Calcium: Amplitude, Duration, or Location?

Calcium: Amplitude, Duration, or Location?

Calcium plays a role in long-term plasticity by triggering postsynaptic signaling pathways for both the strengthening (LTP) and weakening (LTD) of synapses. Since these are opposing processes, several hypotheses have been developed to explain how calcium can trigger LTP in some situations and LTD in...

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Veröffentlicht in:The Biological bulletin (Lancaster) 2015-02, Vol.228 (1), p.75-83
Hauptverfasser: EVANS, R. C., BLACKWELL, K. T.
Format: Artikel
Sprache:eng
Schlagworte:
Animals
Calcium
Calcium - metabolism
Calcium channels
Calcium Signaling - physiology
Calcium, Dietary
Computational modeling
Diffusion
Health aspects
Humans
Long term depression
Long term potentiation
Modeling
Models, Biological
Molecules
N methyl D aspartate receptors
Neural transmission
NEUROBIOLOGY AND BEHAVIOR
Neurons
Neuroscience
Synapses - physiology
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Zusammenfassung:Calcium plays a role in long-term plasticity by triggering postsynaptic signaling pathways for both the strengthening (LTP) and weakening (LTD) of synapses. Since these are opposing processes, several hypotheses have been developed to explain how calcium can trigger LTP in some situations and LTD in others. These hypotheses fall broadly into three categories, based on the amplitude of calcium concentration, the duration of the calcium elevation, and the location of the calcium influx. Here we review the experimental evidence for and against each of these hypotheses and the recent computational models utilizing each. We argue that with new experimental techniques for the precise visualization of calcium and new computational techniques for the modeling of calcium diffusion, it is time to take a new look at the location hypothesis.
ISSN:0006-3185
1939-8697
DOI:10.1086/BBLv228n1p75