L11 - protein processing and targeting Flashcards Preview

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Flashcards in L11 - protein processing and targeting Deck (96)
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1
Q

What is the constitutive secretory pathway?

A

A secretory pathway from the golgi to outside the cell by exocytosis. In constitutive secretion proteins are secreted from a cell continuously, regardless of external factors or signals. No external signals are needed to initiate this process.

2
Q

What is an endosome?

A

endocytic vesicle

3
Q

On a histological slide, how can you tell the difference between lysosome and peroxisomes?

A

Lysosomes are darker

4
Q

What types of proteins are synthesised by ribosomes attached to the ER membrane?

A

Proteins destined for membrane or secretory pathway

5
Q

What types of proteins are synthesised by ribosomes free in the cytoplasm?

A

Protein destined for cytosol, or post-translational import into organelles

6
Q

If a protein synthesised by a ribosome in the cytoplasm doesn’t remain in the cytoplasm which organelles can it be imported into?

A

Peroxisome
Mitochondrion
Nucleus (via nuclear pores)

7
Q

If a protein synthesised by a ribosome attached to the ER doesn’t remain in the ER but goes onto the golgi complex, where can it be directed to after the golgi?

A

Plasma membrane
Lysosome
Secretory vesicle -> extracellular

8
Q

How is a protein synthesised by a ribosome attached to the outside membrane of the ER imported into the lumen of the ER?

A

Co-translational insertion

9
Q

Which general four things are required for proteins to be sorted?

A
  1. Signal (address) - intrinsic to the protein
  2. Receptor - recognises signal&directs to correct membrane
  3. Translocation machinery - to transport across membranes
  4. Energy - for protein transfer
10
Q

Where can the signal peptide be found in proteins?

A

N-terminus
C-terminus
Internal (but available)

11
Q

Describe the 5 stages of import of proteins into the mitochondrial matrix

A
  1. Protein with signal peptide kept unfolded by chaperones
  2. Signal binds receptor
  3. Protein fed through pore in outer membrane
  4. Protein moves through channel in adjacent inner membrane
  5. Targeting signal cleaved
12
Q

Describe how proteins are imported into the nucleus

A
  1. Cargo protein (with nuclear localisation sequence) binds the carrier protein importin
  2. Cargo+ importin travel through nuclear pore
  3. Cargo displaced inside nucleus by binding of Ran-GTP
  4. Ran-GTP+ cargo recycled into cytoplasm
13
Q

Which localisation signal can be mutated in Pyruvate dehydrogenase deficiency?

A

Mitochondrial targeting sequence

14
Q

Which localisation signal can be mutated in Swyer syndrome (XY genotype but outwardly female due to malfunction in localisation of the sex determining Y protein (SRY required for testis differentiation)

A

Nuclear localisation signal

SRY is a transcription factor

15
Q

Which localisation signal can be mutated in Leri-Weill dyschondrosteosis and Langer mesomelic dysplasia which leads to a short stature because SHOX protein (required for skeletal develpoment) is not localised to the correct area?

A

Nuclear localisation signal

SHOX is a transcription factor

16
Q

Describe how proteins are imported into the peroxisome

A
  1. Cytosol peroxisomal import receptor binds cargo with PTS (peroxisome targeting sequence)
  2. Peroxisomal protein remains folded and import receptor integrates into translocation channel - opening it
  3. Import receptor and PTS dissociate
  4. Receptor returned to cytosol (Energy requiring step)
17
Q

What is a regulated secretion?

A

In regulated secretion, proteins are packaged as described in the constitutive pathway, but they are only secreted in response to a specific signal, such as neural or hormonal stimulation.

18
Q

List some cells which do regulated secretion?

A
  1. Endocrine cells
  2. Exocrine cells
  3. Neurocrine cells - secreting neurotransmitters
19
Q

What is meant by cell polarity?

A

These cells have an apical-basal polarity defined by the apical membrane facing the outside surface of the body, or the lumen of internal cavities, and the basolateral membrane oriented away from the lumen.

20
Q

What are the features of cells which do regulated secretion?

A

Specialised cells
Polarised
Very organised ultrastructure

21
Q

How does co-translational insertion of proteins into the ER occur?

A
  1. Ribosome translating protein
  2. SRP binds signal peptide and ribsome
  3. SRP mediates binding to SRP receptor on ER membrane, stopping translation
  4. GTP binding to SRP receptor triggers transfer of ribsomome and peptide to translocon, which opens
  5. Peptide transported through translocon
  6. Signal peptide cleaved
  7. Channel closes, ribosome disconnect and protein folds
22
Q

Which protein mediates a 3-way association with an ER receptor, ribosome and signal peptide so that co-translational insertion of proteins into the ER can occur?

A

Signal-recognition particle (SRP) - multi-domain riboprotein

23
Q

Which proteins other than secretory proteins need to be inserted into ER membrane?

A

Membrane proteins for plasma membrane or internal membrane of secretory pathway

24
Q

How is a membrane protein inserted into the ER membrane?

A

Same mechanism as secretory proteins but the protein has a stop transfer anchor sequence (a second hydrophobic sequence) which prevents is transferring any further into the lumen of the ER

25
Q

What is hydroxylated in the ER?

A

selected lysine and proline residues

26
Q

What conformation changes to proteins occur in the ER?

A

Formation of S-S bonds
Proper folding of proteins
Assembly of multisubunit proteins

27
Q

What alterations to the peptide chain occur in the ER?

A

Specific proteolytic cleavage
Glycosylation
Formation of S-S bonds
Hydroxylation of selected Lys Pro residues

28
Q

What occurs to some membrane proteins in the ER?

A

Insertion of proteins into membranes

29
Q

Why is glycosylation of proteins important?

A
  1. Correct protein folding
  2. Protein stability
  3. Facilitates interactions with other molecules
  4. Deficiency in N-linked glycosylation -> severe inherited diseases: congenital disorders of glycosylation (CDG)
30
Q

What is N-linked glycosylation?

A

Sugars are added on an asparagine side chain (contains an amino group, hence N-linked)

31
Q

How is the oligosaccharide transferred to the asparagine side chain in N-linked glycosylation?

A

It is preassembled on a lipid carrier and then transferred as the peptides crosses the ER membrane into the lumen

32
Q

What happens to the oligosaccharide side chain in the ER and Golgi?

A

It is modified extensively by trimming and addition of further sugars

33
Q

What do peptidyl-prolyl isomerases do?

A

Accelerate the interconversion of cis and trans isomers of proline residues.
This needs to occur during the folding of a number of proteins (especially IgGs)

34
Q

What is the role of protein disulphide isomerase (PDI)?

A

It contains two cysteine residues which are bonded together (oxidised). It comes along and catalyses a disulphide bond forming (oxidation) between two reduced cysteines in a substrate molecule - being reduced itself in the process

35
Q

How is PDI (an ER resident protein) retained in the ER and not secreted?

A

It has a KDEL region which binds to a KDEL receptor in the cis-Golgi cisternae, triggering retrograde transport from golgi back to ER

36
Q

Why can folding problems occur?

A
  1. Proteins may be trapped in mis-folded conformation
  2. Protein contains mutation resulting in mis-folding
  3. Protein may be incorrectly associated with other subunits
37
Q

What happens if there are folding problems of proteins?

A

ER chaperone proteins attempt to correct the problem

38
Q

Name 3 chaperone proteins?

A

BIP - binding immunoglobulin protein
Calnexin
Calreticulin

39
Q

What does the chaperone protein BIP bind to?

A

It binds to exposed amino acid sequences that would normally be buried in the interior of a folded protein

40
Q

What do the chaperone proteins Calnexin and Calreticulin bind to?

A

They bind to OLIGOSACCHARIDES on incompletely folded proteins

41
Q

What does binding of chaperone protein due to misfolding achieve?

A
  1. Retain unfolded proteins in the ER
  2. Act as sensors to “monitor” extent of protein mis-folding:
    (i) mediate increased transcription of chaperones
    (ii) mediate reduction in translation
42
Q

What happens if misfolding can not be corrected?

A

Protein may return to cytosol for degradation

Protein may accumulate to toxic levels in the ER, leading to a disease (may arise due to single mutations)

43
Q

What modifications to proteins can occur in the Golgi apparatus?

A

Modification of sugars:

i) phosphorylation
(ii) sulfation (of tyrosine too
(iii) addition
(iv) removal

44
Q

Other than modifications, what role does the Golgi apparatus have?

A

Sorting of proteins into vesicles for the:
lysosome
plasma membrane
secretory vesicles

45
Q

What signal is added in the Golgi apparatus to lysosomal proteins so that they can be delivered to the lysosome?

A

mannose-6-phosphate signal

46
Q

Which receptor mediates the delivery of lysosomal enzymes from the trans-Golgi network to the lysosomes?

A

mannose-6-phosphate receptor

47
Q

Where does O-linked glycosylation occur?

A

Golgi apparatus

48
Q

Where does N-linked glycosylation occur compared to O-linked glycosylation?

A

ER lumen vs Golgi apparatus

49
Q

What does O-linked glycosylation entail?

A

Attachment of sugar to -OH group of serine or threonine

50
Q

What type of molecules is O-linked glycosylation important for?

A

Proteoglycans - component of extracellular matrix and mucus secretions

51
Q

Name a molecule which undergoes consitutive secretion

A

Collagen

52
Q

Name some molecule which undergo regulated secretion

A
Insulin
Also these peptides derived from the precursor protein POMC:
Beta-endorphin
ACTH
alpha-MSH
beta-lipotropin
53
Q

What can be a signal for regulated secretion?

A

Hormones

neurotransmitters

54
Q

How does an extracellular signal result in regulated secretion?

A

Binds to a membrane receptor triggering an intracellular signalling pathway which stimulates secretory vesicles (which are storing secretory proteins) to fuse with the cell’s plasma membrane and release their proteins into intercellular space

55
Q

What is the most abundant protein in the body?

A

Collagen (35-30%)

56
Q

Where is collagen found?

A

Connective tissue:

tendons, ligaments, cartilage, bone, loose connective tissue (providing structure to internal organs)

57
Q

Which cell secretes collagen?

A

Fibroblasts in connective tissue

58
Q

What is the basic unit of collagen?

A

tropocollagen

59
Q

Describe the structure of tropocollagen

A

300nm rod-shaped protein
characteristic right-handed triple helix
3 polypeptide (alpha-chains), each 1000ish aa long
glycine in every third position in each alpha-chain

60
Q

What are the properties of the triple helix?

A

non-extensible
non-compressible
high tensile strength

61
Q

What should the triple helix of collagen not be confused with?

A

The protein secondary structure - alpha-helix

62
Q

Apart from glycines in every third position in the alpha-chains, what other amino acids tend to be in the chains?

A

Mostly proline of hydroxyproline

63
Q

What stabilises the triple helix?

A

H-bonds between alpha chains

64
Q

There are different types of alpha-chains of collagen. What does this allow?

A

Different combination of alpha chains make different types of collagen.
Different tissues have different distributions of collagen types

65
Q

What characteristic feature of collagen fibres can be seen with high resolution electron microscopy?

A

Regular repeating grooves in the fibres

66
Q

Why does assembly of collagen occur outside of fibroblasts?

A

Collagen fibres are very long. They would cause damage to the cell if assembled intracellularly.

67
Q

What is the pneumonic to help remember the steps of the biosynthesis of collagen?

A

CHADPOGRL

68
Q

What does C stand for in the pnemonic CHADPOGRL?

A

CLEAVAGE of signal peptide (as enters rER lumen)

69
Q

What does H stand for in the pnemonic CHADPOGRL?

A

HYDROXYLATION of selected proline and lysine residues

70
Q

What does A stand for in the pnemonic CHADPOGRL?

A

Addition of N-linked oligosaccharides and galactose to hydroxylysine residues

71
Q

What does D stand for in the pnemonic CHADPOGRL?

A

DISULPHIDE bonds - between chains at C-terminus -> chain alignment

72
Q

What does P stand for in the pnemonic CHADPOGRL?

A

PROCOLLAGEN - triple helix formed

73
Q

What does O stand for in the pnemonic CHADPOGRL?

A

O-LINKED - oligosaccharide chains are completed by addition of glucose (in Golgi)

74
Q

What does G stand for in the pnemonic CHADPOGRL?

A

GOLGI- transports vesicles out of cell

75
Q

What does R stand for in the pnemonic CHADPOGRL?

A

REMOVAL - of N-and C-terminal propeptides

76
Q

What does L stand for in the pnemonic CHADPOGRL?

A

LATERAL association - of collagen molecules followed by covalent cross-linking -> aggregation of fibrils into collagen fiber

77
Q

What event changes prepro alpha-chains into pro-alpha chains?

A

Cleavage of signal peptide by signal peptidase as enter ER lumen

78
Q

Why are proline and lysine of collagen alpha-chains hydroxylated in the rER?

A

Increase the available h-bonding between alpha-chains in the triple helix

79
Q

Why does lack of Vitamin C cause scurvy?

A

Vitamin C (ascorbate) is a cofactor of the enzyme prolyl hydroxylase which hydroxylates proline and lysine residues of collagen alpha-chains. A lack of Vit C therefore decreases the number of hydroxylated prolines and lysine in the alpha-chain, decreasing the number of h-bonds that can form between each other in the triple helix. Therefore the triple helix conformation is not as stable and the collagen is not as strong.

Collagen is found in all types of connective tissue: skin, bone, tendons, cartilage, loose connective tissue which gives organs their form. These tissues can breakdown in scurvy giving the following symptoms:

  1. bleeding and swelling of the gums
  2. muscle and joint pain
  3. tiredness
  4. the appearance of red dots on the skin
80
Q

What is the role of prolyl hydroxylase?

A
  1. Associated with PDI (protein disulphide isomerase) in the ER
  2. Requires Vit C and Fe2+ irons for activity
  3. Allows H-bonding to stabilise triple helix
  4. Scurvy is due to weak tropocollagen triple helices
81
Q

Which parts of the alpha-chains do not form triple helices?

A

Propeptides : regions of amino acids at the N and C-terminus (removed outside the cell)

82
Q

Disulphide bonds between alpha-chains at the C-terminus allow for what?

A

Chain alignment

83
Q

Why does collagen display regular banding?

A

Collagen molecules associate laterally in a regular arrangement. Gaps between tropocollagen molecules stain darker with a heavy metal stain. This creates a light and dark banding pattern, where light regions have no gaps and dark regions do.

84
Q

What is the role of lysyl oxidase?

A

It coverts lysine residues into aldehyde derivatives which can form cross-links between tropocollagens in the collagen fiber

85
Q

Where is lysyl oxidase found? What are its cofactors? Function?

A

Extracellularly
Vitamin B6 and Cu2+
Covalent cross-links

86
Q

What disease does a deficiency in lysly oxidase cause?

A

Ehlers-Danlos syndrome

87
Q

Apart from a deficiency in lysly oxidase, what else can cause Ehlers-Danlos syndrome?

A

Mutation in collagen type V

88
Q

Describe the structure of proinsulin

A

Single polypeptide

89
Q

What modification happens to proinsulin in the ER?

A

Disulphide bonds are formed, stabilising the folding

90
Q

What modifications to proinsulin occur post-Golgi?

A

Connecting peptide removed (C peptide), leaving complete two-chain insulin molecule (A and B peptide held together by disulphide bonds)

91
Q

How many enzymes does the proteolytic processing of insulin require?

A

3

92
Q

Where does proteolytic processing of pro-insulin occur?

A

Inside the secretory vesicle, after it has bud from the Trans Golgi Network

93
Q

Proteolytic processing can be very complex. How can it yield different products in different cell locations?

A

Different cell locations have different amounts of processing enzymes

94
Q

What type of secretory protein is commonly proteolytically processed?

A

Hormones

95
Q

Why is the precursor protein POMC protelytically processed into:
(i) ACTH and beta-lipotropin, in the anterior lobe of the pituitary
BUT
(ii) alpha-MSH, gamma-lipotropin, beta-MSH and beta-endorphin, in the intermediate lobe of the pituitary?

A

Different processing enzymes are compartimentalised to different parts of the pituitary

96
Q

Why is proteolytic processing so common in the secretory pathway?

A
  1. Can give rise to very small products that would be too short to enter the ER via co-translational mechanism.
  2. Some secreted protein (e.g. hydrolytic enzymes) would be destructive if activated inside the cell.
  3. Multiple bioactive products can be produced at the same time
  4. Avoid activation of insulin receptors in secretory pathway