Neurotoxicology LECTURE NOTES PDF

Summary

These lecture notes provide an introduction to neurotoxicology, covering the nervous system, neurotransmitter signaling, and various neurotoxic chemicals. The document details the mechanisms of action of some of these compounds, as well as their environmental and health impacts. The document is geared toward understanding neurotoxic processes relating to learning.

Full Transcript

Neurotox
Jessica Legradi
Learning goals

Know what the nervous system is

Understand how neurotransmitter signaling can be disrupted

Know examples and the MoA of
Pyrethroids
Organophosphates
Organochlorates
Neonicotinoids

Introduction to Toxicology 2
 Relevance

A link between human exposure to some chemical substances and neurotoxicity
has been firmly established (Anger, 1986; OTA, 1990).

It has been estimated that alone in Europe, exposure to solely endocrine
disrupters that lead to neurological disorders, costs society €150 billion per year
(Bellanger 2015)

The number of chemicals with neurotoxic potential has been estimated to range
from 3% to 28% of all chemicals (OTA, 1990)
Majority of the materials in
commercial use have not been tested
for neurotoxic potential (NRC, 1984)
 What is neurotoxicity?

Neurotoxicity is toxicity in the nervous system. It occurs when exposure to
natural or artificial toxic substances, which are called neurotoxins, alters the normal
activity of the nervous system in such a way as to cause damage to nervous tissue

wikipedia
What is the nervous system?

Where compounds could be active and
how?
 The nervous system

nerve system = neural system = nervous system

CNS:
a) brain
b) Spinal cord

PNS:
a) Somatic - voluntary movements
b) Autonomic - sympathetic and parasympathetic
c) Enteric - gastrointestinal system
Structural elements Nerve cells
Glial cells
Molecular elements

Neurotransmitter
Enzymes
Calcium, Sodium,..

ATP….
TNF-α, caspases,…
 The Synapse

1. action potential arrives at presynaptic neurone
2. stimulates opening of voltage-gated channels for Ca2+
3. Ca2+ diffuse into cytoplasm of presynaptic membrane
4+5. Ca2+ cause vesicles containing acetylcholine (ACh – a type of neurotransmitter) move towards
the presynaptic membrane
6. Vesicle fuses with the membrane, Ach is released and diffuses across the synaptic cleft
7. Ach temporarily binds to receptor proteins on the postsynaptic membrane; causes chemically-
gated ion channels for Na+ to open
8. Na+ diffuse through postsynaptic membrane àdepolarizes membrane à generates action
potential
Signaltransduction
Blood-Brain-Barrier
Neurogenesis
 What is neurotoxicity?

Neurotoxicity is toxicity in the nervous system. It occurs when exposure to natural
or artificial toxic substances, which are called neurotoxins, alters the normal
activity of the nervous system in such a way as to cause damage to nervous tissue

wikipedia
 Neurotoxic
Neurons can be damaged:
Directly via substances (Neuronopathy)
Indirectly by damaging the axon (Axonopathy)
By damaging the myelin sheet or neuroglia (Myelopathy)
By disturbing the synaptic signaling
Pesticide classes

Introduction to Toxicology 17
Acetylcholinesterase inhibition

Mechanism of Action 18
Principle cholinesterase inhibition

neurotransmission
acetylcholine acetylcholinesterase
(ACh) (AChE)

neuron 1 neuron 2

+
ACh + AChE

+
Inhibitor + AChE

Mechanism of Action 19
Organophosphate esters and carbamatic
esters AChE inbitors

carbofuran
methiocarb

propoxur oxamyl

Mechanism of Action 20
Sarin is a AChE inhibitor

Mechanism of Action 21
Species differences in sensitivity to
organophosphate esters

Mechanism of Action 22
Ion channels

Channels for …. ions
Chloride
Sodium
Calcium
Potassium
Proton
Non selective
Blockage = Antagonist
Activation = Agonist

Introduction to Toxicology 23
Ion channel types

Ligand-gated = Receptor gated
 The Action Potential

http://bcs.whfreeman.com/webpub/Ektron/Hillis%20Principles%20of%20Life2e/Animated%20Tutorials/pol2
e_at_3402_The_Action_Potential/pol2e_at_3402_The_Action_Potential.html
 Organochlorine insecticides

Accumulating in the environment and in biota
Iterative evaporation and condensation: global distillation or grasshopper effect
Low volatility
Chemically stable
Lipophilic
Resistant
All organochlorines are qualified as POPs (Stockhom convention)

Mechanism of Action 26
 DDT
Responsible for decline in bird populations
Eggshell thinning
Endocrine disrupting

Cl Cl
Cl

Cl Cl

Mechanism of Action 27
p,p’-DDE causes eggshell thinning
Interferes with Ca-ATPase
Possible by inhibited synthesis of prostaglandin E2 (PGE2)
Not true ENDOCRINE disruption, but MESSENGER
disruption

Mechanism of Action 28
Neurotoxic mechanism of action DDT

Blocks voltage gated sodium channels in neurons
Sodium channels do not close properly after depolarisation
“After-potential”
Faster new depolarisation
“Repetitive firing”

Mechanism of Action 29
Pyrethroids
“Modern” insecticides (since 1980)
Derived from pyrethrins
Smell like chrysanths
Type I (without CN group) and Type II (with CN group)
Bind to Block voltag gated Na-channels

pyrethrin I pyrethrin II

permethrin cypermethrin deltamethrin

Mechanism of Action 30
 Pyrethroids

Mode of action
Prolonged Na-influx in the cell
Negative after-potential as with DDT
Type I
Hyperexcitable state
Repetitive firing
Type II
Loss of membrane potential
Action potential impossible
Advantage
Very toxic (efficient)
Degradable in sun light
Degradable in water
Disadvantage
Very toxic (side effects)
Fish are very sensitive

Mechanism of Action 31
 Neonicotinoids

Derived from nicotine
Most well-known example imidacloprid
Activation of acetylcholine receptor

nicotinic ACh-receptors are Na, Ca, K channels
Neonicotinoids and bee decline
Volkskrant 30 maart 201

Mechanism of Action 33
Curare = arrow poison

34 Mechanis
m of
Drugs
Drugs
cocaine Amphetamine

Dopamin- Stimulant
Medicine

Potassium Channel Antagonist:
used in the treatment of cardiac arrhythmia
block the potassium channels, thereby prolonging repolarization
Azimilide, Bretylium
Potassium channel opener:
smooth muscle relaxing activity, treat angina
Diazoxide, Nicorandil
Calcium Channel Antagonist:
to reduce systemic vascular resistance and arterial pressure, treat
angina
Alcohol, Verapamil

Introduction to Toxicology 37
Other mechanisms

Introduction to Toxicology 38
 Parkinsonism - MPTP

Dopaminergic neurons get specifically damaged by 1-Methyl-4-phenyl-
1,2,3,6-tetrahaydropyridin (MPTP). Selectivity for dopaminergic neurons is
based on a special transport mechanism: Astrocytes metabolise MPTP to
Methylpyridin(MPP+) which is taken up specifically by dopaminergic
neurons where it accumulates in the mitochondria
 Botulinum toxin
produced by the bacterium Clostridium botulinum
In 1820, Justinus Kerner, a small-town German medical officer studied
the sausage poisoning and discovered botox. He suggested the use for
medical purposes.
Used for cosmetic treatments and a variety of diseases (migraine,
stigmatisms, chronic pain, sweating,…)
Inhibits excretion of Acetylcholinesterase

Mechanism of Action 40
Chronic solvent induced encephalopathy
(CSE)
a condition induced by long-term exposure to organic solvents
often but not always in the workplace
leads to a wide variety of persisting sensorimotor polyneuropathies and
neurobehavioral deficits
even after solvent exposure has been removed

Figure 3. SPM maps of significant correlations (p < 0.001)
between activation and lifetime solvent exposure in
painters. Green indicates decreased activation with
increased exposure levels (observed in anterior cingulate
gyrus, prefrontal cortex, PC, and IC); blue indicates
increased activation with increased exposure levels (no
significant voxels present); and red indicates general group
activation patterns with the N-Back task.

Mechanism of Action 41