S9) Protein Targeting and Collagen Biosynthesis

Question 1

What is collagen?

Answer 1

Collagen is a secreted protein produced by fibroblasts in the connective tissue and is the most abundant protein in the body (25-35%)

Question 2

Identify some structures composed largely of collagen

Answer 2

• Tendons
• Ligaments
• Cartilage
• Bone
• Loose connective tissue

Question 3

What is the basic unit of collagen?

Answer 3

Basic unit is tropocollagen

Question 4

Describe the structure of the collagen molecule

Answer 4

• Consists of 3 polypeptides
• Rod-shaped protein
• (Gly-X-Y)_n repeat (glycine in every 3rd position in chain)
• Characteristic triple helix (right-handed)

Question 5

Which type of bonding in predominant in a collagen molecule?

Answer 5

H-bonds between α chains stabilise structure

Question 6

State three structural benefits of the triple helix structure of collagen

Answer 6

• Non-extensible
• Non-compressible
• High tensile strength

Question 7

Why is glycine a central part of the collagen molecule?

Answer 7

Glycine is the only amino acid with a side chain small enough to fit in the middle of the helix

Question 8

Which other monomers form an integral part of the collagen structure (Gly-X-Y)_n ?

Answer 8

• Proline
• Hydroxyproline

Question 9

What is prolyl hydroxylase and what does it do?

Answer 9

Prolyl hydroxylase is an enzyme which catalyses the formation of hydroxyproline and allows increased H-bonding to stabilise the collagen triple helix

Question 10

What is scurvy?

Answer 10

- Scurvy is a condition which arises due to insufficient Vitamin C (ascorbic acid) intake

• It presents with weakness, fatigue, and sore arms and legs

Question 11

Why does scurvy occur?

Answer 11

Prolyl hydroxylase requires ascorbate as a cofactor to function so its absence compromises the enzyme’s function and and weak tropocollagen triple helices form

Question 12

Describe the tissue distribution of Type I collagen

Answer 12

Type I collagen is found in the skin, tendons, ligaments and bone

Question 13

Describe the tissue distribution of Type II collagen

Answer 13

Type II collagen is found in cartilage and intervertebral discs

Question 14

Describe the tissue distribution of Type III collagen

Answer 14

Type III collagen is found in the foetal skin and cardiovascular system

Question 15

Describe the tissue distribution of Type IV collagen

Answer 15

Type IV collagen is found in the basement membrane

Question 16

Describe the tissue distribution of Type V collagen

Answer 16

Type V collagen is found in the placenta and skin

Question 17

The synthesis and modification of collagen involves three stages; synthesis in the ER, procollagen secretion and the formation of the collagen fibre.

In 7 steps, describe the synthesis and modification of collagen in the ER

Answer 17

⇒ Synthesis and entry of chain into lumen of rER

⇒ Cleavage of signal peptide (prepro α chains → pro α chains)

⇒ Hydroxylation of proline and lysine residues

⇒ N-linked glycosylation

⇒ Addition of galactose to hydroxylysine residues

⇒ Formation of disulphide bonds

⇒ Formation of triple-helical procollagen from C- to N-terminus

Question 18

The synthesis and modification of collagen involves three stages; synthesis in the ER, procollagen secretion and the formation of the collagen fibre.

In 4 steps, describe the secretion of procollagen from the cell

Answer 18

⇒ O-linked glycosylation (addition of glucose)

⇒ Transport vesicle

⇒ Exocytosis

⇒ Conversion of procollagen to tropocollagen (removal of N- and C-terminal propeptides)

Question 19

The synthesis and modification of collagen involves three stages; synthesis in the ER, procollagen secretion and the formation of the collagen fibre.

In 3 steps, describe the formation of the collagen fibre

Answer 19

⇒ Lateral association of collagen molecules

⇒ Covalent cross-linking

⇒ Aggregation of fibrils

Question 20

Summarise protein target signals to the ER in terms of:

• Nature of signal
• Signal location in the primary sequence
• Folding during transfer
• Specialist proteins involved
• Signal retention/cleavage
• Energy requirement

Answer 20

• Nature of signal: Hydrophobic signal sequence
• Signal location in the primary sequence: N-terminus
• Folding during transfer: unfolded
• Specialist proteins involved: SRP, SRP receptor & protein translocator
• Signal retention/cleavage: cleaved by signal peptidase
• Energy requirement: yes for hydrolysis of GTP

Question 21

Summarise protein target signals to the nucleus in terms of:

• Nature of signal
• Signal location in the primary sequence
• Folding during transfer
• Specialist proteins involved
• Signal retention/cleavage
• Energy requirement

Answer 21

• Nature of signal: NLS (basic)
• Signal location in the primary sequence: various positions on surface
• Folding during transfer: folded
• Specialist proteins involved: importin & RanGTP for transport and displacement of NLS
• Signal retention/cleavage: retained
• Energy requirement: yes for hydrolysis of GTP

Question 22

Summarise protein target signals to the mitochondria in terms of:

• Nature of signal
• Signal location in the primary sequence
• Folding during transfer
• Specialist proteins involved
• Signal retention/cleavage
• Energy requirement

Answer 22

• Nature of signal: amphipathic signal
• Signal location in the primary sequence: N-terminus
• Folding during transfer: held partially unfolded by chaperones
• Specialist proteins involved: Tom & Tim channel complex, chaperones
• Signal retention/cleavage: cleaved
• Energy requirement: yes, ATP hydrolysis by mHsp70

Question 23

Summarise protein target signals to the lysosomes in terms of:

• Nature of signal
• Signal location in the primary sequence
• Folding during transfer
• Specialist proteins involved
• Signal retention/cleavage
• Energy requirement

Answer 23

• Nature of signal: Mannose-6-phosphate
• Signal location in the primary sequence: signal patch for distinguishment
• Folding during transfer: folded
• Specialist proteins involved: M-6-P receptor in trans-Golgi
• Signal retention/cleavage: phosphate cleaved by phosphatase
• Energy requirement: Yes

Question 24

Summarise protein target signals for ER retention in terms of:

• Nature of signal
• Signal location in the primary sequence
• Folding during transfer
• Specialist proteins involved
• Signal retention/cleavage
• Energy requirement

Answer 24

• Nature of signal: KDEL (Lys-Asp-Glu-Leu)
• Signal location in the primary sequence: C-terminus
• Folding during transfer: folded
• Specialist proteins involved: KDEL Receptor
• Signal retention/cleavage: retained
• Energy requirement: only for formation of budding vesicle