Transcript Slide 1

Cellular Neuroscience (207)
Ian Parker
Lecture #13 – Postsynaptic
excitation and inhibition
Postsynaptic excitation and inhibition
EXCITATION – current flow through neurotransmitter-activated channels
that tends to depolarize the cell beyond (more positive than) the
threshold for trigering an action potential
INHIBITION – current flow through channels that tends to stop action
potentials from firing by preventing the membrane potential exceeding
the action potential threshold. (Does not necessarily imply
hyperpolarization)
Whether a given synapse is excitatory or inhibitory depends on the ionic
selectivity of the postsynaptic channels.
A particular neurotransmitter is not inherently excitatory or inhibitory – though it is
often the case that a given neurotransmitter consistently plays a given role; e.g.
glutamate as an excitatory transmiiter and GABA as an inhibitory transmitter. But,
some transmitters (e.g. ACh) can be excitatory or inhibitory, depending on the
synapse.
Ionic basis of the endplate potential
Voltage clamp the endplate. Record
currents (e.p.c.’s) evoked by nerve
stimulation (ACh) at different holding
potentials
Plot I/V relationship of e.p.c.’s.
Reversal potential ~ -10 mV: i.e.
not corresponding to the Nernst
potential for any single ion.
Reversal potential changes if [Na] or [K] in extracellular solution are changed, but not with
changes in [Cl] or [Ca]. So, endplate channels are permeable to both Na and K
Equivalent electrical circuit of a nicotinic Ach channel (endplate channel)
Equivalent electrical circuit for ACh action on the endplate
Summated conductance of many thousands
(how many??) of nAChR channels
Relationships between time courses of channel openings, e.p.c. (endplate
current) and e.p.p. (endplate potential)
e.p.c. kinetics are determined by mean channel open time
e.p.p.kinetics are determined by membrane RC time constant
Effects of cholinesterase inhibition
ACh-esterase in the synaptic cleft hydrolyzes ACh to choline (which is recycled into the nerve
terrminal) This breakdown is very rapid, so that each ACh molecule gets only one chance to bind to a
receptor site before it is hydrolyzed.
But: if esterase is blocked (e.g. with neostigmine), an ACh molecule can bind repeatedly and open
several channels before eventually diffusing away.
Peak amplitude of e.p.c. is not changed, but its decay is slowed. Thus e.p.p. becomes larger (integral
of charge movement during e.p.c)
Used for treatment of myasthenia gravis: autoimmune disease of impaired nerve/
muscle transmission owing to antibodies against AChR.
Integration of excitatory signals by a neuron
(The nerve-muscle junction does not process information, just one-to-one transmission)
1. TEMPORAL SUMMATION The e.p.s.p. (excitatory postsynaptic potential) produced by
a single presynaptic action potential may not be enough to depolarize the postsynaptic neuron to
threshold for an action potential. BUT, if stimulated several times in quick succession e.p.s.p.s
summate to depolarize above threshold. (Temporal summation via RC time constant of
membrane.)
2. SPATIAL SUMMATION
Summation of (near) simultaneousexcitatory
conductances from several synapses to give an e.p.s.p. large enough to exceed action
potential threshold. Spatially limited by cable properties (length constant) of dendrite.
Inhibitory conductance changes
Receptors to GABA and glycine cause opening of Cl-permeable channels
Equilibrium potential for Cl- in neurons is around -80 mV. So action of GABA is to “pull’ the
neuron’s potential toward -80 mV.
This might cause a hyperpolarization or depolarization, depending on the
initial resting potential.
So – if GABA actually causes a depolarization, why is it inhibitory?
1.
The potential change evoked by GABA cannot go more positive than -80 mV no
matter how much GABA : This is well below the action potential threshold
2.
Current through GABA-activated channels tends to hold the neuron at -80 mV,
opposing depolarization by excitatory synapses.
Of course, interactions between inhibitory and excitatory synapses depend on both
temporal and spatial integration, as with interactions between excitatory synapses.
Equivalent circuit for
interactions
between excitatory and
inhibitory synapses