Lecture 25 - PTM, protein localisation and degradation

Question 1

What must proteins do in the cytoplasm to function

Answer 1

Fold

Question 2

What can cause protein missfolding and aggregation?

Answer 2

stress

Question 3

How efficient is folding in vitro and in vivo, and why is this?

Answer 3

20-3-%
100% (Vivo)
Because in vivo chaperone proteins are present

Question 4

Give an example of a molecular chaperone, and where they are found and why it’s important

Answer 4

hsp90 (heat shock protein - origionally identified as proteins upregulated by heat shock, which causes protein denaturation and surgfaces become exposed and proteins aggregate)
Found ubiquitiously (although hsp70 is most ubiquitous)
Upregulated in response to stress - important for cell health and organismal longevity

Question 5

What are the primary roles of chaperone proteins

Answer 5

assist nacent protein folding and prevent aggregation

stabilise polypep surfaces in unfolded state

Question 6

How do chaperones achieve their function - generally

Answer 6

• Bind transiently to newly synthesised protein
• binding during translation too to prevent it
• bind stably to the surface of to misfolded proteins
• Have affinity for exposed hydrophobic peptides rather than specific sequences

Question 7

Molecularly how do chaperone proteins work

Answer 7

undergo cycles of binding and release, powered by ATP hydrolysis
Have 2 domains joined by tenuous link - the domains can move large distances and rotate (up to 50aa and 100 degrees relative to each other)
binding and release from the polypeptide substrate is what assists the conformation rearrangement

Question 8

How do the 2 domains of chaperone proteins attach to the substrate polypeptide?

Answer 8

‘lid’ folds over the polypeptide substrate
ATP binds
refolding occurs,
lid opens, allows access of another substrate to the substrate binding domain
it’s the cycle that facilitates the conformational change

Question 9

How does hsp90 specifically bind to a substrate? (same as a normal chap but just more detail)

Answer 9

It has 3 different structures: open, ATP bound, ADP bound
Open - ATP binds - cofactor assist - substrate attached - conformational changes occur (it’s closed and twisted) - now ADP is bound - ADP released-Open

Question 10

Other than in nascent protein folding, what roles in homeostasis do chaps have?

Answer 10

-Aid interaction between cellular components for transport and degradation
androgen and oestrogen receptors require hsp90 for efficient binding of steroid hormones

Question 11

Describe how hsp90 is present in steroid binding to androgen

Answer 11

• steroid receptors are not present on cell surface because steroids diffuse through the membrane
• the steroid receptor (inside the cell) is unstable until hsp90 bound
• Now the androgen (receptor) can bind to the steroid, hsp90 displaced
• receptor ligand complex now stable so can enter nucleus , attach to DNA and act as TF

Question 12

What are many hsp90 ‘client proteins’ implicated in

Answer 12

cancer. surprise.

Question 13

Give an example of a hsp90 client prominent in breast cancer, and what the effects would be if drugs could successfully target hsp90

Answer 13

HER2 tyrosine kinase (an estrogen receptor)
If hsp90 inhibited, the oncogenic client proteins such as HER2 are compromised and cancers are less able to withstand the stress of accumulating unfolded proteins - proteolytic stress is induced

Question 14

how much normal protein is degraded per hour in mammals

Answer 14

1-2% i.e. a significant amount of cellular protein is degraded normally

Question 15

What are the 3 main types of proteins that are degraded and why have these arisen

Answer 15

INCOMPLETE OR MISSENSE PROTEINS - errors in lation
-cellular errors, disruptive mutations, prem termination, accidental proteolytic cleavage
POST SYNTHETIC DAMAGED PROTEINS - environmental toxins e.g. UV damage, ROS
-misfolded, protein aging, denatured
UNWANTED (SIMPLY NOT NEEDED) PROTEINS
-inactive/used proteins, free subunits of multimeric complexes, proteins made in excess
BASICALLY ANY PROTEIN IN WRONG PLACE AT WRONG TIME

Question 16

What are the options for where proteins can be degraded in eukaryotic cells

Answer 16

Proteosome
Lysosome
Caspase enzymes (that are not organelle associated)

Question 17

What are the features the proteins it degraded by the proteosome

Answer 17

cytoplasmic and nuclear proteins

Its is a targeted, selective, highly regulated process

Question 18

What are the features of the proteins degraded in the lysosome and what is it’s internal environment like

Answer 18

mainly defecitve organelles and extracellular proteins taken up by cell
It’s an acidic environment with hydrolytic enzymes

Question 19

What are the features of proteins degraded by the caspase enzymes

Answer 19

(This is a proteolytic enzyme)
Degrades cystolic and nuclear proteins
activated by signals that promote programmed cell death

Question 20

What are the structural features of the proteosome and features of how it process proteins

Answer 20

complex molecular machine
There are about 30000 per cell
made of 50 protein subunits
assembled as a 26s compex - 20s core containing proteolytic enzymes and 2x19s regulatory caps
Caps control entry of ‘marked’ (with ubq) proteins - it denatures them to allow them inside
6 proteolytic sites are inside, accessed only through the cap

produces fragments of viral proteins to be presented on cell surface
proteins broken down to fragments 7-9aa long, then further degraded in cytoplasm by peptidases

Question 21

What are used to tree multiple melonomas and explain why

Answer 21

proteosome inhibitors
In mmplasma cells produce lots of defective immunoglobin, so high proteolytic stress if proteasomes can’t degrade the extra protein

Question 22

Give an example of a proteosome inhibiting drug and how it does this
What can it work in comination with?

Answer 22

Bartzomib - targets 1 core enzyme within it. Doubles life expectancy but lots of nausea as side effect, often people become resistant and relapse
hsp90 inhibitors - has synergenic effect because both cause proteotoxic effects fro cancer cells

Question 23

What molecule must proteins be labelled with so they are degraded by admission to proteosome and how long is this

Answer 23

ubiquitin - 76aa

Proteins actually polyubiquitinated (multiple chains added to a protein)

Question 24

Is ubq degraded by the proteosome?

Answer 24

No , cleaved off and recycled

Question 25

What are the 3 enzymes involved in polyubiquitination?

Answer 25

E1, E2, E3

Question 26

Describe the process of ubiquitination

Answer 26

E1 binds to and activates ubiquitin in ATP dependant manner
Ubq transfered, in it’s activated state, to E2 conjugating enzyme
E3 ubq ligase recognised the target protein to be destroyed and associates with it
ubq (via E2) is targetted to this protein by E3.
Ubq tramsfered from E2 to a lysine on the target protein
E3 releases the now ubqated target protein

The cycle is repeated until target protein has a short chain of ubq
Proteosome recognises this chain
ubq remove and target protein swallowed by proteosome

Question 27

Can you have monoubiquitination?

Answer 27

Yes - but regulates protein function rather than triggers degradation

Question 28

GIve an example of an E3 ligase with a specific substrate (or class of substates)

Answer 28

e3 ligase that regulate cell cycle by degrading cyclins
Entry into mitosis is via cyclins A and B, exit from it requires their destruction therefore a specific E3
diff e3’s are specific to diff substrates

Question 29

Give another, very specific example of a E3 ligase and it’s substrate
Why is it necessary

Answer 29

e3 = mdm2
substrate = p53 (tumour surpressor)
necessary because p53 triggers apoptosis very easily

Question 30

What experiement proved mdm2 was crucial to organism survival

Answer 30

KO in mouse - die in utero because p53 induced apoptosis

KO for mdm2 crossed with KO for p53 - survived

Question 31

HOw do some cancers incorporate mdm2 into their survival

Answer 31

some overexpress it so as to detroy more p53 so it won;t come along and surpress the tumours

Question 32

What cancer therapy involved mdm2 and p53 and how does it work

Answer 32

nutin - occupies p53 binding site of mdm2 (a hydrophobic pocket pf alpha helices) to prevent p53 binding and being ubiquitinated and then depleted

Question 33

As well as ubq, what other ptm regulate p53 and where do most modifications occur and why

Answer 33

neddylation, methylation, sumoylation, acetylation, phosphorylation
most occur at either terminus - becasue the middle is the DNA binding domain so less mods needed

Question 34

What effects do neddylation, methylation and sumoylation have on p53

Answer 34

influence it’s ability to regulate the gene transcription (positvely or negatively) ie. regulates scriptional activity

Question 35

What phosphorylates p53? GIve and example and the result

Answer 35

many kinases, different ones in different conditions and not always the same effects
E.g. ATM kinase phosphorylates p53 on ser15 in response to DNA damage
Effect of stabilising p53 by inhibiting it’s interaction with mdm2. Therefore p53 can accumulate and direct apoptosis or cell cycle arrest until DNA repaired

Question 36

What is acetylation of p53 done by? Give and example and general results

Answer 36

done by acetyltransferases e.g. p300 - adds acyl group to lysine residue, triggered by various stresses
Effects: Stimulates p53 ability to bind to DNA and activate scription
also stabilises p53 if residues that would be targeted by mdm2 are acetylated polyubq can’t occur and it won;t be destroyed

Question 37

Overall how do PTMs have regulatory versatility?

Answer 37

Diff ptms induced in diff conditions

diff ptms can regulate a protein’s function in many diff ways

Question 38

Give an example of a histone PTM

Answer 38

N-terminal tail is acetylated on lys residues, so the +ve charge is neutralised, therefore accesibility of DNA increases because no longer so tightly wound around histone

Question 39

Apart from acetylation what other tail ptms occur on histones

Answer 39

phosphorylation of ser or thr residues

methylation of lys or arg residues

Question 40

What do histone tail modifications states contain info about?

Answer 40

The gene regions where they reside

Question 41

What do some TFs recruit to stimulate transcription?

Answer 41

acetyl transferases - they take advantage of acetylation to stimulate expression of certain genes

Question 42

Give an example where acetylation leads to promotion of gene transcription

Answer 42

p53 is acetylated, followed by the nucleosomes around it once the p53 has bound to DNA (post acetylation)
This therefore promotes trascription of genes because they’re now more accessible - - because acetylated regions are more accessible to basal factor and rna polymerases

Question 43

what is the histone code hypothesis

Answer 43

specific combinations of histone ptm may convey infor about what genes are invovled because some modifications are recognised by particular proteins

Question 44

Give 3 examples of histone modifications and what they are associated with

Answer 44

histone 3 - lysine 9 trimethylated - silent genes
histone 3 - lysine 4 trimethylated - active promotors
histone 3 - lysine 4 monomethylated - active enhancers

Question 45

Give an example of a protein modification dictating protein location

Answer 45

the enzyme catalysed fatty acid attachments that anchor protein to the membrane - this protein has been modified so it knows to go here
rubbish example I know but it’s in the notes

Question 46

What is a lipid anchor?

Answer 46

= a glycophosphatidyl inositol attched to protein c terminus. ie the anchor is the ptm
composed of oligosaccharides and inosotil phospholipids
There’s not more that 1 GPI anchor per protein
added to proteins in the er

Question 47

What do GPI anchors do?

Answer 47

• anchor cell surface proteins to plasma membrane

- target proteins to outer leaflet

Question 48

How are proteins targetted to the ER? And on what other proteins is it normally found

Answer 48

via an N terminal signal sequence that contains 6-12 hydrophobic residues
This sequence is found on most proteins destined for secretion, the lysosome, or for integration into the plasma membrane

Question 49

If we need to know the sequence reqired for different destinations we can look at the glorious table in my notes

Answer 49

I really don;t think we do actually need to know them

Question 50

What is the signal sequence of a nacent polypeptide recognised by, so it can be targetted to the right place?

Answer 50

Signal recognition particle - a ribonucleoprotein particle found in the cytoplasm
Contains 6 proteins, 7 slRNA and a 300 nucleotide RNA scaffold

Question 51

Name a subunit of an SRP and it’s role in the SRP’s overall function

Answer 51

-p54
-Binds to the signal peptide of the nascent polypeptide
-SRP docks with SRP receptor (a 2 subunit integral membrane protein on cytolic face of the ER ), docks specifically with the alpha subunit of the receptor
The interaction allows GTP hydrolysis, and the SRP is released and recylced

Question 52

What is a translocon

Answer 52

protein lined membrane channel

Question 53

Describe co translational translocation

Answer 53

• SRP has bound to polypep (which is still attached to ribosome)
• this brings ribosome to ER surface
• GTP hydrolysis, release of SRP - this pushes poly pep through the translocon
• more pushing through is driven by the energy of protein synthesis, as growing polypep is fed through to ER
• N terminus emerges 1st -ie signal sequence
• signal sequence cleaved off by siganl peptidase enzyme
• remainer of poly pep pushed through to ER lumen and folds up

Question 54

What changes are inflicted in the protein once released into the ER lumen?

Answer 54

Glycosylation - covalant additiona nd processing of carbohydrates. O and N linked oligosaccharides added
Disulphide bond formation - catalysed by protein disulphide isomerase
Folding and assembly - of multi subunit proteins
specific proteolytic cleavages - in both ER and Golgi

Question 55

What is the ultimate goal of proteins secretion through ER and golgi

Answer 55

functional proteins for secretion

Question 56

Describe vesivular transport from the ER, via the golgi to the plasma membrane

Answer 56

proteins secreted via trafficking vesicles from ER
vesicles bud off
move into golgi
then trafficked to cell surface or lysosome