM)-regulated mechanisms in hippocampal neurons: a CaM kinase cascade involving nuclear CaMKIV and a calcineurin-dependent regulation of nuclear protein phosphatase 1 activity. Prolongation of the synaptic input on the time scale of minutes, in part by an activity-induced inactivation of calcineurin, greatly extends the period over which phospho-CREB levels are elevated, thus affecting induction of downstream genes.

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Kinetic and pharmacological properties distinguishing three types of calcium currents in chick sensory neurones.

Fox

Nowycky

Tsien

1987

The Journal of Physiology

1,227

748

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SUMMARY1. Calcium currents in cultured dorsal root ganglion (d.r.g.) cells were studied with the whole-cell patch-clamp technique. Using experimental conditions that suppressed Na+ and K+ currents, and 3-10 mM-external Ca2+ or Ba2+, we distinguished three distinct types of calcium currents (L, T and N) on the basis of voltage-dependent kinetics and pharmacology.2. Component L activates at relatively positive test potentials (t.p. > -10 mV) and shows little inactivation during a 200 ms depolarization. It is completely reprimed at a holding potential (h.p.) of -60 mV, and can be isolated by using a more depolarized h.p. (-40 mV) to inactivate the other two types of calcium currents.3. Component T can be seen in isolation with weak test pulses. It begins activating at potentials more positive than -70 mV and inactivates quickly and completely during a maintained depolarization (time constant, r-. 20-50 ms). The current amplitude and the rate of decay increase with stronger depolarizations until both reach a maximum at approximately -40 mV. Inactivation is complete at h.p. > -60 mV and is progressively removed between -60 and -95 mV.4. Component N activates at relatively strong depolarizations (t.p. > -20 mV) and decays with time constants ranging from 50 to 110 ms. Inactivation is removed over a very broad range of holding potentials (h.p. between -40 and -110 mV).5. With 10 mM-EGTA in the pipette solution, substitution of Ba2+ for Ca2+ as the charge carrier does not alter the rates of activation or relaxation of any component. However, T-type channels are approximately equally permeable to Ca2+ and Ba2+, while L-type and N-type channels are both much more permeable to Ba2 .6. Component N cannot be explained by current-dependent inactivation of L current resulting from recruitment of extra L-type channels at negative holding potentials: raising the external Ba2+ concentration to 110 mm greatly increases the amplitude of L current evoked from h.p. = -30 mV but produces little inactivation. 9. The dihydropyridine antagonist nifedipine (10 JIM) inhibits L current (-60 % block) at a holding potential that inactivates half the L-type channels. It does not reduce T or N currents at holding potentials that produce similar degrees of inactivation.10. w-Toxin fraction GVIA (wo-CgTX VIA), a peptide from the venom of Conus geographuas, was used to produce long-lasting block of N and L currents. Properties of T currents isolated in this manner agree with those inferred from kinetic analysis.

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Calmodulin supports both inactivation and facilitation of L-type calcium channels

Zühlke

Pitt

Deisseroth

et al. 1999

Nature

827

799

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L-type Ca2+ channels support Ca2+ entry into cells, which triggers cardiac contraction, controls hormone secretion from endocrine cells and initiates transcriptional events that support learning and memory. These channels are examples of molecular signal-transduction units that regulate themselves through their own activity. Among the many types of voltage-gated Ca2+ channel, L-type Ca2+ channels particularly display inactivation and facilitation, both of which are closely linked to the earlier entry of Ca2+ ions. Both forms of autoregulation have a significant impact on the amount of Ca2+ that enters the cell during repetitive activity, with major consequences downstream. Despite extensive biophysical analysis, the molecular basis of autoregulation remains unclear, although a putative Ca2+-binding EF-hand motif and a nearby consensus calmodulin-binding isoleucine-glutamine ('IQ') motif in the carboxy terminus of the alpha1C channel subunit have been implicated. Here we show that calmodulin is a critical Ca2+ sensor for both inactivation and facilitation, and that the nature of the modulatory effect depends on residues within the IQ motif important for calmodulin binding. Replacement of the native isoleucine by alanine removed Ca2+-dependent inactivation and unmasked a strong facilitation; conversion of the same residue to glutamate eliminated both forms of autoregulation. These results indicate that the same calmodulin molecule may act as a Ca2+ sensor for both positive and negative modulation.

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Richard W. Tsien

Three types of neuronal calcium channel with different calcium agonist sensitivity

Different modes of Ca channel gating behaviour favoured by dihydropyridine Ca agonists and antagonists

CREB Phosphorylation and Dephosphorylation: A Ca2+- and Stimulus Duration–Dependent Switch for Hippocampal Gene Expression

Kinetic and pharmacological properties distinguishing three types of calcium currents in chick sensory neurones.

Calmodulin supports both inactivation and facilitation of L-type calcium channels

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