Chemicals in the brain Flashcards
Specific amino acids are in high concentrations in the in the CNS acting as neurotransmitters. Are they always inhibitory and excitatory?
- no
- can inhibitory OR excitatory OR both
- depends on the receptor
Neurotransmitters are created from amino acids, that are in high concentrations in the in the CNS. What effect do inhibitory and excitatory neurotransmitters have on the action potential?
- inhibitory = hyperpolarise (no action potential)
- excitatory = depolarise (increase action potential)
What is the main excitatory and inhibitory neurotransmitters in the CNS?
- excitatory = glutathione, inhibitory = glutamate
- excitatory = GABA, inhibitory = glutamate
- excitatory = dopamine, inhibitory = glutamate
- excitatory = GABA, inhibitory = dopamine
GABA = y-aminobutyric acid
- excitatory = GABA, inhibitory = glutamate
The main excitatory neurotransmitters in the CNS is glutamate. Glutamate possess both direct (the main way it causes depolarisation) and indirect effects (a mechanism coupled with direct effects) that cause depolarisation. What are the direct and indirect effects of this neurotransmitter on the action potential of the cell?
- direct = increased Na+ and Ca2+ enter cell, indirect = K+ cannot leave the cell
- direct = increased K+ and Ca2+ enter cell, indirect = Na+ cannot leave the cell
- direct = increased K+ and Mg+ enter cell, indirect = Na+ cannot leave the cell
- direct = increased Mg+ and Ca2+ enter cell, indirect = K+ cannot leave the cell
- direct = increased Na+ and Ca2+ enter cell, indirect = K+ cannot leave the cell
- direct = increased Ca2+ and Na+ enter the cell
- indirect = K+ is stopped from leaving the cell and increased Ca2+ enters the cell
The main inhibitory neurotransmitters in the CNS is y-aminobutyric acid (GABA). GABA possess both direct (the main way it causes hyperpolarisation) and indirect effects (a mechanism coupled with direct effects) that cause hyperpolarisation. What are the direct and indirect effects of this neurotransmitter on the action potential of the cell?
- direct = increased Ca2+ enters the cell, indirect = K+ cannot leave the cell
- direct = increased Cl- enters the cell, indirect = Ca2+ blocked from entering the cell
- direct = increased Cl- enters the cell, indirect = Na+ blocked from entering the cell
- direct = increased Po enters the cell, indirect = K+ cannot leave the cell
- direct = increased Cl- enters the cell, indirect = Ca2+ blocked from entering the cell
- direct = increased Cl- enters the cell
- indirect = Ca2+ is blocked from entering the cell as K+ leaves the cell instead
Where are the neurotransmitters GABA (inhibitory) and glutamate (excitatory) present in the CNS?
- throughout, especially in the brain
Is the majority of glutamate be synthesised or consumed in the diet?
- mostly consumed in the diet
- little can be synthesised
Glutamate is transported in high concentrations into synaptic vessels before they are released at the pre synapse following an action potential. What is the name of the vesicular glutamate transports?
- microtubules
- post synaptic vesicles
- Vesicular Glutamate Transporter
- dynaine
- Vesicular Glutamate Transporter (VGLUTs)
What does glutamatergic mean?
- receptor in CNS that bind with glutamate
- present throughout the CNS
What are 3 main effects that glutamatergic synapses (glutamate specific receptors) are linked with in the brain?
- cerebral neurotoxicity, memory, addiction
- pain, cerebral neurotoxicity, amnesia
- pain, synaptogenesis, memory
- pain, cerebral neurotoxicity, memory
- pain, cerebral neurotoxicity, memory
* pain is initially good to help protect ourselves, but can then become toxic
Glutamatergic transmission is 99.9% excitatory. What 2 classes of receptors bind with glutamate? (i.e. ligand gates ion, tyrosine kinase receptor etc..)
- ionotropic (NMDA, AMPAr and Kainate)
- metabotropic (ACPD)
Glutamatergic transmission is 99.9% excitatory. Glutamate can bind with both ionotropic (NMDA, AMPAr and Kainate) and metabotropic (ACPD) receptors. Are these receptors fast transmission and which receptors are the main receptors that facilitate this?
- fast excitatory transmission
- AMPA is fastest
- NMDA is slower than AMPA
Glutamatergic transmission is 99.9% excitatory. Both ionotropic (NMDA, AMPAr and Kainate) and metabotropic (ACPD) receptors can bind with glutamate. Which receptors has a small amount of glutamatergic transmission and is mediated by a slower receptor?
- metabotropic (lots of intracellular pathways)
- specifically mGlu (Metabotropic Glutamate Receptor Groups)
NMDA and AMPA are fast glutamatergic transmission receptors. How many subunits does each one have?
- 2 subunits
- 3 subunits
- 4 subunits
- 5 subunits
4 subunits
NMDA and AMPA are fast glutamatergic transmission receptors. That have 4 subunits in each receptor. Which ions are AMPA and NMDA channels permeable to?
- AMPA = Na+ and K+, NMDA = all are Ca2+, Na+ and K+
- AMPA = Na+ and Ca2+, NMDA = all are Ca2+, Na+ and Cl-
- AMPA = Na+ and K+, NMDA = all are Ca2+
- AMPA = Na+, NMDA = all are Ca2+, Na+ and K+
- AMPA = Na+ and K+, NMDA = all are Ca2+, Na+ and K+
* most AMPA are Na+ and K+