neuronal transmission
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Neuronal Transmission. BN Fall 2011 Julia Sobesky. Types of synapses Electrical Chemical Neurotransmitters Criteria Types Release Inactivation Receptor types Ionotropic Metabotropic Ligand binding Plasticity. Outline. Electrical synapse: gap junctions. ~3nm apart - PowerPoint PPT PresentationTRANSCRIPT
Neuronal Transmissio
nBN Fall 2011Julia Sobesky
Outline
• Types of synapses• Electrical• Chemical
• Neurotransmitters• Criteria• Types• Release• Inactivation
• Receptor types• Ionotropic• Metabotropic
• Ligand binding
• Plasticity
Electrical synapse: gap junctions
• ~3nm apart
• Very fast communication
• Direct pore between cells, allows bidirectional flow of ions
• 6 connexins= 1 connexon
• Allows rapid and synchronous firing of interconnected cells
Why would we need anything more?
• Why don’t our brains just use electrical transmission?
Benefits of Chemical signaling
• 60+ different NTs and neuromodulators• Each NT can have up to 15 different
receptors• Co-localization of several NTs in one
synapse• One neuron can have TONS of different
synapses• Simple or complex post-synaptic
responses
The chemical synapse
• ~20-50 nm apart
• NTs released by pre-synaptic cell bind receptors on post-synaptic membrane
• EPSP, IPSP or complex responses
• *** The RECEPTOR determines the response, not the NT ***
Criteria for NTs• Synthesized in pre-
synaptic cell
• Activity dependent release
• Mechanism for deactivation
• Predictable pharmacological activity
Major classes of neurotransmitters
• Small neurotransmitter molecules • Synthesized near axon terminals• Acetylcholine, monoamines, indolamines, amino
acids
• Large neurotransmitter molecules- Neuropeptides• Synthesized in soma • hormones• enkephalin/ endorphin
• Soluble gasses• nitric oxide • carbon monoxide
Small Neurotransmitters
• 1. Amino Acids• Glutamate/ Gamma-aminobutyric acid (GABA)
• MAJOR NTs in the CNS/ All over
• 2. The Monoamines• Catecholamines
• Dopamine- DA- reward/movement• Norepinephrine- NE –sympathetic• Epinephrine-released from adrenals
• Indolamines• Serotonin -5-HT
• 3. Acetylcholine (ACh)
Glutamic AcidDecarboxylase (GAD)
Tyrosine Hydroxylase
Then what?• NTs are synthesized at terminal and
packaged• Or• Neuropeptides are transcribed, translated,
packaged and trafficked down to the terminal
• How does an Action Potential initiate their release?
Exocytosis
SNARE Proteins
Ca++ facilitated
What happens to NTs after release?
• Diffusion through synapse to post-synaptic cell
• NT binding to receptors is TRANSITORY, more NT around to bind, the greater the receptor effects
• …….
2 Main Types of Receptors
Ionotropic• Ligand-gated ion
channels• Directly alters the
membrane potential
Metabotropic• Slower, but can
have greater effects
• 2 types: • G-protein coupled• Tyrosine Kinase
receptors
Ionotropic Receptors• Excitatory (EPSP) or
Inhibitory (IPSP) responses
• K+, Na+, Ca++
• CL-
• Some can be ligand and voltage-gated (NMDA)
Complex effects of metabotropic
receptors• NO PORE, but binding can initiate:
• 2nd messenger system
• Other products could open ion channels
• Modulate enzyme activity
• Regulate ion channels in membrane
• Initiate gene transcription/translation
What happens to NTs after release?
• Diffusion through synapse to post-synaptic cell
• NT binding to receptors is TRANSITORY, more NT around to bind, the greater the receptor effects
• NT must be cleared • removal just as important as release
• Multiple things can happen….
Uptake and degradation
Glial Sponge• Glial cells can act
as buffers for excess NTs
• Can process and release NTs
• Passive diffusion away from the synapse• Why?
NT binding to receptor shape-
specific• Lock and key arrangement
• Endogenous vs. exogenous
• Drugs work because we already have the receptors in place to receive them
• Drug actions are so intense because they cause actions so far above and beyond what endogenous compounds do
• Agonists
• Antagonists
• Full vs. partial
• Competitive vs. non-competitive
• Allosteric
Receptor agonists and antagonists
Organization dictated by experience
• Synapses can grow and retract, continually being altered by use
• Plasticity can occur in a variety of ways:• Create new synapses• Strengthen or weaken
existing synapses• Break old connections
Synaptic connections change over time
Putting it all together:
Neuropharmacology• Tolerance develops
due to cellular and receptor alterations in response to chronic drug use
• The changes also mediate withdrawal symptoms
• Withdrawal= opposite of drug effects
• Depression is most likely not due to a lack of serotonin (i.e. SSRIs)
• …Serotonin receptor is metabotropic
• Severe alcohol withdrawal can kill you: • Seizures• Glutamate
excitotoxicity
Organization dictated by experience
Thanks! Questions?