PD: Animal Models and Drug Development

Question 1

Describe features of toxin based models of PD?

Answer 1

Toxins are injected into nigrostriatal system/systemically to kill DA neurons

NB: route of delivery depends on if toxin can cross BBB

Question 2

Examples of toxin-based models of PD?

Answer 2

• 6-OHDA
• MPTP
• Lactacystin

Question 3

6-hydroxydopamine (6-OHDA) features and properties?

Answer 3

[oxidative product of dpoamine found in small amounts]

Can’t cross BBB so must be administered as unilateral stereotaxic injection in anaesthetised animals

Dose responsive loss of nigrostriatal DA neurons

This is ideal to model different stages of cell loss (e.g. 60-70%)

Question 4

Outcome of 6-hydroxydopamine (6-OHDA) injection into different regions of animal brain?

Answer 4

Injection into SNpc -> rapid cell loss (3-4 days)

Inject into medial forebrain bundle -> cell loss 7 days

Inject into striatum -> cell loss over 2 weeks

Question 5

Compare features of 6-OHDA and PD?

Answer 5

• mitochondrial inhibition
• selective neuronal loss
• oxidative stress

(BUT no altered proteins)

Question 6

How to assess outcomes using 6-OHDA model?

Answer 6

• behaviour
• immunohistochemistry (neuronal counts and glial activity)
• High Performance Liquid Chromatography (HPLC)]- detect neurotransmitters
• tyrosine hydroxylase immunopositive neurons (general neuron stain -> cell loss)]- compare loss of neurons in lesion vs control

Question 7

Environmental mimics of PD

Answer 7

• Manganese -> Parkinson-like syndrome w/ fixed gaze, bradykinesia, postural difficulties, rigidity, dystonia]- from mining manganese ore
• Carbon disulphide (from rubber processing)
• Cycad seeds (from Guam) -> Parkinson-like syndrome w/ dementia

Question 8

MPTP features and properties?

Answer 8

Lipophilic i.e. penetrates BBB]- can be given systematically

Question 9

Compare features of MPTP and PD

Answer 9

• mitochondrial inhibition
• oxidative stress

(BUT no protein inclusions…but yes if given with probenicid)

Question 10

Which species are susceptible to MPTP?

Answer 10

Humans, primates, mice (C57black)

Mice, rats, cats and dogs are relatively resistant to MPTP

Question 11

MPTP in non-human primates?

Answer 11

3 doses of MPTP produces persisten behavioural syndrome: akinetic, flexed posture, increased limb rigidity, tremor, clumsy movement, freezing episodes

Question 12

MPTP in primate brain?

Answer 12

MPTP rapidly converted to MPP+, which remains for several days

NB: in other species, both MPP+ and MPTP are rapidly removed from the brain

Question 13

Outcome of MPTP administration?

Answer 13

Loss in SNpc but not VTA/NAc

Behavioural changes are reversed w/ L-DOPA + carbidopa (or DA agnoists)

Question 14

What are Proteasome Inhibitor (PSI) Models?

Answer 14

Proteasome degrades altered proteins. Build up of altered proteins intracellularly -> oxidative stress + cell death

Question 15

How to administer PSI?

Answer 15

Peripheral (systemic) administration

2 injections/week over 5 weeks

Question 16

Disadvantages of PSI model for PD?

Answer 16

Not reproducible

Question 17

Lactacystine features and properties?

Answer 17

Proteasome inhibitor

Doesn’t cross BBB

(more stable model than PSI)

Question 18

Lactacystin method of administration?

Answer 18

Stereotactic injection into SNpc/MFB

Question 19

Lactacystin compared to 6-OHDA and MPTP?

Answer 19

Chronic progressive model and spread

(compared to rapid cell loss seen in 6-OHDA and MPTP

Question 20

Compare features of Lactacystin and PD?

Answer 20

• selective neuronal loss
• oxidative stress
• altered proteins

(BUT no mitochondrial inhibition)

Question 21

Outcome of a-syn in drosophiliae?

Answer 21

• Selective DA neuronal death
• Lewy body-like structures
• movement disorder (change in climbing behaviour)

Question 22

Outcome of increased wild-type a-syn in transgenic mice?

Answer 22

• neuronal inclusions (hLB sunflower structure, rLB is disorganised)
• no neuronal loss

Question 23

Outcome of expressing A30P/A53T double mutant

Answer 23

• age dependent decrease in SNpc TH cell number
• decreased motor function
• no inclusions

Question 24

Disadvantages of using transgenic mice w/ a-syn to model PD?

Answer 24

• need to wait 18 months for pathology
• transgenic mice expensive
• mice require 2-3 mutations of a-syn, but no human has >1 a-syn mutation

Question 25

Outcome of rAAV a-syn overexpression (viral vector delivers wild-type or mutated a-syn)?

Answer 25

• deficits in motor behaviour

- decreased DA striatal terminalis and cell bodies

Question 26

Disadvantages of using rAAV a-syn overexpression?

Answer 26

Have to wait 6 months for pathology]- it is a progressive model

Question 27

Mechanism of injecting pre-formed a-syn fibrils?

Answer 27

Braak hypothesis: injecting protofibrils in SNpc mirrors spread of altered proteins in similar pattern to PD

Taken up by striatal neurons -> Lewy bodies

• fibrils cause native a-syn to misfold
• inclusions spread across brain over time

Question 28

Outcome of injecting pre-formed a-syn fibrils?

Answer 28

Small amount of nigrostriatal DA cell loss (30%) which doesn’t translate to behavioural deficits

Question 29

Outcome of using LRRK2 Transgenic mice?

Answer 29

Cell death in neuroblastoma cells and mouse cortical neurons

Question 30

Compare LRRK2 model and PD

Answer 30

• movement dysfynction
• abnormal proteins

(BUT no neuronal loss in SNpc)

NB: you can add MPTP to induce stress or neurodegeneration

Question 31

Function of mtDNA?

Answer 31

Encodes 13 key subunits of respiratory chain. It is critical for mitochondrial biogenesis

Question 32

Relationship between mtDNA and age?

Answer 32

mtDNA mutations increase with age

Question 33

What regulates mtDNA transcription?

Answer 33

Mitochondrial transcription factor A (Tfam)

Question 34

Outcome of Tfam KO mice (MitoPark Mouse)

Answer 34

Reduced mtDNA expression and mitochondrial respiratory chain deficiency in DA neurons

Question 35

List some ways of assessing behaviour in PD models

Answer 35

• Forepaw reaching behaviour
• Amphetamine-induced rotational assessment
• Walking on a beam (no. of falls)

Question 36

Outcome of unilateral lesion in:

forepaw reaching behaviour

amphetamine-induced rotational assessment

Answer 36

forepaw reaching: assymetry in paw use

amphetamine-induced rotation: [unilateral DA release (inhibition on intact side)] -> turn towards
|
assymetry causes animals to walk in circles (no. of turns corresponds to lesion size)

Question 37

Evaluation of PD models?

Answer 37

• Rodents don’t have stresses of human cells synapses (require E) per DA neuron is greater in humans
• PD has mixed motor and non-motor symptoms]- cannot mirror all of these

Question 38

Drug development from models example in PD?

Answer 38

Deferiprone (iron chelator) for PD

PD has increased iron in SNpc (iron redox -> ROS)

Animal model (ferrocene deposits iron globally, not just in SNpc): shows iron chelators to be neuroprotective

Question 39

Ways of assessing animal models with PD?

Answer 39

• behavioural tests
• tyrosine hydroxylase immunopositive neurons (general neuronal stain to look for cell loss)
• high pressure fluid chromatography (detect NTs)