Lecture 3: Healing

Question 1

Mention and describe the three types of tissue based on their proliferative capacities.

Answer 1

• Labile tissue: constant proliferation to allow turnover
  
  • Example: hematopoietic cells, surface epithelia
• Stable tissue: quiescent, but proliferation can be activated
  
  • Example: parenchyma of most solid organs, endothelial cells, fibroblast
• Permanent tissue: no proliferation, injury is irreversible, repair leads to scar formation.
  
  • Example: Neurons, cardiac muscle cell

Question 2

Explain the mechanism of tissue regeneration in labile tissues.

Answer 2

Labile tissues such as the epithelial tissues, when injured, will be replaced by proliferation of residual cells and differentiation of cells derived from tissue adult stem cells.

Notes:

• Residual epithelial cells produce GFs.
• The newly generated cells migrate to fill-in the gap.
• Tissue integrity and function is restored.

Question 3

Explain the characteristics of tissue regeneration in stable tissues.

Answer 3

In parenchymal (functional) organs, cells are capable of proliferation, but usually a limited process (except for liver).

Restoration of normal tissue architecture (regeneration) only occurs if residual tissue is structurally intact (partial liver resection). If the entire tissue is damaged, the regeneration is incomplete and is accompanied by scarring (cirrhosis).

Question 4

Define interstitial matrix and basement membrane.

Answer 4

Interstitial matrix: synthesized by mesenchymal cells (eg. fibroblasts), forming an amorphous three-dimensional gel (collagens, fibronectin, elastin, proteoglycans…).

Basement membrane: highly organized around epithelial cells & endothelial cells

Question 5

Describe the two types of healing.

Answer 5

• Regeneration
  
  • occurs by the proliferation of cells that remain in tissue and survive the injury
  • retain the capacity to proliferate and tissue stem cells
  • e.g. skin epithelia, some parenchymal organs (liver)
• Connective tissue deposition (scar formation)
  
  • occur by the deposition of new connective tissue (structural stability)

Question 6

How is cell proliferation regulated?

Answer 6

• Cell-cell contact (damaged neighbouring cells, inflammatory cells)
• Cell –ECM (integrins)
• Paracrine or Autocrine factors (cytokines, hormones)
  
  • Receptors (cell surface)
  • Transcription factors (direct outcome on gene expression) - Growth factors

Question 7

Mention and describe examples of major GFs responsible fro cell proliferation.

Answer 7

• EGF/TGF alpha (epidermal growth factor)
  
  • enriched in macrophages, platelets, epithelial cells, tissue fluids & secretions
  • mitogenic for epithelial cells and fibroblasts
• PDGF (platelet derived …)
  
  • 3 isoforms - enriched in platelets, endothelial, smooth muscle, and tumour cells
  • proliferation and migration of fibroblasts, smooth muscle cells, monocytes - also pro-inflammatory
• FGF (fibroblast …)
  
  • large family of factors
  • enriched in macrophages, T cells, endothelial cells and fibroblasts
  • angiogenesis - migration during wound repair
  • development of skeletal muscle and lung
  • haematopoiesis
• HGF (hepatocyte …)
  
  • enriched in fibroblasts, endothelial cells, liver non-parenchymal cells
  • mitogenic for epithelial cells - liver, bile duct, lung, breast, skin
  • causes cell migration
  • required for survival during embryogenesis
• VEGF (vascular endothelial …)
  
  • enriched in fibroblasts and endothelial cells
  • induce blood vessel formation
  • bind to receptors in endothelial cells

Question 8

Recall the molecular mechanism of healing.

Answer 8

Question 9

Mention examples of second messenger pathways.

Answer 9

Question 10

Describe the process of transcription activation.

Answer 10

Transcription factors would bind DNA at specific recognition sequences in gene promoters. This would either activate or repress transcription initiation.

In repair/healing, the changes in gene expression generally lead to activation of proliferation and inhibition of differentiation.

Question 11

Describe the ECM.

Answer 11

• Reservoir of GFs
• Acts as scaffolding
• Consists of:
  
  • Interstitial matrix: in connective tissue, Synthesized by mesenchymal cells (e.g. fibroblasts), forming an amorphous three-dimensional gel (collagens, fibronectin, elastin, proteoglycans, hyaluronate).
• Basement membrane: highly organized to support epithelial cells, endothelial cells, and smooth muscle cells (nonfibrillar type IV collagen and laminin).

Question 12

Cell interactions with ECM are critical for ___________________, ___________________, and __________________.

Answer 12

• Mechanical support for cell anchorage and cell migration, and maintenance of cell polarity (collagen, elastins)
• Control of cell proliferation via growth factors and integrin signalling pathways, and is a reservoir of embedded growth factors (VEGF, FGF, HGF)
• Scaffolding for tissue renewal (proteoglycan, hyaluronan)

Question 13

Describe the structural fibers of ECM.

Answer 13

It consists of material such as elastin, fibrillin, and elastic fibres. It is found usually in blood vessels, skin, uterus, lung.

Question 14

Describe the importance of the adhesive protein in ECM.

Answer 14

Adhesive protein, such as fibronectin, is important for signal transduction (ECM => cell interior). Actin cytoskeleton is organised into focal adhesion complexes - which activate signal transduction pathways

Question 15

Describe proteoglycans in the ECM.

Answer 15

Proteoglycans consist of core protein + polysaccharide (glycosaminoglycans/GAGS). The polysaccharides are negatively charged, occupies a large volume, and hydrophilic. It can be found in all ECM, on the cell surface, and in biological fluids.

It regulates connective tissue structure and permeability as well as modulating cell growth and differentiation.

Question 16

Describe the Marfan Syndrome.

Answer 16

It is a connective tissue genetic disorder affecting the FBN1 gene that encodes Fibrillin-1. Tall stature and long limbs resulting in defects of the aorta and heart valves, lungs, eyes, skeleton,

Affected individuals exhibit increased chronic inflammatory disease since Fibrillin-1 regulates TGF-beta availability => inflammation

Question 17

How is neo-angiogenesis controlled?

Answer 17

Other endothelial cells

• VEGFs, PDGF, NO, prostaglandins

ECM

• Integrins
• Collagen debris

Inflammatory cells

• Prostaglandins (PGs), Angiopoietins (Ang), COX, NO
• Inflammatory cytokines

GF from activated cells (eg.epithelial cells & fibroblasts)

• EGF, FGFbeta
• TGFbeta
• VEGFA
• HIF‐1alpha

Question 18

Mention the factors influencing healing.

Answer 18

Question 19

_____________ is the most important GF in the control of angiogenesis.

Answer 19

Question 20

What is fibrosis?

Answer 20

Any abnormal deposition of connective tissue that occurs in chronic disease/inflammation.

Question 21

What is present in granulation tissue?

Answer 21

• Presence of neo-angiogenesis
• Reconstituted ECM
  
  • Scaffold for healing
    
    • migration and proliferation of fibroblasts at injury site
    • deposition of ECM

Question 22

Describes the mechanisms of fibrosis.

Answer 22

Question 23

Describe the process of wound maturation.

Answer 23

The change from vascular granulation tissue to avascular scar involves changes in the composition of the ECM (mainly collagen).

It involves the balance between the proliferation of fibroblasts (ECM synthesis) and activation of matrix metalloproteinases (degrade ECM).

Question 24

Describe the process of liver regeneration.

Answer 24

• In priming phase, cytokines (IL6, Kupffer cells) and act on hepatocytes to make the parenchymal cells competent to receive and respond to growth factor signals.
• In growth factor phase, growth factors (HGF, TGF‐α) act on primed hepatocytes to stimulate cell metabolism and entry of the cells into the cell cycle. During the phase of hepatocyte replication, more than 70 genes are activated => proliferation of almost all hepatocytes.
• In the termination phase, hepatocytes return to quiescence.

Question 25

Mention the steps of cutaneous wound healing.

Answer 25

1. Wounding activates coagulation pathways; the clot stops the bleeding and protects the wounded area.
2. Macrophages release proteolytic enzymes and begin to clear the debris.
3. Neutrophils are replaced by macrophages, and GT is synthesized by activated fibroblast (ECM), neoangiogenesis
4. Epithelial cells from both edges proliferate & migrate over the granulation tissue (GT).
5. Leukocyte infiltrates, edema, and angiogenesis are diminished
6. Scar is formed

Question 26

Describe the inflammatory phase of cutaneous wound healing.

Answer 26

• Haemostasis: starts with very first moments of injurt
  
  • Platelets play a key role by aggregating - also releases fibrin. cytokines, chemokines, and hormones
  • Vasocontriction - limit blood loss (pro-coagulants like prothrombin)
  • Platelet aggregation and vascular leaking => clot
  • Activation of platelets (degranulation) and release of chemotactic and GF (PDGF, proteases, serotonin, and histamine)
  • Chemokines released by platelet activation attract inflammatory cells
• Acute inflammation
  
  • Injured blood vessels leak transudate => oedema
  • Increased porosity of blood vessels - facilitates the entry of inflammatory cells like neutrophils
  • Inflammation prevents infection - damaged cells and pathogens removed form wound area

Question 27

Describe the proliferation phase of cutaneous wound healing.

Answer 27

Fibroblasts migrate, proliferate and (some) differentiate

• They then synthesize “immature” ECM that allows the strength of tissue (type III collagen, fibronectin)
• Secrete factors (FGFs, TGF-beta) and ECM factors (integrins), and angiogenic factors (VEGF) that regulates cell proliferation and neo-angiogenesis
• Contractile fibroblasts pull collagen fibres together - type I collagen that re-enforces contraction

Note: Acute inflammation still on M2 macrophages (TGF-beta - stimulates fibroblasts + epithelial + endothelial cells)

Question 28

Describe the proliferation phase of cutaneous wound healing in the case of re-epithelialisation.

Answer 28

Starts when the new GT provides support for epithelial cells migration

1. Transformation: epithelial cells become less differentiated, more SC-like (loose cell-cell contact and change shape)
2. Proliferation
3. Migration: newly formed cells migrate along a newly synthesized basement membrane
4. Epithelial migration ceases with contact inhibition with other wound edges
5. Epithelial cells differentiate (keratinisation, desquamation scales)

Question 29

Describe the process of angiogenesis in the proliferation phase.

Answer 29

It involves endothelial cell activation and separation of pericytes from the vessel walls. The M2 macrophages and the endothelial cells secrete proteases (collagenases, MMPs) to break down existing vascular basement membrane.

Epithelial cells are then activated and attracted by GF (NO, VEGF). They then proliferate and detach from the vascular wall, degrade, and invade the ECM (guided by FGFs secreted by fibroblasts, integrins).

The sprouts extend in length until they encounter another cell (chemoattraction, Notch signalling). Then, endothelial proliferation and migration stop (PDGF, TGF-b), along with new deposition of the basement membrane and new pericytes. (Ang 1, 2)

Question 30

Why is angiogenesis important in repair?

Answer 30

Due to the activity level of fibroblasts, inflammatory cells, and EC, all of them requires oxygen and nutrients to function. Hence, angiogenesis is imperative to sustain proliferation, migration, and differentiation.

Question 31

Describe the maturation phase of the cutaneous wound healing.

Answer 31

In this phase, the granulation tissue is remodelled and shrinks. Cells organize their surrounding connective tissue matrix and lead to scar formation. Fibroblasts replace type III collagen into dense type I collagen. The mature orientation of collagen fibres allows tensile strength (provided by the contractile activity of myofibroblasts). FIbres are organised along the lines of tension and crosslinked - to allow strong wound.

Fibroblasts become less proliferative and eventually vascular regression leads to an avascular scar. New basement membrane also created under regenerated epithelium.

The connective tissue are also remodelled by matrix metalloproteinases (MMPs), such as collagenases (MMP-1, 2, 3), gelatinases (MMP-2, 9), and stryomelins (MMP-3, 10, 11). MMPs activation is regulated by proteases (e,g, plasmin) and inactivates by specific tissue inhibitors (TIMPs).