12-10-21 - Cell adhesion and Extracellular Matrix

Question 1

What are the 6 main cells in connective tissues?

Answer 1

• Fibroblasts – production of the ECM of connective tissues
• Myofibroblasts – wound healing, and specifically contraction of wound
• Blood derived (visitor cells) – mast cells, plasma cells, macrophages
• Chondroblasts – cartilage
• Osteocytes – bone
• Adipocytes – fat cells

Question 2

What is the extracellular matrix?

What is it composed of?
4 proteins embedded in what/

Answer 2

• The extracellular matrix is an extensive molecule network outside the cell.
• It is composed of:
• Fibrillar proteins:
• Collagen – allows for strength
• Elastin – stretch
• Fibronectin and laminin – linking proteins
• All of these proteins are embedded in polysaccharides glycosaminoglycan gel (GAGs), with the GAGs linked to proteins at the appropriate places to form proteoglycans

Question 3

What is the function of fibroblasts?

How are collagen fibres formed?

What does the Fibroblast also do during this process?

Answer 3

• Fibroblasts synthesise and secret fibrillar proteins called collagen and elastin, as well as creating proteoglycans
• In the RER, 3 propeptides are used to form a triple helix, which is known as procollagen.
• Procollagen molecules are transported to the Golgi, where they are packaged in a secretory vesicle, and sent towards the plasma membrane.
• The procollagen molecule leaves the cell via exocytosis
• The loose ends are trimmed off the procollagen to form tropocollagen
• The tropocollagen are arranged in a quarter stagger model and linked through an enzyme catalysed reaction to form a microfibril, many of which are used to form a fibril.
• Many fibrils are used to create a collagen fibre
• The fibroblast is also creating GAGs during this process

Question 4

Why is procollagen secretion special in the Golgi?

How does the fibroblast physically assemble fibrils from tropocollagen? il vont poser

Answer 4

• Procollagen has to be packaged into specialised larger vesicles in the Golgi, as it is too big for regular vesicles.
• Fibroblasts are oriented along the tendon,
• They crawl along, and secrete a tropocollagen cable behind them using a fibropositor in order to make fibrils.

Question 5

What is elastin?

who creates elastin ?

What are they made from?

How are they able to recoil?

Answer 5

• Elastin’s are another fibrous protein which are secreted by fibroblasts, smooth muscle cells, and chondroblast
• Elastin fibres are composed of aggregations of many elastin chains
• The elastin contains hydrophobic elements within it, so when it is stretched, it recoils in order to get these hydrophobic areas away from the aqueous environment

Question 6

What are proteocoglycans made from?

What 4 things do proteoglycans contribute to extracellular matrix?

Answer 6

• Proteoglycans are assemblies of glycosaminoglycans and proteins, which are linked together by link proteins
• Proteoglycans provide:
• Matrix support, cushioning, and hydration
• Glue-like function
• Links between proteins of ECM
• Links between ECM and cell surface

Question 7

What are GAGs? GAGSSSSS

How are they charged?

What are 2 features of them?

What are different example of GAG chains?

Answer 7

• Glycosaminoglycans are long chains of repeating disaccharide units
• GAGs are highly negatively charged and highly hydrated

Question 8

What are integrins?

what do they facilitate?

how do collagen and proteoglycans bind to integrin

how does integrin bind to the cytosqueleton

Answer 8

• Integrins are transmembrane receptors that facilitate cell to cell and cell to extracellular matrix adhesion.
• Collagen/proteoglycans can bind fibronectin (linking protein) that links to integrins
• Integrins bind to the actin cytoskeleton via adaptor proteins

Question 9

What properties of other cells do myofibroblasts have?

How are myofibroblasts formed?

What are 4 ways myofibroblasts are involved in healing?

Answer 9

• Myofibroblasts are fibroblasts like – they can secret collagen
• Myofibroblasts have smooth muscle like properties – they can contract using smooth muscle type actin-myosin complexes.
• Fibroblasts differentiate to myofibroblasts under mechanical tension

4 Ways myofibroblasts are involved in healing:
• Myofibroblasts can proliferate and rapidly increase in number
• They secrete collagen (scaffold)
• They consolidate damaged area (fibrous scar)
• Myofibroblasts can contract, which reduces the size of the damaged area and aids in healing (think of pulling a wound closed)

Question 10

What are mast cells?

Where do they come from?

What do they contain?

How do they aid in healing?
=> type of tissue

Answer 10

• Mast cells are progenitor cells. (Similar to stem cells)
• The originate in the bone marrow, travel to tissues, and differentiate to have granules
• These granules contain inflammatory mediators, such as histamine (anti-coagulant) and heparin (increases vascular permeability)
• When the appropriate stimulus is given, this causes the mast cell to degranulate and release the contents of its granules.

Question 11

What are plasma cells?
PB

What do they form from?

What is their function?

How can they be identified?
RECs

Answer 11

• Plasma cells are professional differentiated B-lymphocytes
• Their job is to make lots of anti-bodies through the secretory pathway
• Plasma cells have ER packed full of secretary component, which can be seen on photos.
  The also have a large amount of cytoplasm for antibody production

Question 12

What are macrophages?

What are their functions?

What do they secrete?

Answer 12

• Macrophages are monocytes in the tissue
• They phagocytose bacteria, secrete pro-inflammatory and antimicrobial mediators
• They also eliminate diseases and damaged cells through their programmed cell death.

Question 13

What are adipocytes?

What is their structure like? what happens to orgs

What are 4 adipocytes functions?
1. house
2. protection example
3. atp
4. secretion + ex

Answer 13

• Adipocytes are white fat cells
• They contain a lipid droplet, which occupies most of the cell
• This causes the organelles of the cell to be squished to the side
• Adipocytes provide insulation to the body
• Adipocytes are present in the eye to stop it from hitting bone
• Adipocytes can also act as an energy store
• Adipocytes also secretes adipokines, which send signals to regulate nutritional balance and other systems
• An example of this is the hormone leptin, which is a satiety signal.

Question 14

What are mice with mutant ob genes called?

What happens to these mice?

What happened when these mice were injected with leptin?

Why was this not the same in humans?

Answer 14

• Mice with mutant ob genes are called obob mice.
• The white fat in these mice doesn’t produce leptin
• This results in their being no satiety signal, which causes these mice to eat excessively and become obese.
• When these mice were injected with leptin, they stopped eating ferociously and became a normal weight.
• When this was tired in humans, little change occurred.
• This was due to the fact that the white fat of obese people was still producing leptin, but they had a reduced sensitivity of leptin (leptin receptors didn’t function)

Question 15

What are the functions of cell junctions/adhesion proteins?

Answer 15

• Cell junctions/adhesions link cells and their cytoskeleton to other cells, the extracellular matrix (ECM), and the basal lamina.

Question 16

What are the 3 functions of Tight junctions?

How can epithelia be classed depending on tight junctions?

What proteins determine this?

Answer 16

• Tight junctions define polarity in cells – influence shape, structure and function in a cell
• This is done by fencing off membrane lipids and proteins on one side of the cell from the other by zipping together cells with tight junctions = separating molecules
• Tight junctions can control the passage of substances between cells (controls the paracellular pathway)
• Tight junctions can link to the actin cytoskeleton
• Epithelia can be classed as tight or leakey, depending on the ability of the tight junctions to prevent water and solute movement through the paracellular pathway.
• Claudins are the transmembrane proteins of tight junctions
• There are 24 different types of claudins, which will provide the epithelium with a different permeability

Question 17

What is the function of adherens junctions? boat

What do they allow?

How do they achieve this?

What are some of the different cadherins in different tissues? VCC

Answer 17

• Adherens junctions are anchoring junctions, which anchors actin filaments at the membrane of cells via catenin (anchor)
• Anchoring junctions allow communications of the actin network of the cytoskeleton from cell to cell (often epithelial cells)
• Adaptor proteins called vinculins link to transmembrane proteins called catenins
• Catenin then goes through the membrane, and links to the other cell via cadherins, which attach on to the other cells cadherins

Question 18

What is the function of desmosomes?

How do they do this?

Answer 18

• Desmosomes provide a link between strong intermediate filaments in adjacent cells
• Intermediate filaments of a cell attach to plaque glycoproteins
• The plaque glycoproteins then connect to each other via desmosome specific cadherins

Question 19

What are gap junctions made of?

How do they link?

What are the 3 functions of the gap junction?

Where can gap junctions be found?

Answer 19

• 6 Connexin proteins make a connexon
• 3 connexons from one cell link up in pairs with 3 connexons from another cell to form a passage.
• The gap junction allows for communication between cells
• It is a hydrophilic channel that allows small molecules to pass through
• Gap junctions can also allow the coordination of function => gap junctions help cells work together more effectively by sharing small molecules and signals. This coordination is important for processes like muscle contractions and nerve signal transmission, where groups of cells need to respond together.
• The heart muscle has gap junctions

Question 20

What are focal adhesions?

What do they do?

What does this allow the cell to do?

What can focal adhesions also act as?

Answer 20

• Focal adhesions are macromolecular assemblies that act as strong spots for linking the ECM to the actin filaments of the cytoskeleton through transmembrane proteins called integrins.
• These adhesions to the ECM allow the cell to grip and crawl during migration
• Focal adhesions can also act as signalling platforms

Question 21

What are hemidesmosomes?

What are they used for?

How is this different than what focal adhesions do?

Where might this be found?

Answer 21

• Hemidesmosomes are a junctional complex
• They link the ECM of the cell to the intermediate filaments of the cytoskeleton of the cell through transmembrane proteins called integrin
• This is more stable than focal adhesions
• It can be found linking epithelial cells to laminin the basement membrane through integrins and intermediate filaments

Question 22

What is dystrophin?

What causes Duchenne’s Muscular Syndrome? => kind of mut

How does DMS affect mobility?

What is used to treat DMS?

Answer 22

• Dystrophin is an adaptor protein that links integrin to the actin/intermediate filaments of the cytoskeleton.
• Duchenne’s muscular syndrome is cause by a gene mutation, which results in the absence of dystrophin in muscle cells due to premature termination of translation.
• This premature termination is causes by a premature stop signal during translation
• DMS results in muscle weakness and wasting, which causes the patient to be unable to walk by the time they are 12.
• PTC 124 (ataluren) is a drug that overrides the premature stop signal mutation to produce regular dystrophin

Question 23

Describe the first stages of cell adhesion in cancer stages

Answer 23

• Tumour cells accumulate, due to mutations causing a dysregulated cell cycle
• Cells have not yet breached the basement membrane
• Carcinoma in situ (carcinoma – cancer in epithelial tissue of skin/lining internal organs) (situ – in place)

Question 24

Describe the 5 stages of cancer microinvasion

CMEBI

Answer 24

Here’s a summary in clear steps:

1. Cell Conversion: Cells begin to change into mesenchymal cells, reducing the expression of cadherins, which allows for greater movement.
2. Microinvasion: The process of microinvasion starts, aided by structures called invadipodia that help cells push through.
3. Enzyme Secretion: Cells secrete metalloproteinases, enzymes that break down proteins like collagen in the tissue spaces.
4. Basement Membrane Breach: The basement membrane, which supports tissues, is now penetrated.
5. Integrin Expression: Invading tumor cells express integrins, which helps them interact with the extracellular matrix (ECM) and other non-epithelial cells as they move.

Question 25

What is metastases?

Describe the progression of cancer to metastasis

1. def
2. how is it more mobile
3. angie
4. where do cells go
5. metastatic cancer

Answer 25

Here’s a summary in clear steps:

1. Metastasis Definition: Metastases refer to the formation of secondary malignant growths away from the original cancer site.
2. Autocrine Motility Factors: Tumors secrete autocrine motility factors that reduce e-cadherin expression, making cancer cells more mobile.
3. Angiogenesis Promotion: The tumor secretes angiogenesis factors that stimulate the formation of new blood vessels, providing nutrients to the tumor. (Note: Anti-cancer drugs like VEGFs can block this process.)
4. Cell Entry into Vessels: Malignant cells enter and travel through lymphatic and blood vessels.
5. Dissemination: The cancer spreads to other parts of the body, marking the progression to metastatic cancer.