Jump to content

Neural facilitation: Difference between revisions

From Wikipedia, the free encyclopedia
Content deleted Content added
10.1113/jphysiol.1954.sp005130
10.1113/jphysiol.1968.sp008469
Line 18: Line 18:
Early experiments by Del Castillo & Katz in 1954 and Dudel & Kuffler in 1968 showed that facilitation was possible at the neuromuscular junction even if transmitter release does not occur, indicating that facilitation is an exclusively presynaptic phenomenon.<ref>{{cite journal | last1=Del Castillo | first1=J | last2=Katz | first2=B | title=Statistical factors involved in neuromuscular facilitation and depression | journal=J. Physiol. | volume=124 | year=1954 | pages=574–585 | pmid=13175200 | issue=3 | pmc=1366293 | doi=10.1113/jphysiol.1954.sp005130 }}</ref><ref>{{cite journal | last1=Dudel | first1=J | last2=Kuffler | first2=SW | title=Mechanism of facilitation at the crayfish neuromuscular junction | journal=J. Physiol. | volume=155 | year=1961 | pages=530–542 | pmid=13724751 | pmc=1359873 | issue=3 | doi=10.1113/jphysiol.1961.sp006645 }}</ref>
Early experiments by Del Castillo & Katz in 1954 and Dudel & Kuffler in 1968 showed that facilitation was possible at the neuromuscular junction even if transmitter release does not occur, indicating that facilitation is an exclusively presynaptic phenomenon.<ref>{{cite journal | last1=Del Castillo | first1=J | last2=Katz | first2=B | title=Statistical factors involved in neuromuscular facilitation and depression | journal=J. Physiol. | volume=124 | year=1954 | pages=574–585 | pmid=13175200 | issue=3 | pmc=1366293 | doi=10.1113/jphysiol.1954.sp005130 }}</ref><ref>{{cite journal | last1=Dudel | first1=J | last2=Kuffler | first2=SW | title=Mechanism of facilitation at the crayfish neuromuscular junction | journal=J. Physiol. | volume=155 | year=1961 | pages=530–542 | pmid=13724751 | pmc=1359873 | issue=3 | doi=10.1113/jphysiol.1961.sp006645 }}</ref>


Katz and Miledi proposed the '''residual Ca<sup>2+</sup> hypothesis.''' They attributed the increase in neurotransmitter release to residual or accumulated Ca<sup>2+</sup> ("active calcium") within the axon membrane that remains attached to the membrane's inner surface.<ref name = katz>{{Citation | last1=Katz | first1=B | last2=Miledi | first2=R | title=The role of calcium in neuromuscular facilitation | journal=J. Physiol. | volume=195 | year=1968 | pages=481–492 | pmid=4296699 | issue=2 | pmc=1351674}}</ref> Katz and Miledi manipulated the Ca<sup>2+</sup> concentration within the presynaptic membrane to determine whether or not residual Ca<sup>2+</sup> remaining within the terminal after the first impulse caused an increase in neurotransmitter release following the second stimulus.
Katz and Miledi proposed the '''residual Ca<sup>2+</sup> hypothesis.''' They attributed the increase in neurotransmitter release to residual or accumulated Ca<sup>2+</sup> ("active calcium") within the axon membrane that remains attached to the membrane's inner surface.<ref name = katz>{{Citation | last1=Katz | first1=B | last2=Miledi | first2=R | title=The role of calcium in neuromuscular facilitation | journal=J. Physiol. | volume=195 | year=1968 | pages=481–492 | pmid=4296699 | issue=2 | pmc=1351674 | doi=10.1113/jphysiol.1968.sp008469 }}</ref> Katz and Miledi manipulated the Ca<sup>2+</sup> concentration within the presynaptic membrane to determine whether or not residual Ca<sup>2+</sup> remaining within the terminal after the first impulse caused an increase in neurotransmitter release following the second stimulus.


During the first nerve impulse, Ca<sup>2+</sup> concentration was either significantly below or nearing that of the second impulse. When Ca<sup>2+</sup>concentration was approaching that of the second impulse, facilitation was increased. In this first experiment, stimuli were presented in intervals of 100&nbsp;ms between the first and second stimuli. An absolute [[refractory period (physiology)|refractory period]] was reached when intervals were about 10&nbsp;ms apart.
During the first nerve impulse, Ca<sup>2+</sup> concentration was either significantly below or nearing that of the second impulse. When Ca<sup>2+</sup>concentration was approaching that of the second impulse, facilitation was increased. In this first experiment, stimuli were presented in intervals of 100&nbsp;ms between the first and second stimuli. An absolute [[refractory period (physiology)|refractory period]] was reached when intervals were about 10&nbsp;ms apart.

Revision as of 13:50, 13 June 2018

Neural facilitation, also known as paired pulse facilitation (PPF), is a phenomenon in neuroscience in which postsynaptic potentials (PSPs) (EPPs, EPSPs or IPSPs) evoked by an impulse are increased when that impulse closely follows a prior impulse. PPF is thus a form of short-term synaptic plasticity. The mechanisms underlying neural facilitation are exclusively pre-synaptic; broadly speaking, PPF arises due to increased presynaptic Ca2+ concentration leading to a greater release of neurotransmitter-containing synaptic vesicles.[1] Neural facilitation may be involved in several neuronal tasks, including simple learning, information processing,[2] and sound-source localization.[3]

Mechanisms

Overview

Ca2+ plays a significant role in transmitting signals at chemical synapses. Voltage-gated Ca2+ channels are located within the presynaptic terminal. When an action potential invades the presynaptic membrane, these channels open and Ca2+ enters. A higher concentration of Ca2+ enables synaptic vesicles to fuse to the presynaptic membrane and release their contents (neurotransmitters) into the synaptic cleft to ultimately contact receptors in the postsynaptic membrane. The amount of neurotransmitter released is correlated with the amount of Ca2+ influx. Therefore, short-term facilitation (STF) results from a build up of Ca2+ within the presynaptic terminal when action potentials propagate close together in time.[4]

Facilitation of excitatory post-synaptic current (EPSC) can be quantified as a ratio of subsequent EPSC strengths. Each EPSC is triggered by pre-synaptic calcium concentrations and can be approximated by:

EPSC = k([Ca2+]presynaptic)4 = k([Ca2+]rest + [Ca2+]influx + [Ca2+]residual)4

Where k is a constant.

Facilitation = EPSC2 / EPSC1 = (1 + [Ca2+]residual / [Ca2+]influx)4 - 1

Experimental evidence

Early experiments by Del Castillo & Katz in 1954 and Dudel & Kuffler in 1968 showed that facilitation was possible at the neuromuscular junction even if transmitter release does not occur, indicating that facilitation is an exclusively presynaptic phenomenon.[5][6]

Katz and Miledi proposed the residual Ca2+ hypothesis. They attributed the increase in neurotransmitter release to residual or accumulated Ca2+ ("active calcium") within the axon membrane that remains attached to the membrane's inner surface.[7] Katz and Miledi manipulated the Ca2+ concentration within the presynaptic membrane to determine whether or not residual Ca2+ remaining within the terminal after the first impulse caused an increase in neurotransmitter release following the second stimulus.

During the first nerve impulse, Ca2+ concentration was either significantly below or nearing that of the second impulse. When Ca2+concentration was approaching that of the second impulse, facilitation was increased. In this first experiment, stimuli were presented in intervals of 100 ms between the first and second stimuli. An absolute refractory period was reached when intervals were about 10 ms apart.

To examine facilitation during shorter intervals, Katz and Miledi directly applied brief depolarizing stimuli to nerve endings. When increasing the depolarizing stimulus from 1-2 ms, neurotransmitter release greatly increased due to accumulation of active Ca2+. Therefore, the degree of facilitation depends on the amount of active Ca2+, which is determined by the reduction in Ca2+ conductance over time as well as the amount of removed from axon terminals after the first stimulus. Facilitation is greatest when the impulses are closest together because Ca2+ conductance would not return to baseline prior to the second stimulus. Therefore, both Ca2+ conductance and accumulated Ca2+ would be greater for the second impulse when presented shortly after the first.

In the Calyx of Held synapse, short term facilitation (STF) has been shown to result from the binding of residual Ca2+ to neuronal Ca2+ sensor 1 (NCS1). Conversely, STF has been shown to decrease when Ca2+ chelators are added to the synapse (causing chelation) which reduce residual Ca2+. Therefore, "active Ca2+" plays a significant role in neural facilitation.[8]

In the synapse between Purkinje cells, short-term facilitation has been shown to be entirely mediated by the facilitation of Ca2+ currents through the voltage-dependent calcium channels.[9]

Relation to other forms of short-term synaptic plasticity

Augmentation and potentiation

Short-term synaptic enhancement is often differentiated into categories of facilitation, augmentation, and potentiation (also referred to as post-tetanic potentiation or PTP).[1][10] These three processes are often differentiated by their time scales: facilitation usually lasts for tens of milliseconds, while augmentation acts on a time scale on the order of seconds and potentiation has a time course of tens of seconds to minutes. All three effects increase the probability of neurotransmitter release from the presynaptic membrane, but the underlying mechanism is different for each. Paired-pulse facilitation is caused by the presence of residual Ca2+, augmentation likely arises due to increased action of the presynaptic protein munc-13, and post-tetanic potentiation is mediated by presynaptic activation of protein kinases.[4] The type of synaptic enhancement seen in a given cell is also related to variant dynamics of Ca2+ removal, which is in turn dependent upon the type of stimuli; a single action potential leads to facilitation, while a short tetanus generally causes augmentation and a longer tetanus leads to potentiation.[1]

Short-term depression (STD)

Short-term depression (STD) operates in the opposite direction of facilitation, decreasing the amplitude of PSPs. STD occurs due to a decrease in the readily releasable pool of vesicles (RRP) as a result of frequent stimulation. The inactivation of presynaptic Ca2+ channels after repeated action potentials also contributes to STD.[8] Depression and facilitation interact to create short-term plastic changes within neurons, and this interaction is called the dual-process theory of plasticity. Basic models present these effects as additive, with the sum creating the net plastic change (facilitation - depression = net change). However, it has been shown that depression occurs earlier on in the stimulus-response pathway than facilitation, and therefore plays into the expression of facilitation.[11] Many synapses exhibit properties of both facilitation and depression. In general, however, synapses with low initial probability of vesicle release are more likely to exhibit facilitation, and synapses with high probability of initial vesicle release are more likely to exhibit depression.[3]

Relation to information transmission

Synaptic filtering

Because the probability of vesicle release is activity-dependent, synapses can act as dynamic filters for information transmission.[3] Synapses with a low initial probability of vesicle release act as high-pass filters: because the release probability is low, a higher-frequency signal is needed to trigger release, and the synapse thus selectively responds to high-frequency signals. Likewise, synapses with high initial release probabilities serve as low-pass filters, responding to lower-frequency signals. Synapses with an intermediate probability of release act as band-pass filters that selectively respond to a specific range of frequencies. These filtering characteristics may be affected by a variety of factors, including both PPD and PPF, as well as chemical neuromodulators. In particular, because synapses with low release probabilities are more likely to experience facilitation than depression, high-pass filters are often converted to band-pass filters. Likewise, because synapses with high initial release probabilities are more likely to undergo depression than facilitation, it is common for low-pass filters to become band-pass filters, as well. Neuromodulators, meanwhile, may affect these short-term plasticities. In synapses with intermediate release probabilities, properties of the individual synapse will determine how the synapse changes in response to stimuli. These changes in filtration affect information transmission and encoding in response to repeated stimuli.[3]

Sound-source localization

In humans, sound localization is primarily accomplished using information about how the intensity and timing of a sound vary between each ear. Neuronal computations involving these interaurual intensity differences (IIDs) and interaural time differences (ITDs) are typically carried out in different pathways in the brain.[12] Short-term plasticity likely assists in differentiating between these two pathways: short-term facilitation dominates in intensity pathways, while short-term depression dominates in temporal pathways. These different types of short-term plasticity allow for different kinds of information filtration, thus contributing to the division of the two kinds of information into distinct processing streams.

The filtering capabilities of short-term plasticity may also assist with encoding information related to amplitude modulation.[12] Short-term depression can dynamically adjust the gain on high-frequency inputs, and may thus allow for an expanded high-frequency range for AM. A mixture of facilitation and depression may also assist in AM coding by leading to rate filtering.

See also

References

  1. ^ a b c Zucker, Robert S.; Regehr, Wade G. (2002). "Short-Term Synaptic Plasticity". Annu. Rev. Physiol. 64: 355–405. doi:10.1146/annurev.physiol.64.092501.114547. PMID 11826273.
  2. ^ Fortune, Eric S.; Rose, Gary J. (2001). "Short-term synaptic plasticity as a temporal filter". Trends in Neurosciences. 24 (7): 381–385. doi:10.1016/s0166-2236(00)01835-x.
  3. ^ a b c d Abbot, LF; Regehr, WG (2004). "Synaptic Computation". Nature. 431 (7010): 796–803. doi:10.1038/nature03010. PMID 15483601.
  4. ^ a b Purves, Dale; Augustine, George J.; Fitzpatrick, David; Hall, William C.; LaMantia, Anthony-Samuel; While, Leonard E. (2012). Neuroscience (Fifth ed.). Sunderland, MA: Sinauer Associates, Inc. ISBN 978-0-87893-695-3.
  5. ^ Del Castillo, J; Katz, B (1954). "Statistical factors involved in neuromuscular facilitation and depression". J. Physiol. 124 (3): 574–585. doi:10.1113/jphysiol.1954.sp005130. PMC 1366293. PMID 13175200.
  6. ^ Dudel, J; Kuffler, SW (1961). "Mechanism of facilitation at the crayfish neuromuscular junction". J. Physiol. 155 (3): 530–542. doi:10.1113/jphysiol.1961.sp006645. PMC 1359873. PMID 13724751.
  7. ^ Katz, B; Miledi, R (1968), "The role of calcium in neuromuscular facilitation", J. Physiol., 195 (2): 481–492, doi:10.1113/jphysiol.1968.sp008469, PMC 1351674, PMID 4296699
  8. ^ a b Jianhua, Xu; Liming, He; Ling-Gang, Wu (2007), "Role of Ca2+ channels in short-term synaptic plasticity", Current Opinion in Neurobiology, 17 (3): 352–359, doi:10.1016/j.conb.2007.04.005
  9. ^ Díaz-Rojas, Françoise; Sakaba, Takeshi; Kawaguchi, Shin-Ya (Nov 15, 2015). "Ca(2+) current facilitation determines short-term facilitation at inhibitory synapses between cerebellar Purkinje cells". Journal of Physiology. 593 (22): 4889–904. doi:10.1113/JP270704. PMC 4650412. PMID 26337248.
  10. ^ Thomson, Alex M. (2000). "Facilitation augmentation and potentiation at central synapses". Trends in Neurosciences. 23 (7): 305–312. doi:10.1016/s0166-2236(00)01580-0.
  11. ^ Prescott, Steven (May 2012). "Interactions between Depression and Facilitation within Neural Networks: Updating the Dual-Process Theory of Plasticity". Learning & Memory. 19 (5): 446–466. doi:10.1101/lm.5.6.446 (inactive 2018-03-15).{{cite journal}}: CS1 maint: DOI inactive as of March 2018 (link)
  12. ^ a b MacLeod, KM (2011). "Short-term synaptic plasticity and intensity coding". Hearing Research. 279 (1–2): 13–21. doi:10.1016/j.heares.2011.03.001. PMC 3210195. PMID 21397676.

Further reading

  • Johnston, Daniel; Wu, Samuel (1995), Foundations of Cellular Neurophysiology.
  • Kandel, Eric; Schwartz, James; Jessell, Thomas M. (2000). Principles of Neuroscience (Fourth ed.). McGraw-Hill. pp. 1247–1253. ISBN 0-8385-7701-6.