Download
1 / 40
410 likes | 772 Views
Neurotransmitters. František Duška. Overview. General physiology of synaptic transmission Chemical division of neurotransmitters Amino acid excitatory: Glu, Asp inhibitory: GABA, Gly Monoamines: Catecholamines: NA, D Serotonin, (melatonin) Acetylcholine Peptides
E N D
Neurotransmitters František Duška
Overview • General physiology of synaptic transmission • Chemical division of neurotransmitters • Amino acid • excitatory: Glu, Asp • inhibitory: GABA, Gly • Monoamines: • Catecholamines: NA, D • Serotonin, (melatonin) • Acetylcholine • Peptides • Others: purines, gases, endogenous cannabinoids
1. General physiology of synaptic transmission Definice: neurotransmitter, neuromodulator Synapsis Excitatory and inhibitory postsynaptic potentials
Definitions of terms • neurotransmitter: • a componud secreted into synaptic cleft and bound to postsynaptic receptors • removal from synaptic cleft by spercific biochemical mechanism • neuromodulator: • a compound secreted by neurons into environment and spread by diffusion (or CSF) • modulates behavior of other neurons
Postsynaptic membrane • Resting ponential = - 70 mV • negative IC, positive EC • spontaneous depolarization treshold = -55 mV • Excitatory neurotransmitters EPSP: • open Ca2+, Na+ channels (influx) • depolarize = decrease membrane negativity • Inhibitory neurotransmitters IPSP • open K+ channels (efflux) or Cl- channels (influx) • hyperpolarize = increase negativity
Summatin of postsynaptic potentials • Neurone: integrates inputs (EPSPs, IPSPs) into output: 0 or 1 (action potential or not)
2. Neurotransmitter metabolism synthesis postsynaptic receptor (receptors) mechanism of removal from synaptic cleft clinical and pharmacological significance
Glutamate • Most cammon excitatory neurotransmitter • Synthesis: • from 2-OG (GDH or transaminase) • deamination of glutamine (glutaminase) • postsynaptic receptors: • NMDA (N-methyl-D-aspartát): • AMPA (α-amino-3-hydroxy- 5-methyl-4-isoxazolepropionate) • cainate
Glutamate • Clinical significance: • antagonisté NMDA: ketamin (disociativní anestezie), fencyklidin („angel dust“) • excitotoxicita • synaptická plasticita, role v učení and paměti
Aspartate • Excitatory neurotransmitter, mostly of spinal cord • Synthesis • derived from OAA (citric acid cycle) • Postsynaptic receptor • NMDA – lower affinity than Glu • Removal from synaptic cleft: re-uptake
GABA = γ-aminobutyric acid • inhibitory neurotransmitter of the brain Synthesis: GABA shunt
GABA: postsynaptic receptors • GABAA: chloridový channel • agonisté: benzodiazepiny, barbituráty • antagonisté: flumazenil • GABAB: metabotropní rec.G-prototevření K+ channel • agonista: baclofen
Glycine • Inhibitory neurotransmitter of spinal cord • Synthesis: • from serine • Receptor • chloride channel: IPSP • (co-agonist on NMDA receptors) • Antagonist = strychnine • „seizure poison“
Catecholamines - Degradation • Reuptake followed by IC degradation: • Final metabolite: vanilmandelic acid
Dopamine • Receptors are metabotropic: • D1: Gs proteincAMP ion. channel phosph. EPSP • D2: Gi protein: phosphodiesterase activation IPSP
Dopamine – Clinical significance • Antipsychotics: • phenothiazines = D-receptor blockers • AE = parkinsonism, hyperprolactinemia • Cocaine, amfetamines: • dopamine re-uptake blockers • Parkinson disease: • loss of dopaminergic neurons in s. nigra. Treatment: L-DOPA
Noradrenaline • postsynaptic receptors: • metabotropic: α1, 1 … • ! presynaptic, inhibitory receptors also exist: α2 • Adrenergic systems: • locus coeruleus, lateral tegmentum • arousal, stress, mood
Serotonin • = 5-hydroxytryptamin • Anatomy: limbic systém, retikular formation • Function: • anger/aggression, mood, sleep • appetite/satiety/vomitting • body temperature • sexual behavior
Serotonin • Degradation MAO: 5-hydroxyindolacetate
Melatonine • Pineal gland • Biorythms • Hormone/neuromodulator
Acetylcholine • CNS: pontomesencefalotegmental complex • autonomic NS: preganglionic mediator of both symp. and p-symp., postganglionic mediator of p-symp • peripheral NS: neuromuscular junction • Synthesis: AcCoA + choline: • Degradation: Acetylcholine eserase
Acetylcholine: postsyn. receptors • Nicotinic = inotropic • Na+ channels, neuromuscular junction • Muscarinic = metabotropic • M1 = Gq-prot. = K+ current: CNS (cognit. function), autonomic ganglia • M2= Gi-prot = K+current: CNS, heart • M3= Gq: eye, glands • etc.
Acetylcholine –Clinical significance • Lecithin = phosphatidylcholine as nootropic agent • Acetylcholine esterase inhibitors: • physostigmine (passes through HEB): arousal from general anesthesia • neostigmine (does not pass): p-sympatomimetic, myastenia gravis • M-receptor blockade = atropin • parasympatolytics • N-receptor blockade = curare (arrow poison)
Peptides • Appr. 50 known • Hypothalamus • Synthesis: • prepropeptidER, signal sequence cleavage propeptide in vesicles further processing peptide neurotransmitter (1 or more) • Removal from synaptic cleft: • Degradation, but not re-uptake
Peptides: examples • Opioids: endorfines, enkefalins • limbic system, inhibits l. coeruleus • axo-axonal synapsis • NP-Y • mediates the influence of leptin on food intake • Neurotensine: • regulates LH and prolactin secretion • substance P…
Others • Endocannabinoid system: • retrograde neurotransmission: anandamide • synthesized in the postsynaptic neurone • diffuses to presynaptic neurone • bound to CB1 and CB2 rec. (G-prot.) • influence presynaptic neuron behavior • regulates cognitive function, food intake • THC as illicit drug
Closing remark • Neurotransmitters cannot cross hematoencefalic barrier • Chemically identical compounds have many functions aoutside the brain. • These have not been discussed!! • catecholamines in regulating blood pressure and blood flow • serotonin: immunity • pituitary peptides…. etc…
