1 / 37

Biochemistry of the Nervous System

Biochemistry of the Nervous System Transport through BBB Metabolism of Neurotransmitters Metabolism of CNS Biochemical Aspects of CNS diseases CSF chemical analysis . Biochemistry of the Nervous System. Transport of substances through the blood-brain barrier (BBB)

uta
Télécharger la présentation

Biochemistry of the Nervous System

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Biochemistry of the Nervous SystemTransport through BBBMetabolism of NeurotransmittersMetabolism of CNS Biochemical Aspects of CNS diseasesCSF chemical analysis

  2. Biochemistry of the Nervous System • Transport of substances through the blood-brain barrier (BBB) • Metabolism of neurotransmitters • Synthesis (precursors – role of vitamins) • Release • Effect • Termination • Metabolism of CNS : • Energy Metabolism of CNS • Lipid Metabolism in CNS • Myelin sheath • Biochemical aspects of CNS diseases • Hypoglycemia • Cerebral ischemia • CSF chemical analysis

  3. Transport through Blood-Brain Barrier (BBB) Large number of compounds are transported through endothelial capillaries by facilitated diffusion 1- Fuels Glucose: The principal fuel of the brain Transported through endothelial membranes by facilitated diffusion via GLUT-1 At blood glucose of 60 m/dl, glucose is reduced to below Km of GLUT-1 leading to appearance of symptoms of hypoglycemia 2- Others: as ketone bodies by another transport system When blood levels of KB are elevated (during starvation) KBs are important fuels for brain during prolonged starvation Non-essential fatty acids (of diet or lipolysis) do not cross BBB Essential fatty acids (linoleic & linolenic) can pass BBB

  4. Transport through Blood-Brain Barrier (BBB) 2- Amino acids Amino acids are transported by amino acid transporters Amino acids are used in brain for synthesis of: - Proteins of CNS - Neurotransmitters (requires certain vitamins as B12, B6 & B1 …) Types of transported amino acids: 1- Long neutral amino acids (by single amino acid transporters) Essential: Phenylalanine , Leucine, Isoleucine, Valine, Tryptophan, Methionine Non-essential: Tyrosine Semi-essential: Histidine 2- Small neutral amino acids (entry is markedly restricted as their influx markedly change content of neurotransmitters) Nonessential: Alanine, Glycine, Proline 3- Vitamins: transported by special transporters

  5. Metabolism of Neurotransmitters • Neurotransmitters • Are chemicals released at synapses for transmission of nerve impulses • Generally, each neuron synthesizes only those neurotransmitters that it uses for transmission through synapses So, the neuronal tracts are often identified by their neurotransmitters • Structurally divided into two categories: • - Small nitrogen-containing neurotransmitters • - Neuropeptides: Targeted in CNS as endorphins OR Released to circulation as GH & TSH • Major small nitrogen containing neurotransmitters: • Glutamate • GABA • Glycine • Acetylcholine • Dopamine • Norepinephrine • Serotonin • Histamine • In addition to: epinephrine, aspartate, nitric oxide

  6. Metabolism of Neurotransmitters General features of neurotransmitters synthesis, release & termination 1- Most are synthesizedin presynaptic terminal from : Amino acids Intermediates of glycolysis Intermediates of TCA 2- Once synthesized, they are storedin vesicles (by active uptake) 3- Releasedin response to nerve impulse: 1- Nerve impulse causes Ca2+ influx (through Ca2+ channels) to presynaptic terminal 2- Exocytosis of neurotransmitters into synaptic cleft 3- Neurotransmitter binds to receptors on postsynaptic membrane-----EFFECT 4- Termination: by: Reuptakeof the neurotransmitter into presynaptic terminal (or by glial cells) Or/ Enzymaticinactivation(in presynaptic terminal, postsynaptic terminal or in astrocyte)

  7. Metabolism of Neurotransmitters

  8. Neurotransmitters: Catecholamines & Serotonin Phenylalanine Tyrosine Tyrosine Hydroxylase Cu-dependent BH4 DOPA Melanin DOPA Decarboxylase melanocytes PLP Dopamine Dopamine Hydroxylase Cu2+ Monoamine Oxidases Vit . C MAO-A Norepinephrine VMA in Adrenal Medulla Methyl transferase (& few neurons) using SAM Vit. B12 Epinephrine Folate Tryptophan Tryptophan Hydroxylase BH4 MAO-A 5 HIAA Serotonin Melatonin In URINE

  9. Neurotransmitter: Histamine • Histamine is an excitatoryneurotransmitter in CNS • Synthesized in CNS from the amino acid histidine by histidine decarboxylase (requires PLP) • Antihistaminic drugs (for treatment of allergy) cause drowsinessBUT new generations of antihistaminics do not pass BBB & so do not cause CNS effects

  10. Neurotransmitter: Acetylcholine Synthesis in CNS (in presynapses) Choline Acetyltransferase enzyme Acetyl CoA + Choline Acetyl Choline Choline: 1- From diet 2- From phosphatidylcholine (PC) in membrane lipids PC is synthesized from PE utilizing methyl groups of S-adenosyl methionine (SAM) Requires vitamins B12 & B6 Acetyl group From glucose oxidation (requires oxygen) is the major source (little FA oxidation in CNS) Thiamine (vit. B1) Glucose Pyruvate AcetylCoA ATP Pyruvate Decarboxylase N.B. In thiamine deficiency & hypoxia: no ATP & no acetylcholine neurotransmitter

  11. Neurotransmitter: Glutamate & GABA • Glutamateis the main excitatoryneurotransmitterin the CNS • Neurons that respond to glutamate are referred to as glutaminergic neurons Sources of glutamate in nerve terminals: 1- Synthesized from glucose through glucose metabolism in neurons (main source) Glucose --- aKetoglutarate (a KG) ------ glutamate (Requires PLP) 2- From glutamine (of glial cells) by glutaminase 2- From blood (few as no cross BBB) Mechanism of action of glutamate as a neurotransmitter: 1- Synthesis from glucose metabolism & concentration in vesicles (in presynapses) 2- Release by exocytosis to synaptic cleft 3- Uptake by postsynaptic 4- Binding to glutaminergic receptors in postsynapses 5- Functional effect 6- Termination: glutamate reuptake by astrocytes (glial cells) .. REQUIRES ATP(ENERGY) In astrocytes, glutamate is converted to glutamine (REQUIRES ATP) Glutamine is released from astrocytes & is taken up by neurons In neurons, glutamine is converted to glutamate by glutaminase

  12. Neurotransmitter: Glutamate & GABA GABAIs an inhibitoryneurotransmitters in CNS In presynaptic neurons, GABA is synthesized from glutamate by glutamate decarboxylase (GAD) by a reaction that requires PLP Then, GABA is released to synaptic cleft. It is recognized by receptors on postsynaptic neurons. Termination: GABA in synaptic cleft is uptakenby glial cells (as astrocytes) & converted to glutamate Glutamate is converted to glutamineby glutamine synthetase (requires ATP) Fate of glutamine of astrocytes: 1- A fraction of glutamine is released from astrocytes & is taken up by neurons. In neurons, glutamine is deaminated to glutamate by glutaminase 2- Another fraction of glutamine is released to blood------to kidney --- ammonia Tiagabine is used as an antiepileptic (anticonvulsant) as it inhibits the reuptake of GABA `

  13. Neurotransmitter: Glutamate & GABA Glutamate metabolism in hyperammonemia: • During hyperammonemia, ammonia can diffuse into the brain from the bloodto neurons. • The ammonia is able to inhibit the glutaminase in neurons, thereby decreasing formation of glutamate in presynaptic neurons (not regenerated) This effect of ammonia might contribute to the lethargyassociated with the hyperammonemia found in patients with hepatic disease. (hepatic encephalopathy)

  14. Neurotransmitter: Glutamate & GABA Relation between glutamate synthesis & citric acid cycle: • In neurons, synthesis of glutamate removes aketoglutarate from the citric acid cycle ending in a decrease in regeneration of oxalacetate • Regeneration of oxalacetate is necessary for oxidation of acetyl CoA & this is performed by two major anaplerotic pathways: 1- Degradation of isoleucine & valine amino acids to butyric succinyl CoA, which yields oxalacetate. This reaction requires vitamin B12 (coenzyme for methylmalonyl CoA mutase) 2- Pyruvate carboxylation to oxalacetate (by pyruvate carboxylase, requires the vitamin biotin as a coenzyme).

  15. Metabolism of CNSGlucose & Energy Metabolism Energy source of the brain • The mass of the brain is only 2% of the total body mass, yet its energy requirement is more than seven times than that of the other organs • Thus for brain metabolism, there is a high requirement for glucoseand oxygen at steady rate. • The main source of energy is the generation of ATP by the aerobic metabolism of glucose Aerobic Glycolysis In Cytosol Mitochondria & Oxygen Glucose ---- Pyruvate ----- Acetyl CoA ---- With oxalacetate in CAC ------- ATP

  16. Metabolism of CNSGlucose & Energy Metabolism Glucose metabolism & neurotransmitters (in CNS) There is a relationship between the oxidation of glucose in glycolysis and the supply of precursors for the synthesis of neurotransmitters in neurons within CNS. Accordingly, deficiencies of either glucose or oxygen (hypoglycemia or hypoxia) affect brain function because they influence: 1- ATP production for CNS neurons 2- Supply of precursors for neurotransmitter synthesis. Glucose Metabolism & Neurotransmitter Synthesis

  17. Metabolism of CNSBrain Lipids Synthesis & Oxidation Sources of lipids to CNS: • BBB significantly inhibits entry of certain fatty acids & lipids into CNS. So, all lipids found in CNS must be synthesized within CNS (e.g. non-essential fatty acids, cholesterol, sphingolipids, glycosphingolipids & cerebrosides) All these are needed for neurological functions & synthesis of myelin by glial cells (non- neuronal cells) • EXCEPTION is: Essential fatty acids (linoleic & linolenic FAs) can enter the brain Within CNS, these two FAs are elongated & desaturated to yield the very-long chain fatty acids required for synthesis of myelin sheath. Fatty acid oxidation as a source of energy: • Intake of fatty acids (coming from diet and/or lipolysis of TG ) to CNS is insufficientto meet the energy demands of CNS (by FA oxidation) & hence the requirement for aerobic glucose metabolism • Recall that ketone bodies are sources of energy to brain during prolonged starvation as they can pass BBB easily….

  18. Metabolism of CNSBrain Lipids Synthesis & Oxidation • Peroxisomal fatty acid oxidation is important in the brain as the brain contains very-long-chain fatty acids & branched-chain fatty acids as phytanic acid (of diet) Both are oxidized by a oxidation in the peroxisomes • Refsumes disease: a disorder that affects the peroxisomes – severely affects the brain due to inability to metabolize both very long chain & branched chain fatty acids

  19. Myelin Synthesis Rapid rate of nerve conduction in PNS & CNS depends on the formation of myelin. Myelin is a multilayered lipid (sphingolipids) & protein structure that is formed by the plasma membrane of glial cells to wrap around the axon. In PNS, myelin is synthesized by Schwan cells In CNS, myelin is synthesized by oligodendrocytes Multiple sclerosis (MS) Progressive demyelination of CNS neurons May be due to an event that triggers the formation of autoimmune antibodies directed against components of the nervous system (as viral or bacterial infection) Loss of myelin (insulator) in the white matter of the brain that interferes with nerve conduction along demyelinated area CNS compensates by stimulating the oligodendrocytes to remyelinate the damaged axon(& hence remission is activated) Remyelination is accompanied by slowing in conduction (speed is proportional to myelin thickness)

  20. Clinical Manifestation Hypoglycemic Encephalopathy Clinical manifestations of hypoglycemia: Earlyclinical signs in hypoglycemia initiated by hypothalamic sensory nuclei as sweating, palpitations, anxiety and hunger. Inlatestages, these symptoms give way to serious manifestations of CNS disorders as confusion, lethargy, seizures & coma

  21. Biochemistry of Hypoglycemic Encephalopathy • As blood glucose falls below 45 mg/dL the brain attempts to use internal substrates such as glutamate and TCA cycle intermediates as fuels for ATP production. Because the pool size of these substrates is quite small, they are quickly depleted. • As the blood glucose drops from 45 to 36 mg/dL NO EEG changes are observed Symptoms appear to arise from decreased synthesis of neurotransmitters in particular regions of the brain (hippocampal & cortical structures) • If blood glucose levels continue to fall below 18 mg/dL EEG becomes isoelectric Neuronal cell death ensues that may be caused by glutamate excitotoxicity ?? (as result of ATP depletion) SO, GLUTAMATE METABOLIDSM HAS TO BE UNDERSTOOD

  22. Glutamate as a neurotransmitter Role of glutamate as a transmitter in CNS: Within the CNS, glutaminergic neurons are responsible for the mediation of many vital processes such as the encoding of information, the formation and retrieval of memories, spatial recognition and the maintenance of consciousness. Postsynaptic glutaminergic neurons perform their roles through: 1- Ionotropic receptors that bind glutamate released from presynaptic neurons referred to as kainate, 2-amino-3-hydroxy-5-methyl-4-isoxalone propionic acid (AMPA) and N-methyl-D-aspartate (NMDA) receptors. 2- Metabotropic glutamate receptorsthat are members of the G-protein coupled receptor (GPCR) family.

  23. IonotropicGlutamate Receptors Non- NMDA NMDA NMDA receptors allows the passage of both Na+andCa++ions. (More permeable to Ca++) AMPA KAINATE AMPA and Kainate receptors generally allow the passage of Na+and K+

  24. Glutamate Excitotoxicity Exciotoxicity is the pathological process by which nerve cells are damaged and killed by glutamate (and similar substances). This occurs when receptors for glutamate such as the NMDA & AMPA receptor are over activated (overstimulated). Excessive excitation of glutamate receptors has been associated with hypoglycemia & stroke (cases in which there is lack of glucose and/or oxygen ending in lack of energy production in CNS)

  25. Glutamate Excitotoxicity occurs when the cellular energy reserves are depleted (as in hypoglycemia or stroke, etc ) Failure of the energy-dependent reuptake pumps of glutamate Accumulation of glutamate in the synaptic cleft Overstimulation of the postsynaptic glutamate receptors Prolonged glutamate receptor activation leads to prolonged opening of the receptor ion channel and the influx of lethal amounts of Ca2 ions, which can activate cytotoxic intracellular pathways in the postsynaptic neurons

  26. Biochemistry of Cerebral Ischemia Cerebral ischemia • It is the potentially reversible altered state of brain physiology and biochemistry that occurs when substrate delivery is cut off or substantially reduced by vascular stenosis or occlusion Stroke • is defined as “an acute neurologic dysfunctionof vascular origin with sudden (within seconds) or at least rapid (within hours) occurence of symptoms and signs corresponding to the involvement of focal areas in the brain” (Goldsteinet al, 1989)

  27. ↓↓ ATP Induction Amplification Expression Pathophysiology of Cerebral Ischemia

  28. Lack of oxygen supply to ischemic neurones The cell switches to anaerobic metabolism, producing lactic acid. ATP depletion malfunctioning of membrane ion system Induction Phase Depolarisationof neurones Influx of calcium Release of neurotransmittersasglutamate (causing glutamate excitotoxicity) Amplification Phase Accumulation of more intracellular levels of Ca2+ which causes additional release of glutamate (viscious cycle)

  29. Expression Phase Ca2+ 1-overexcites cells and causes the generation of harmful chemicals like free radicals ( causing oxidative stress) 2- Activation of calcium-dependent enzymes such as: calpain( causing apoptosis) phospholipases (causing membrane breakdown) 3- Calcium can also cause the release of more glutamate (glutamate excitotoxicity) The cell's membrane is broken down by phospholipases Cell membrane becomes more permeable, and more ions and harmful chemicals flow into the cell. + Mitochondria membrane break down, releasing toxins and apoptotic factors into the cell

  30. lactic acid is produced in excess in ischemia In cerebral ischemia, lack of oxygen switches metabolism of glucose to the anaerobic pathway & lactic acid production Lactic acid contribute to the pathophysiology of ischemia as: 1- It decreases pH that may injure and inactivate mitochondria. 2- Lactic acid degradation of NADH(which is needed for ATP synthesis) may also interfere with adequate post-ischemic recovery of ATP levels. 3- Lactic acid increase the amount of free-radical mediated injury. Lactic acid in neurons  acidosis  promotes the pro-oxidant effect  ↑ the rate of conversion of O2- to H2O2 or to hydroxyperoxyl radical

  31. Oxidative stress is caused by ischemia What is meant by ROS? Reactive oxygen species (ROS) are formed from partial reduction of molecular O2 i.e. adding electrons to oxygen leading to the formation of superoxide, hydrogen peroxide & hydroxyl radical. Generally, ROS cause damage to DNA, protein and unsaturated lipids of the cells. What is meant by oxidative stress A condition in which cells are subjected to excessive levels of ROS (free radicals) & they are unable to counterbalance their deleterious effects with antioxidants

  32. Oxidative stress is caused by ischemia Cellular Effects of Reactive Oxygen Species (ROS) in CNS • Nitric oxide isover produced and turns to be a neurotoxic mediatoras itreacts with superoxide anions to generate toxic peroxynitritewhich leads to production of more potent neurotoxin such ashydroxyl radicals • Lipid peroxidation • Inactivation of enzymes • Nucleic acid (DNA & RNA) damage • Release of calcium ions from intracellular stores with more damage to neurons • Damage to cytoskeleton

  33. Apoptosis & necrosis are caused by ischemia • Necrosis: is commonly observed early after severe ischemic insults • Apoptosis: occurs with more mild insults and with longer survival periods • The mechanism of cell death involves calcium-induced calpain-mediated proteolysis of brain tissue • Substratesfor calpain include: • Cytoskeletal proteins • Membrane proteins • Regulatory and signaling proteins

  34. Apoptosis Mitochondria break down, releasing toxins and apoptotic factors into the cell. The caspase-dependent apoptosis cascade is initiated, causing cells to "commit suicide." Broughton et al., 2009; Stroke

  35. Caplains are cytosolic proteinases Whose irreversible proteolytic activity is against cytoskeleton and regulatory proteins Broughton et al., 2009; Stroke

  36. Broughton et al., 2009; Stroke

More Related