Week 8 part 2

Question 1

What are major neurodegenerative disease?

Answer 1

1. Alzheimers
2. Parkinson
3. Triplet repeat disease (Huntington and spino-cerebellar ataxias)
4. Spinal muscular atrophy
5. ALS/FTD (frontotemporal dementia)

Question 2

What does major neurodegenerative disorders affect?

Answer 2

More than 25 million people worldwide

Question 3

What does major neurodegenerative disorders bring?

Answer 3

Disproprionate amount of suffering and economic loss

Question 4

Prion disease

Answer 4

Location: diffuse cortical
Macro: cerebral atrophy
Micro: Spongiosis, PrP deposits

Question 5

AD

Answer 5

Location: temporoparietal
Macro: cerebral atrophy
Micro: AB plaques, tangles

Question 6

PD

Answer 6

Location: midbrain
Macro: pallor of substantia nigra
Micro: Lewy bodies

Question 7

ALS

Answer 7

Location: motor cortex, brain stem and spinal cord
Macro: atrophy of motor neurons and muscles
Micro: Inclusions (Bunina bodies, Lewy body-like)

Question 8

HD

Answer 8

Location: Basal Ganglia
Macro: Neostratial atrophy
Micro: neuronal loss and astrocytosis

Question 9

LBD

Answer 9

Location: frontrotemporal
Macro: cerebral atrophy
Micro: Lewy bodies

Question 10

FTD

Answer 10

Location: Frontotemporal
Macro: cerebral atrophy
Micro: tau deposits, Pick bodies

Question 11

What are some features of Neurodegenerative diseases?

Answer 11

1. Most strike at mid-life or later
2. Aging may contribute to susceptibility
3. The first symptoms usually involve loss of fine motor movement control
4. Duration can be 10-20 years with progressive deterioration and quite a helpless, terrible death

Question 12

What are the two caterogies of Neurodegenerative diseases?

Answer 12

1. Sporadic (unknown ateiology, most of Alzheimers and Parkinson)
2. Inherited (Huntington

Question 13

What are most neurodegenerative disorders characterised by?

Answer 13

Presence of insoluble protein aggregates

Question 14

What is one of the causes of neurodegenerative disease?

Answer 14

1. protein misfolding

2. The inability of the body/cells to properly fold and/or dispose of misfolded protein accumulations

Question 15

What happens in Parkinson’s patients?

Answer 15

Alpha-synuclein form clumps known as Lewy bodies

Question 16

What happens in Alzheimer’s disease

Answer 16

sees tau tangles form inside brain cells and amyloid plaques accumulate near them

Question 17

What happens in Huntington’s?

Answer 17

the nucleus becomes gummed up with clusters formed by an abnormal version of the huntingtin protein

Question 18

What happens in ALS?

Answer 18

The proteins superoxide dismutase (SOD) and TDP43 or FUS accumulate in the body and projections of nerve cells

Question 19

What are animal models to study neurodegenerative diseases?

Answer 19

1. Transgenic mouse models
2. Drosophila
3. C. Elegans

Question 20

What do lots of transgenic animals mimick?

Answer 20

A lot of human mutations

study some mechanisms

Question 21

C. Elegan worm

Answer 21

1. Short half life span
2. Quick generation time
3. Study the effects quicker
4. Ask questions about aging better than mouse

Question 22

What are the most common pathologies in the family of MND (motor neuron diseases)?

Answer 22

1. SMA (spinal muscle atrophy)

2. ALS

Question 23

What are SMA and ALS characterised by?

Answer 23

Progressive degeneration of motor neurons in the anterior horns of the spinal cord

Question 24

What are the incidence of SMA and ALS?

Answer 24

1. SMA - 1/6000-10000 newborns

2. ALS - 1-2 people/10,000 (Age of onset ca 50 years)

Question 25

What varies between SMA and ALS?

Answer 25

1. Disease onset
2. Genetic causes
3. Affected neurons

Question 26

What is the most common genetic cause of infant mortality?

Answer 26

Proximal SMA

Question 27

What is SMA caused by?

Answer 27

95% of the patients

deletions of SMN1 gene

the remaining 5% carry small mutation in this gene

Question 28

What are the differences between SMN1 and SMN2?

Answer 28

When SMN1 is made it encodes a functional SMN and degrades very quickly

The way the genes are spliced

what they encode as a result of this alternative splicing

Question 29

What happens if SMN1 is mutated or lost?

Answer 29

SMN2 cannot compensate for it because its not functional/processed in the right way

Question 30

What does functional SMN1 when it is spliced together incorporate?

Answer 30

Exon 7 that gives the function of the protein

Question 31

SMN2

Answer 31

It is spliced out generating a fusion between exon 6 + 8

This gene is non-functional

Question 32

Why doesnt SMN1 never sit independently?

Answer 32

The muscle tone never develops

Question 33

What does SMN1 die from?

Answer 33

Respiratory defect

The motor innervation doesn work so they cant breathe

Question 34

SMA1 Werdnig-Hoffman disease

Answer 34

Age of onset: Antenatal-before 6 months

Maximum motor milestones: Never sits independently

Other features: Flkoppy child, no control of head movements, normal facial expression, swallowing difficulty, paradoxal breathing, Fasciculation of tongue

Life expectancy: median survival of < 6 months
Death from respiratory insufficiency

Question 35

SMA2 intermediate type

Answer 35

Age of onset: 7-18 minths

Maximum motor milestones: sits independently, never walks independently

Other featurs: Scoliosis, joint contractutes, Postural tremors of hands, Fasciculation of tongue and/or limb muscles

Life expectancy: most patients die < age 30-40 from respiraotry insufficiency, some survive longer

Question 36

SMA3 Kugelberg Welander disease

Answer 36

Age of onset: 18 month- 30 year

Maximum motor milestones: Walks independently , some patients become wheelchair dependent in childhood

Other featureS: Joint contractures, postural tremors of the hands
Fasciculation of limb muscles
some patients require NIV

Life expectancy: normal

Question 37

SMA4 Adult-onsent (very rare)

Answer 37

Age of onset: 30 year

Maximum motor milestones: Normal

Other features: patient can become wheelchair dependent
some patients require NIV

Life expectancy: normal

Question 38

What does SMN protein do?

Answer 38

1. Has a crucial role in regulating pre-MRNA splicing

2.Catalyses the assembly of Sm proteins on to the snRNPs
(small nuclear ribonuclearproteins) which form the functional
core of the splicing machinery.

Question 39

What is SMN required for?

Answer 39

Cell survival

Question 40

How is complex of SMN assembled?

Answer 40

arginine methylation dependent manner

Question 41

JBP1

Answer 41

Arginine methylase

methylates 3 of these proteins

Question 42

What does SMN complex help assemble

Answer 42

the cellular machinery needed to process pre-mRNA

Question 43

What is SMN complex important for?

Answer 43

development of specialized outgrowths from nerve cells called dendrites and axons

Question 44

What are dendrities and axons required for?

Answer 44

the transmission of impulses between neurons and from neurons to muscles.

Question 45

What has damaging effects on motor neuron development and survival

Answer 45

A lack of mature mRNA, and subsequently the proteins needed for normal cell functioning

Question 46

Spinal muscular atrophy type III (also called Kugelberg-Welander disease)

Answer 46

causes muscle weakness after early childhood. Individuals with this condition can stand and walk unaided, but over time, walking and climbing stairs may become increasingly difficult. Many affected individuals require wheelchair assistance later in life. People with spinal muscular atrophy type III typically have a normal life expectancy.

Question 47

Why is alternative splicing affected?S

Answer 47

So many RNA binding proteins are affected

Question 48

What happens in mammals?

Answer 48

95% of genes are spliced increasing the proteome

Question 49

What is alternative splicing mediated by?

Answer 49

interaction of basal splicing machinery with proteins that either stimulate or inhibit the assembly of the processing complex on alternative exons

Question 50

What are the 3 classes of factors that plays a major role in splice-site selection?

Answer 50

1.SR proteins normally activate nearby splice sites, the bound
region is included as an exon during splicing

2.hnRNPs – usually silence nearby splice sites – the bound region becomes an intron

3.U1 and U2 snRNPs recognise potential splice donors and
interact with possible splice acceptors

Question 51

What determines the choice of splice site?

Answer 51

• Competition between positive (SR and U1/U2snRNPs) and negative
(hnRNPs) regulators of splicing

Question 52

What does SMN protein do?

Answer 52

Involved in the assembly and/or function of additional
RNPs
Transport of mRNA in neurites – especially long ones
Proteins other than Sm ones interact with SMN in mRNPs
which are transported to distant location of neurons for
local protein translation of bound mRNA

Question 53

What does SMN1 produce?

Answer 53

full-length functional SMN protein

Question 54

What does SMN2 produce?

Answer 54

shorter non-functional form of SMN protein

Question 55

What happens in SMA patients?

Answer 55

SMN1 is either missing or mutated, leading to a large decrease in the available SMN protein

Question 56

What binds to SMN2 mRNA and encourages the inclusion of important regions needed to make SMN protein?

Answer 56

Anti-sense oligonucleotide ASO-10-27

Question 57

hat is the function of anti-sense oligonucleotides?

Answer 57

Prevents the exons from being spliced in

Injected in patients at high doses

Question 58

What is ALS?

Answer 58

1. kills more than a 100000 people annually
2. Characterised by degeneration of upper and lower motor neurons in the brain and spinal cord
3. Rapidly progressing
4. Patients lose ability to speak, swallow, move breath
5. ca 10% of ALS cases have genetic origin

Question 59

What is the hallmarks of ALS?

Answer 59

In most cases of ALS there is nuclear depletion of
the RNA-binding protein TDP-43 and its cytoplasmic
accumulation in degenerating neurons.

Nucleocytoplasmic trafficking has emerged as an
important mechanism contributing to ALS pathology.

Nucleocytoplasmic trafficking defects are found in
other neurodegenerative disease and in normal
physiological ageing.

Question 60

What are the molecular causes of ALS?

Answer 60

Factors identified in ALS which are linked to mRNA metabolism
Examples are FUS and TDP-43 (RBPs)
C90rf72 hexanucleotide repeat expansion

Question 61

What is Neuropathology of ALS?

Answer 61

the abnormal accumulation of insoluble proteins in the cytoplasm of degenerating motor neurons

Question 62

What is the pathological condition of TDP-42?

Answer 62

Abnormally accumulated from the nucleus of neurons and glia cells, to the neuronal cytoplasmic inclusions (NCI)

Question 63

What is FUS?

Answer 63

1.similar to hnRNP, binds to mRNAs and to SR proteins and influences splice site selections

Question 64

Where is most mutations of FUS clustered?

Answer 64

Nuclear localisation signal leading to its accumulation in the cytoplasm and inclusion formation

Question 65

What does FUS interact with?

Answer 65

SMN

Question 66

What does mutant form of FUS change?

Answer 66

Sub-cellular localisation of SMN

Question 67

What does wild type and mutant FUS interact with?

Answer 67

U1 and U2 snRNAs leading to their mislocalisation to the cytoplasm and reducing their availability for splicing in the nucleus.

Question 68

TDP-43

Answer 68

has a domain structure similar to hnRNP, binds to RNA and other hnRNPs as well as SR proteins

Question 69

What is TDP-43 linked to?

Answer 69

SMN and U snRNPs biogenesis

Question 70

What does mutant TPD-43 have an effect on?

Answer 70

SMN levels

changes its subcellular distribution

Question 71

What do FUS and TDP-43 do?

Answer 71

interact

Question 72

What is hnRNP?

Answer 72

are complexes of RNA and protein present in the cell nucleus during gene transcription and subsequent post-transcriptional modification of the newly synthesized RNA (pre-mRNA)

Question 73

What became a prominent feature of the aggregate formation?

Answer 73

Biophysical properties of the proteins

Question 74

What tends to aggregate?

Answer 74

proteins containing prion like domains

Question 75

What is complexity domain?

Answer 75

They don’t have alpha helices or beta sheets like you would in structure proteins

Question 76

What is the first intron of C9orf72?

Answer 76

C9orf72 non-coding GGGGCC repeat expansion

Question 77

What do the repeats have propensity to form?

Answer 77

Stable quadruplex structure in RNA

Question 78

What can the expanded RNA repeats be?

Answer 78

the toxic species which compromises

the function of affected neurons

Question 79

What does expanded repeats sequester away?

Answer 79

RNA binding proteins causing splicing deficit

Question 80

Where is C9orf72 detected in?

Answer 80

RNA foci of patients

Question 81

Where does C9orf72 repeats bind?

Answer 81

proteins of hnRNP A family

Question 82

What is a common histopatholgoical hallmark of ALS and TFD?

Answer 82

The cytoplasmic mislocalization and aggregation of TAR DNA-binding protein-43 (TDP-43)

Question 83

what is proximity-dependent biotin identification (BioID ) used for?

Answer 83

to interrogate the interactome of detergent-insoluble TDP-43 aggregates and found them enriched for components of the nuclear pore complex and nucleocytoplasmic transport machinery

Question 84

What did aggregated and disease-linked mutant TDP-43 trigger ?

Answer 84

sequestration and/or mislocalization of nucleoporins and transport factors, and interfered with nuclear protein import and RNA export in mouse primary cortical neurons, human fibroblasts and induced pluripotent stem cell–derived neurons

Question 85

Where is nuclear pore pathology present?

Answer 85

brain tissue in cases of sporadic ALS and those involving genetic mutations in TARDBP and C9orf72.

Question 86

What did data strongly implicate?

Answer 86

TDP-43-mediated nucleocytoplasmic transport defects as a common disease mechanism in ALS/FTD.

Question 87

What is a staining for nuclear lamina?

Answer 87

lamina b

Question 88

What does oligo-dt recognise?

Answer 88

Oligo tails of RNA

you can detect localization within the cell

Question 89

What happens in healthy neurons?

Answer 89

nucleocytoplasmic trafficking of RNAs and proteins through nuclear pores is tightly regulated
TDP-43 normally shuttles between the nucleus and cytoplasm, but is predominantly nuclear

Question 90

In neurodegenerative diseases with TDP-43 proteinopathy, including sporadic ALS and familial ALS

Answer 90

TDP-43 mutation, cytoplasmic aggregates of pathological TDP-43 co-localize with several nucleoporins (including FG-Nups, scaffold Nups and cytoplasmic Nups) and export factors (including Gle1)

Several transmembrane Nups and proteins of the nuclear lamina are mislocalized, and nuclear accumulation of DNA damage and poly(A) RNAs are observed

Question 91

C9ORF72 ALS/FTD

Answer 91

transcripts containing expanded G4C2 repeats interact with the import factor RanGAP1 and are translated into dipeptide repeat (DPR) proteins through repeat-associated non-ATG (RAN) translati on

Arginine-containing DPRs associate with nuclear pore proteins, leading to abnormal nucleocytoplasmic transport, nuclear accumulation of poly(A) RNA and DNA damage. Deficit in protein nuclear import may participate in a feedforward mechanism, with subsequent cytoplasmic accumulation of TDP-43 enhancing the disruption of nuclear pores

Question 92

In Huntington’s disease

Answer 92

expanded polyglutamine (poly(Q))-containing huntingtin coaggregates with Nups (including Nup62 and Nup88) and the transport factors Gle1 and RanGAP1. Abnormal nuclear architecture, accumulation of DNA damage and nuclear retention of poly(A) RNAs, as well as cytoplasmic accumulation of TDP-43, are observed

Question 93

What are the key challenges and perspectives?

Answer 93

Some mechanistic insight into the pathology mechanisms in various neurodegenerative disorders allows to begin rational design of medications
Targets include – dopamine replacement therapy for Parkinson, targeting machinery which controls protein folding, e.g., heat-shock proteins; inhibitors of histone deacetylases (HDACs), e.g., sodium butyrate all improve viability and suppress cell death in a variety of model systems.
Ideally, therapies should be targeted at some early stages of disease development as these may allow recovery of function