Spine, Muscle and Limb Development

Question 0

What are the precursors for: Smooth muscle Cardiac muscle Skeletal muscle

Answer 0

Smooth - Splanchnic mesoderm and local mesenchyme

Cardiac - Splanchnic mesoderm

Skeletal - Paraxial mesoderm

Question 1

What are the three types of muscle tissue?

Answer 1

Smooth Cardiac Skeletal

Question 2

What is intraembryonic mesoderm divided into?

Answer 2

Pariaxial mesoderm

Intermediate mesoderm

Lateral mesoderm

Question 3

Which mesoderm forms somites?

Answer 3

Paraxial mesoderm

Question 4

What is a somite?

Answer 4

Temporary structure in embryo allowing embryo to segregate certain precursor structures that eventually become skeletal muscle and bone

Question 5

Two types of tissue in the embryo

Answer 5

Epithelium and mesenchyme

Question 6

How does mesenchyme become somite?

Answer 6

Mesenchymal to epithelium transformation causes a structure with an outer surface of epithelium and inner portion of mesenchyme

Question 7

What is the outer epithelial surface of somites called

Answer 7

Dermomyotome

Question 8

What causes differentiation of the dermomyotome

Answer 8

Signals from surrounding tissues (notochord, neural tube and BMPs)

Question 9

What is the lateral somite frontier

Answer 9

The boundary between different sets of signals sent to the somite

Question 10

What is the primaxial domain?

Answer 10

Forms muscles that attache to scleratome derived bones (vertebrae)

Question 11

What is the abaxial domain

Answer 11

Forms muscles of ventrolateral abdominal wall and limbs

Question 12

What do the dermomyotomes form after they are differentiated?

Answer 12

Myogenic cells, which then become myoblasts

Question 13

How is skeletal muscle formed from myoblasts?

Answer 13

Signals from other cells cause myoblasts to fuse together into myotubules which then join to form skeletal muscle cells

Question 14

Why does skeletal muscle have multiple nuclei

Answer 14

Because it is formed from multiple myoblasts

Question 15

The central region of the dermomyotome forms…

Answer 15

Satellite cells - precursors to skeletal muscle cells (muscle stem cells)

Question 16

What are the master regulators for skeletal muscle formation?

Answer 16

Myo-D family of genes: Myf-5 Myogenin MRF-4 PAX-3 PAX-7

Question 17

How do myotubes differentiate into different types of muscles (proposed strategies)?

Answer 17

Change in muscle fiber direction (abdominal muscles) Tangential splitting into layers Fusion of adjacent myotomes (for large muscles)

Question 18

How do skeletal muscles become innervated

Answer 18

• Innervated early as pre-muscle masses - Some pre-muscle masses take their innervation with them as they migrate - Spinal nerves innervate somite derived skeletal muscles of trunk and limbs

Question 19

What does myotome mean structurally?

Answer 19

All of the muscles that come from a single pair of dermomyotomes (which have the same innervation)

Question 20

What innervates myotomes?

Answer 20

Branches of primary Rami of Spinal nerves

Question 21

What are the muscles innervated by dorsal primary rami?

Answer 21

Epaxial muscles (above the axis) - Back muscles

Question 22

What muscles are innervated by the ventral primary rami?

Answer 22

Hypaxial muscles (below the axis) - abdominal muscles

Question 23

How many weeks does it take for all muscle groups to have formed

Answer 23

8 weeks

Question 24

What is abnormal skeletal muscular development

Answer 24

Absence of a muscle or part of a muscle

Question 25

What is missing in Poland syndrome

Answer 25

Pectoralis major

Question 26

What is missing in Prune Belly syndrome

Answer 26

Abdominal muscles

Question 27

What is congenital toricollis

Answer 27

Missing sternocleidomastoid

Question 28

What is the most common congenital muscle problem?

Answer 28

Muscular dystrophy

Question 29

Myoblasts from the _________ dermomyotome form primaxial domain muscles

Answer 29

dorsomedial

Question 30

Myoblasts from the ___________ dermomyotome form abaxial muscles

Answer 30

dorsolateral

Question 31

What two tissues make up the skeleton?

Answer 31

Bone and cartilage

Question 32

What embryonic progenitor tissues are used to form skeletal tissues?

Answer 32

Mesenchyme

Question 33

In the trunk, mesenchyme is derived from…

Answer 33

Paraxial mesoderm

Somatic mesoderm

Question 34

In the head, mesenchyme is derived from…

Answer 34

Neural crest ectomesenchyme Head mesoderm

Question 35

What is STFM

Answer 35

Skeletal Tissue forming mesenchyme

Question 36

What are some of the shared features of STFM development?

Answer 36

• Often skeletal progenitor cells migrate or are displaced from their site of origin
• STFM condenses into pre-skeletal condensations

Question 37

What influences STFM differentiation?

Answer 37

• Epithelial-mesenchymal interactions
• Specific transcription factors
• Other signaling molecules

Question 38

What is the osteoblast-specific transcription faster gene (bone master gene)

Answer 38

RUNX2a (CBFA1)

Question 39

What is the chondroblast specific transcription factor

Answer 39

Sox 9

Question 40

What is the first step in the primary differentiation pathways of STFM?

Answer 40

The initial step is a condensation of pre-skeletal mesenchyme (influenced by signals from adjacent epithelium)

Question 41

What transcription factors are involved in endochondrial ossification?

Answer 41

Sox-9 Ihh; VEGF RUNX-2

Question 42

What transcription factor is involved in intramembranous ossification?

Answer 42

Runx-2

Question 43

What is the ossification center?

Answer 43

The area of bone where ossification begins

Question 44

Where are locations for the primary center of ossification?

Answer 44

The initial center to appear

• Shaft of long bone
• Center of flat bone

First appears at 7 weeks of development

Question 45

When would you see secondary ossification centers?

Where would you see secondary ossification center?

Answer 45

Appear in perinatal, postnatal or postpuberal period Ends of long bones (epiphysis), heads of ribs

Question 46

When does the secondary ossification center close?

Answer 46

20s -30s and controlled by hormones

Question 47

Why are there spaces between the long bones of the limbs as seen on the X-ray of a newborn?

Answer 47

Those spaces are still cartilage

Question 48

What is Bone Age?

Answer 48

The amount of Epiphyseal cartilage retained - Comparison of bone and chronological ages is a measure of skeletal growth and maturation

Question 49

Generalized Skeletal Tissue Dysplasias

Answer 49

May affect all or part of the skeleton:

• Often affect growth and may result in short or tall stature
• Often a component of the ECM, causing it to be defective
• Often there is a recognized genetic component

Question 50

Marfan’s syndrome

Answer 50

Alteration of Fibrillin production

Question 51

Mucopolysaccharidoses

Answer 51

Defect in synthesis, storage and transport of a particular lysosomal enzyme - results in accumulation of substrate (lysosomal storage diseases)

Question 52

Altered hormone secretion can affect skeletal growth. What happens in

Growth Hormone (Increases)

Growth Hormone (Decreases)

Thyroid Hormone (Decreases

Answer 52

Growth hormone Increased: Lead to Gigantism

Growth Hormone Decrease: Lead to Pituitary Infantilism (Dwarfism)

Thyroid hormone Decrease: Lead to Cretinism (mental deficits included)

Question 53

Which disease results from a mutation in the gene encoding fibroblast growth factor receptor 3 (FGFR3)?

Answer 53

Achondroplasia

Question 54

What is the abnormality seen in achondroplasia?

Answer 54

Failure of endochondral ossification

Question 55

What lower extremity deformity is seen in achondroplasia?

Answer 55

Genu varum (bowlegs)

Question 56

What cell functions abnormally in osteopetrosis?

Answer 56

Osteoclasts

Question 57

How would you treat osteopetrosis?

Answer 57

Bone marrow transplant

Question 58

What are the two parts of a skeleton?

Answer 58

Axial and appendicular

Question 59

What’s the genetic abnormality in osteogenesis imperfecta?

Answer 59

Type 1 collagen

Question 60

What types of bones are formed by:

• Paraxial mesoderm
• Somatic mesoderm

Answer 60

Paraxial mesoderm: vertebral column and ribs Somatic mesoderm: sternum and limb skeleton

Question 61

Which signal causes the medial and inferior portions of the somite to become mesenchymal cells?

Answer 61

Sonic the hedgehog

Question 62

What is the scleratome?

Answer 62

Precursor to the vertebrae formed from portions of the somites

Question 63

Scleratome tissue organizes into _____ and _______ subdivisions

Answer 63

Cranial; caudal

Question 64

What is resegmentation of Scleratome tissue?

Answer 64

The process by which the two subdivisions of the scleratome separate from each other due to the spinal nerve cutting across them

• The cranial portion of one scleratome fuses with the caudal portion of an adjacent scleratome
• Myotome does not separate with the scleratome and ends up linking pairs of vertebrae

Question 65

Subdomains of scleratome tissue:

Central:

Ventral:

Dorsal:

Lateral:

Somitocoel cells:

Answer 65

Central: Pedicle, proximal ribs

Ventral: Vertebral body, IV disc

Dorsal: Dorsal part of neural arch, spine

Lateral: Distal rib

Somitocoel cells: Vertebral joints, IV disc, proximal ribs

Question 66

Cells from the cranial half of the scleratome contribute to:

Answer 66

Vertebral body, small parts of neural arch and distal rib (in thoracic region

Question 67

Cells from the caudal half of the scleratome contribute to:

Answer 67

Vertebral body, transverse process, most of neural arch and proximal part and main part of distal rib (in thoracic region)

Question 68

Cells at intersegmental boundary and somatocoel cells (of the scleratome) form:

Answer 68

The intervertebral disc

Question 69

Patterning of vertebrae is determined by:

Answer 69

Homeobox genes (Hox genes)

Question 70

What happens to the costal process in the thoracic region?

Answer 70

Extends laterally and becomes a rib

Question 71

Closure of the neurocentral junction (primary growth center of vertebrae) occurs at what age?

Answer 71

3 - 6 years old

Question 72

What is the klippel-fiel sequence?

Answer 72

Fusion of cervical vertebrae

• Number of cervical bodies is less than normal.

Question 73

Dysraphism

Answer 73

Open Vetebral Column

Due to failure of fusion of the Nueral arches of the A SINGLE vertebra process.

Question 74

Rachischisis

Answer 74

Many or all vertebrae have unfused spinous processes

Extensive opening of vertebral column with CNS involvement

Question 75

Spina Bifida

Answer 75

Variation in length of opening of vertebral column

• lack of formation of spinous processes
• Only a few vertibrae are unfused

Question 76

Defects Resulting in assymetry

Answer 76

Congenital kyphosis

Congenital lordosis

Congenital scoliosis

Question 77

Two causes of congenital scoliosis

Answer 77

Failure of segmentation

Failure of formation

Question 78

Describe the formation of the sternum

Answer 78

Sternal bands fuse together to form cartilage sternum; ossification centers lead to an ossified sternum

• Sternum is the location of the first ossification centers in development

Question 79

Abnormal development of ribs can lead to…

Answer 79

• Extra ribs
• Abnormal ribs (fused or forked)
• Clefts
• Pectus Excavatum (hollow)
• Pectus carinatum (keel shaped)

Question 80

What is the basic organizational plan of tissues in the adult limb?

Answer 80

Consist of:

• Skeletal elements
• Skeletal muscles
• Fibrous connective tissue
• Neurovascular Structures
• Skin

Question 81

Limb Precursor tissues

Answer 81

Limb mesenchyme (somatic mesoderm and somitic mesoderm)

Surface ectoderm

Question 82

Development of the upper limb is ahead of that in the lower limb by about __ - __ days

Answer 82

1-2

Question 83

Step 1 of the limb development

Answer 83

Establishment of the limb field

• Bilateral areas of somatic mesoderm induced by gene expression

Question 84

What is the area between the limb fields called?

Answer 84

Flank region

Question 85

Step 2 of Limb development

Answer 85

Budding (appearance)

• Located at specific axial levels
• Budding is an inherent property of mesoderm

Question 86

What is the name of the thickening that appears at the dorsal/ventral surface interface?

Answer 86

Apical Ectodermal Ridge (AER)

Question 87

Step 3 of limb development

Answer 87

Elongation of the limb

• Segments appear along a proximal-distal axis
• Elongation results from epithelial-mesenchymal intearactions at AER/mesoderm interaface

Question 88

Step 4 of limb development (week 5)

Answer 88

Tissue formation and organization

• Differentiation occurs in proximal-distal direciton
• Somatic mesoderm condenses to form cartilage
• Somite derived myoblasts migrate into limb to form skeletal muscles
• Nerves and vascular precursors migrate into limb

Question 89

What are the three linear axes upon which limb development occurs?

Answer 89

Proximal-Distal: Elongation, segment formation

Anterior-Posterior: Cranial-caudal/Preaxial-postaxial borders, digit development

Dorsal-Ventral: Compartments - muscles and neurovascular structures

Question 90

What allows a bud to become a 3 part limb?

Answer 90

Reciprocal signaling

• Mesenchyme produces Fgf10 which goes to ectoderm which responds by producing Fgf8 (Fgf8 produces the AER)
• Retinoic acid - stronger proximally and weaker distally
• Fgf and Wnt - stronger distally and weaker proximally

Question 91

Role of Mesenchyme in limb development

Answer 91

Induces the AER (Fgf10)

Sustains AER (Fgf10)

Determines limb type (upper or lower)

Question 92

AER role in limb development

Answer 92

• Maintains a proliferating pool of mesenchyme cells for linear growth (Fgf8)
• Maintains A-P axis signaling center
• Interacts with P-D and A-P specific proteins to provide mesenchyme cells with positional information

Question 93

What is the fate of the mesenchyme adjacent to the AER?

Answer 93

Forms segment specific skeletal elements Forms fibrous connective tissue

Question 94

Removal of the AER leads to…

Answer 94

Limb truncation - elongation of the limb stops

Question 95

How common are limb malformations?

Answer 95

2/1000 births (1/500)

Question 96

Types of limb anomalies (7)

Answer 96

Failure of formation of parts

Failure of differentiation

Duplication of parts

Overgrowth of parts

Undergrowth of parts

Congenital Constrictive Band syndrome

Generalized skeletal abnormalities

Question 97

Failure of communication between AER and mesenchyme can lead to…

Answer 97

Failure of formation of parts

Question 98

What is a fibular hemimelia

Answer 98

Congenital absence of the fibula

• most common congenital absence of long bone extremities

Question 99

What is Phocomelia? What drug can cause it?

Answer 99

Distal part of the extremities are attached directly to the body;

Thalidomide

Question 100

What develops along the anterior-posterior axis in limb development?

Answer 100

Digits

Question 101

What is the zone of polarizing activity (ZPA)?

Answer 101

A signaling center along the posterior border of the limb that controls pattern of digits

• mediated by Sonic Hedgehog (Shh)
• Retinoic acid mimics Shh

Question 102

What happens if an additional ZPA signal is added?

Answer 102

Secondary focus of Hox gene expression - duplication of the digits

Question 103

How does apoptosis play a role in limb development?

Answer 103

Separation of digits

Absence of distal phalanx of large digit

Question 104

Failure of differentiation leads to…

Answer 104

Syndactyly - Two partially combined toes

Sirenomelia - Combined legs

Triphalyngeal Thumb - Three phalanges in the thumb

Question 105

What type of inheritance is involved in duplication of digits?

Answer 105

Autosomal dominant

Question 106

Mediators of Dorsal-Ventral patterning

Answer 106

Secreted factors: Wnt 7a

Transcription factor engrailed (En)

Question 107

In the anatomical position the thumb is…

Answer 107

Cranial

Question 108

What is developmental dysplasia of the hip?

Answer 108

Underdevelopment of femoral head or hip socket and general joint laxity

More common in females

Question 109

Cleidocranial Dysplasia

Answer 109

Missing clavicle and facial anomalies

Question 110

What is talipes equinovarus?

Answer 110

Club foot - turning in of the feet