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BMS 242 - Principles of Developmental Biology COPY > Heart development > Flashcards

Flashcards in Heart development Deck (97)
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1
Q

Why are many different model organisms used when looking at the heart?

A
  • Different model organisms have different advantages

- Have different structures to their heart - show different developmental and evolution of the heart

2
Q

What is the structure of a 4-chambered heart?

A

2 atrium
2 ventricles
Separated by valves and septum
2 separate circulatory systems (pulmonary and body circuits)
Oxygenated and deoxygenated blood kept separate in the heart

3
Q

Which organisms have a 4-chambered heart?

A

Human
Mouse
Chick

4
Q

What is the structure of a 3-chambered heart?

A

2 atrium
1 ventricle
2 separate circulatory systems
Oxygenated and deoxygenated blood kept separate in the heart

5
Q

What organism has a 3-chambered heart?

A

Xenopus

6
Q

What is the structure of a 2-chambered heart?

A

1 atrium
1 ventricle
1 circulatory system
Blood from ventricle –> to gills (where becomes oxygenated) –> rest of body

7
Q

What organism has a 2-chambered heart?

A

Zebrafish

8
Q

What is the structure of a tubular heart?

A

Single tube

Lined with valves - promote blood flow in ONE direction

9
Q

What organism has a tubular heart?

A

Drosophila

10
Q

Where does the heart derive from in the human?

A

From the cardiogenic mesoderm

11
Q

What are the basics of how the heart develops in humans?

A

1) Cardiogenic mesoderm forms cardiac crescent
2) Cells within the cardiac crescent migrate towards the MIDLINE and COALESCE to form a SINGLE TUBE
3) Tube then undergoes highly ASYMMETRIC CARDIAC LOOPING to form the heart

12
Q

When is the cardiac crescent of the heart formed in humans?

A

2 weeks pf

13
Q

What does the cardiac crescent consist of at 2 weeks pf?

A

Mesodermal tissue and 2 endocardial tubes either side of the crescent

14
Q

When is the single heart tube in humans formed?

A

3 weeks pf

15
Q

How long does heart looping in the human take?

A

1 week

16
Q

At what point is the heart well-looped?

A

4 weeks pf

17
Q

Why is heart looping required?

A
  • To ensure the future chambers of the heart are well aligned
  • So, when the heat undergoes MATURATION - everything is in the right place
18
Q

What happens in the human during maturation of the heart?

A
  • Formation of the septa and valves

- Connection of the inflow/outflow tracts

19
Q

When is the heart well-formed?

A

7 weeks pf

20
Q

How is the development of the heart in the mouse different/same to in humans?

A

Quicker process but highly CONSERVED:
- Cardiac crescent formation at E7.5

  • Heart looping at E8.5 - E9.5
  • Well looped heart and emergence of chambers at E10.5
  • Mature, functional heart at E13
21
Q

What is the process of heart formation in the zebrafish?

A

1) Migration of 2 groups of precursors from the left and right sides of the heart tube to form the CARDIAC DISC
2) Cardiac disc undergoes EXTENSION to form the HEART TUBE
3) Heart tube undergoes looping

22
Q

Why is studying the formation of the zebrafish heart advantageous?

A

Everything happens very quickly - advantageous if looking at the very EARLY stages of heart development

23
Q

When does the cardiac disc in the zebrafish from?

A

20 hours pf

24
Q

In the zebrafish, where does the cardiac disc undergo extension to form the heart tube?

A

24 hours pf

25
Q

In the zebrafish, where does the heart tube undergo looping?

A

36 hpf

26
Q

In the zebrafish, when has the heart finished looping?

A

48hpf

27
Q

At 48hpf, what 2 things can be seen in the zebrafish heart?

A
  • Restriction of the atrioventricular canal

- Initiation of the formation of the valves

28
Q

What happens once the heart has formed?

A

Undergoes maturation

29
Q

Where do cardiac cells originate from?

A

2 separate origins (2 heart fields)

From the mesodermal tissues

30
Q

What are the heart fields?

A

2 separate sets of cardiac precursors that are specified very early on in development:

  • First heart field
  • Second heart field
31
Q

How are the 2 heart fields different from each other?

A
  • Very distinct spatial arrangement during morphological heart development
  • Contribute to very specific structures of the heart
32
Q

What structures do the FHF cells contribute to in the developed heart?

A
  • LEFT ventricle

- Left and right atria

33
Q

What structures do the SHF cells contribute to in the developed heart?

A
  • RIGHT ventricle
  • Left and right atria
  • Outflow tract
34
Q

Where are heart field cells specified?

A

Along the primitive streak (mouse)
OR
Along the embryonic margin (fish)

35
Q

What is the specification of the heart field cells controlled by?

A

Combinatorial MORPHOGEN signalling

36
Q

Describe the specification of FHF cells

A

1) Cardiac mesoderm subjected to NON-CANONICAL WNT signalling
2) BMP signalling

37
Q

Describe the specification of SHF cells

A

1) Cardiac mesoderm subjected to NON-CANONICAL WNT signalling
2) Beta-catenin and FGF signalling

38
Q

Once the cardiac cells are specified, what must the cells do?

A

Express specific transcription factors that demark them as:
- Cardiac cells
AND
- Either FHF or SHF SPECIFIC cardiac precursors

39
Q

What transcription factor is common to both FHF and SHF cells?

What does this show?

A

NKX2.5

Shows that NKX2.5 is important to show have CARDIAC MYOCYTES

40
Q

What transcription factor is only expressed in FHF cells?

A

Tbx5

41
Q

What transcription factor is only expressed in SHF cells?

A

Islet1

42
Q

What are the heart field specific transcription factors required for?

A

Cardiac differentiation and specific aspects of cardiac function

43
Q

Once the heart field cells are specified, what happens?

A

They migrate ANTERIORLY to form the primitive heart tube

44
Q

What HF cells initially make up the heart tube?

Where are the the other HF cells?

A

FHF cells make up the heart tube

SHF cells are in the adjacent mesoderm

45
Q

What is important about the heart tube, even when it is linear?

A
  • Patterning of the heart tube

- There is distinction between the different regions of the heart - it is coordinated

46
Q

What is different kinds of patterning in the heart tube important for?

Examples?

A

Subsequent development and function of the heart between the different parts

Examples:

  • Chamber vs non chamber
  • Contractile vs non-contractile
  • Atrial vs ventricular contractility
  • Inflow vs atrioventricular canal vs outflow
47
Q

What are the non-contractile parts of the heart?

A

Valves
Septum
Atrioventricular canal
Connective tissue

48
Q

Why is there a need for different pattering in the atria and ventricles?

What do they express differently?

A
  • Must contract differently and in a DIRECTED way for proper flow of blood through the heart
  • Ventricles undergo trabeculation - must have genes expressed for this

Express different MYOSINS

49
Q

What signalling needs to occur in the heart tube?

A

1) Notch - tbx20 pathway

2) Bmp2

50
Q

What is the Notch - tbx20 pathway important in?

What occurs in this signalling pathway?

What does it result in?

A

Specifying CHAMBER myocardium in the heart

Pathway:
1) Notch activates tbx20

2) Tbx20 inhibits BMP2 and tbx2

Results in:
Specification of chamber myocardium in the heart

51
Q

What is CHAMBER myocardium characterised by?

A

Expression of Nppa and Nppb

52
Q

What does BMP2 do?

What does this result in?

A

Activated tbx2

Results in the specification of the atrioventricular canal

53
Q

What is tbx2 a marker of?

A

Atrioventricular myocardium

54
Q

What does tbx2 KO in mice cause?

A
  • Abnormal valve morphology and Nppa expression
  • Widened atrioventricular canal
  • Expansion of Nppa into what would have been the atrioventricular canal
55
Q

What occurs in tbx20 KO in mice?

A
  • Loss of chamber identity

- Expression of tbx2 (valve markers) throughout the heart

56
Q

When heart looping occurs, which way does the heart loop?

A

Rightward looping

57
Q

What model organism is useful in studying heart looping?

A

The zebrafish

58
Q

What processes occur during heart looping?

A

1) Changes in cell shape
2) Asymmetric cell movements at the POLES of the heart
3) Regional changes in ECM composition
4) Lateralised cell signalling from the embryo

59
Q

What happens the cell shape/size when the heart loops?

A

INCREASE in shape/size

60
Q

Describe the regional DIFFERENCES in cell shape change during heart looping

A

Cells on INNER curvature of ventricle:
- Stay CUBOIDAL

Cells on OUTER curvature of ventricle:

  • Grow MORE
  • Elongate MORE
  • Change orientation
61
Q

How does the heart tube grow during heart looping?

Why does this occur?

A

SHF cells migrate to both poles of the heart and add into the heart tube

Helps the heart tube to undergo morphogenesis

62
Q

During heart looping, what occurs at the poles of the heart?

What does this help to occur?

A
  • Rotation of some cells
  • Occur in OPPOSITE directions at either end of the heart tube

Helps the heart tube to undergo buckling/bending

63
Q

Describe the regional changes in ECM composition when the heart undergoes looping

What does this allow?

A

Regionalised EXPANSION of the ECM at the ATRIOVENTRICULAR CANAL (where the valves form)

Allows:

  • The valves to emerge from the heart tube
  • Changes to the stiffness of the tube
64
Q

Why is lateralised signalling from the embryo needed during heart looping?

A

To tell the heart tube which direction to bend in - this is very important

65
Q

How can cardiac cells be visualised?

A
  • Using the promoter of myl17 to drive GFP expression

- So that all cardiac cells are expressing GFP - able to visualise the linear heart time

66
Q

What transcription factor is a marker of the specified SHF cells?

What does in situ hybridisation show of this transcription factor?

A

Islet1

ISH shows this transcription factor is expressed in the MESODERM adjacent to the heart early in development

67
Q

What does lineage tracing of Islet1 expressing SHF cells show?

What reporter is used in lineage tracing?

A

That the cells that WERE expressing Islet1 end up inside the heart itself

LacZ reporter

68
Q

What happens to Islet1 as the SHF cells enter the heart?

A

Islet 1 is switched off

69
Q

What does ISH of myl17 in Islet mutant mice show?

A

Heart is REDUCED in size and is INCOMPLETELY looped

70
Q

What is myl17 a marker of?

A

Cardiac cells

71
Q

What is heterotaxia?

A

L/R asymmetry abnormalities

72
Q

What do people with heterotaxia often have, in relation to the heart?

What does this show?

A

Congenital heart defects - abnormal cardiac development

Shows that it is important that heart looping occurs int he correct direction

73
Q

What is situs invertus?

A

Complete reversal of the organ organisation

74
Q

What is situs ambiguious/heterotaxia?

A

NOT a full reversal of organ organisation

75
Q

What is organ asymmetry controlled by?

A

The ASYMMETRIC expression of NODAL

76
Q

How is nodal expressed in the embryo?

What causes this?

A

In the LEFT LATERAL PLATE MESODERM prior to organ formation

Due to elevated calcium expression on the left of the node/Kupffer’s vesicle

77
Q

What does loss of nodal function result in?

A

Disrupted organ asymmetry

78
Q

What is the nodal homologue in zebrafish?

A

South paw (spaw)

79
Q

What forms at the posterior of the embryo during somatogenesis?

What is this called in mice? Zebrafish?

A

Cup-shaped organ

Called:
The node (mouse)
Kupffer’s vesicle (zebrafish)

80
Q

What is the structure of the node/Kupffer’s vesicle?

A

Cup-shaped organ

Lined with motile cilia

81
Q

What substance is elevates in the left of the embryo?

How?

A

Calcium

Cilia of the Kupffer’s vesicle/node beat in a CLOCKWISE direction
Causing a directional fluid flow

82
Q

What does the elevated calcium on the LEFT of the node/Kupffer’s vesicle result in?

A

1) Asymmetric expression of NODAL in the LEFT lateral plate mesoderm
2) This nodal propagates itself from the POSTERIOR part of the embryo (where the node is) to more ANTERIORLY in the LPM

83
Q

What happens once nodal reaches the more anterior part of the embryo?

What does this help?

A

Starts to turn on ASYMMETRIC gene expression in the regions where the organs are going to form

  • Helps the heart tube to form in the CORRECT POSITION
  • Goes onto dictate the DIRECTION of organ looping
84
Q

What is expressed where the gut is going to form?

A

Asymmetric expression of pitx2

85
Q

What is expressed where the heart is going to form?

A

Cyclops and lefty2

86
Q

Where are cyclops and lefty2 expressed in the heart?

A

In the LEFT part of the cardiac disc

87
Q

What is expressed where the brain is going to form?

A

Lefty1

88
Q

What happens if there is a loss of nodal FLOW?

What causes this loss of nodal flow?

A

RANDOMISATION of lateralised gene expression

Loss of nodal flow due to the KV/Cilary genes not working

89
Q

What happens if there is loss of nodal (but the node/KV is still working)?

A

ABSENCE of lateralised gene expression

90
Q

When does the heart beat during development?

A

Even BEFORE the heart tube forms

91
Q

What are the 2 sources of mechanical force in the heart?

A

1) Cardiac contractility

2) Flow of blood (caused by cardiac contractility)

92
Q

What is blood flow important for?

How does this occur?

A

Spatiotemporal gene expression of valves

  • Induction and maintenance of FLOW-RESPONSIVE genes
93
Q

What is an example of a flow responsive gene?

What does it require to be turned on?

A

klf2

Requires blood flow through the heart to be turned on

94
Q

Describe the blood flow in the heart over devleopment

What does this cause?

A
  • As heart undergoes morphogenesis - different patterns of blood flow through the heart
  • Causes differences in the STRESS in different parts of the heart
95
Q

What happens to the blood flow where there is narrowing of the heart tube?

What is this sensed by?

What does this cause?

A

There is retrograde (backwards) flow

Sensed by the cells in the adjoing regions

Causing these cells to turn on flow-responsive genes that are required for VALVE formation

96
Q

How does the heart form different internal structures?

A

Sense SPECIFIC flow patterns in DIFFERENT regions of the heart

97
Q

How are the differential patterns of blood flow through the heart as it develops

A

Architecture of the tissue changes
Due to the tissues undergoing MORPHOGENESIS

(When the heart loops - the sides of the vessels come closer together)