1. Bio 127 - Section I Introduction to Developmental Biology
Cell-Cell Communication in Development
Gilbert 9e – Chapter 3

2. It has to be EXTREMELY well coordinated for the single-celled fertilized ovum to develop into the complex adult
This coordination requires a systematic way for the cells to know what’s happening around them so that they can change their gene expression correctly
They must also then change the signals they are sending out to let surrounding cells know what changes they are making

3. Developmental Activities Coordinated in this Way
1. The formation of tissues from a mix of individual cells 2. The formation of organs from a mix of tissue types 3. The formation of cells, tissues and organs in specific locations 4. The growth and death of cells, tissues and organs 5. The achievement of polarity in cells, tissue and organs

4. Membrane molecules sense:
The plasma membranes of cells are designed to sense what is happening in their environment
Membrane molecules sense:
other cell membranes
soluble signals sent by other cells
the type of extracellular matrix that surrounds them
A few signals can get past the plasma membrane

5. Most cells in the embryo have molecules on their surface that identify who they are
DevBio9e-Fig jpg
These molecules also instruct them
who they should be in contact with

6. Sorting out and reconstruction of spatial relationships in aggregates of embryonic amphibian cells
All
cell
types
can
do it
DevBio9e-Fig jpg

7. Aggregates formed by mixing 7-day chick embryo neural retina cells with pigmented retina cells
DevBio9e-Fig jpg
....just to show
that it’s more
than an artist’s
rendition....

8. Figure 3.4 Hierarchy of cell sorting in order of decreasing surface tensions
The more
adhesive the
cell’s plasma
membrane is,
the more it
migrates to
the middle of
a cell mixture.
DevBio9e-Fig jpg

9. The molecular biology of cell adhesion: Cadherins
The calcium-dependent
adhesion molecules
(or cadherins) are the
main source of adhesive
activity on the cell surface
DevBio9e-Fig R.jpg
The more you express,
the more central you
become in a mixture

10. Importance of amount of cadherin for morphogenesis
DevBio9e-Fig jpg
--- A nearly perfect linear relationship

11. Importance of type of cadherin for morphogenesis
Early embryo cells all express E-cadherin
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Presumptive neural tube cells lose E-cadherin and gain N-cadherin.
N-cadherin expression does something very similar in limb cartilage.

12. Cadherins can activate migration through actin
DevBio9e-Fig R.jpg
Cadherin binding outside of
the cell can cause actin-based
migration in some cells

13. Disruption of N-Cadherin in Frog Embryos
failed migration
failed actin assembly
DevBio9e-Fig jpg
blocked
normal

14. The cadherins activate migration through Rho GTPase
Migratory cells have Rho
in their cadherin-actin
apparatus – cadherin
activates Rho, Rho activates
actin-myosin migration.

15. Drosophila gastrulation
DevBio9e-Fig jpg
The cells that have Rho activated
migrate to become the mesoderm.

16. Migration is started by expression of Twist and Snail which causes Rho and B-catenin to translocate in cells
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Rho build-up on E-cad causes actin polymerization and migration

17. Tracheal Development in Drosophila
Rho can also be linked to cell
surface receptors and cause
chemotactic migration.
The cadherin attachments
remain strong and the cells
migrate as a cohesive unit.
DevBio9e-Fig jpg

18. Figure Cell migration
Mesenchymal Cell Migration is also Rho-Dependent
DevBio9e-Fig jpg
- not always cadherin-dependent however!

19. One-Way, Two-Way and Reciprocal Communications Strategies
Ligands Receptors 2nd Messengers Target Mechanisms

20. Cell Signaling Terminology
Paracrine
Endocrine
Synaptic
Induction
Inducer
Responder
Signal Competence
Signal Transduction
Permissive Signals
Instructive Signals

21. Ectodermal competence and the ability to respond to the optic vesicle inducer in Xenopus
DevBio9e-Fig jpg

22. HOW? Optic vesicle secretes...... Head ectoderm expresses......
BMP 4
Fgf 8
Head ectoderm expresses......
Sox 2
L-Maf
Pax 6
Lens genes turned on......
crystallin
others

23. Induced Differentiation

24. Induction Cascades
We know that tissues tend to aggregate through cell contact
It’s common for tissues to play off each other to produce an organ
Anything from two tissues signaling back and forth to many tissues coordinating each other’s actions
The common theme is that a change in gene expression internally (TF’s, functional proteins) is often accompanied by a change in secreted proteins (paracrine, endocrine factors)

25. Eye formation is a classically studied cascade of induction
DevBio9e-Fig jpg
Simple lens induction...

26. Reciprocal induction
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27. DevBio9e-Fig R.jpg

28. DevBio9e-Fig R.jpg

29. The reciprocal interaction between an epithelium and a closely associated mesenchyme is a very common means of organ development (organogenesis)

30. These are
backwards
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31. Different mesenchyme induces different epithelial structures
DevBio9e-Fig jpg

32. Also, different epithelium can only become what they are competent to become
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33. A little about some of the actual molecules.....
Growth Factors carry most of the signals
Hormones and neurotransmitters later on
4 big families:
FGF, Hedgehog, Wnt, TGF-b
Receptors and signaling cascades premade for them make you competent

34. Fibroblast growth factor (FGF) family are classic growth factors: FGF 1-8
lots of others: VEGF, HGF, PDGF, etc.
can change transcription of genes 2 ways
RTK Pathway: receptor tyrosine kinase
JAK-STAT: JAK activates STAT TF’s

35. Optic vesicle secretes......
BMP 4
Fgf 8
Head ectoderm expresses......
Sox 2
L-Maf
Pax 6
Lens genes turned on......
crystallin
others

36. Figure 3.20 Fgf8 in the developing chick (Part 1)
DevBio9e-Fig R.jpg

37. Figure 3.20 Fgf8 in the developing chick (Part 2)
FGF8 in optic vesicle
L-Maf expression in ectoderm
DevBio9e-Fig R.jpg

38. Figure A mutation in the gene for FgfR3 causes the premature constitutive activation of the STAT pathway and the production of phosphorylated Stat1 protein
DevBio9e-Fig jpg

39. Hedgehog family includes sonic (shh), desert (dhh) and indian (ihh) in vertebrates
Change transcription through an interesting series of inhibitory activities
the patched receptor inhibits the smoothened protein until hedgehog binds
smoothened then moves to inhibit proteins that inhibit the Gli activator protein

40. Figure (A) Sonic hedgehog expression is shown by in situ hybridization in the nervous system, gut, and limb bud of a chick embryo. (B) Head of a cyclopic lamb
DevBio9e-Fig jpg
Both shh and patched proteins require cholesterol.
Blocking its production can cause cyclopism.

41. Wnt family has 15 members in vertebrates
Glycoproteins with lipid tails!
Work through frizzled receptors and disheveled activators (fly guys!)
Also activate by inhibition of an inhibitor

42. Interestingly, Wnt can do much of what cadherins can do
Send catenins to the nucleus
Activate rho and change the cytoskeleton
This is called “crosstalk” and it is very important in cell signaling

43. Remember the structure of the cadherin system
Implantation of the mammalian embryo in adhere to the uterine wall
E- and P-cadherin
Integrin and uterine ECM
Proteins that bind sugars on uterine wall
Rho proteins
associate with
catenins and
actin system.
They can change
actin’s structure.

44. The receptors are also a large family of proteins
The TGF-b superfamily is a very large family of very active peptide growth factors
involved in the development of most tissues
The receptors are also a large family of proteins
They are serine-threonine kinases, not RTK
They work through the activation of SMAD transcription factors

45. Figure 3.29 Relationships among members of the TGF-β superfamily
We’ll hear a lot
of these names
again this semester!
DevBio9e-Fig jpg

46. Remember: The Big 4 are just part of the story
We’ll talk about others as they come into play

47. The Delta-Notch family: “Juxtacrine” signals
Transmembrane proteins on cells in contact
Delta, Jagged or Serrate bind to Notch family
Signals go both ways
The Notch signal is interesting in that it’s internal domain is cleaved and enters nucleus
This activates a dormant transcription factor

48. Figure 3.33 Mechanism of Notch activity
DevBio9e-Fig jpg

49. Apoptosis: genetically programmed cell death
Absolutely essential to control cell numbers, cell quality and to create space
The space between our fingers
2/3 of all neurons we make
The middle ear
The cerebral ventricles
Frog tails
Male mammary epithelium

50. Figure 3.32 Disruption of normal brain development by blocking apoptosis
DevBio9e-Fig jpg

51. Apoptosis Often cells are set to apoptose by default
They require a signal to keep them alive
The signal can be soluble or can be attachment, such as cadherins, integrins
These are guarantees that cells remain where they should be in the body

52. Figure 3.31 Apoptosis pathways in nematodes and mammals
Early work
done mostly
in worms
Mammalian
homologs
A signal that
turns on CED-9
(Bcl2) saves the
cell from death
DevBio9e-Fig jpg

53. Other Related Strategies of Developmental Biology
Maintaining the differentiated state
B. The extracellular matrix as a source of
developmental signals
C. Epithelial-mesenchymal transition

54. Maintaining the Differentiated State
Just changing gene expression is not enough
Maintaining the new expression pattern is essential for differentiation
So far, four ways to do this have been described

55. Four ways of maintaining differentiation after the initial signal has been given (Part 1)
TF Positive feedback loop
Trithorax opens promoter
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56. Four ways of maintaining differentiation after the initial signal has been given (Part 2)
Autocrine loop
Paracrine loop
DevBio9e-Fig R.jpg

57. The Role of the Extracellular Matrix (ECM)
As development proceeds, all cells secrete sugars and proteins to create solid substrate between the cells
Nearly all cells require adhesion to survive
Cell migration is also dependent on ECM

58. Figure 3.37 Extracellular matrices in the developing embryo
A fibronectin tract allows mesoderm migration during gastrulation
DevBio9e-Fig jpg
The epithelial cells secrete
fibronectin into basal lamina
and then can use it migrate upon.

59. Figure 3.38 Simplified diagram of the fibronectin receptor complex
Integrins bind the ECM
to the cytoskeleton
DevBio9e-Fig jpg

60. Figure 3.40 Basement membrane-directed gene expression in mammary gland tissue
Plated on plastic
(A)
Plated on
basal lamina
(B,C,D)
DevBio9e-Fig jpg

61. Epithelial to Mesenchymal Transition
A key type of differentiation in many tissue forming activities in embryos and adults
formation of mesoderm from epiblast
formation of neural crest cells from neural tube
formation of coronary arteries from epicardium
formation of vertebrae from somites
wound healing in skin and vasculature
metastasis of epithelial cancers

62. Figure 3.41 Epithelial-mesenchymal transition, or EMT (Part 1)
If not accompanied
by differentiation,
loss of connections
would lead to death
DevBio9e-Fig R.jpg

63. Figure 3.41 Epithelial-mesenchymal transition, or EMT (Part 2)
DevBio9e-Fig R.jpg