Trilaminar Embryo (week 3)

Question 1

when does hemangiogenesis begin?

Answer 1

end of week 3

Question 2

where does hemangiogenesis begin?

Answer 2

in the extraembryonic mesoderm

Question 3

what are blood islands?

Answer 3

hemangiogenic mesorderm within the wall of the yolk sac

Question 4

what are hemangioblasts?

Answer 4

progenitor cells capable of differentiating into angioblasts and hematopoeitic stem cells

Question 5

what are angioblasts precursors to?

Answer 5

endothelial cells of the blood vessels

Question 6

what are the precursors of blood cells?

Answer 6

hematopoitic cells

Question 7

what is angiogenesis

Answer 7

formation of new blood vessels by fusion of pre-existing blood vessels,

Question 8

what does the blood island give rise to

Answer 8

angioblasts and hematopoeitic stem cells

Question 9

when does primitive hemangiogenesis start?

Answer 9

beginning of week 3 in the yolk sac

Question 10

when does definitive hemangiogenesis start?

Answer 10

2 days after primitive hemangiogenesis in the embryo

Question 11

what is vasculogenesis?

Answer 11

process in which the primitive blood vessels form within the blood islands via fusion of endothelial cells (angioblasts)

Question 12

what is the main event of week three of embryonic development?

Answer 12

gastrulation (formation of 3 embryonic germ layers)

Question 13

what is gastrulation?

Answer 13

bilaminar embryo is transformed into a trilaminar embryo and the formation of three embryonic germ layers: embryonic ectoderm, mesoderm, and endoderm

Question 14

at what end of the embryonic disk does gastrulation begin at? (caudal or cranial)

Answer 14

caudal

Question 15

when does gastrulation begin (day number)

Answer 15

day 15

Question 16

How does gastrulation start? (what is the first thing to begin to develop)

Answer 16

primitive streak

Question 17

what does structures does the primitive streak consist of?

Answer 17

primitive groove + primitive node

Question 18

what types of cells make up the primitive streak?

Answer 18

proliferating epiblasts

Question 19

where is the primitive pit found?

Answer 19

it is the depression in the primitive node

Question 20

what does the first wave of migrating epiblast cells through the primitive groove (during gastrulation) form?

Answer 20

embryonic endoderm (displaces the hypoblast)

Question 21

what does the second wave of migrating epiblast cells through the primitive groove (during gastrulation) form?

Answer 21

embryonic mesoderm (moves between the endoderm and epiblast)

Question 22

what does the remaining epiblast cells that don’t migrate during the first or second wave during gastrulation form?

Answer 22

embryonic ectoderm

Question 23

what cells make up the primitive pit? what is their function?

Answer 23

ciliated cells; their cilia protrude toward the ventral side of the embryo and constantly rorate creating nodal flow to the left

Question 24

Towards which side is nodal flow created? how?

Answer 24

to the left; via the ciliated cells in the primitive pit constantly rotating

Question 25

what is responsible for the left-right embryo asymmetry?

Answer 25

the leftward gradient of the signaling protein Nodal (secreted by the primitive node)

Question 26

what protein is secreted by the primitive node? what is it’s function?

Answer 26

nodal; its a signaling protein responsible for the left-right embryo asymmetry

Question 27

where do the ectoderm and endoderm tightly adhere during gastrulation?

Answer 27

at the buccopharyngeal (oropharyngeal) membrane and at the cloacal membrane

Question 28

Do the buccopharyngeal and cloacal membrane have any intervening mesoderm?

Answer 28

NO! they are only made up of tightly adhering ectoderm and endoderm

Question 29

what does the buccopharyngeal membrane define? what future cavity does it make?

Answer 29

defines the cranial end of the embryo; gives rise to the future oral cavity (mouth)

Question 30

what does the cloacal membrane define? what future cavity does it give rise to?

Answer 30

defines the caudal end of the embryo; gives rise to future cloaca (anus and urethra)

Question 31

what is the notochord process?

Answer 31

a hollow tube, which grows cranially from the primitive pit between the ectoderm and endoderm until is it blocked by the prechordal plate

Question 32

When does the notochord process stop growing?

Answer 32

once it reaches the prechordal plate

Question 33

what is the prechordal plate? where is it located?

Answer 33

a condensation of the mesoderm, adjacent to the the buccopharyngeal membrane

Question 34

What is the notochordal canal?

Answer 34

the hollow center of the notochordal process which is continuous with primitive pit

Question 35

what makes up the notochord plate

Answer 35

the notochordal canal unzipped and fused with the endoderm

Question 36

what is the neuroenteric canal?

Answer 36

a transient canal, which temporarily links the amniotic cavity with the yolk sac through the notochordal canal

Question 37

As the three germ layers are established, the cells of the notochordal plate begin to proliferate and separate from the _________, forming the ________.

Answer 37

endoderm; definitive notochord

Question 38

what does the notochord get incorporated into after notocord transformation?

Answer 38

vertebral bodies of the vertebral column during axial skeleton development

Question 39

What are the main functions of the notochord?

Answer 39

1. defines the dorsal-ventral and left-right axes of the embryo
2. provides midline patterning signals for the surrounding tissues
3. serves as a major skeletal element of the developing embryo

Question 40

which cells make up the neural ectoderm?

Answer 40

epiblasts closest to the midline of the ectoderm layer

Question 41

which cells make up the surface ectoderm?

Answer 41

epiblasts closes to the lateral surfaces of the ectoderm layer

Question 42

what does the neural ectoderm give rise to?

Answer 42

1. brain
2. spinal cord
3. all cranial and spinal MOTOR neurons
4. retina
5. neurohypophysis
6. epithelium and muscles of the iris
7. epithelium of the ciliary body of the eye

Question 43

from which germ layer does the epithelium of the ciliary body of the eye arise from?

Answer 43

neural ectoderm

Question 44

which germ layer gives rise to the epithelium and muscles of the iris?

Answer 44

neural ectoderm

Question 45

which germ layer gives rise to the neurohypophysis?

Answer 45

neural ectoderm

Question 46

which germ layer gives rise to the retina

Answer 46

neural ectoderm

Question 47

which germ layer gives rise to all of the MOTOR cranial and spinal neurons?

Answer 47

neural ectoderm

Question 48

which germ layer gives rise to the spinal cord and brain?

Answer 48

neural ectoderm

Question 49

which germ layer gives rise to the epidermis and its appendages?

Answer 49

surface ectoderm

Question 50

which germ layer gives rise to the epithelial lining of the cornea and conjunctiva?

Answer 50

surface ectoderm

Question 51

which germ layer gives rise to the epithelial lining of the external ear?

Answer 51

surface ectoderm

Question 52

which germ layer gives rise to the epithelial lining of the mouth and appendages?

Answer 52

surface ectoderm

Question 53

which germ layer gives rise to the proctodeal epithelium and epithelium of terminal male urethra?

Answer 53

surface ectoderm

Question 54

where are the cells that make up the mesoderm found?

Answer 54

between the ectoderm and endoderm during gastrulation

Question 55

what layers does the mesoderm differentiate into?

Answer 55

paraxial, intermediate, and lateral mesoderm

Question 56

Where is the paraxial mesoderm located?

Answer 56

caudal to the otic vesicles

Question 57

what forms the somites?

Answer 57

paraxial mesoderm segmentation

Question 58

what are somites?

Answer 58

symmetrical condensations of mesenchymal cells on both sides of the developing neural tube

Question 59

are all parts of the paraxial mesoderm segmented? If not, what area(s) are not?

Answer 59

No! The area cranial to the otic vesicles remains unsegmented

Question 60

what are the four specialized regions of the somite?

Answer 60

1. dermotome
2. myotome
3. lateral somite
4. sclerotome

Question 61

which region of the somite loses its compact organization first?

Answer 61

the sclerotome

Question 62

where do the sclerotome cells migrate toward?

Answer 62

toward the notochord and neural tube

Question 63

what do the sclerotomal cells form?

Answer 63

the vertebral column (later in development)

Question 64

what area of the somite gives rise to the dermatome, myotome, and lateral somite regions?

Answer 64

dorsal portion of the somite

Question 65

what does the dermatome give rise to?

Answer 65

dermis of the skin over the dorsal region of the trunk

Question 66

what does the lateral somite give rise to?

Answer 66

ALL voluntary striated muscles of the body wall and limbs (hypaxial muscles)

Question 67

what does the myotome give rise to?

Answer 67

segmented muscles of the axial skeletome (epaxial muscles)

Question 68

what does the unsegmented area of the paraxial mesoderm give rise to?

Answer 68

straiated muscles of the head

Question 69

What does the intermediate mesoderm give rise to

Answer 69

connective tissue and the smooth muscle cells of the gonads, urinary system, and reproductive tracts

Question 70

what layers of mesoder does the lateral mesoderm divide into?

Answer 70

somatic (parietal) and splanchnic (visceral) mesoderm

Question 71

where is somatic mesoderm found?

Answer 71

adjacent to the surface of the ectoderm

Question 72

where is splanchnic mesoderm found?

Answer 72

adjacent to the endoderm

Question 73

what makes up somatopleure?

Answer 73

surface ectoderm + somatic mesoderm

Question 74

what makes up splanchnopleure?

Answer 74

visceral mesoderm + endoderm

Question 75

which germ layer (specific) gives rise to the skeleton of the limbs?

Answer 75

somatic mesoderm

Question 76

which germ layer (specific) gives rise to the connective tissues of the limbs and trunk?

Answer 76

somatic mesoderm

Question 77

which germ layer (specific) gives rise to the dermis of the ventral body wall and limbs?

Answer 77

somatic mesoderm

Question 78

which germ layer (specific) gives rise to the connective tissues of the external genitalia?

Answer 78

somatic mesoderm

Question 79

which germ layer (specific) gives rise to the smooth muscle and connective tissue of the blood vessels?

Answer 79

somatic mesoderm

Question 80

which germ layer (specific) gives rise to the smooth muscle and connective tissues of the intestinal tract, associated glands, and abdominal mesenteries?

Answer 80

visceral mesoderm

Question 81

which germ layer (specific) gives rise to the smooth muscle and connective tissues of the respiratory tract and associated glands?

Answer 81

visceral mesoderm

Question 82

which germ layer (specific) gives rise to the smooth muscles and connective tissues of the blood vessels?

Answer 82

visceral mesoderm

Question 83

which germ layer (specific) gives rise to the cardiac muscle?

Answer 83

visceral mesoderm

Question 84

where do the first blood islands appear?

Answer 84

in the splanchnopleuric mesoderm surrounding the definitive yolk sac

Question 85

how is primitive vasculature formed?

Answer 85

the angioblasts of blood islands differentiate into the endothelial cells that fuse to form primitive vasculature filled with primitive blood (found within the yolk sac)

Question 86

where is primitive vasculature found?

Answer 86

within the yolk sac

Question 87

where are hemangioblasts found?

Answer 87

in the blood islands

Question 88

where are the definitive hematpoeitic stem cells formed?

Answer 88

within the hemangiogenic mesoderm

Question 89

what do angioblasts originating within the hemangiogenic mesoderm form?

Answer 89

endothelial lining of the vessels (including aorta and heart)

Question 90

where are primitive hematpoeitic stem cells formed?

Answer 90

within the blood islands located in the walls of the definitive yolk sac

Question 91

what do definitive hematpoeitic stem cells give rise to?

Answer 91

the embryonic liver

Question 92

what is the function of the embryonic liver? how does this change after birth?

Answer 92

it is the main site of hematopoiesis during embryonic development; after birth, hematopoiesis shifts to the bone marrow

Question 93

what does the septum transversum give rise to?

Answer 93

the mesenchyme of the developing liver, epicardium, the central portions of the diaphragm, and the esophageal mesentery

Question 94

what does the endoderm give rise to largely?

Answer 94

epithelial lining of the developing gut and its appendages (foregut, midgut, hindgut, and allantois)

Question 95

what germ layer gives rise to the epithelial lining of the gut?

Answer 95

endoderm

Question 96

what germ layer gives rise to the epithelial lining of the respiratory tract?

Answer 96

endoderm

Question 97

what germ layer gives rise to the hepatocytes of the liver?

Answer 97

endoderm

Question 98

what germ layer gives rise to the bilary tract?

Answer 98

endoderm

Question 99

what germ layer gives rise to the endocrine and exocrine cells of the pancreas?

Answer 99

endoderm

Question 100

what germ layer gives rise to the epithelium of the middle ear and auditory tube?

Answer 100

endoderm

Question 101

what germ layer gives rise to the urinary bladder

Answer 101

endoderm

Question 102

what germ layer gives rise to the epithelial lining of the vagina?

Answer 102

endoderm

Question 103

what germ layer gives rise to the epithelial lining of the urethra?

Answer 103

endoderm

Question 104

what germ layer gives rise to the secretory cells of the prostate and urethral glands?

Answer 104

endoderm

Question 105

what is primary ciliary dyskinesia (PCD)?

Answer 105

a rare autosomal recessive genetic disorder in which genetic mutations affect genes encoding various proteins comprising motile cilia; results in cilia which do not rotate, causing disruption of leftward flow of fluid in the primitive node during gastrulation, leading to disruption in the normal signaling cascade responsible for the establishment of left-right body asymmetry

Question 106

what is a common result of primary ciliary dyskinesia (PCD)?

Answer 106

sius inversus– karatagener syndrome

Question 107

what is sius inversus– karatagener syndrome?

Answer 107

a PCD where the laterality of the internal organs is the mirror-image of normal

Question 108

what are PCD symptoms?

Answer 108

1. susceptibility to chronic recurrent respiratory infections due to absent mucus clearance from the resp. system
2. infertility in both males and females (due to diminished sperm motility in males or defective ciliary action in the fallopian tubes in females)

Question 109

what is situs ambiguus?

Answer 109

organ placement is neither typical (situs solitus) nor totally reversed (situs inversus)