Dendritic spike

Figure A. shows the idealized phases of an action potential. Figure B. is a recording of an actual action potential N.B. Actual recordings of action potentials are often distorted compared to the schematic view because of variations in electrophysiological techniques used to make the recording.

In neurophysiology, a dendritic spike refers to an action potential generated in the dendrite of a neuron. Dendrites are branched extensions of a neuron. They receive electrical signals emitted from projecting neurons and transfer these signals to the cell body, or soma. Dendritic signaling has traditionally been viewed as a passive mode of electrical signaling. Unlike its axon counterpart which can generate signals through action potentials, dendrites were believed to only have the ability to propagate electrical signals by physical means: changes in conductance, length, cross sectional area, etc. However, the existence of dendritic spikes was proposed and demonstrated by W. Alden Spencer, Eric Kandel, Rodolfo Llinás and coworkers in the 1960s[1][2] and a large body of evidence now makes it clear that dendrites are active neuronal structures. Dendrites contain voltage-gated ion channels giving them the ability to generate action potentials. Dendritic spikes have been recorded in numerous types of neurons in the brain and are thought to have great implications in neuronal communication, memory, and learning. They are one of the major factors in long-term potentiation.

A dendritic spike is initiated in the same manner as that of an axonal action potential. Depolarization of the dendritic membrane causes sodium and potassium voltage-gated ion channels to open. The influx of sodium ions causes an increase in voltage. If the voltage increases past a certain threshold, the sodium current activates other voltage-gated sodium channels transmitting a current along the dendrite. Dendritic spikes can be generated through both sodium and calcium voltage-gated channels. Dendritic spikes usually transmit signals at a much slower rate than axonal action potentials.[3] Local voltage thresholds for dendritic spike initiation are usually higher than that of action potential initiation in the axon; therefore, spike initiation usually requires a strong input.[4]

  1. ^ Spencer, W. A.; Kandel, E. R. (1961). "Electrophysiology of Hippocampal Neurons: Iv. Fast Prepotentials". Journal of Neurophysiology. 24 (3): 272–285. doi:10.1152/jn.1961.24.3.272. ISSN 0022-3077. PMID 25286477.
  2. ^ Llinás, R.; Nicholson, C.; Freeman, J. A.; Hillman, D. E. (1968-06-07). "Dendritic spikes and their inhibition in alligator Purkinje cells". Science. 160 (3832): 1132–1135. Bibcode:1968Sci...160.1132L. doi:10.1126/science.160.3832.1132. ISSN 0036-8075. PMID 5647436. S2CID 27657014.
  3. ^ Kampa BM, Letzkus JJ, Stuart GJ. 2007. Dendritic mechanisms controlling spike-timing-dependent synaptic plasticity. Trends in Neurosciences 30:456-63 doi:10.1016/j.tins.2007.06.010
  4. ^ Häusser M, Spruston N, Stuart GJ. 2000. Diversity and dynamics of dendritic signaling. Science 290:739-744 doi:10.1126/science.290.5492.739