Chondrogenesis

Question 1

What are the 3 embryonic origins of BONES?

Answer 1

1) Cranial neural crest cells
2) Somites
3) Lateral mesoderm

Question 2

What bones do the cranial neural crest cells give rise to?

Answer 2

The craniofacial skeleton

Question 3

What bones do the somites give rise to?

Answer 3

The axial skeleton

Question 4

What is the axial skeleton?

Answer 4

Trunk - ribs and vertebrae

Question 5

What does the lateral mesoderm give rise to?

Answer 5

The limb (appendicular) skeleton

Question 6

What do Hox genes do?

How?

Answer 6

Control the anterior-posterior patterning of somites

How?
- Organised in sequential expression in the embryo in AP fashion

• Determines a CODE that is read by cells - provides positional identity to cells
• Tells the cells what type of vertebrae to become

Question 7

What does the hox code dictate?

Answer 7

The TRANSITIONS between the different types of vertebrae

Question 8

What is the transition between the cervical and thoracic vertebrae determined by in the mouse/chick?

Answer 8

Hox c5

Hox c6

Question 9

Why does the chick have more cervical vertebrae than the mouse?

Answer 9

Boundary between Hox c5 and Hox c6 is shifted more anteriorly in the mouse

Question 10

How many cervical vertebraes do mammals have?

Answer 10

7

Question 11

How do mammal vertebrae differ?

How is this controlled?

Answer 11

Differ in size

Controlled by hox genes:
- Control the genes that are involved in cell proliferation

Question 12

What genes do hox genes control?

Answer 12

• Genes that control positional identity

- Genes that control proliferation

Question 13

What are the 3 steps leading to AXIAL skeleton formation?

Answer 13

1) Scelerotome induction in the somite
2) Cartilage formation
3) Ossification of axial skeleton

Question 14

Where are the sclerotome precursors in the somite?

Answer 14

In the VENTRAL part

Question 15

What does the sclerotome form?

Answer 15

Cartilage and bone

Question 16

What is chondrogenesis?

Answer 16

The formation of cartiladge

Question 17

What is osteogenesis?

Answer 17

The formation of bone (ossification)

Question 18

What are the stages of chondrogensis?

Answer 18

1) Start with a MULTIPOTENT cell in the somite
2) Cell becomes SPECIFIED to become a SCLEROTOMAL cell
3) Cell DETERMINED to specific lineage - CHONDROBLASTS
4) Cell DIFFERENTIATES to CHONDROCYTES
5) Cell undergoes MATURATION - to form HYPERTROPHIC CHONDROCYTES

Question 19

What are the first cell types of cartilage?

Answer 19

Chondroblasts

Question 20

What are pax genes?

Answer 20

Paired-box genes

Question 21

What pax genes are involved in the formation of cartilage?

How is this different to muscle?

Answer 21

Cartilage:

• Pax 1
• Pax 9

Muscle:
- Pax 3

Question 22

In sclerotomal tissue, where is pax 1 and pax9 expressed?

Where is pax1 more strongly expressed?

Pax 9?

Answer 22

In BOTH the medial and lateral sclerotome

Pax 1 - more medial

Pax 9 - more lateral

Question 23

What is the result of a Pax 1 KO?

Answer 23

Abnormalities in the vertebral column, sternum and scapula

Question 24

What is the result of a Pax9 KO?

Answer 24

Abnormalities in the skeleton of:

• Craniofacial
• Visceral
• Limb

Die shortly after birth

Question 25

Where is pax9 expressed?

Answer 25

• Cranial region
• Limbs
• Somites

Question 26

What is the result of Pax 1/9 KO?

What does this show?

Answer 26

COMPLETELY lack derivatives of the MEDIAL sclerotome

Shows:

• Functional redundancy
• Need at least one of Pax1 or Pax9 to go through axial skeleton formation

Question 27

What are the derivatives of the MEDIAL scelerotome?

Answer 27

• Vertebral bodies
• Intravertebral discs
• Proximal ribs

Question 28

What structures are unaffected in the Pax 1/9 KO?

Answer 28

• Distal ribs

- Neural arches

Question 29

What lead scientists to fate map where distinct regions of the axial skeleton arise from?

Examples?

Answer 29

The phenotype from the Pax1/Pax9 KO

Example:
- Loss of vertebral bodies, intravertebral discs and proximal ribs –> mean these structures are derived from the medial and lateral sclerotome

• Remains of neural arches and distal ribs –> these structures do NOT arise from the medial or lateral sclerotome

Question 30

Where do the neural arches arise from?

Why?

Answer 30

From the DORSAL sclerotome

Doesn’t express pax1/9

Question 31

Where do the proximal part of the ribs derive from?

Answer 31

Lateral sclerotome

Question 32

Where does the vertebral bodies arise from?

Answer 32

Medial scelrotome

Question 33

Which parts of the ribs have a dermomyotomal origin?

Answer 33

• Distal parts of the rib

- Sternal ribs

Question 34

What parts have sclerotomal origin?

Answer 34

• Vertebral body
• Neural arches
• Proximal rib

Question 35

What are the signals that control sclerotome formation?

Answer 35

Extrinsic cues:

• Shh release from the notochord
• Diffuses into the ventral parts of the somite
• Induces Pax1 and Pax9 expression

Question 36

How do we know that shh induces the expression of Pax1 and Pax9 in the ventral somite?

Answer 36

KOs of shh cause the same defects as KOs in Pax1/Pax9

Question 37

How is transcription restricted to the sclerotome?

What else does this do?

Answer 37

• BMP4 INHIBITORS released from the lateral mesoderm, prevents the expansion of the pax1/9 domain
• Also contributes to the medial/lateral boundary by restricting pax1 diffusion into the lateral part of the somite

Question 38

What is the next step in the formation of bone, once have specification to sclerotome?

Answer 38

Cells must undergo determination and differentiation to form CARTILAGE

Question 39

How does a sclerotmal cell become determined and form a condroblast cell?

Answer 39

1) Migration of sclerotomal cells to around the notochord
2) Down regulation of Pax1 and Pax9
3) Up regulation of ECM proteins that are specific to cartilage and help with CONDENSATION of the cells

Question 40

Why is Pax1 and Pax9 down regulated when the sclerotomal cells are undergoing determination?

Answer 40

They are no longer needed as the scelrotomal cells are already specified

(Pax1 and Pax9 are only needed to SPECIFY)

Question 41

How is a chondroblast different to a chondrocyte?

Answer 41

Chondroblast - un-differnetiated cartilage cell

Chondrocyte - differentiate cartilage cell

Question 42

How go from a chondroblast –> chondrocyte?

Answer 42

1) Proliferation induced by BMP2, BMP4, BMP5

2) Production of a cartilage matrix (collagen)

Question 43

What does the production and secretion of a cartilage matrix require?

Answer 43

Sox9

Question 44

What is Sox9 proteins?

Answer 44

A HMG-box TRANSCRIPTION FACTOR

Question 45

What are the cartilage matrix proteins?

Answer 45

Collagen II

Collagen IX

Collagen XI

Question 46

Why does the sclerotome condense around the notochord?

Answer 46

In order to form a vertebrae

Question 47

What is osteogenesis/ossification?

Answer 47

The formation of bone

Question 48

What are the 2 main models for osteogenesis?

Answer 48

1) Intramembranous ossification

2) Endochondral ossification

Question 49

What is intramembranous ossification used for?

Answer 49

To form the bones of the skull

Question 50

Where does endochondral ossification occur?

Answer 50

In the SOMITES and LIMB skeleton

Question 51

What is the main difference between intramembranous ossification and endochondral ossification?

Answer 51

Intramembranous:

• FOLLOWING condensation of cells - don’t have differentiation into cartilage
• Differentiation STRAIGHT into osteoblasts

Endochondral:

• Cartilage forms
• Cartilage later REPLACED by bone

Question 52

What is the model for intramembranous ossification?

Answer 52

• Mesenchymal cells condense (NOT around the notochord)
• Nodules
• Osteoblasts
• Osteocytes
• Bone

Question 53

What is the process of endochondral ossification?

Answer 53

1) Start with tissue made of mesenchymal cells
2) Forms a CARTILAGE MODEL of the bone
3) Chondrocytes stop dividing and start becoming hypertrophic (increase in size)
4) Hypertrophic chondrocytes then DIE by APOPTOSIS - leaving a SPACE
5) Space left is invaded by BLOOD VESSES from the PERICHONDRIUM
6) Blood vessels bring in OSTEOBLASTS
7) SECONDARY OSSIFICATION in the epiphysis

Question 54

What is the pericondrium?

Answer 54

The connective tissue that surrounds the cartilage when it is not a joint

Question 55

What is the function of the osteoblasts that the blood vessel brings in?

Answer 55

Degrade the matrix (collagen)
AND
Deposit bone matrix

Question 56

What do the osteoblasts become after they have deposited bone matrix?

Answer 56

Bone marrow

Question 57

What is the epiphysis?

Answer 57

The end part of the bone

Question 58

What is the diaphysis?

Answer 58

The long part of the bone

Question 59

What is left after secondary ossification?

What is this structure known as?

Answer 59

A cartilage plate between the epiphysis and the diaphysis - that hasn’t been modified

Known as the GROWTH PLATE

Question 60

What is the growth plate important in?

Answer 60

Important in the POSTNATAL growth of bones

Question 61

What occurs during secondary ossification?

Answer 61

The same process as primary ossification:

• Chondrocytes –> hypertrophic chondrocytes
• Hypertrophic chondrocytes DIE
• Leave gap
• Gap invaded by blood vessels
• Blood vessels bring in osteoblasts
• Osteoblasts degrade the cartilage matrix and deposit bone matrix

Question 62

What studies helped us to understand how you maintain a balance between producing osteoblasts or chondrocytes from chondrocytes and how maintain balance between intramembranous or endochondral ossification?

Answer 62

Studies of human syndromes and studies in mice:

• CD
• CCD

Question 63

What is CD?

Answer 63

Campomelic dsplasia

Question 64

What is CCD?

Answer 64

Cleidocranial dysplasia

Question 65

What is CD a result of?

What does it cause?

What does this show?

Answer 65

Mutation in Sox9

Leads to the death of children at a young age:

• Defect in formation of cartilage and long bones
• Defect in intramembranous ossification

Shows:
- Sox9 occurs EARLY on in the COMMON STEP between intramembranous ossification and endocondral ossification (condensation of mesenchyme)

Question 66

What does the phenotype of So9 KO resemble?

What does this show?

Answer 66

Resembles mice with a KO of collagen II and collagen XI

Shows:
Sox9 is needed to induce the transcription of cartilage matrix

Question 67

Using conditional KO, what happens if KO Sox9 IMMEDIATELY AFTER the condensation?

What does this show?

Answer 67

Deficit in the formation of proliferative chondrocytes and bones

Shows:
Sox9 is required for the differentiation of the sclerotomal mesenchymal cells –> Chondrocytes

Question 68

What type of cells are chondroblasts?

Answer 68

Mesenchymal cells

Question 69

Using conditional KO, what happens if KO Sox9 immediately AFTER the formation of chondrocytes?

What does this show?

Answer 69

Perturbations in the maturation of chondrocytes into hypertrophic chondrocytes

Shows:
- Sox9 has a role by LIMITING how much MATURATION of chondrocytes occurs

Question 70

What causes CCD?

Answer 70

Mutation in transcription factor Runx2

Question 71

What do mutations of Runx2 cause in the human?

Answer 71

• Deficits in the formation of BONES and HYPERTROPHIC CHONDROCYTES
• But there is presence of CHONDROCYTES (not able to mature)

Question 72

What is Runx2 required for in the mouse?

Answer 72

The expression of the transcription factor Osterix

Question 73

What happens if KO Osterix in the mouse?

Answer 73

• NO defects in the formation of cartilage

- Defects in the formation of BONE

Question 74

What is the function of Runx2?

Answer 74

2 functions:

1) Controls the formation of cartilage by allowing chondrocytes to mature to hypertrophic chondrocytes
2) Controls ossification through the control of Osterix transcription factor (controls the formation of osteoblasts and osteocytes)

Question 75

What transcription factor is used to balance cartilage formation vs ossification?

Answer 75

Runx2

Question 76

What is the structure of the growth plate?

Answer 76

Layered organisation containing ALL the cell types:

• Proliferative chondrocytes
• Differentiated chondrocytes
• Pre-hypertrophic chondrocytes
• Hypertrophic chondrocytes
• Zone of ossification

Question 77

What ensures that bones will grow postnatally in a continuous manner?

Answer 77

The layered organisation of the growth plate
AND
How many cells are present in the growth plate

Question 78

How are the different cell types int he growth plate controlled and maintained as we grow postnatally?

How do these molecules interact?

Answer 78

Using 3 factors:

1) PTHrP - Parathyroid hormone-related protein
2) Ihh - Indian hedgehog
3) FGFR3 - Fibroblast growth receptor 3

FGFR3 —| Ihh —> PTHrP

Question 79

What do gain-of-function mutations in FGFR3 cause?

How?

Answer 79

Dwarfism

Promote the proliferation of chondroblasts
(Activate Ihh, which activates PTHrP, which activates the proliferation of cells and prevents the differentiation)

Question 80

What do mutations in PTHrP cause?

How?

Answer 80

Dwarfism

Failure to control MATURATION of chondrocytes into hypertrophic chondrocytes

Due to cells differentiating too quickly (loss of the progenitor pool)

Question 81

How do FGFR3, Ihh and PTHrP control the growth of bones?

Answer 81

1) Postnatally, as cells progress in the growth plate - PRE-HYPERTROPHIC CHONDROCYTES begin to express Ihh
2) Ihh acts on the pericondrium and promotes the release of PTHrP from the pericondrial cells
3) PTHrP diffuses into the area of the CHONDROBLASTS - preventing them from progressing and differentiating into CHONDROCYTES
4) Feedback loop promotes the PROLIFERATION of chondroblasts and PREVENTS their differentiation

Question 82

Why is it important to maintain the proliferation of chondroblasts and prevent their differentiation?

Answer 82

To maintain a POOL of PROGENITOR cells in the growth plate

Question 83

How do mutations in FGFR3 and PTHrP cause dwarfism?

Answer 83

• Drive cells to differentiate too quickly - prevent the maintenance of the progenitor pool

OR

• Get an excess of progenitors that are unable to differentiate