Molecular Patterning During Development

Question 1

How does the embryo predict a description of its future adult form?

Answer 1

It does not

Rather it contains a generative program for making it

Question 2

Discuss cell differentiation

Answer 2

• Process by which embryonic cells become
different from one another
• Involves the emergence of cell types such as muscle, nerve, skin and fat cells
• Is the achievement of a stable terminal state (not just transitory differences)
• Is characterized by the profile of proteins in that cell

Question 3

Discuss the hierarchy of stem cells in regards to their potency

Answer 3

(Totipotent and pluripotent also make copies of themselves)

Totipotent
I
V
Pluripotent
I
V
Multipotent

Question 4

What is potency?

Answer 4

The entire repertoire of cell types a particular cell can give rise to in all possible environments

Question 5

Define totipotency

Answer 5

‘toti’ = whole. eg. Cells of the very early mammalian embryo; identical and unrestricted; can give rise to any cell of the body (EMBRYONIC)

Question 6

Define pluripotent

Answer 6

‘pluri’ = more. eg. Inner cells of the blastocyst; less potent; can give rise to many cell types but not all (EMBRYONIC)

Question 7

Define multipotent

Answer 7

‘multi’ = many. e.g. Blood stem cells;

they give rise to cells that have a particular function (ADULT)

Question 8

In each level of decision that restricts cell fate cells become committed. In what two stages dos commitment occur?

Answer 8

First stage: specification (reversible)
Capable of differentiating autonomously if placed in isolation BUT can be respecified if exposed to certain chemicals/ signals.

Second stage: determination (irreversible)
Cell will differentiate autonomously even when exposed to other factors or placed in a different part of the embryo.

Question 9

How does a naive cell become specified?

Answer 9

Intrinsic signal – cell autonomous signal tells the cell ‘who is it’

Extrinsic signal -a chemical or molecule in the environment gives the cell spatial information, tells the cell ‘where it is’

Question 10

What is cell fate?

Answer 10

The fate of a cell describes what it will become in the course of normal development.
When a cell “chooses” a particular fate, it is said to be determined, although it still “looks” just like its undetermined neighbours. Determination implies a stable change - the fate of determined cells does not change.

Question 11

What causes the change from a naive cell to a specified cell?

Answer 11

Cytoplasmic determinants or induction

Question 12

Describe the change from specified to determined cell

Answer 12

Loss of competence for alternative fates

Question 13

Describe the change from determined to differentiated cell

Answer 13

Cell specific gene expression

Question 14

What is competence in cell development?

Answer 14

Ability of a cell to respond to the chemical stimuli.

A cell can lose competence by changes in surface receptor or intracellular molecules

Question 15

What is the mechanistic basis of fate decisions?

Answer 15

Bivalent chromatin

Question 16

How early are cell fate decisions made?

Answer 16

As early as the four-cell stage

Question 17

How many specific regulatory proteins make the many cell types of the body?

Answer 17

Only a few but with different combinations along generations

Question 18

What is another term for developmental regulatory genes?

Answer 18

Transcription factors

e.g. HOX, SOX, T-box

Question 19

Describe the process of therapeutic cloning

Answer 19

Creation of ES cells by somatic cell reprogramming

Cells isolated from patient
Nucleus removed from egg cell
Transfer of nucleus from patients cells to the egg
Egg cell will ‘reprogram’ patients DNA
Cell is stimulated to begin division, it is left to divide until the blastocyst stage
Inner cell mass is isolated from the blastocyst and grown in a dish

Question 20

Describe somatic cell reprogramming by defined factors (creation of iPS cells)

Answer 20

Skin or fibroblasts isolated from patient and grown in dish

Cells treated with reprogramming factors

Wait a few weeks

Pluripotent stem cells are produced

Culture conditions may now be changed to stimulate cells to differentiate into a variety of cell types

Question 21

What is a pentadactyl limb?

Answer 21

A limb with 5 digits

Question 22

What is the radiological relevance endochondrial ossification?

Answer 22

Radiologists can determine the skeletal age of a patient by examining the development of epiphyseal plates

Question 23

Describe the process of endochondrial ossification

Answer 23

A ‘soup’ of cells known as mesenchyme from a group

Mesenchyme differentiates into cartilage in the shape of the to-be bone

Cartilage is pushed to the longitudinal poles of the developing bone as osteoblasts form a primary ossification site in a core of bone surrounded by proliferating chondrocytes and a vascular supply reaches the bone (WEEK 12)

The bone continues to develop, with defined growth plates and secondary ossification centres in the heads of the bone (AT BIRTH)

Question 24

Discuss intramembranous ossification

Answer 24

Intramembraneous ossification is the formation of bone in fibrous connective tissue (which is formed from condensed mesenchyme cells)
The process occurs during the formation of flat bones such as the mandible and flat bones of the skull

Question 25

What is mesoderm broadly?

Answer 25

Mesoderm is one of the early embryonic germ layers ectoderm, mesoderm, endoderm

Question 26

What is mesenchyme?

Answer 26

Mesenchyme is generalised embryonic connective tissue derived from mesoderm

Question 27

Discuss HOX genes pattern in the body axis

Answer 27

Hox genes are a related group of genes that are expressed along the long axis of the embryo from head to tail.
They are ancient (highly conserved) genes and are therefore present in many animal groups. They have been extensively studied in Drosophila melanogaster

Question 28

Discuss Limb Development

Answer 28

During embryonic development HOX genes determine the body axis and the position of the limbs along the body axis - Intrinsic factors
The products of HOX genes belong to a class of proteins known as transcription factors, which bind to DNA, and thereby regulate the transcription of other genes (e.g. TBX5, TBX4).
Once the cranio-caudal position is set, limb growth is regulated along three axes:

1. Proximo-distal axis
2. Antero-posterior axis
3. Dorso-ventral axis

Question 29

When and where do upper limb buds appear?

Answer 29

Upper Limb buds appear on approximately day 24 between somites C5-T1

Question 30

When and where do lower limb buds appear?

Answer 30

Lower limb buds appear on approximately day 28 between somites L1-S2

Question 31

When are all major components of the limbs present?

Answer 31

By week 8 all major components of the limbs are present

Medial rotation of the LL is complete

Question 32

Discuss rotation of the limbs

Answer 32

• Development of fore and hind limbs is similar
• In week 7 the forelimbs rotate 90° laterally and the hind limbs
rotate 90 ° medially.
• Results in the flexor compartments being anterior in the upper limb
and posterior in the lower limb
• The sole of the foot is equivalent to the palm of the hand
• Big toe (hallux) is equivalent to the thumb (pollux)

Question 33

What is proximo-distal development controlled by?

Answer 33

Apical Ectodermal Ridge AER

Question 34

What do limb buds consist of?

Answer 34

• Core of mesenchyme derived from parietal layer of lateral plate mesoderm
• Ectoderm which forms the outer covering of the limb (epidermis)
• Ectoderm is thickened at the ‘apex’ of the developing limb to form the Apical Ectodermal Ridge (AER)

Question 35

What does AER control?

Answer 35

Proximo-distal development

Question 36

Discuss the Apical Ectodermal Ridge (AER)

Answer 36

• The AER is a key structure in limb development
• It induces the underlying tissue to remain as a population of undifferentiated, rapidly proliferating cells- known as the PROGRESS ZONE
• As cells move further away from the AER they will begin to differentiate into cartilage and muscle
• This differentiation results in proximo-distal development

Question 37

Discuss AER Proximo-distal development

Answer 37

1 HOX-8 controls the position of the limb
on the long axis of the body
2 Initiation of outgrowth of the fore limb is
controlled by the TBX5 gene and FGF-10
3 AER secretes FGF4 and FGF8 to maintain the progress zone and the further development of the proximo- distal axis
4 As growth progresses, mesenchymal cells are left behind the advancing ridge (and its influence) and so they begin to differentiate

Question 38

What controls the development of the anterograde-posterior axis (Cranio-caudal axis)?

Answer 38

Zone of Polarizing Activity (ZPA)

Question 39

Discuss the Zone of Polarizing Activity (ZPA)

Answer 39

The antero-posterior axis iiis regulated by the Zone of Polarizing Activity (ZPA)
Cluster of cells near the posterior border of the limb form the ZPA which regulates the AP axis
It ensures that the thumb grows on the cranial (anterior) side of the limb bud
ZPA expresses the protein sonic hedgehog (SHH). ZPA moves distally with the AER
Expts. in chicks show that adding a ZPA to the limb bud results in mirror image duplication of digits

Question 40

Discuss the development of the doors-ventral axis

Answer 40

BMPs in the ventral ectoderm induce EN1

EN1 represses WNT7 restricting its expression to the dorsal limb ectoderm

WNT7 induces LMX1 which then specifies the cells to be dorsal

Question 41

What determines the shape of bones?

Answer 41

Hox Genes

Question 42

Discuss Hox Genes determining the shape of bones

Answer 42

Variations in the combinations of HOX genes ensure that the:
• Upper and lower limbs are different TBX5 (upper limb), TBX4 (lower limb)
• Patterns for the proximal (arm) middle (radius and ulna) and distal (hand) are
defined
Expression of the HOX genes is dependent on SHH, FGFs and WNT7a

Question 43

What is the importance of apoptosis in limb development?

Answer 43

To ‘cut away’ unneeded areas such as the webs between fingers and toes

Question 44

Discuss incidence of limb defects

Answer 44

• Congenital heart defects are the most common non- chromosomal malformation (6.5 /1000)
• Limb malformations occur in approx. 3.8/1000 live births
• UL abnormalities more common that LL
• Limb defects are often associated with other abnormalities
affecting CVS, GU system and craniofacial structures
• Amelia complete absence of the limbs
• Meromelia partial absence of the limbs
• Phocomelia absence of long bones
• Micromelia segments are abnormally short
• Cause may be hereditary but also by environmental (teratogens)
• Affects the progress zone with failure of cell division (weeks 4&5)

Question 45

What is Amelia?

Answer 45

Complete absence of the limbs

Question 46

What is Meromelia?

Answer 46

Partial absence of the limbs

Question 47

What is Phocomelia?

Answer 47

Absence of long bones

Question 48

What is Micromelia?

Answer 48

Limb segments are abnormally short

Question 49

Discuss the thalidomide tragedy

Answer 49

Between 1957 and 1962 in the UK, Canada, Germany, Japan thalidomide was prescribed as a sleeping pill. An increase in the incidence of limb abnormalities was reported …..
12,000 babies survived, with phocomelia (flipper-like arms or legs) associated also with intestinal atresia and cardiac abnormalities
Phocomelia or amelia

Question 50

What is Holt Oram Syndrome?

Answer 50

Holt Oram Syndrome-TBX5 mutations lead to defects in limb development
Upper limb deformities, heart defects

Question 51

What is Brachydactyly?

Answer 51

Short digits

Question 52

What is Syndactyly?

Answer 52

Fused digits - failure of apoptosis (1 in 2,000 births)

Question 53

What is Polydactyly?

Answer 53

Extra digits

Question 54

What is Cleft Foot?

Answer 54

‘lobster claw’ deformity. - Cleft down centre