Steps Of Neuromuscular Transmission, Synapse, Neuro-Muscular Junction, Quantal Release, Acetyl Choline Receptor Physiology

4. Anatomy
Critical to function

8. NMJ on the muscle fiber
10µm
10µm

10. Synaptic selectivity at developing
NMJ

12. Synapse from a frog sartorius neuromuscular
junction showing vesicles clustered in the active
zone, some docked at the membrane (arrows).
(from
Heuser,
1977)

13. Synaptic Transmission
The Steps

14. Synaptic Transmission Model
•
•
•
•
•
•
Precursor transport
NT synthesis
Storage
Release
Activation
Termination ~diffusion, degradation,
uptake, autoreceptors

15. Presynaptic
Axon Terminal
Terminal
Button
Postsynaptic
Membrane

16. (1) Precursor
Transport

17. (2)
Synthesis
_
_
_
enzymes/cofactors
NT

18. (3) Storage
in vesicles

19. A quantum is the number of transmitters
released from a single synaptic vesicle
Vesicles have a fairly uniform size and diameter ≈ 40- 50 nm
Individual vesicles contain 8000 - 10,000 phospholipid molecules and several
proteins. The vesicle molecular weight is approx. 3-5 x 106

21. Proteins associated with synaptic vesicles
(identified through sequencing and cloning of cDNA’s)
Membrane proteins
A.
B.
C.
Synaptophysin (~ 36 kD)
Synaptotagmin (~ 61 kD; the Ca2+ sensor)
Snares (residents of either the vesicle
[v-snare] or the target membrane [t-snare])
1.
VAMP (also called synaptobrevin), a v-snare (~18 kD)
2.
Syntaxin, a t-snare that also associates with Ca 2+
channels (~32 kD; technically not a vesicle protein)
3.
SNAP-25, a t-snare (~25 kD; also technically not a
vesicle protein)
D. Electrogenic proton ATPase -creates emf that drives
neurotransmitter uptake against a concentration gradient

22. Proteins associated with synaptic vesicles
(identified through sequencing and cloning of cDNA’s)
Membrane proteins
A.
B.
C.
Synaptophysin (~ 36 kD)
Synaptotagmin (~ 61 kD; the Ca2+ sensor)
Snares (residents of either the vesicle
[v-snare] or the target membrane [t-snare])
1.
VAMP (also called synaptobrevin), a v-snare (~18 kD)
2.
Syntaxin, a t-snare that also associates with Ca 2+
channels (~32 kD; technically not a vesicle protein)
3.
SNAP-25, a t-snare (~25 kD; also technically not a
vesicle protein)
D. Electrogenic proton ATPase -creates emf that drives
neurotransmitter uptake against a concentration gradient

23. An alternative form of Ca2+-dependent vesicle fusion, termed fast tracking, or
“kiss and run” predominates at low frequency stimulation.

24. Life cycle of a
synaptic vesicle

27. Terminal
Button
Dendritic
Spine
Synapse

28. (4) Release
Terminal
Button
Dendritic
Spine
Synapse
Receptors

29. Terminal
Button
AP
Dendritic
Spine
Synapse

30. Exocytosis
Ca2+

31. From Kristin Harris Lectures.
http://synapses.mcg.edu/lab/harris/lectures.htm

33. Stimulation
mini
Evoked amplitudes.
1X
4X
Mini histogram.
2X
1X
3X
4X
2X
1 mV
Squire Fund. Neurosci.

34. From Kristin Harris Lectures.
http://synapses.mcg.edu/lab/harris/lectures.htm

35. “docked”
No firing
“fast”
“slow”
Firing
Heuser and Reese,
1981
Electron micrographs of “omega figures” (fusing synaptic vesicles) after slam freezing a
firing synapse provided clinching evidence for the vesicle hypothesis.

36. A cholinergic synapse
Ne
rv
Action
potential
Choline
ef
ibe
r(
ax
on
)
Na+, Cl-
Acetyl-CoA
Acetyl-Choline
Ca + +
Ca + +
Acetyl-Choline

37. A cholinergic synapse (2): Rapid
transmitter inactivation by
cholinesterase
Choline
Acetate
Action
potential
Acetyl-CoA
Acetyl-Choline
Ca + +
Choline
esterase

38. (5) Activation

40. (1) Ionotropic Channels
Channel
NT
neurotransmitter

41. Ionotropic Channels
NT
Pore

42. Ionotropic Channels
NT

43. Ionotropic Channels
NT

44. Acetylcholine Receptor
α
β
γ
(or
ε)
ACh
ACh
δ
α
Miyazawa, A., Y. Fujiyoshi, and N. Unwin. 2003. Structure and gating
mechanism of the acetylcholine receptor pore. Nature 423:949-955.

45. End Plate Potential (EPP)
Presynaptic
terminal
VNa
Muscle Membrane
Voltage (mV)
The movement of Na+ and K+
depolarizes muscle membrane
potential (EPP)
0
EPP
Threshold
-90 mV
VK
Presynaptic
AP
Time (msec)
Outside
Muscle membrane
Inside
ACh Receptor Channels
Voltage-gated
Na Channels
Inward Rectifier
K Channels
45

46. Normal EPPs invariably evoke muscle action
potentials
• Normally, the average EPP amplitude = 60 mV
-In frog, ~150 vesicles
• Safety factor for transmission is therefore high (greater than 1)
- Frog example:
∆VEPP ÷ ∆VAPthreshold
= 60 mV ÷ │-90 mV*- [-50 mV] │
= 60 mV ÷ 40 mV = 1.5
(*muscle resting VM = -90 mV)

47. (6) Termination

48. (6.1) Termination by...
Diffusion

49. (6.2) Termination by...
Enzymatic degradation

50. Acetylcholine
Metabolism
acetylcholine
ACh
esterase (AChE)
choline + acetate
• AChE is located in the synaptic cleft
• Choline is taken back up into the
presynaptic terminal – active process
• Acetate diffuses away to be utilized in
other metabolic roles

51. (6.3) Termination by...
Reuptake

52. (6.4) Termination by...
Autoreceptors
A

54. The Safety Factor !!!
• Number of Quanta
• The receptor density on the post synaptic
membrane
• The activity of ACH esterase
• The folds of the PS membrabe
• The presence of active zones

57. Voltage-gated channels

58. Na+ channelopathies
Gene
Channel
Disease
Muscle
SCN4A
α subunit of NaV1.4
Hyperkalaemic periodic paralysis
Hypokalaemic periodic paralysis
Paramyotonia congenita
Potassium-aggravated myotonia
Myotonia fluctuans
Myotonia permanens
etc
Neuronal
SCN1A
α subunit of NaV1.1
(somatic)
Generalised Epilepsy with Febrile
Seizures + (GEFS+),
Severe myoclonic epilepsy of
infancy (SMEI)
SCN2A
α subunit of NaV1.2
(axonal)
GEFS+
SCN1B
β1 subunit

59. Ca2+ channel structure
α2δ
γ
β
α1

60. Ca2+ channelopathies
Gene
Neuronal
Disease
CACNA1S
α subunit of CaV1.1
HypoK periodic paralysis
Malignant hyperthermia
RYR1
Muscle
Channel
Ryanodine receptor
(sarcoplasmic channel)
Malignant hyperthermia
Central core disease
CACNA1A
α subunit of CaV2.1
(P/Q-type channel)
Familial hemiplegic migraine
Episodic ataxia type 2
Spinocerebellar ataxia type 6
Absence epilepsy?
CACNA1H
αsubunit of CaV3.2
(T-type channel)
Absence epilepsy

61. Nicotinic receptor channelopathies
Gene
CHRNA1
α1 subunit
Congenital myasthenic syndrome
β1 subunit
CHRND
δ subunit
CHRNE
Neuronal
Disease
CHRNB1
Muscle
Channel
ε subunit
CHRNA2
α4 subunit
CHRNB4
β2 subunit
AD nocturnal frontal lobe epilepsy

62. Slow channel
syndrome
Sine et al
(1995)

63. Fast channel syndrome
can be associated with congenital joint
deformities (arthrogryposis multiplex)
Brownlow et al
(2001)