Chapter 12: Neural Tissue * * Neurotransmitter Mechanism of

About This Presentation

Title:

**Chapter 12: Neural Tissue * * Neurotransmitter Mechanism of**

Description:

Chapter 12: Neural Tissue * * Neurotransmitter Mechanism of Action Direct effect on membrane potential Open or close ion channels upon binding to the post synaptic ... – PowerPoint PPT presentation

Number of Views:381

Avg rating:3.0/5.0

Slides: 114

Provided by: annmariea

Category:

more less

Transcript and Presenter's Notes

Title: Chapter 12: Neural Tissue * * Neurotransmitter Mechanism of

1
Chapter 12 Neural Tissue
2
Neural Tissue

3 of body mass
Cellular, 20 extracellular space
Two categories of cells
Neurons conduct nervous impulses
- cells that send and receive signals
Neuroglia/glial cells nerve glue
Supporting Cells
Protect neurons

3
Organs of the Nervous System

Brain and spinal cord
Sensory receptors of sense organs (eyes, ears,
etc.)
Nerves connect nervous system with other systems

4
(No Transcript)
5
Nervous Systems

Central Nervous System (CNS)
Spinal cord, brain
Functions
integrate, process, coordinate sensory input and
motor output
Peripheral Nervous System (PNS)
All neural tissue outside of CNS
Functions Carry info to/from the CNS via nerves
Nerves
Bundle of axons (nerve fibers) with blood vessels
and CT
Carry sensory information and motor commands in
PNS
Cranial nerves brain
Spinal nerves spinal cord

6
Division of PNS

Sensory/Afferent Division carries sensory
information
Sensory receptors ? CNS
Somatic afferent division
- From skin, skeletal muscles, and joints
Visceral afferent division
- From internal organs

7
Division of PNS

2. Motor/Efferent Division carries motor
commands
CNS ? effectors
Somatic Nervous System Controls skeletal muscle
contractions
- voluntary nervous system
To skeletal muscles ? contractions
Autonomic Nervous System (ANS)
involuntary nervous system
To smooth and cardiac muscle, glands ?
contractions
Sympathetic Division stimulating effect
- fight or flight
Parasympathetic Division relaxing effect
rest and digest
Tend to be Antagonistic to Each Other

8
Receptors and Effectors

Receptors
detect changes or respond to stimuli
neurons and specialized cells
complex sensory organs (e.g., eyes, ears)
Effectors
respond to efferent signals
cells and organs

9
What would damage to the afferent division of the
PNS affect?

ability to learn new facts
ability to experience motor stimuli
ability to experience sensory stimuli
ability to remember past events

10
The structure of a typical neuron, and the
function of each component.
11
Histology of Nervous System

Neuron/Nerve Cell
Function conduct nervous impulses (message)
Characteristics
Extreme longevity
Amitotic
- Direct cell division by simple cleavage of the
nucleus without spindle formation or appearance
of chromosomes
- exceptions hippocampus, olfactory receptors
High metabolic rate need O2 and glucose

12
The Structure of Neurons
Figure 121
13
The Structure of Neurons

Large soma/perikaryon(cytoplasm)
Large nucleus, large nucleolus (rRNA)
Many mitochondria, ribosomes, RER, Golgi
Increase ATP, increase protein synthesis to
produce neurotransmitters
Nissl bodies visible RER and ribosomes, gray
Neurofilaments internal structure
Neurofibrils, neurotubules
No centrioles
2 types of processes (cell extension)
Dendrite
Axon

14
Regions of a Neuron

Dendrites
Receive info
Carry a graded potential toward soma
Contain same organelles as soma
Short, branched
End in dendritic spines

15
Regions of a Neuron

Axon
single, long
Carry an action potential away from soma
Release neurotransmitters at end to signal next
cell
Long ones nerve fibers
Contains
Neurofibrils and neurotubules (abundant)
Vesicles of neurotransmitter
Lysosomes, mitochondria, enzymes
No nissl bodies, no golgi (no protein synthesis
in axon)

16
Regions of a Neuron

2. Axon
Connects to soma at axon hillock
Covered in axolemma (membrane) --- Axoplasm
(cytoplasm)
May branch axon collaterals
End in synaptic terminals or knobs
May have myelin sheath proteinlipid
Function
Protection, Insulation, and Increase speed of
impulse
CNS myelin from Oligodendrocytes
PNS myelin from Schwann cells

17
Axoplasmic Transport

Move materials between soma and terminal
Large molecules synthesized in the cell body,
such as vesicles and mitochondria are unable to
move via simple diffusion
Large molecules are transported by motor proteins
called kinesins, which walk along neurotubule
tracks to their destinations.
Anterograde transport soma ? terminal
neurotransmitters from soma
Retrograde transport terminal ? soma
Recycle breakdown products from used
neurotransmitters
Some viruses use retrograde transport to gain
access to CNS (polio, herpes, rabies)

18
Synapse

Site where neuron communicates
with another cell
neuron or effector
Presynaptic cell sends message
along axon to axon terminal
Postsynaptic cell receives message
as neurotransmitter
Neurotransmitter chemical, transmits signal
from pre- to post- synaptic cell across synaptic
cleft
Synaptic knob small, round, when postsynaptic
cell is neuron, synapse on dendrite or soma
Synaptic terminal complex structure, at
neuromuscular or neuroglandular junction

19
Structural Classification of Neurons

Anaxonic neurons
Dendrites and axon look same
Brain and special sense organs
Bipolar neurons
1 dendrite, 1 axon
Soma in middle
Rare special sense organs,
relay from receptor to neuron
Unipolar neurons
1 long axon, dendrites at one end,
soma off side (T shape)
Most sensory neurons
Multipolar neurons
2 or more dendrites
1 long axon
99 of all neurons
Most CNS

20
A tissue sample shows unipolar neurons. Are
these more likely to be sensory neurons or motor
neurons?

sensory neurons
motor neurons

21
Functional Classification of Neurons

Sensory/Afferent Neurons
Transmit info from sensory receptors to CNS
Mostly unipolar neurons
Soma in peripheral sensory ganglia
Ganglia collection of cell bodies in PNS
Somatic Sensory Neurons
- Receptors monitor outside conditions
Visceral Sensory Neurons
Receptors monitor internal conditions

22
Functional Classification of Neurons

Motor/Efferent Neurons
Transmit commands from CNS to effectors
Mostly multipolar neurons
Somatic Motor Neurons
Innervate skeletal muscle
Innervation distribution of sensory/motor
nerves to a specific region/organ
Conscious control or reflexes
Visceral/Autonomic Motor Neurons
- Innervate effectors on smooth muscle, cardiac
muscle, glands, and adipose

23
Functional Classification of Neurons

Interneurons/Association Neurons
Distribute sensory info and coordinate motor
activity
Between sensory and motor neurons
In brain, spinal cord, autonomic ganglia
Most are multipolar

24
The locations and functions of neuroglia.
25
Neuroglia

Neuroglia supporting cells
Neuroglia in CNS
Outnumber neurons 101
Half mass of brain
Neuroglia Cell in the CNS
Ependymal cells
Astrocytes
Oligodendrocytes
Microglia

26
Neuroglia Cells of the CNS

Ependymal Cells
Line central canal of spinal cord and ventricles
of the brain
Secrete cerebrospinal fluid (CSF)
Have cilia to circulate CSF
CSF cushion brain, nutrient and gas exchange
Astrocytes
Most abundant CNS neuroglia
Varying functions
Blood brain barrier
Processes wrap capillaries
Control chemical exchange between blood and
interstitial fluid of the brain
Framework of CNS
Repair damaged neural tissue
Guide neuron development in embryo
Control interstitial environment
- Regulate conc. Ions, gasses, nutrients,
neurotransmitters

27
Neuroglia Cells of the CNS

Oligodendrocytes
Wide flat processes wrap around local axons
myelin sheath
1 cell contributes myelin to many neighboring
axons
Lipid in membrane insulates axon for faster
action potential conductance
Gaps on axon between processes/myelin nodes of
Ranvier, necessary to conduct impulse
White, myelinated axons white matter
Microglia
Phagocytic
Wander CNS
Engulf debris, pathogens
Important CNS defense
No immune cells or antibodies

28
Neuroglia of the CNS
Figure 124
29
Neuroglia in PNS

Satellite Cells
Surround somas in ganglia
Isolate PNS cells
Regulate interstitial environment of ganglia
Ganglia mass of neuronal soma and dendrites
Schwann cells
Myelinate axon in PNS
Whole cells wraps axon, many layers
Neurilemma bulge of schwann cell,
contains organelles
Nodes of Ranvier between cells

30
Neuroglia in PNS

Schwann Cells cont.
Some hold bundles of unmyelinated axon
Vital to repair of peripheral nerve fibers after
injury
Guide growth to original synapse

31
Which type of neuroglia would occur in larger
than normal numbers in the brain tissue of a
person with a CNS infection?

astrocytes
microglial cells
ependymal cells
oligodendrocytes

32
Neural Responses to Injuries
Figure 126 (1 of 2)
33
Neural Responses to Injuries
Figure 126 (2 of 2)
34
KEY CONCEPT

Neurons perform all communication, information
processing, and control functions of the nervous
system
Neuroglia preserve physical and biochemical
structure of neural tissue, and are essential to
survival and function of neurons

35
How the resting potential is created and
maintained.
36
5 Main Membrane Processes in Neural Activities
Figure 127 (Navigator)
37
Neurophysiology

Neurons conduct electrical impulse
Requires transmembrane potential electrical
difference across the cell membrane
Cells positive charge outside (pump cations out)
and negative charge inside (protein)
Voltage measure of potential energy generated
by separation of opposite charges
Current flow of electrical charges (ions)
Cell can produce current (nervous impulse) when
ions move to eliminate the potential difference
(volts) across the membrane
Resistance Restricts ion movement (current)
High resistance low current
Membrane has resistance, restricts ion
flow/current

38
Neurophysiology

Ohms Law current voltage resistance
Current is highest when voltage is high and
resistance is low
Cell voltage set at -70mV but membrane resistance
can be altered to create current
Membrane resistance depends on permeability to
ions open or closed ion channels
Cell must always have some resistance or ions
would equalize, voltage zero
No current generated no nervous impulse

39
Membrane Ion Channels

Allow ion movement (alter resistance)
Each channel is specific to one ion type
Passive Channels (leaky channels)
Active Channels
Chemically regulated/ligand-gated
Voltage regulated channels
Mechanically regulated channels

40
Membrane Ion Channels

Passive Channels (leaky channels)
- Resting Potential
Always open, free flow
Sets resting membrane potential at -70mV

41
Active Channels Gated Channels
Figure 1210
42
Membrane Ion Channels

Active Channels
open/close in response to signal
Chemically regulated/ligand-gated
Open in response to chemical binding
Located on any cell membrane
Dendrites and soma

43
Membrane Ion Channels

2. Active Channels
B. Voltage regulated channels
- open/close in response to shift in
transmembrane potential
- excitable membrane only conduct action
potentials
- axolemma, sarcolemma

44
Membrane Ion Channels

2. Active Channels
C. Mechanically Regulated Channels
- Open in response to membrane distortion
- On dendrites of sensory neurons for
- touch, pressure, vibration

45
Membrane Ion Channels

When channel opens, ions flow along
electrochemical gradient
Diffusion (high conc. to low)
Electrical attraction/repulsion

46
Sodium-Potassium Pump
47
Sodium-Potassium Pump

Uses ATP to move 3 Na out and 2 K in
70 of neurons use ATP for this
Runs anytime the cell is not conducting an
impulse
Creates high K inside and high Na outside
When Na cell opens
Na flows into cell
Favored by diffusion gradient
Favored by electrical gradient
Open channel decr. Resistance incr. ion
flow/current
When K channel opens
K flows out of cell
Favored by diffusion gradient only
Electrical gradient repels K exit
- Thus less current than Na

Channels open resistance low ions move until
equilibrium potential depends on
Diffusion gradient
Electrical gradient
Equilibrium Potential

49
Electrical vs. Chemical Gradients

The electrical gradient opposes the chemical
gradient
K inside and outside of the cell are attracted
to the negative charges on the inside of the cell
membrane, and repelled by the positive charges on
the outside of the cell membrane
indicated in white on the next slide
Chemical gradient is strong enough to overpower
the electrical gradient, but this weakens the
force driving K out of the cell
Net driving force indicated in grey on the next
slide
The Electrochemical Gradient

50
Electrochemical Gradients
Figure 129c, d
51
Summary Resting Potential
Table 12-1
52
Changes in Transmembrane Potential

Transmembrane potential rises or falls
in response to temporary changes in membrane
permeability
resulting from opening or closing specific
membrane channels
Membrane permeability to Na and K determines
transmembrane potential
Sodium and potassium channels are either passive
or active

53
Graded Potentials The Resting State

Opening sodium channel produces a current which
causes graded potential

Figure 1211 (Navigator)
54
Graded Potential

Graded potential
localized shift in transmembrane potential due to
movement of charges into/out of cell
Na channel opens Na flows in
depolarization (cell less negative)
K channel opens K flows out
hyperpolarization (cell more negative)

55
Graded Potentials

Occur on any membrane dendrites and somas
Can be depolarizing or hyperpolarizing
Amount of depolarization or hyperpolarization
depends on the intensity of stimulus
Incr. channels open Incr. voltage change
Passive spread from site of stimulation over
short distance
Effect on membrane potential decreases with
distance from stimulation site
Repolarization occurs as soon as stimulus is
removed
Leaky channels and Na/K pump reset resting
potential

56
Graded Potentials

Localized change in transmembrane potential, not
nervous impulse (message)
If big enough depolarization
Action potential nervous impulse transmission
to next cell

57
Graded Potentials Step 1

Resting membrane exposed to chemical
Sodium channel opens
Sodium ions enter the cell
Transmembrane potential rises
Depolarization occurs
A shift in transmembrane potential toward 0 mV

Figure 1211 (Step 1)
58
Graded Potentials Step 2

Movement of Na through channel
Produces local current
Depolarizes nearby cell membrane (graded
potential)
Change in potential is proportional to stimulus

Figure 1211 (Step 2)
59
Characteristics of Graded Potentials
Table 12-2
60
Action Potential

Occur on excitable membranes only
Axolemma, sarcolemma
Always depolarizing
Must depolarize to threshold (-55mV) before
action potential begins
Voltage gated channels on excitable membrane open
at threshold to propagate action potential
all-or-none
All stimuli that exceed threshold will produce
identical action potentials
Action potential at one site depolarizes adjacent
sites to threshold
Propagated across entire membrane surface without
decrease in strength

61
Generating the Action Potential
Figure 1213 (Navigator)
62
Generation of an Action Potential

Depolarization to threshold
A graded potential depolarizes local membrane and
flows toward the axons
If threshold is met (-55mV) at the hillock, an
action potential will be triggered
Activation of sodium channels and rapid
depolarization
At threshold (-55mV) , voltage-regulated sodium
channels on the excitable membrane open
Na flows into the cell depolarizing it
The transmembrane potential rapidly changes from
-55mV to 30 mV

63
Generation of an Action Potential

3. Inactivation of sodium channels and
activation of potassium channels
At 30mV Na channels close and K channels open
K flows out of the cell repolarizing it
4. Return to normal permeability
At -70mV K channels begin to close
The cell hyperpolarizes to -90mV until all
channels finish closing
Leak channels restore the resting membrane
potential to -70mV

64
Generation of an Action Potential

Restimulation only when Na channels closed
Influx of Na necessary for action potential
Absolute Refractory Period
Threshold (-55mV) to 30mV, Na channels open,
membrane cannot respond to additional stimulus
Relative Refractory Period
30mV to -70mV (return to resting potential)
Na channels closed, membrane capable of second
action potential but requires larger/longer
stimulus (threshold elevated)
Cell has ions for thousands of action potentials
Eventually must run Sodium-Potassium pump (burn
ATP) to reset high K inside and high Na
outside
Death no ATP, but stored ions can generate
action potentials for awhile

65
Table 12-3
66
How would a chemical that blocks the sodium
channels in neuron cell membranes affect a
neurons ability to depolarize?

It would enhance depolarization.
It would inhibit depolarization completely.
It would slow depolarization.
It would have no effect on depolarization.

67
What effect would decreasing the concentration of
extracellular potassium ions have on the
transmembrane potential of a neuron?

repolarization
hypopolarization
decreased transmembrane potential
hyperpolarization

68
Propagation of Action Potential

Once generated must be transmitted along the
length of the axon hillock to terminal
Speed depends on
Degree of myelination
Axon diameter

69
2 Methods of Propagating Action Potentials

Continuous propagation
unmyelinated axons
Saltatory propagation
myelinated axons

70
Propagation of Action Potential

Myelination
Continuous Propagation
Unmyelinated axons
Whole membrane depolarizes and repolarizes
sequentially hillock to terminal
Only forward movement
Membrane behind always in absolute refractory
period

71
Continuous Propagation

Of action potentials along an unmyelinated axon
Affects 1 segment of axon at a time

Figure 1214
72
Continuous Propagation Step 1

Action potential in segment 1
Depolarizes membrane to 30 mV

Figure 1214 (Step 1)
73
Continuous Propagation Step 2

Local current
Depolarizes second segment to threshold

Figure 1214 (Step 2)
74
Continuous Propagation Step 3

Second segment develops action potential
First segment enters refractory period

Figure 1214 (Step 3)
75
Continuous Propagation Step 4

Local current depolarizes next segment
Cycle repeats
Action potential travels in 1 direction (1
m/sec)

Figure 1214 (Step 4)
76
Propagation of Action Potential

Myelination
Saltatory Propagation
Myelinated axons
Depolarization only on exposed membrane at nodes
Myelin insulates covered membrane from ion flow
Action potential jumps from node to node
Faster and requires less energy to reset

77
Saltatory Propagation

Of action potential along myelinated axon

Figure 1215
78
Saltatory Propagation
Figure 1215 (Steps 1, 2)
79
Saltatory Propagation
Figure 1215 (Steps 3, 4)
80
Graded Potentials and Action Potentials
Table 124
81
Axon Diameter and Propagation Speed

Ion movement is related to cytoplasm
concentration
Axon diameter affects action potential speed
The larger diameter, the lower the resistance

82
Propagation of Action Potentials

Axon Diameter
Larger axon ? less resistance ? easier ion flow ?
faster action potential
Axons are classified by
Diameter, myelination, speed of action potentials
Three types of axons
Type A, Type B, and Type C fibers

83
Axon Diameter

Type A Fibers
- 4-20µm diameter
Myelinated (saltatory propagation)
Action potential 140m/sec
Carry somatic motor and somatic sensory info
Type B Fibers
2-4µm diameter
Myelinated (saltatory propagation)
Action potential 18m/sec
Carry autonomic motor and visceral sensory info
Type C Fibers
lt 2µm diameter
Unmyelinated (continuous propagation)
Action potential 1m/sec
Carry autonomic motor and visceral sensory info

84
KEY CONCEPT

Information travels within the nervous system
as propagated electrical signals (action
potentials)
The most important information (vision, balance,
motor commands) is carried by large-diameter
myelinated axons

85
Myelination

Requires space, metabolically expensive
Only important fibers large and myelinated
Occurs in early childhood
Results in improved coordination
Multiple Sclerosis
Genetic disorder, myelin on neurons in PNS
destroyed ? numbness, paralysis

86
Synapse

Synapse
Junction between transmitting neuron (presynaptic
cell) and receiving cell (postsynaptic cell),
where nerve impulse moves from one cell to the
next
Two types
Electrical Synapse
Direct contact via gap junctions
Ion flow directly from pre to post cell
Less common synapse
In brain (conscious perception)
Chemical Synapse
- Most common

2. Chemical Synapse
Most common
Pre and post cells separated by synaptic cleft
Presynaptic neuron releases neurotransmitter to
trigger effect on post synaptic cell
Dynamic facilitate or inhibit transmission,
depends on neurotransmitter
Excititory Neurotransmitters
Depolarization (shift from resting potential
toward 0 mV)
Propagate Action Potential
Inhibitory Neurotransmitters
Hyperpolarization (shift from resting potential
to -80 mV)
Suppress Action Potential
Propagation across chemical synapse always slow
but allow variability

88
The events that occur at a chemical synapse.
89
The Effect of a Neurotransmitter

On a postsynaptic membrane
depends on the receptor
not on the neurotransmitter
e.g., acetylcholine (ACh)
usually promotes action potentials
but inhibits cardiac neuromuscular junctions

90
Synaptic Activity
Figure 1216 (Navigator)
91
Cholinergic Synapses

Any synapse that releases ACh
all neuromuscular junctions with skeletal muscle
fibers
many synapses in CNS
all neuron-to-neuron synapses in PNS
all neuromuscular and neuroglandular junctions of
ANS parasympathetic division

92
Events at a Cholinergic Synapse Step 1

Action potential arrives, depolarizes synaptic
knob

Figure 1216 (Step 1)
93
Events at a Cholinergic Synapse Step 2

Calcium ions enter synaptic knob, trigger
exocytosis of ACh

Figure 1216 (Step 2)
94
Events at a Cholinergic Synapse Step 3

ACh binds to receptors, depolarizes postsynaptic
membrane

Figure 1216 (Step 3)
95
Events at a Cholinergic Synapse Step 4

AChE breaks ACh into acetate and choline

Figure 1216 (Step 4)
96
Events at a Cholinergic Synapse
Table 12-5
97
What effect would blocking voltage-regulated
calcium channels at a cholinergic synapse have on
synaptic communication?

Communication would cease.
Communication would be enhanced.
Communication would be misdirected.
Communication would continue as before.

98
Neurotransmitter Mechanism of Action

Direct effect on membrane potential
Open or close ion channels upon binding to the
post synaptic cell
Provides a rapid response
E.g. Ach (cholinergic synapse)

99
Neurotransmitter Mechanism of Action

Indirect effect on membrane potential
Binds a receptor that activates a G protein in
the post synaptic cell
Active G protein activates a second messenger
cAMP, cGMP, diacylglyceride, Ca
The second messenger opens ion channels or
activates enzymes
Provides slower but longer lasting effects
E.g. Norepinephrine (Adrenergic synapse)

100
Neurotransmitter Mechanism of Action

Indirect effect on membrane potential
Example of indirect action
Neurotransmitter binds receptor
Receptor activates G protein
G Protein activates adenylate cyclase
Adenylate cyclase converts ATP into cyclic AMP
cAMP opens ion channels

101
Post Synaptic Potential

Graded potential caused by a neurotransmitter due
to opening or closing of ion channels on post
synaptic cell membrane
Two types
Excititory Post Synaptic Potential (EPSP)
- Causes depolarization
Inhibitory Post Synaptic Potential (IPSP)
Causes hyperpolarization
Inhibits postsynaptic cell
Need larger stimulus to reach threshold

102
Post Synaptic Potential

Multiple EPSPs needed to trigger action potential
in post cell axon
EPSP summation
Temporal and Spatial Summation
Temporal Summation
Single synapse fires repeatedly
String of EPSPs in one spot
Each EPSP depolarizes more until threshold
reached at hillock

103
Post Synaptic Potential

EPSP summation
Temporal and Spatial Summation
Spatial Summation
Multiple synapses fire stimultaneously
Collective depolarization reaches threshold

104
EPSP/IPSP Interactions
Figure 1219
105
Post Synaptic Potential

Facilitated Depolarized
Brought closer to threshold by some sort of
stimulus
Less stimulus now required to reach threshold
E.g. Caffeine
Post Synaptic Potentiation
Repeat stimulation of the same synapse conditions
synapse, pre cell more easily stimulated,
allowing the post cell to reach the threshold
(repetition)
Most nervous system activities results from
interplay of EPSPs and IPSPs to promote differing
degrees of facilitation or inhibition to allow
constant fine tuning of response
Neuromodulators
Chemicals that influence synthesis, release, or
degradation of neurotransmitters thus altering
normal response of the synapse

106
Common Neurotransmitters

Acetycholine cholinergic synapses
Excititory
Direct effect
Skeletal neuromuscular junctions, many CNS
synapses, all neuron to neuron PNS, all
parasympathetic ANS
Norepinephrine adrenergic synapses
Excititory
Second messengers
Many brain synapses, all sympathetic ANS effector
junctions

107
Common Neurotransmitters

Dopamine
Excititory or inhibitory
Second messengers
Many brain synapses
Cocaine inhibits removal high
Parkinsons disease damage neurons ticks,
jitters
Serotonin
Inhibitory
Direct or second messenger
Brain stem for emotion
Anti-depression/anti-anxiety drugs block uptake
Gamma aminobytyric acid (GABA)
Inhibitory
Direct effect
Brain anxiety control, motor coordination
Alcohol augments effects loss of coordination

108
Presynaptic Facilitation

Activity at an axoaxonal synapse increases the
amount of neurotransmitter released when an
action potential arrives at the synaptic knob.
This increase enhances and prolongs the
neurotransmitters effect on the Postsynaptic
membrane

Figure 1220a
109
Presynaptic Inhibition

Activity at an axoaxonal synapse via the release
of GABA inhibits the opening of voltage-regulated
calcium channels in the synaptic knob.
Results in a reduced amount of neurotransmitters
released when an action potential arrives there
Thus, reducing the effects of synaptic activity
on the postsynaptic membrane

Figure 1220a
110
Factors that Disrupt Neural Function