Chap:5 How do neurons used electrochemical signals to communicate and adapt?
dendrodendritic
dendrites send messages to other dendrites
neurotransmission
1. synthesis 2.release 3.receptor action 4.inactivation
what determines what is a neurotransmitter
1.chemical must be synthesize or present in neuron 2.when released, it must produce response in target cell 3.same receptor action must be obtained when chemical is experimentally placed on target 4.there must be a mechanism for removal after chemical work' is done
Cholinergic system
Acetylcholine -> plays a tole in normal working behavior, attention and memory
what are the 4 types of small molecules neurotransmitters
Acetylcoline synthesis Amine synthesis Serotonin synthesis Amino Acid synthesis
Acetylcoline made up of
Choline and Acetate
The 4 types of activating systems in CNS
Cholinergic system dopaminergic system noradrenergic system serotenergiic system
Amino Acid synthesis makes
GABA GLUTAMATE
2 types of receptors in postsynaptic neurons
Ionotropic receptor metabotropic receptor
3 types of neurotransmitters
Small molecules peptide (neuropeptides) tranmitter gasses
Transmitter Gasses
Synthesized in the cell as needed. Very fast acting, activate metabolic processes in cells such as MODULATING PRODUCTION OF OTHER NTs. Ex: nitric oxide, carbon monoxide.
Activating systems
Uses specific neurotransmitter to control other places. neural pathway that coordinates brain activity through a single neurotransmitter; cell bodies are located in nucleus in the brainstem and axons are distributed through a wide region of the brain
neurotransmitters
a chemical released by a neuron onto a target with an excitatory0 or inhibitory effect. Acts in the CNS, out side the CNS is called a hormone
Learning
a relative change in behavior that results from experience
Acetylcholine (ACh)
activities skeletal muscles ans can inhibit or slow down heart beat. First neurotransmitter discovered in the peripheral and central nervous system; activates skeletal muscles in the somatic nervous system ans may either excite or inhibit internal organs in the autonomic system
Dopamine
amine neurotransmitter that plays a role in coordinating movement, in attention and learning, ans in behavior reinforcing
Glutamate
amino acid neurotransmitter that excites neurons. Pumps you UP - Sympathetic System
GABA
amino acid neurotransmitter that inhibits neurons. COMES you Down. -Parasympathetic
Synapses were first seen through
an electron microscopes
Sensitization
an enhanced response to a stimulus where synapses change at the potassium channel. More POTASIUM leads to greater Neurotransmitter in the synapse creating larger response to same stimulus
Axoaxonic
axon terminal ends on another axon
axosynaptic
axon terminal ends on another terminal
axosomatic
axon terminal ends on cell body
axosecretory
axon terminal ends on tine blood vessel and secretes transmitter into blood stream
axodendritic
axon terminal of one neuron synapses on dendritic spine of another
Ionotropic receptor
binding site for NT ans has a channel for Na+, K+ to cross the membrane (the shape of the protein changes as the ions travel through). RAPIDLY changes voltage across membrane . Usually EXITATORY- Triggers action potentials
Metabotropic receptor
binding site for NT but no channel of its own. It Activates other channels near it to open or close for ions to cross membrane. Linked to a G protein that can affect other receptors or act with second messengers to affect other cellular processes. Alpha sub unit attaches to the near by channel to open it or Alpha sub unit attaches to enzyme and then the enzyme creates a secondary messenger that causes a channel to open.
Epinephrine (adrenaline)
chemical messenger that acts as a hormone to mobilize the body for fight of flight during times of stress ans as a neurotransmitter in the central nervous system.
Synaptic variety
dendrodendritic axodendritic axoextracellular axosomatic axoaxonic axosynaptic axosecretory
how are neurotransmitters deactivates?
diffusion degradation re-uptake glia uptake
dopaminergic system
dopamine: coordinating movements and involved in addictive behavior
degradation
enzymes break down neurotransmitters in the synaptic cleft to create building blocks to create new ones
Amine synthesis includes
epinephrine dopamine nor-epinephrine
gap junction
fused prejucntion ans postjucntion cell membrane in which connected ion channels form a pore that allows ions to pass directly from one neuron to the next
re-uptake
membrane transporter proteins can break down or take whole neurotransmitters back into presynaptic neuron
Seretonin synthesis controls
mood/ agression / sleepiness / daily activities to live
Small molecules neurotransmitters
most common in nervous system. quick acting NT synthesized in the axon terminal from products derived from the diet.
Peptides (neuropeptides) Neurotransmitters
multifunctional chain of amino acids that act as Neurotransmitters. TAKE MORE TIME TO Synthesis than small molecules. Ex: opioid, insulin, corticosteroid
Norepinephrine (noradrenaline)
neurotransmitter found in the brain and in the sympathetic division of the autonomic nervous system; accelerates hear rate in mammals
1.Synthesis
neurotransmitters must be made to be ready to be released when action potential travels down the axon
4.inactivation
neurotransmitters then either keep working in the synapse or is broken down into molecules and taken into the synaptic neuron
noradrenergic system
norapinephrine: may stimulate neurons to change structure during learning , emorional processing
Amine synthesis depends on
rate limiting factors, which are any enzyme that is in limited supply, thus restricting the pace at which a chemical can be synthesized
serotenergic system
seratonin: weakfulness, mood, plays a role in learning
glia uptake
some glia take in the neurotransmitter and can store it for future use in the synaptic cleft through phagocytosis
diffusion to deactivate neurotransmitters
some neurotrnamitters diffuse away from receptors sites to no longer act on the receptor
neurotransmitters must cross the
synaptic gap once released by a vesicle in the presynaptic neuron
axonextracellular
terminal with no specific target. secretes transmiter to extracellular fluid
Habituation
the response to a stimulus WEAKENS with repeated presentations of the stimulus. can happen with all the senses. NEURAL BASIS: as habituation develops, the EPSPs in motor neurons become smaller, calcium channels, less neurotransmitters are transmitted from presynaptic neuron.
3.Receptor action
transmitter activated receptors receive neurotransmitters on postsynaptic membrane and new action potential is generated
Seretonin depends on
triptophan
2.Release
upon action potential reaching the axon terminal, Neurotransmitters must be released to the synaptic cleft (gap)
In the synapse glia cells
work to provide the building blocs for the synthesis of neurotransmitters and help "mop up" used neurotransmitters
