1. Neurons: Cellular and Network Properties
Chapter 8b
Neurons: Cellular and Network Properties

2. Cell-to-Cell: A Chemical Synapse
Axon of presynaptic neuron
Postsynaptic neuron
Axon terminal
Mitochondrion
Synaptic vesicles
Synaptic cleft
Receptors
Neurotransmitter
Postsynaptic membrane
Chemical synapses use neurotransmitters; electrical synapses pass electrical signals.
Figure 8-20

3. Cell-to-Cell: Events at the Synapse and Exocytosis1
An action potential
depolarizes the axon
terminal. 2
The depolarization opens
voltage-gated Ca2+
channels and Ca2+
enters the cell.
Axon
terminal
Synaptic
vesicle
Neurotransmitter
molecules 3
Calcium entry triggers
exocytosis of synaptic
vesicle contents.
Action
potential 4
Neurotransmitter diffuses
across the synaptic cleft
and binds with receptors
on the postsynaptic cell. 1 3 5
Neurotransmitter binding
initiates a response in
the postsynaptic cell.
Ca2+
Synaptic
cleft
Docking
protein 2 4
Receptor
Postsynaptic cell
Voltage-gated
Ca2+ channel
Cell
response 5
Figure 8-21

4. Cell-to-Cell: Neurocrines
Seven classes by structure
Acetylcholine
Amines
Amino acids
Purines
Gases
Peptides
Lipids

5. Cell-to-Cell: Synthesis and Recycling of Acetylcholine at a Synapse
Mitochondrion
Myasthenia gravis
Axon
terminal
Acetyl CoA
CoA
Enzyme
Acetylcholine 1 1
Acetylcholine (ACh) is made
from choline and acetyl CoA.
Synaptic
vesicle 2
In the synaptic cleft ACh is rapidly
broken down by the enzyme
acetylcholinesterase. 3
Choline
Cholinergic
receptor 2 3
Choline is transported back into
the axon terminal and is used
to make more ACh.
Acetate
Acetylcholinesterase (AChE)
Postsynaptic
cell
Figure 8-22

6. Derived from single amino acid Tyrosine
Amines
Derived from single amino acid
Tyrosine
Dopamine
Norepinephrine is secreted by noradrenergic neurons
Epinephrine
Others
Serotonin is made from tryptophan
Histamine is made from histadine

7. Glutamate: Excitatory  CNS Aspartate: Excitatory  brain
Amino Acids
Glutamate: Excitatory  CNS
Aspartate: Excitatory  brain
GABA: Inhibitory  brain
Glycine
Inhibitory  spinal cord
May also be excitatory

8. Other Neurotransmitters
Purines
AMP and ATP
Gases
NO and CO
Peptides
Substance P and opioid peptides
Lipids
Eicosanoids

9. Cholinergic receptors
Nicotinic on skeletal muscle, in PNS and CNS
Monovalent cation channels  Na+ and K+
Muscarinic in CNS and Parsympathetic NS
Linked to G proteins to 2nd messengers
Adrenergic Receptors
 and 
Linked to G proteins and 2nd messengers
Glutaminergic
Excitatory in CNS
Metabotropic and Ionotropic

10. Cell-to-Cell: Postsynaptic Response
Fast and slow responses in postsynaptic cells
Postsynaptic
cell
Presynaptic axon
terminal
Ion channels open
More
Na+ in
More K+
out or
Cl– in
EPSP =
excitatory
depolarization
IPSP =
inhibitory
hyperpolarization
Ion channels close
Less
Less K+
out
Alters open
state of
ion channels
Activated second
messenger pathway
Inactive
pathway
Modifies existing
proteins or regulates
synthesis of new
proteins
Coordinated
intracellular
response
Rapid, short-acting
fast synaptic potential
Neurocrine
Slow synaptic potentials
and long-term effects
Chemically
gated ion channel
G protein–coupled
receptor
Figure 8-23

11. Cell-to-Cell: Postsynaptic Response
Presynaptic axon
terminal
Rapid, short-acting
fast synaptic potential
Neurocrine
Chemically
gated ion channel
G protein–coupled
receptor
Postsynaptic
cell
Ion channels open
More
Na+ in
More K+
out or
Cl– in
EPSP =
excitatory
depolarization
IPSP =
inhibitory
hyperpolarization
Figure 8-23, step 1

12. Cell-to-Cell: Postsynaptic Response
Presynaptic axon
terminal
Slow synaptic potentials
and long-term effects
Rapid, short-acting
fast synaptic potential
Neurocrine
Chemically
gated ion channel
G protein–coupled
receptor
Postsynaptic
cell
Ion channels open
More
Na+ in
More K+
out or
Cl– in
EPSP =
excitatory
depolarization
IPSP =
inhibitory
hyperpolarization
Figure 8-23, steps 1–2

13. Cell-to-Cell: Postsynaptic Response
Presynaptic axon
terminal
Slow synaptic potentials
and long-term effects
Rapid, short-acting
fast synaptic potential
Neurocrine
Chemically
gated ion channel
G protein–coupled
receptor
Inactive
pathway
Postsynaptic
cell
Alters open
state of
ion channels
Activated second
messenger pathway
Ion channels open
More
Na+ in
More K+
out or
Cl– in
EPSP =
excitatory
depolarization
IPSP =
inhibitory
hyperpolarization
Figure 8-23, steps 1–3

14. Cell-to-Cell: Postsynaptic Response
Presynaptic axon
terminal
Slow synaptic potentials
and long-term effects
Rapid, short-acting
fast synaptic potential
Neurocrine
Chemically
gated ion channel
G protein–coupled
receptor
Inactive
pathway
Postsynaptic
cell
Alters open
state of
ion channels
Activated second
messenger pathway
Ion channels open
Ion channels close
More
Na+ in
More K+
out or
Cl– in
Less
Na+ in
Less K+
out
EPSP =
excitatory
depolarization
IPSP =
inhibitory
hyperpolarization
Figure 8-23, steps 1–4

15. Cell-to-Cell: Postsynaptic Response
Presynaptic axon
terminal
Slow synaptic potentials
and long-term effects
Rapid, short-acting
fast synaptic potential
Neurocrine
Chemically
gated ion channel
G protein–coupled
receptor
Inactive
pathway
Postsynaptic
cell
Alters open
state of
ion channels
Activated second
messenger pathway
Ion channels open
Ion channels close
More
Na+ in
More K+
out or
Cl– in
Less
Na+ in
Less K+
out
EPSP =
excitatory
depolarization
IPSP =
inhibitory
hyperpolarization
EPSP =
excitatory
depolarization
Figure 8-23, steps 1–5

16. Cell-to-Cell: Postsynaptic Response
Presynaptic axon
terminal
Slow synaptic potentials
and long-term effects
Rapid, short-acting
fast synaptic potential
Neurocrine
Chemically
gated ion channel
G protein–coupled
receptor
Inactive
pathway
Postsynaptic
cell
Alters open
state of
ion channels
Activated second
messenger pathway
Ion channels open
Ion channels close
Modifies existing
proteins or regulates
synthesis of new
proteins
More
Na+ in
More K+
out or
Cl– in
Less
Na+ in
Less K+
out
EPSP =
excitatory
depolarization
IPSP =
inhibitory
hyperpolarization
EPSP =
excitatory
depolarization
Coordinated
intracellular
response
Figure 8-23, steps 1–6

17. Cell-to-Cell: Inactivation of Neurotransmitters1
Neurotransmitters can be returned
to axon terminals for reuse or
transported into glial cells.
Rapid termination of NTs 2
Enzymes inactivate
neurotransmitters.
Blood
vessel 3
Neurotransmitters can diffuse
out of the synaptic cleft.
Axon
terminal of
presynaptic cell
Synaptic
vesicle 3
Glial
cell 1
Enzyme
Postsynaptic cell 2
Figure 8-24