1. The Emergence of the Ectoderm: Central Nervous System and Epidermis
BIOL 370 – Developmental Biology
Topic #12
The Emergence of the Ectoderm: Central Nervous System and Epidermis
Lange

2. Major derivatives of the ectoderm germ layer
Three subdivisions of the ectoderm:
Surface
Neural Crest
Neural Tube
DevBio9e-Fig jpg

3. Major derivatives of the ectoderm germ layer (Part 1)
Know that the surface ectoderm will form an organism’s eventual 
DevBio9e-Fig R.jpg

4. Major derivatives of the ectoderm germ layer (Part 3)
DevBio9e-Fig R.jpg
Know that the surface ectoderm will form an organism’s eventual 

5. Gastrulation and neurulation in a chick embryo
DevBio9e-Fig jpg

6. Gastrulation and neurulation in a chick embryo (Part 1)
Neural plate - a key developmental structure that serves as the basis for the nervous system.
Notochord -a flexible rod-shaped body found in embryos of all chordates composed of mesodermal cells. In most adult organisms, the notochord remains as the nucleus pulposus of the intervertebral disc.
DevBio9e-Fig R.jpg

8. Gastrulation and neurulation in a chick embryo (Part 2)
Pharynx – a part of both the digestive system and also the respiratory system.
The pharynx is considered the conducting zone for both systems.
DevBio9e-Fig R.jpg

9. Gastrulation and neurulation in a chick embryo (Part 3)
From the gastrula stage you move into the neural stage….
Where the nervous system develops.
DevBio9e-Fig R.jpg

10. Gastrulation and neurulation in a chick embryo (Part 4)
DevBio9e-Fig R.jpg

11. Gastrulation and neurulation in a chick embryo (Part 5)
DevBio9e-Fig R.jpg

12. Figure 9.3 Three views of neurulation in an amphibian embryo, showing early, middle, and late neurulae in each case (Part 1)
DevBio9e-Fig R.jpg

13. Figure 9.4 Primary neurulation: neural tube formation in the chick embryo
For more details, see next two slides. But notice how we are focusing now exclusively on chick endoderm.
DevBio9e-Fig jpg

14. Figure 9.4 Primary neurulation: neural tube formation in the chick embryo (Part 1)
DevBio9e-Fig R.jpg
MPH (medial hinge point) – the combined Hensen's node and epiblast region that is involved in the intial bending of the neural plate during neurulation.

15. Figure 9.4 Primary neurulation: neural tube formation in the chick embryo (Part 2)
DevBio9e-Fig R.jpg

16. Anencephaly is the absence of a major portion of the brain that occurs during embryonic development. This is a cephalic disorder resulting from a neural tube defect occurring when the rostral end of the neural fails to close. This typically happebs between the 23rd and 26th day of conception.

17. Spina Bifida is a similar defect this time occurring at the caudal end of the neural tube.
Children with this condition often times have locomotor disorders.

18. Figure 9.5 Neurulation in the human embryo
DevBio9e-Fig jpg

19. Figure 9.6 Expression of N- and E-cadherin adhesion proteins during neurulation in Xenopus
In the experimental protocol (B) neurulation has been altered by the injection of N-cadherin and E-cadherin. The alteration leads to the neural tube not showing the normal stages of separation from the presumptive epidermis.
DevBio9e-Fig jpg

20. Figure 9.7 Folate-binding protein in the neural folds as neural tube closure occurs
Women who are pregnant are often advised to take supplements of folic acid. The reason is due to the role that foliate binding protein exerts on neural tube closure.
DevBio9e-Fig jpg

21. Figure 9.8 Secondary neurulation in the caudal region of a 25-somite chick embryo
DevBio9e-Fig jpg

22. Mammalian Brain Development
In development, the rostral neural tube will begin to differentiate into more distinctive brain regions. The first differentiation is into primary vesicles (there are three of them).
Following this vesicle development the brain continues to differentiated into the secondary vesicles (there are five of them).

23. Figure 9.9 Early human brain development (Part 1)
DevBio9e-Fig R.jpg

24. Figure 9.9 Early human brain development (Part 2)
Telencephalon derived
Diencephalon
Derived
Mesencephalon derived
Meten cephalon derived
Mylencephalon derived
DevBio9e-Fig R.jpg

25. Figure 9.10 Rhombomeres of the chick hindbrain
Rhombomeres - a transiently divided segment of the developing neural tube within the hindbrain region (a neuromere) in the area that will eventually become the rhombencephalon.
Rhombomeres appear as a series of slightly constricted swellings in the neural tube, caudal to the cephalic flexure. In human embryonic development, the rhombomeres are present by day 29.
DevBio9e-Fig jpg

26. Figure 9.11 Brain ventricle formation in zebrafish
Ventricles are a set of spaces within the brain containing cerebrospinal fluid (CSF). The ventricles are continuous with the central canal of the spinal cord. The ventricle lining consists of an epithelial membrane called ependyma, made up of ependymal cells.
DevBio9e-Fig jpg
The red dye is being injected to show the cavities where the cerebrospinal fluid resides.

27. Figure 9.11 Brain ventricle formation in zebrafish (Part 2)
The snakehead neural tube undergoes normal ventricle morphogenesis; however, the ventricles do not inflate, probably owing to impaired ion transport.
DevBio9e-Fig R.jpg

28. Figure 9.12 Occlusion of the neural tube allows expansion of the future brain region
A programmed and prescribed occlusion of the neural tube allows normal expansion of the brain regions.
However….
DevBio9e-Fig jpg

29. Long term, non prescribed occlusion may lead to hydrocephaly.
Note that the example here has occurred post parturition. In cases where hydrocephaly occurs earlier in development, viability of the fetus is doubtful.

30. Figure 9.14 Cascade of inductions initiated by the notochord in the ventral neural tube (Part 1)
Sonic Hedgehog protein concentrations (produced by the notochord) will differ depending upon distance away from the notochord (due to paracrine signaling)
DevBio9e-Fig R.jpg

31. In “B” we see normal development.
Figure Cascade of inductions initiated by the notochord in the ventral neural tube (Part 2)
Shh = Sonic Hedgehog
In “B” we see normal development.
In “C” we see a donor notochord placed in an abnormal position near the neural tube and its guiding of a second floor plate and motor neuron region.
DevBio9e-Fig R.jpg

32. Figure 9.15 Diagram of a motor neuron
DevBio9e-Fig jpg

33. Ross Harrison discovered this
Axonal outgrowth occurs in a neuron through the production of microtubules and F-actin at the axonal endings.
Ross Harrison discovered this
basic process in 1907.

34. Figure 9.16 Axon growth cones
These projections form microspikes.
DevBio9e-Fig jpg

35. Figure 9.17 Myelination in the central and peripheral nervous systems
DevBio9e-Fig jpg

36. Figure 9.17 Myelination in the central and peripheral nervous systems (Part 1)
DevBio9e-Fig R.jpg

37. Figure 9.17 Myelination in the central and peripheral nervous systems (Part 2)
DevBio9e-Fig R.jpg

38. Stereotypical Human Cell Cycle

39. Figure 9.18 Neural stem cells in the germinal epithelium
DevBio9e-Fig jpg
Unlike later in life (at least for mammals), the neural stem cells display all stages of the cell cycle.

40. Figure 9.19 Differentiation of the walls of the neural tube
The neural tube will further differentiate into a wide array of structures that are dependent upon location.
DevBio9e-Fig jpg

41. Figure 9.20 Development of the human spinal cord
DevBio9e-Fig jpg

42. Figure 9.21 Cerebellar organization
Cerebellum - a region of the brain that plays an important role in motor control.
The cerebellum may also be involved in some cognitive functions such as attention and language, and in regulating fear and pleasure responses.
DevBio9e-Fig jpg

43. Bergmann glia - a type of glia also known as radial epithelial cells or Golgi Epithelial Cells are astrocytes in the cerebellum.
Bergmann glia express high densities of glutamate transporters that limit diffusion of the neurotransmitter glutamate during its release from synaptic terminals.
In addition to their role in early development of the cerebellum, Bergmann glia are also required for the pruning or addition of synapses.

44. Some studies have suggested that over pruning of dendritic spines may occur in the prodromal and early stages of schizophrenia.

45. Thymidine (T) is one of the four nucleosides that form the bridges with adenosine (A) in DNA. In the next experimental data, ferret cortex development is examined by using tritiated thymidine to map where the cell cycle is occurring in brain development.

46. Figure 9.23 Determination of cortical laminar identity in the ferret cerebrum (Part 1)
This study looks at the role of thymidine on determining cortical identity in the cerebrum in ferrets. In “A” an early pulse of thymidine is administered late in prenatal development, whereas “B” has a later pulse after parturition. The stem cells in “A” become layer 6, whereas the same cells in “B” become layers 2&3.
DevBio9e-Fig R.jpg

47. Figure 9.23 Determination of cortical laminar identity in the ferret cerebrum (Part 2)
The blue represents “early” neuronal precursors that have formed and been transplanted into an “old” host brain. If these cells have completed synthesis prior to transplant, they move to region 6, but if they undergo S, and G2 within the host, they will migrate to region 2&3.
DevBio9e-Fig R.jpg

48. Figure 9.25 Evidence of adult neural stem cells
DevBio9e-Fig jpg

49. Figure 9.27 Retention of fetal neuronal growth rate in humans
Compare the brain weights and body weights to see the significance of differential (and continued) development in human brains versus other primate brains.
DevBio9e-Fig jpg

50. Figure Dorsal view of the human brain showing the progression of myelination (“white matter”) over the cortical surface during adolescence
What would you anticipate the effects of the increased cortical myelination be?
DevBio9e-Fig jpg

51. Figure 9.34 Retinal neurons sort out into functional layers during development
DevBio9e-Fig jpg

52. Marcello Malpighi (most work occurred in the 1660s)
was an Italian physician, who identified (and named after himself) several anatomical structures. Examples include the Malpighian tubule system in the kidney and the Malpighi layer in the skin.

53. Figure 9.37 Layers of the human epidermis
The Malpighian layer of the skin is defined as the combination of both the stratum basale and stratum spinosum layers of the epidermis.
DevBio9e-Fig jpg

54. The main structural features of the skin epidermis.
Keratinocytes
Stratum corneum
Most superficial layer; 20–30 layers of dead
cells represented only by flat membranous
sacs filled with keratin. Glycolipids in
extracellular space.
Stratum granulosum
Three to five layers of flattened cells, organelles
deteriorating; cytoplasm full of lamellated gran-
ules (release lipids) and keratohyaline granules.
Epidermal
dendritic
cell
Stratum spinosum
Several layers of keratinocytes unified by
desmosomes. Cells contain thick bundles of
intermediate filaments made of pre-keratin.
Tactile
(Merkel)
cell
Stratum basale
Deepest epidermal layer; one row of actively
mitotic stem cells; some newly formed cells
become part of the more superficial layers.
See occasional melanocytes and epidermal
dendritic cells.
Dermis
Sensory
nerve
ending
(a)
Desmosomes
Melanocyte
Dermis
(b)
Melanin granule

55. Figure 9.38 Early development of the hair follicle and hair shaft
DevBio9e-Fig jpg

56. Figure 9.38 Early development of the hair follicle and hair shaft (Part 1)
DevBio9e-Fig R.jpg

57. Figure 9.38 Early development of the hair follicle and hair shaft (Part 2)
DevBio9e-Fig R.jpg

58. Figure 9.38 Early development of the hair follicle and hair shaft (Part 3)
DevBio9e-Fig R.jpg

59. Figure 9.41 Facial anomalies of anhidrotic ecotodermal dysplasia, caused by mutation of an EDA gene
Anhidrotic Ectodermal Dysplasia (also called "Christ-Siemens-Touraine Syndrome“) is a disorder resulting in the abnormal development of a variety of structures including the skin, hair, nails, teeth, and sweat glands.
Individuals with this condition have a reduced ability to sweat (hypohidrosis) because they have fewer sweat glands than normal or their sweat glands do not function properly potentially leading to a dangerously high body temperature (hyperthermia) in certain circumstances
Affected individuals tend to have sparse scalp and body hair (hypotrichosis). The hair is often light-coloured, brittle, and slow-growing.
This condition is also characterized by absent teeth (hypodontia) or teeth that are malformed. The teeth that are present are frequently small and pointed.
DevBio9e-Fig jpg

60. The most common cause of Anhidrotic Ectodermal Dysplasia is due to a mutation in the EDA gene that provides instructions for ectodermal and mesodermal interaction and development.

61. End.