Nervous System Introduction PDF

Summary

This document provides an introduction to the nervous system. It includes learning objectives, a summary of functions and components of the nervous system, and details of various neuronal structures and functions. It presents information on neurotransmitters, receptors, synapses, and the blood-brain barrier.

Full Transcript

Used sources; Recommended readings
 Textbook of Medical Physiology
– Arthur C. Guyton ve John E. Hall
 Review of Medical Physiology :
– Kim E. Barrett, Susan M. Barman, Scott Boitano, Heddwen L. Brooks
 Medical Physiology - Principles for Clinical Medicine
 Yazar: Rodney A. Rhoades ve David R. Bell
 İnsan Fizyolojisi
 Fizyoloji Derneği
 Internet
 Introduction
to
Central Nervous System
Central nervous system-Introduction
 Next / Today’s topic’s learning
objectives

 At the end of this lecture you will be able:
– To relate function of brain and neuron
– To decribe parts of neuons,
– To list ion channels involved in generation of action potential
– To decribe types of propagation of action potential
– To describe types of postsynaptic potentials
– To explain neuromuscular junction and transmission

Prof.Dr. Ramazan Bal
 What does nervous system do?
 Nervous system
– Pick up signals from internal and external environment
– Conduct these signals to the CNS
– Integrate these signals
in order to form immediate or delayed responses such as,
– thoughts,
– senses,
– movements,
– balance, and so on
 Functions of the nervous system
 Functions of the nervous system:
– Sensory system
– Motor system
– Limbic system –behaviour - motivation
– Sleep-wakefulnes
– Thinking –thoughts
– Planning
– Learning and memory
– Intellegence
– Consciousness
 Neurons
 There are 100 trillion cells in the body
– Of which, 100 billion are in the brain
 What is the main defining characteristic of neurons?
– have the property of electrical excitability - ability to
produce action potentials or impulses in response to stimuli
 Neurons Cell body (soma)
 Soma: Cell body; metabolic center of neuron;
– İntegrates signals
 Nucleus (contains genetic material) with prominent nucleolus (high synthetic activity)
 Nissl bodies: rough ER & free ribosomes for protein synthesis
– proteins were used to replace neuronal cellular components for growth and repair of
damaged axons in the PNS
 Neurofilaments (neurofibrils): bundles of intermediate filaments & give cell shape &support
 Microtubules move material inside the cell
 Neurons Dendrites (little trees)
 Dendrites receive messages from other neurons;
 Short, tapering and highly branched
 Input portion of the neuron
 Neurons Axon & Dendrites
Axon Carries information away from the cell body; longest part of neuron
 Conduct impulses away from cell body
 impulses arise at the junction of axon hillock &initial segment of axon
 Swollen tips called synaptic end bulbs contain vesicles filled with neurotransmitters
 Axon end in fine processes called axon terminals
– cytoplasm = axoplasm
– plasma membrane = axolemma
– Axon collaterals arise from the axon
 Axonal Transport
 Cell body is location for most protein synthesis (FE: neurotransmitters & repair proteins)
– However the axon or axon terminals require proteins e.g. neurotransmitters
(1). Slow axonal flow
 Axoplasm move in only anterograde direction away from cell body at 1-5 mm/day
 Replenishes axoplasm in regenerating or maturing neurons

retrograde

anterograde
 Axonal Transport
(2). Fast axonal flow Axonal microtubules are used as tracks
 moves organelles & materials along surface of microtubules at 200-400 mm per day
 Transports material in either direction for use in terminals or for recycling in cell body
– Degenerating mitochondria is transported in the retrograde direction for recycing
– New mitochondria move down axon in anterograde direction
 Axonal Transport
(2). Fast axonal flow
 Polypeptides packaged into vesicules are attached to the motor molecules,
– Movement in the anterograde direction is mediated by the molecular motor kinesin
– But the force necessary to move organelles retrograde direction is generated by dynein
 Types of glial cells
A. Microglia
– Act as phagocytes; clear away dead cells
– Protect CNS from disease through phagocytosis of microbes
– Migrate to areas of injury where they clear away debris of injured cells

Prof.Dr. Ramazan Bal
 Types of glial cells
B. Macroglia
 1. Astrocytes: Star shaped with many processes
– Form blood-brain barrier: processes wrap around blood capillaries,
– Regulate nutrient concentrations for neuron survival
– Maintain appropriate pH & [K+] for action potential generation by neurons
– Take up excess neurotransmitters
– Assist in neuronal migration during brain development
– Perform repairs to stabilize tissue – scar formation (?)

Prof.Dr. Ramazan Bal
 Types of glial cells
B. Macroglia
 2. Oligodendroglia: myelinate axons of central nervous system (CNS)
 4. Schwann cells: myelinate axons of peripheral nervous system(PNS)
 5. Ependymal Cells
– Form epithelial membrane lining cerebral cavities that contain CSF
– Produce & circulate CSF found in these chambers
 6. Satellite Cells
– Flat cells surrounding peripheral axonsSupport neurons in the PNS

Prof.Dr. Ramazan Bal
Prof.Dr. Ramazan Bal
 Nerve action potential
 Nerve signals are transmitted by action potentials
 Action potential is rapid changes in resting membrane potential that spread
rapidly along the nerve fiber membrane
– a sudden change from the normal resting membrane potential to a
(+)potential and then back to normal resting membrane potential
 At rest, before action potential begins, conductance for K+ is ~75times more than
that for Na+
 The membrane is polarized

 Nerve action potential
 At the onset of action potentials, Na channels become activated
– Na conductance increases by 5000-fold leading to Na influx.
– membrane potential shift rapidly in positive direction (Depolarization)
 Within milliseconds, Na channels begin to close &K channels open more
– The onset of the action potential also causes openning of K+channels more
slowly
– Then, rapid diffusion of K+ efflux establishes the normal negative resting
membrane potential (repolarization)
Prof.Dr. Ramazan Bal Na
Kanalı

K
Kanalı
Aktivasyon
kapısı

At rest At rest

Hyperpolarization
After hyperpolarizing potential (AHP)

Na+-K+ pump are operate continiously whenever Na+and K+ gradienst are disturbed by leak channels &gated channels
Leak channels are open all the time: It is more permiable to K ion than Na by 75-100 times
 Receptor potantiel - Graded potentials
 When ion channels open with stimuli in receptors
– receptor potantiel is generated
 Receptor potentials are not action potential and therefore they are not all-or-none
– If the receptor potential rises above the threshold
– Action potential occur in the nerve fiber attached to the receptor,

Prof.Dr. Ramazan Bal
 Receptor potantiel - Graded potentials
 As intensity of stimuli increases
– Amplitude of receptor potential increases
 if amplitude of receptor potential increase
– Frequency of action potential increase
 Examples of graded potansiyele:
– Synaptic potentials (EPSP & IPSP)
– Receptor potantials

Prof.Dr. Ramazan Bal
Properties of Graded potentials vs Action potential
1). Graded potentials can be a depolarization or a hyperpolarization
– Action potential is only a depolarization
2). Graded potentials is initiated by environment stimulus (receptor), by
neurotransmitter (synapse), or spontaneously
– Action potential is initiated by a graded potential
Properties of Graded potentials vs Action potential
3). In graded potentials, mechanism depends on ligand-gated channels or
other chemical or physical changes
– In action potential mechanism depends on voltage-gated channels
4). In graded potentials amplitude varies with size of the initiating event
– In action potentials, amplitude of action potential is independent of the
size of the initiating event
– they are all-or-none
Properties of Graded potentials vs Action potential
5). Graded potentials can be summed over time (temporal summation)
&across space (spatial summation)
– Action potentials cannot be summed
– Summation is not possible with action potentials (due to the all-or-none
nature, and the presence of refractory periods)
Properties of Graded potentials vs Action potential
6). Graded potentials has no threshold
– Action potentials has a threshold that is usually 15 mV depolarized
relative to the resting potential
7). Graded potentials has no refractory period
– Action potentials has a refractory period
Properties of Graded potentials vs Action potential
8). In graded potentials amplitude decreases with distance
– Action potentials is conducted without decrement;
– The depolarization is amplified to a constant value at each point along
membrane
9) Graded potentials are not all-or-none
– Action potentials are all-or-none
Synapses
 Learning objectives
 At the end of this lecture you will be able:
– To decribe anatomical structure of a synaps
– To explain types of synaptic potentials
– To describe types of summation of synaptic potentials

Prof.Dr. Ramazan Bal
 CNS Synapses (1) Electrical synapse
Electrical synapses is mediated by gap junctions
Gap junctions are formed from hexameric pores, called connexons (Cx36),
– Connexons is an assembly of six proteins called connexins that form the
pore for a gap junction
– The pore is wide enough to allow ions and even medium-size molecules
– In adult human no electrical synaps between neurons

Prof.Dr. Ramazan Bal
 CNS Synapses (1) Electrical synapse
Gap junctions conduct ions freely (electricity) from one cell to the next
– Gap junctions form channels between adjacent cells.
Synchronize the electrical activity of large populations of neurons;
Synchronization may be required for
– neuronal development
– synthesis and release of hormones by some neurosecretory neurons

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 CNS Synapses (2) Chemical synapse
Almost all the synapses in the mamalian CNS is this type
– Neurotransmitter is responsible for signal transmission at chemical
synapse
 The part of the synapse that belongs to the initiating neuron is called presynaptic membrane.
 The part of the synapse that belongs to the receiving neuron is called postsynaptic membrane.
 The space between the two is called the synaptic cleft (space)

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 Anatomy of the synapse
 Human brain contain, ~1012 nöron (1.000.000.000.000= 1 trilyon);
– There are 1015 synapse in the brainEach neuron has 1000 synapse in avarage
– Synaptic cleft: 200-330 Angstrom
 Axon Terminals make synapse with the dendrites and soma of other
neurons
– ~90% on the dendrites
– 10% on the soma.


Prof.Dr. Ramazan Bal
 Anatomy of the synapse
 There are three types of synapse:
– Axo-dendritic: commonest type of synapse
– Axo-somatic
– Axo-axonic: least frequent


Prof.Dr. Ramazan Bal
 Presynaptic terminals
 Synaptic Gap: Space between end of axon & postsynaptic membrane
 Synaptic cleft have a width of 200-300 Ao.
 The terminal has two internal structures
– Transmitter vesicles contain the transmitter substance
– Mitochondria provide ATP, which is used for synethesizing transmitter

Prof.Dr. Ramazan Bal
 Receptors for neurotransmitter
 Receptors for neurotransmitter are located on the postsynaptic membrane
 But presynaptic neurons may also have receptors for the transmitter that they
release
– They are called autoreceptors and detect the transmitter released by that neuron
– The autoreceptors are metabotropic
– These autoreceptors are often important for regulating the subsequent
amount of transmitter release.
– Best known example is serotonin autoreceptors

Prof.Dr. Ramazan Bal
Transmitter release from the presynaptic terminals
 If an action potential depolarizes
++
the presynaptic membrane, voltage-
++
gated Ca channels open and Ca flow into the axon terminal and [Ca ]i rise
Calcium in the axon terminal has two major effects:
(1) Ca ions binds to calmoduline
 Ca-calmodulin complex activate Ca-calmodulin dependent protein kinase (CaMK)
– CaMK, in turn, phosphorilates synapsin I
– Phosphorilated synapsin I uncages the vesiclesthe vesicles becomes free
Normally synapsin I cages around synaptic vesicles

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 Transmitter release from the presynaptic terminals
(2). Ca++ bind to synaptotagmin found within the membranes of the synaptic vesicles
Synaptotagmin act as a Ca++ sensor
– Binding of Ca++ to synaptotagmin promotes fusion of the vesicle to the
presynaptic plasma membrane, since
SNARE proteins (synaptobrevin, Syntaxin 1 & SNAP-25) pulls the
vesicle closer to the presynaptic plasma membrane
– Transmitter substance is released from
the active zone in the terminal
membrane into the synaptic cleft

Prof.Dr. Ramazan Bal
 The sequence of events that lead to postsynaptic changes
– The action potential signal arrives at the axon terminal
– The local depolarization causes voltage gated Ca2+ channels to open.
– Ca2+ enters the presynaptic cell
– Ca2+ causes vesicles filled with neurotransmitter to migrate towards the
presynaptic membrane &the vesicle merges with the presynaptic membrane
– Neurotransmitter is released into the synaptic cleft by exocytosis.
– Transmitter diffuses through synaptic cleft & binds with receptor in postsynaptic membran
– Synaptic potantial (EPSP or IPSPs) develop

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 Transmitter substance
 Receptor molecules on postsynaptic membrane have:
(1) binding component: protrudes outward from membrane
(2) ionophore component: passes all the way through membrane to interior
– Ionophore can be (1) an ion channel (ionotropic receptors) or
– Ion channels cause transient postsynaptic neuronal changes
– Ionophore can be (2) a second messenger activator (metabotropic receptors):
– Second messenger causes prolonged postsynaptic excitation/inhibition

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 Excitatory or inhibitory receptors
 Some receptors cause excitation of postsynaptic neuron (EPSP);
– Opening of Na channelsNa influxdepolarisation (excitation)
 Others cause inhibition of postsynaptic neuron (IPSP)
– Opening of Cl- channelsCl influxrepolarisation (inhibition)

Membrane potantial (mV)
Repolarization
Resting potantia

Depolarization
Hyperpolarization

Time (msec)

Prof.Dr. Ramazan Bal
Prof.Dr. Ramazan
 Excitatory postsynaptic potential (EPSP)
 Discharge of axon terminals causes release of excitatory neurotransmitter, which
acts on excitatory receptor
– Na+ move to the interior through receptor channels depolarized to -45 mV
– If reach thresholdelicit an action potentials in the initial segment of axon (axon hillox)

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 Excitatory postsynaptic potential (EPSP)
 Axon hilox has seven times voltage-gated Na channels as does soma
– EPSP of more than 15mV will elicit an action potentials
 Once the action potentials begins, it travels along the axon and also backward over the soma
– It may travels backward into the dendrites, but no action potentials is
generated, since there is few Na channels in dendrites

Prof.Dr. Ramazan Bal
 Inhibitory postsynaptic potential (IPSP)
 Discharge of axon terminals causes release of inhibitor neurotransmitter
– inhibitor transmitter acts on inhibitory receptor
 (1) Chloride ion (Cl-) move to the interior through receptor channels
– Shift to more hyperpolarizing potential (-70 mV) than the rest (-65 mV)
– Nernst potential for Cl-: ~-70 mV;
– Major contribution

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 Inhibitory postsynaptic potential (IPSP)
 (2) K+ efflux also make membrane potential more negative
– Nernst potential for K+: ~-70-95 mV;
– This inhibits the neuron
– Less contribution

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 Summation in neurons
Time course of postsynaptic potentials
 EPSP due to fast neurotransmitters dies away in ~15ms.
 Neuropeptide transmitters can excite /inhibit postsynaptic neuron
for msec / sec / min / hours

Neuropeptide: CGRP
 Summation in neurons: Spatial Summation
 A single terminal to cause an EPSP no greater than 0.5-1 mV:
– 10-20 mV required to reach threshold for action potential.
 Summing simultaneous postsynaptic potentials by activating multiple terminals
 Summation in neurons: Temporal Summation
 Increasing strength is by increasing frequency of nerve impulses in each fiber
 Transmitter opens the membrane channels for at most a millisecons.
– But the postsynaptic potential lasts up to 15 ms
 So, a second opening of the same channels can increase the postsynaptic
potential to a still greater level,
 Successive discharges from a single presynaptic terminal, if they occur rapidly
enough, can add to one another

Prof.Dr. Ramazan Bal
 Summation in neurons: Temporal Summation

Sum of 1th & 2nd
synaptic potantial
Membrane potantial (mV)

1th. synaptic potantial

2nd. synaptic potantial

Resting potential

Time (msec)
First Second
stimulus stimulus
 Neuromuscular junction
 Synapse between a motor neuron and a skeletal muscle fiber is called neuromuscular junction
 The skeletal muscle fibers are innervated by large, myelinated nerve fibers
– Each nerve fiber branches and stimulates 3-500 skeletal muscle fibers
– Each nerve ending makes a neuromuscular junction with the muscle fiber

Prof.Dr. Ramazan Bal
 Neuromuscular junction: motor end plate
 Nerve terminals invaginate into the surface of the muscle fiber
 The post-synaptic region at the neuromuscular junction is called the motor end plate
 Space between terminal &fiber membrane is called synaptic space (cleft)
– Folds of muscle membrane (subneural clefts) increase surface area at
which synaptic transmitter can act
– Acethylecholine receptors mainly found in subneural clefts
 Acethylcholine is synthesized in the terminal, but it is absorbed into synaptic vesicles
 In synaptic space, cholinesterase (acethylcholinesterase) destroys acethylcholine

Prof.Dr. Ramazan Bal
 Secretion of acethylcholine by the nerve terminals
 As an action potential spreads, voltage-gated Ca channels open
– Ca++ goes into nerve terminal
 Vesicles fuse with neural membrane & empty acethylcholine into synaptic
space by exocytosis

Prof.Dr. Ramazan Bal
 Acethylcholine on postsynaptic muscle fiber membrane
 Acetylcholine binds to nicotinic acethylcholine receptor on the postsynaptic
membrane
– Nicotinic receptors in the muscle fiber membrane are acetylcholine-gated ion channels
 Acethylcholine channel are permiable to Na+
 Na+ influx creates a local positive potential change (end plate potential)
– If end plate potential is above threshold, self-regenerative action potential
develops
– Action potential that spreads along muscle membranemuscle contraction occur
Normal end plate potantial-
induced action potential

Curare
Botilismus toxin

Prof.Dr. Ramazan Bal
 Destruction of released acethylcholine
 Acethylcholine continues to activate acethylcholine receptors as long as
acethylcholine persists in synaptic space
It is removed rapidly a few milliseconds by two means:
(1) Most of the acethylcholine is destroyed by acetylcholinesterase,
(2) A small amount of acethylcholine diffuses out of the synaptic space
 Botulinum toxin decreases the quantity of acethylcholine release by the
nerve terminals.

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Neurotransmitters (transmitters )
&
Receptors

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 Learning objectives
 At the end of this lecture you will be able:
– To list excitatory and inhibitory neurotransmitters
– To explain their receptors

Prof.Dr. Ramazan Bal
Transmitters substances

Catecholamine: hormones produced by
adrenal medulla:
Dopamine,
Norepinephrine,
Epinephrine
 Glutamate
 Glutamate (Excitatory Amino-Acid, EAA) is responsible for ~75 % of
excitatory synapses in the CNS
 Glutamate from the extracellular fluid is taken up into both glial cells
&nerve terminals by glutamate transporters
 Glutamate transporters contains two subclasses:
– Excitatory amino acid transporters (EAATs)
– Vesicular glutamate transporters (VGLUTs).

Prof.Dr. Ramazan Bal
 Glutamate
A. Ionotropic receptors (form ligand-gated ion channels)
1). NMDA receptors increase permiability to Ca2+, Na+ &K+induce EPSP;
– Important in synaptic plasticity &memory by development of LTP
– At rest, NMDA receptors are blocked by Mg++ (voltage-dependent block).
Mg++ block is relieved by strong depolarization,
which expels Mg2+ from the pore of the NMDA receptor channel
– Glycine is a required co-agonist along with glutamate for NMDA receptors
– In ischemia, too much Ca influx through NMDAglutamate toxicity
– Ketamine is NMDA receptor antagonists

Prof.Dr. Ramazan Bal
 Glutamate
2). AMPA: increases permiability to Na+ &K+’induce EPSP
– AMPA reseptor subunits: GluR1, GluR2, GluR3, GluR4
3). Kainate: increases permiability to Na+ &K+’induce EPSP
B. Metabotropic receptors activating ion channels through G-protein:
– Metabolize IP3 increases [Ca2+]i

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 Acetylcholine
 Acethylcholine is synthesized in the nerve terminal &then it is transported into vesicles:
– Acetyl coenzyme A + choline choline acetyltransferaseacethyl choline
 If acethylcholine is released into synaptic cleft acethylcholine is rapidly split again
to acetate & choline
– acethylcholine  cholinesterase (acethylcholinesterase )  acetate + choline
 Cholinesterase (acetylcholinesterase) is attached to spongy layer of connective
tissue that fills space of synaptic cleft
 A small amount of acethylcholine diffuses out of the synaptic space



Prof.Dr. Ramazan Bal
 Acetylcholine
 Acetylcholine is secreted by the terminals of many neurons :
– motor neurons that innervate the skeletal muscles
– preganglionic neurons of autonomic nervous system
– postganglionic neurons of parasympathetic nervous system
 Acetylcholine has mostly an excitatory effect;
– but it have inhibitory effects at parasympathetic nerve endings

Prof.Dr. Ramazan Bal
 Acetylcholine
Acetylcholine activate two types of receptor:
1). Nicotinic receptors (nAChR) (ionotropic):
 Responsive to nicotine: a Na+ & K+ ion channel
– When acethylcholine is bound to receptor, Na+ enter the cell
 Where they are found? Examples
– Motor neurons that innervate the skeletal muscles
– Preganglionic nerve terminal of autonomic nervous system
– (The first synapse in the chain of autonomic control)

Prof.Dr. Ramazan Bal
 Acetylcholine
2). Muscarinic (mAChR) (metabotropic): responsive to muscarine.
 Activated through G-protein
 Ion channels are distant from their receptors
 Where there are found? Examples
– Some neurons in the basal ganglia, & cerebral cortex
– Postganglionic nerve terminal of parasympathetic nervous system
– (the final synapse for secondary neurons of the parasympathetic nervous
system)

Prof.Dr. Ramazan Bal
 Acetylcholine
2). Muscarinic (mAChR) (metabotropic):
 Muscarinic receptors are either excitatory or inhibitory
– M1, M3, M5 receptors: activate phospholipase C,
– which increases IP3 &DAG
– leading to increase of intracellular [Ca++]i level
– M2, M4 receptors : inhibit adenylate cyclase, which decreases level of cAMP

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 Norepinephrine
 Catecholamines includes adrenaline, noradrenaline and dopamine
 Synthesis of norepinephrine begins in the axoplasm of the terminal nerve endings of
adrenergic nerve fibers but is completed inside the secretory vesicles:
– The enzyme tyrosine hydroxylase in the first step is
rate-limiting enzyme in the synthesis of adrenaline,
noradrenaline and dopamine

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 Norepinephrine
 After secretion of NE by the terminal nerve endings, it is removed in three ways:
– (1) re-uptake into nerve endings by an active transport: ~65% of the secreted NE
– (2) diffusion away into the surrounding body fluidsinto blood: most remaining NE;
– (3) destruction by tissue enzymes
– Monoamine oxidase (MAO) found in the nerve endings,
– Catechol-O-methyl transferase (COMPT), found in diffusely in all tissues

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 Norepinephrine
 Where there are found? Examples
– Locus cerelous in pons neurons control brain activity level &wakefulness
– Postganglionic neurons of sympathetic nervous system


Prof.Dr. Ramazan Bal
 Norepinephrine
Norepinephrine receptors:
 -adrenergic receptors (1, 2)
 - adrenergic receptors (1, 2)
Norepinephrine & epinephrine open ion channels through second messangers:
 1 affects by activation of phospholipase C (PLC), resulting in increasing [Ca++]i
 2 inactivate adenylate cyclase decrease cAMP
 1 &2 reseptors activate adenylate cyclase
–increase cAMP
–activate protein kinase
–phosphorilate proteins
–open ion channels

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 Serotonin (5-HT)
 Serotonin is secreted by nuclei that originate in the median raphe of the brain stem
project to many brain &spinal cord areas, especially to the dorsal horns of spinal
cord and to the hypothalamus.
 Functions: involved in:
– Controling the mood & anxiety & aggression
– Inhibiting pain pathways in the cord,
– Sexual behavior,
– Feeding,
– Sleep wake cycle
– Memory
– Response to stressors
– Cognition
– Locomotion
– Reward and decision making
 Serotonin (5-HT)
 There are 7 family of 5HT receptor, including 5-HT1, 2,3,4,5,6 and 7
 5-HT3 receptors are ionotropic, the rest are metabotropic (G protein coupled
receptor)
 Serotonine released into the synaptic space is cleared by two mechanisms:
 1) 5-HT is metabolised by monoamine oxidase A (MAO-A)
 2) Serotonin transporter (SERT) reuptake the released serotonin
– Selective serotonin reuptake inhibitor (SSRI) are used to treat mental disorders
 3) Vesicular monoamine transporter (VMAT2 ) carry 5-HT into the vesicles
– VMAT2 is target for psychoactive drug (amphetamine, tetrabenazine)
 Dopamine
 Dopamine is secreted by neurons that originate in the substantia nigra.
– The effect of dopamine is usually inhibition.
 Lack of dopamin in these neurons causes Parkinson disease

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 Dopamine Receptors
 D1 & D5 receptors are couple to Gs alphastimulate adenylyl cyclase activity
– D2, D3 and D4 receptors couple to Gi alphainhibit the formation of cAMP
 Ultimate effect of D1-like activation (D1 and D5) can be
– excitation (via opening of Na channels) or
– inhibition (via opening of K channels);
 Ultimate effect of D2-like activation (D2, D3, and D4) is mostly inhibition of
the target neuron

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 Histamin
 Histamine axons originate from a single source, the tuberomamillary nucleus
(TMN) of the posterior hypothalamus,
– They innervate almost all of the CNS regions
 Active solely during waking, they maintain wakefulness and attention.
 The histamine receptors are a class of G protein–coupled receptors:
– H1, H2, H3, H4 receptors

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 Glycine
 Secreted mainly at synapses in the spinal cord.
 act as an inhibitory transmitter
– Glycine is the smallest (20 amino acids)
– Blocked by strychnine
 Glycine is a required co-agonist along with glutamate for NMDA receptors in brain
 Tetanus toxin blocks the release of glycine &GABA

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 Gamma-Aminobutryic Acid (GABA)
 Secreted by nerve terminals in spinal cord, cerebellum, basal ganglia &cortex
– It always cause inhibition
 Synthesized from glutamate using
– L-glutamic acid decarboxylase (GAD) enzyme &
 Pyridoxal phosphate (which is the active form of vitamin B6) as a cofactor
 B6 insufficiency result in deficiency of GABA in the brain,
– which lead to neural excitability and convulsions
 GABA is made primarily by the interneurons of the brain

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 Gamma-Aminobutryic Acid (GABA)
 There are two types of GABA receptors:
GABAA is an ionotropic receptor (ligand gated) selectively conducts Cl−
– Responsible for most of the physiological activities of GABA in CNS
GABAB is metabotropic receptors that are linked via G-proteins to K+ channels

Prof.Dr.
Prof.Dr.Ramazan
RamazanBal
Bal
 Review USMLE questions
 The NMDA receptor is activated by
– a. Glycine
– b. Acetylcholine
– c. Substance P
– d. Histamine
– e. Glutamate

 The answer is e. (Rhoades, pp 45–51.) The NMDA receptor channel is a large channel
permeable to Ca2+, K+, and Na+. It is activated by glutamate, but unlike other glutamate
receptor channels, the NMDA channel is blocked by Mg2+ in its resting state. Depolarization
of the cell membrane to approximately −40 mV removes the Mg2+ blockade. Therefore, the
NMDA channel is only opened when the cell is depolarized by other excitatory
neurotransmitters. The Ca2 entering the cell activates a number of intracellular enzymes,
some of which may be involved in memory.
 Review USMLE questions
 30. Degeneration of dopaminergic neurons has been
implicated in
– (A) schizophrenia
– (B) Parkinson’s disease
– (C) myasthenia gravis
– (D) curare poisoning
 The answer is B [V C 4 b (3)]. Dopaminergic neurons and
D2 receptors are deficient in people with Parkinson’s
disease. Schizophrenia involves increased levels of D2
receptors. Myasthenia gravis and curare poisoning involve
the neuromuscular junction, which uses acetylcholine
(ACh) as a neurotransmitter.
 TUS-12--sinaps
16. Aşağıdakilerden hangisi adrenerjik sinaps iletiminde
rol oynamaz? 2006 NİSAN
A) Noradrenalin
B) Mono-amino-oksidaz
C) Adrenerjik reseptör
D) Katekol-O-Metil-Transferaz
E) Muskarinik reseptör

Translation
 Which of the following does not play role in
adrenergic synapse transmission?
– A) Noradrenalin
– B) Mono-amino-oxidase
E) Muskarinik reseptör
– C) Adrenergic receptor
– D) catechol-O-Metil-Transferase
– E) Muskarinik receptor
 Nervous System neurotransmitter-second messanger
 Question: Which of the following autonomic drugs acts by
stimulating adenylate cyclase?
 (A) Atropine (reversibly inhibiting the mAChR
 (B) Clonidine
 (C) Curare (reversibly inhibiting the nAChR
 (D) Norepinephrine
 (E) Phentolamine
 (F) Phenylephrine
 (G) Propranolol

 (D) Norepinephrine

 Review USMLE questions
 27. Which of the following is an inhibitory neurotransmitter
in the central nervous system (CNS)?
– (A) Norepinephrine
– (B) Glutamate
– (C) γ -Aminobutyric acid (GABA)
– (D) Serotonin
– (E) Histamine
 The answer is C [V C 2 a–b]. γ-Aminobutyric acid (GABA) is
an inhibitory neurotransmitter. Norepinephrine, glutamate,
serotonin, and histamine are excitatory neurotransmitters.
 Nervous System -1
 Question: NMDA-receptor-dependent LTP, which is the mechanism for learning and
memory, is induced if which of the following occurs?
 A. Ca2+ influx during low-frequency synaptic input activates protein phosphatases.
 B. γ-Aminobutyric acid (GABA) is released near an NMDA receptor.
 C. Glutamate release is inhibited.
 D. Strong depolarization expels Mg2+ from the pore of the NMDA receptor channel.
 E. The equilibrium potential for Ca2+ becomes less positive. Answers

 Answers D. NMDA-receptor-dependent LTP is induced when sufficient depolarization is received
postsynaptically, during the release of glutamate from the presynaptic terminal, so that Mg2+ is expelled
from the pore of the NMDA receptor channel and substantial amounts of Ca2+ can then enter through
the pore. The surge of Ca2+ activates various enzymes, including protein kinases, triggering cascades
that result in a strengthening of that synapse. High-frequency stimulation of multiple presynaptic fibers
usually is needed to cause enough depolarization and allow enough Ca2+ to enter to activate the protein
kinases. Low-frequency stimulation allows a much smaller amount of Ca2+ to enter, which can
selectively activate protein phosphatases to produce the opposite effect, reducing the strength of the
synapse (termed long-term depression

 Organization of the Nervous System

(Prosensefalon)

(Rombensefalon)

Prof.Dr. Ramazan Bal
 Enterin NS
Prof.Dr. Ramazan Bal
 Major levels of CNS function Spinal cord level
 A conduit for signals from periphery to brain, or in the opposite direction
 Also neuronal circuits in the cord can cause
– (1) walking movements,
– (2) reflexes that withdraw portions of the body from painful objects,
– (3) reflexes that stiffen the legs to support the body against gravity,
– (4) reflexes that control local blood vessels, GI movements, or urinary excretion.
 Major levels of CNS function Lower brain (subcortical) level
 Medulla, pons, mesencephalon, hypothalamus, thalamus, cerebellum &basal
ganglia
 Many of subconscious activities of the body are controlled in
– Arterial pressure
– Respiration,
– Equilibrium,
– Feeding reflexes,
– Emotional patterns,
Major levels of CNS function Higher brain (cortical) level
 The cortex, for example, motor cortex, functions in association with lower
CNS centers
 Essential for most of thought processes