Lecture 17

Question 1

What is extracellular matrix (ECM)?

Answer 1

Extracellular= outside of the cell
Matrix= a network of proteins, minerals, sugars and water

Question 2

What does the ECM provide?

Answer 2

Provides:
1) Mechanical support to tissues
2) Pathways for cellular migration
3) Survival signals
4) Sequesters growth factors

Question 3

What are the 5 classes of macromolecules that make up the ECM?

Answer 3

1. Collagen
2. Elastin
3. Glycosaminoglycans and Proteoglucans
4. Hyaluronan (a unique Glycosaminoglycan)
5. Adhesive Glycoproteins

Question 4

What are some facts about ECM?

Answer 4

All can be encoded by multiple genes
All can be alternatively spliced
Geometrical arrangments can change in different environments
This gives rise to many different types of ECMs

Question 5

How is the ECM made?

Answer 5

Usually made by cells that are in the tissue
Eg. Fibroblasts
They secrete the fibrous part of the connective tissue and “ground substance” (the material between the fibres made of variable amounts of water and other molecules). This determines how hard or soft the matrix will be

Question 6

What is collagen?

Answer 6

Most abundant protein in the human body and is found across the phylogenetic tree
Very strong (weight for weight they are as strong as steel)

Question 7

What is the structure of collagen?

Answer 7

Rod shape
Triple helix that can be up to 420 nm long

Question 8

What are glycine residues?

Answer 8

Make up the core of the collaen fibre
They are small, allowing for tight packing of the helices

Question 9

What is the triple helic fibres made of in collagen?

Answer 9

The triple helix fibres can be made of identical chains (called homotrimers). There are also heterotrimers that use 2 or 3 different chains

Question 10

How many collagens are there in the body?

Answer 10

Over 20 different collagens in humans
Over 100 other protein that have collagen gene triple repeating segments within them

Question 11

What does a real collagen have to have?

Answer 11

Other proteins are also triple helixes, but to be a real collagen the protein must form fibres or other structures in the extracellular matrix

Question 12

What are the 3 main types of collagen structures?

Answer 12

1. Fibrillar Collagens
2. Sheet-forming Collagens
3. Anchoring/linking Collagens

Question 13

What are the features of fibrillar collagens?

Answer 13

300nm long
Strong, but flexible

Question 14

How can fibres in fibrillar collagens be seen?

Answer 14

Fibres can be seen in a:
Loose netowrk (eg. connective tissue in the intestine) has a higher proportion of loose ground substance [more water] than collagen
Dense network (tendon) less ground substance, or anything in between
Used to reinforce all of the tissues in the body

Question 15

What kind of collagen does the eye have?

Answer 15

Fibrillar Collagens
Layers of orthogonal fibres (fibres at right angles).
Vitrous body (and cartilage) has glycosaminoglycans and proteoglycans trapped within the collagen

Question 16

What do fibrillar collagens do in the eye?

Answer 16

Allows enough water to be retained in those structures to allow light to pass through and to resist compression

Question 17

What are fibrillar collagens?

Answer 17

Usually form heteropolymers in vivo with 1 other collagen
Are conserved from sponges to vertebratesm

Question 18

What are the general steps for formation of fibrillar collagen?

Answer 18

Fibroblasts make Collagen 1 and release it from the cells using exocytosis

Question 19

How is collagen 1 made?

Answer 19

Very long (42 exons) collagen 1 genes encode collagen 1 chains
Preprocollagen translocates to the rough ER

Question 20

What happens in the ER?

Answer 20

The signal sequence is removed (often referred to as pro collagen)
Sugars are added to the protein
Folding of the proteins begins

Question 21

How is the protein folded?

Answer 21

The protein is folded into the long procollagen triple helix and secreted from the ER using COPII vesicles that are modified by accessory proteins to fit the large (>300nm) fibrils

Question 22

What happens once the protein is secreted?

Answer 22

Once secreted from the cell, other enzymes called matrix metalloproteinases (NMPs) cleave the pro-collagen into pieces resulting in collagen

Question 23

Does collagen self-assemble itself?

Answer 23

Collagen self-assembles into fibrils that have a 67nm stagger and are usually covalently crosslinked (at their lysines) by the enzyme lysyl oxidase to give the high tensile strength of the collagen fibrils

Question 24

What are sheet-forming collagens?

Answer 24

Form sheets instead of fibrils that wrap around organs or tissues (basal lamina), or whole animals (Eg. cuticle of earthworms)

Question 25

What are linking collagens?

Answer 25

These are collagens that link Fibrillar and Sheet-Forming collagens to other structures

Question 26

What are elastic fibers?

Answer 26

Fibers that act like rubber band
Give organs the ability to recoil after being stretched
(Eg. arteries, skin, lungs have a alot of elastic fibres)

Question 27

What are elastic fibers made by?

Answer 27

Made by embryonic and juvenile fibroblasts (so the elastic fibers that you are born with are the ones you have for life, they turn over very slowly if at all)

Question 28

How long do elastic fibers survive for in your arteries?

Answer 28

Elastic fibers in your arteries will survive over 2.5 billion stretch-recoil cycles during your life

Question 29

What are elastic fibers formed of?

Answer 29

Formed of Fibrillin microfibrils that are a scaffold for the protein Elastin to bind to (look at picture in PP)

Question 30

How many Fibrillin genes do humans have?

Answer 30

Humans have 3 genes

Question 31

Where is Elastin made?

Answer 31

Only made in vertebrates, but insects and molluscs have evolved different proteins to make elastic-type fibers

Question 32

How many Elastin genes do humans have?

Answer 32

Humans have 1 gene, alternatively spliced

Question 33

How are elastin proteins linked?

Answer 33

Elastin proteins are covalently linked to one another through the actions of the Lysyl Oxidase enzyme

Question 34

How does elastin stretch?

Answer 34

The segments between the cross-linked elastin protein segments align with other when stretched (look at picture in PP)

Question 35

What does stretched elastin mean?

Answer 35

Stretched, high energy, low entropy

Question 36

What are glycosaminoglycans (Gags)?

Answer 36

Long polysaccharides

Question 37

What are proteoglycans?

Answer 37

Proteins that are colavently post-translationally modified with Glycosaminoglycans

Question 38

Where are proteoglycans made?

Answer 38

Made in all vertebrate cells

Question 39

Where are proteoglycans secreted?

Answer 39

Usually secreted into the ECM

Question 40

What are proteoglycans a major part of?

Answer 40

Cartilage
Loose connective tissue
Basement membranes

Question 41

What is the length of proteoglycans?

Answer 41

Vary in length and sequence for the sugar groups

Question 42

What is the function of proteoglycans in the ECM?

Answer 42

Thought to be in the CM to trap water
Can attract up to 50g of water per gram of proteoglycan

Question 43

What is Hyaluronan (AKA. Hyaluronic Acid?

Answer 43

It is the largest glycosaminoglycan (so its a string of sugars) (20,000 disaccharide repeats) that is released extracellularly
When hydrated it has a diameter of ~200nm (huge)

Question 44

Is Hyaluronan post-translationally modified?

Answer 44

No, it is NOT post-translationally modified
It is a crucial element of cartilage
Can block microbes in other tissues

Question 45

What are some other interesting facts of Hyaluronan?

Answer 45

Hyaluronan and other Gags act as lubricants for joints
Are in the ey and are transparent
High levels might protecr from cancer (Eg. Naked mole rats live very long [31 years] as compaed to other rodents [Eg. mice, 4 years])

Question 46

What are adhesive glycoproteins?

Answer 46

Are though to control interactions between proteins and sugars in the ECM
Bind to integrins within the cell

Question 47

What are 2 well studied examples of adhesive glycoproteins?

Answer 47

1. Fibronectin
2. Tensactin

Question 48

What is fibronectin?

Answer 48

Large (245 kDa) v-shaped proteins linked at their C-termini by disulfide bonds

Question 49

What does fibronectin bind to?

Answer 49

Binds to a lot of things:
Collagen
Cell surface receptors
Proteoglycans
Other proteins

Question 50

What are the 2 types of fibronectin?

Answer 50

2 types (alternatively spliced forms):
1) Tissue fibronectin
2) Plasma fibronectin

Question 51

What is tissue fibronectin?

Answer 51

Makes insoluble fibrils in connective tissue
Used during wound healing

Question 52

What is plasma fibronectin?

Answer 52

In body fluids
Used for blood clots

Question 53

What is tesactin?

Answer 53

Found in all vertebrates
Not in invertebrates

Question 54

What does tensactin do?

Answer 54

N-termini form 3 subunits self associate
Disulfide bonds link 2 of the 3 unit arms together to form a 6 arm protein

Question 55

What is tensactin found in?

Answer 55

Found in:
Embryonic tissues
Wounds
Tumours

Question 56

What does tensactin bind to?

Answer 56

Fibronectin
Integrins
Proteoglycans
Immunoglobulin-superfamily receptors (in the cell surface)

Question 57

What is the basal lamina?

Answer 57

A 2-dimensional, thin arrangment of ECM proteins
Lies very close to the plasma membrane

Question 58

What does the basal lamina form?

Answer 58

Forms a layer under all epithelia
Wraps around muscle cell (Sarcolemma)

Question 59

What can the basal lamina do?

Answer 59

They can filter macromoleucles (eg. filtering blood plasma into urine in kidneys)

Question 60

How does the basal lamina attach to the connective tissue by?

Answer 60

Collagens
Basal lamina + collagens =
Basement membrane

Question 61

What is laminin?

Answer 61

Another protein in the basal lamina

Question 62

What does lamina bind to?

Answer 62

Binds to integrins

Question 63

How does laminin self-assemble?

Answer 63

Self-assembles into a 2D network by binding non-covalently to other laminin

Question 64

What is laminin secreted by?

Answer 64

It is secreted by muscle and epithelial cells

Question 65

How is laminin layed out with collagen?

Answer 65

The 2D laminin and collagen networks lie parallel to one another and are reinforced by other proteins:
Eg. nidogen attached laminin to collagen
Perlecan binds to itself, laminin and collagen

Question 66

What do the cross links in basal lamina provide?

Answer 66

1) The size selectivity of the basal lamina to filter macromolecules
2) A barrier for cell migration (until enzymes [eg. matrix metalloproteinases] degrade the basal lamina… this happens during cancer tumour metastasis)
3) The mechanical support to the cells/tissues
Force transmission
Cells –> basal lamina –> connective tissue
Eg. (muscle cell contracti9on –> basal lamina –> tendons)

Question 67

What are matric metalloproteinases (MMPs)?

Answer 67

Used to breakdown the ECM

Question 68

How many members of metalloproteinases are there?

Answer 68

24 members

Question 69

What kind of domain do metalloproteinases have?

Answer 69

Have a zinc protease domain

Question 70

What does the autoinhibitory propeptide do in metalloproteinases?

Answer 70

The autoinhibitory propeptide binds to the zinc ion in the catalytic domain of the enzyme.

Question 71

Where does substrate specificity come from?

Answer 71

Substrate specificity comes from a regulatory domain at the C-terminus

Question 72

Are there also fibronectin domains in many of the MMPs?

Answer 72

Yes. There are 3 of them

Question 73

What do metalloproteinases bind to?

Answer 73

They usually bind to membrane receptors.
Some dock into the plasma membrane using a C-terminal trans-membrane domain

Question 74

Is metalloproteinases selective?

Answer 74

Yes, each MMP is selective and cleaves specific components of the ECM resulting in:
1) Weakening of the ECM
2) Release of bio-active protein fragments