Somitogenesis

Question 1

Where does the somite originate from?

Answer 1

Paraxial mesoderm (which forms into sclerotome, myotome and dermatome)- produced by the presomitic mesoderm

Question 2

What doe the intermediate and lateral mesoderm differentiate into?

Answer 2

Intermediate mesoderm- kidney and gonads

lateral mesoderm- splanchnic, somitic, extra-embryonic

Question 3

What is the presomitic mesoderm (PSM) generated by?

Answer 3

The cranial (rostral) primitive streak & the tail bud, involving proliferation, specification and emigration

Question 4

What pathways are invovled in somitogenesis and how do they interact?

Answer 4

Wnt, FGF, RA and BMP pathways are required, interacting with each other directly or indirectly, via positive & negative feedback loops

Question 5

How does the embryo grow during somitogenesis?

Answer 5

Traditionally, the PSM is thought of as “regressing” that is moving backwards, leaving somites behind as it goes. In fact, the whole embryo is growing during this phase, and all tissues are moving, relative to one another

• somites laid down sequentially, cranial to caudal

Question 6

In what manner are somites formed (e.g. spacially, temprorally)?

Answer 6

Formed regularly, with the time characteristic of the species (e.g. 1 pair each in 2h mouse, ~5h human, 1.5h chick)

Question 7

What does the number of somite pairs developed depend on?

Answer 7

The total somites formed also characteristic of the species, independent of variations in embryonic size (e.g. zebrafish 33 pairs, human 44, mouse 65)

Question 8

How do somite halves differ?

Answer 8

Cranial & caudal somite halves are different

Question 9

What encodes somite fate?

Answer 9

Each somite has different fate, encoded in the PSM by Hox genes

Question 10

How are somites initially paired and what do thety differentiate to?

Answer 10

Initially paired epithelial spheres each side of neural tube
Differentiate to:
Dermomyotome and sclerotome (vertebrae)
Myotome: epimere, hypomere, limb muscle
Dermatome: dorsal dermis

Question 11

What is the fate of the most cranial 5 somites?

Answer 11

Occipital bone

Question 12

What does the notochord develop into?

Answer 12

Nuclues pulposus

Question 13

What happens if neural arches fail to fuse?

Answer 13

Spina bifida occulta

Question 14

What abnormalities of the sclerotome exist?

Answer 14

Abnormal segmentation
Hemivertebrae, or fused vertebrae
Scoliosis (lateral curve of spine)
Klippel-Feil syndrome (brevicollis)
Short neck, reduced number of cervical vertebrae
Failed fusion or non-union of arches 
Spina bifida occulta
Non-union of sternum: Split xiphoid process

Question 15

What is the Fate of the myotome?

Answer 15

Myotome into epimere, hypomere, limb muscle

Epimere: epaxial extensor muscles of spine
Dorsal ramus of spinal nerve

Hypomere: flexors of spine; outer, intermediate, inner layers in thorax & abdomen
Ventral ramus of spinal nerve

Nerve/muscle segmentation

Question 16

Where do nerves grow in from?

Answer 16

Nerves grow in from spinal nerves of neural tube

Question 17

What are Myoblasts attracted by?

Answer 17

Myoblasts attracted by HGF (scatter factor, only in limb field mesoderm; c-met receptor in myotome)

Question 18

What are muscle patterns dicated by?

Answer 18

Connective tissue

Question 19

Why do muscles produce trophic signals?

Answer 19

For nerves to follow

Question 20

What does dermatome form?

Answer 20

Dermis, subdermal connective tissue

Question 21

What is the fate of the dermatome?

Answer 21

Dermatome: area of skin supplied by a single spinal nerve & its ganglion

Dorsal dermis from dermomyotome

Adjacent spinal nerve - sensory innervation

Initial segmental pattern in limb buds converted to proximo-distal pattern

Rotation of limbs: opposite fore & hind

Outwards fore: elbows caudal
Inward hind: knees cranial

Question 22

How is differentiation of the somite controlled?

Answer 22

LOL JOKE HAHAHAHA

The slide says:

Shh secreted from notochord, along with NT-2, Wnt1,3 from the dorsal neural tube and BMP4/FGF from the lateral plate mesoderm = contributes to somite differentiation

Question 23

What do the signalling molecules involved in somitogenesis differentiate?

Answer 23

Notochord secretes Shh which induces Pax1 in ventral paraxial mesoderm to produce sclerotome.

Wnt1/3 released from dorsal (roof) plate of neural tube induces Myf5 in medial part which forms body wall muscles

NT-3 also secreted from neural tube acts on dorsal part of mesoderm which will form dermis

Wnt secreted from epidermis and BMP4/FGF from lateral plate mesoderm induces Pax3 and MyoD in lateral paraxial mesoderm which will form epaxial muscles

(read slide 20 of somitogenesis it’s lit)

Question 24

What is the syndetome?

Answer 24

The syndetome is the progenitor population for tendons

Question 25

Name properties of the somite halves: cranio-caudal

Answer 25

Cranio-caudal halves of somites have different properties

Neural crest migration
Motor neurone migration
Formation of vertebrae

Specified in PSM, before somite boundary formation

Several genes expressed in half stripes in somitomeres S0 and S-1

Caudal half: HES1, Delta1 (Notch signalling)
Cranial half: MesP (bHLH, Mesp2 nulls lose cranial identity), EphA4 (EPH receptor)

Question 26

What do Cranial & caudal halves make?

Answer 26

Centrum

Question 27

Where do intersegmental arteries between somites come to lie?

Answer 27

Midway over bodies

Question 28

Why do myotomes bridge intervertebral disks?

Answer 28

So they can move vertebrae

Question 29

Where do spinal nerves pass through?

Answer 29

Spinal nerves pass through somites, but come to run through intervertebral foramina

Question 30

Where is somite axial identitiy encoded?

Answer 30

Presomitic mesoderm

Question 31

What TF is important in somitogenesis?

Answer 31

Hox genes-
Hox genes bind DNA in a sequence-specific fashion

They regulate expression of adjacent/nearby genes

Confer positional identity along the A-P (cranio-caudal) axis of the trunk
(highly conserved)

Question 32

Desribe Hox gene evolution

Answer 32

Vertebrates have 4 Hox gene clusters, which have arisen from two duplication events of an ancestral chromosome

Gene order along the chromosome corresponds to the position of expression within the embryo

Gene transcription within each Hox cluster displays spatio-temporal co-linearity

Question 33

Why are Hox genes important?

Answer 33

• they are involved in somite identity

- code their vertebral region (e.g. cervical/thoracic/lumbar/sacral/caudal

Question 34

How is the regular formation of somites achieved?

Answer 34

The clock and wavefront model

In theory, what is needed is a clock mechanism to mark time, plus a wavefront or “trigger” to form a somite at each set period

Oscillations of the clock are generated by delayed negative feedback on gene expression

The trigger is provided by a gradient(s) threshold(s) of signalling proteins

Question 35

Have ago at explaining the wave of gene expression in somitogenesis

(good luck xxx)

Answer 35

PSM cells have cyclic gene expression, with the same period as somite production: part of the somitogenesis clock. Typically, there is an apparent wave in PSM, and a persistent stripe cranially (rostrally). The “wave” is actually rapid switching on and off of expression, and suggests close coupling between cells, which has been shown in real time at the single cell level using a luciferase reporte

Question 36

Describe the three-tier model of segmentation clock

Answer 36

bottom tier: single cell oscilators- so gene expression transcribes and translates protein which then inhibits further gene expression in a negative feedback loop

Middle tier: local synchronisation- involves 2 cells communicating with eachother (but that’s all i can decipher)

Upper tier: global control of slowing and arrest- results in elongation of A/P axis

Question 37

What TFs cycle in PSM in all species?

Answer 37

The expression of Hes/Her transcription factors, effectors of Notch signalling, cycle in PSM in all species

Question 38

Explain the single cell genetic oscillators: e.g. hes/her

Answer 38

Single cell genetic oscillators.
(A) Single-cell oscillator- gene products repress gene activity. This negative-feedback loop involves a sequence of steps. The Her/Hes gene is transcribed with a basal rate and mRNA is transported from the nucleus and translated. Proteins are transported back into the nucleus where they dimerize to form a transcriptional repressor. This repressor accumulates and binds the gene promoter to inhibit gene expression. Finally, when gene products (mRNA, protein, dimer) decay, the gene repression is released and the cycle can start over again.
Oscillations of mRNA and protein concentrations in the single cell oscillator.

Question 39

What proteins modify Notch signalling?

Answer 39

FRINGE :) :) :) e.g. lunatic

Question 40

What cyclic genes are involved in somitogenesis?

of-course, none of this is well understood

Answer 40

Cyclic genes belonging to the Notch and FGF pathways oscillate in opposite phase to cyclic genes of the Wnt pathway. A large number of the cyclic genes are involved in negative feedback loops. The basic circuitry of the three signalling pathways is represented.

All 3 pathways influence expression of Tbox genes e.g. Tbx6

Question 41

Describe local synchronization through intercellular communication in the segmentation clock:

Answer 41

How neighboring oscillating cells send and receive signals via the Delta-Notch pathway:

The genes that encode the Delta ligands are repressed by the same factors that control the single-cell oscillator feedback loop.

The Delta gene is transcribed and the mRNA exported to the cytoplasm. The mRNA is translated, and the protein undergoes post-translational modifications before becoming an active ligand for Notch receptors on the neighboring cell.

Upon ligand/receptor binding, the Notch intracellular domain (NICD) is proteolytically cleaved from the Notch receptor of the neighboring cell and translocates to the nucleus, where it positively regulates the transcription of cyclic genes, such as the Hes/Her gene.

Notch signaling is not required for basal Hes/Her gene transcription. The details of the feedback loop of single-cell oscillator are dimmed to highlight coupling in this figure. Pre-somitic mesoderm cells communicate with multiple neighbors, effectively sitting in a 3D lattice of mobile coupled oscillators.

Question 42

What is expressed in a pulsatile manner in the causal PSM and how do they act?

Answer 42

Notch and DLL

Notch protein precedes DLL

Notch translated and translocates to cell membrane

Notch & DLL at cell membrane = activation

Activation = NICD for Notch effectors, while DLL endocytosed

Question 43

What holds cells in the presomitic state? (part of the wavefront trigger)

Answer 43

A gradient of FGF8 protein, formed by mRNA instability.

Question 44

Describe the “wavefront” or gradient threshold

Answer 44

FGF & Wnt gradients similar, but produced by RNA and protein decay respectively

Cells leaving the tail bud stop de novo production of Wnt3a protein, so levels drop with time

When a threshold level is reached, cycling stops, and a cell is ready to become part of a somite

FGF may enhance Wnt activity, through Akt & Gsk3beta (sexy)

A Retinoic Acid gradient, formed by RALDH2, is in the opposite direction and antagonizes FGF

Question 45

What positions the determination front?

Answer 45

Antagonistic gradients of FGF/Wnt signalling and RA signalling

Question 46

What happens as the embryo extends posteriorly?

Answer 46

The determination front moves caudally

Question 47

What happens to cells that reach the determination front ?

Answer 47

They are exposed to the periodic clock signal, initiating the segmentation program by repressing Tbox genes and activating simultaneously expression of genes such as Mesp2 in a stripe domain that prefigures the future segment. This establishes the segmental pattern of the presumptive somites.

Question 48

Describe global gradients and then teach me xx

Answer 48

Global gradients control slowing and arrest of oscillating cells.

An elongating vertebrate axis showing cyclic gene expression patterns in blue/white and arrested segments and somites (solid boundaries).

Gradients of fibroblast growth factor (FGF) and Wnt (brown) span the tissue from the posterior. An opposing shorter-range retinoic acid (RA) gradient expands from the recently formed somites. The actual shape of these gradients is not known.

Sustained high-frequency oscillations are observed in the posterior region of the tissue. Oscillators gradually slow down as they approach the wavefront of arrest.

The panel on the left shows the different stages that single-cell oscillators undergo as they traverse the tissue. The right panel highlights the maturation program of pre-somitic mesoderm cells, running in parallel to segment length specification controlled by the clock.

Question 49

What happens when a group of cells at the right phase of the oscillating cycle hits the wavefront of FGF/Wnt/RA?

Answer 49

Cycling stops and the cells are induced to express Mesp2, which requires Tbx6 expression.
It is Mesp2, interacting with Tbx6 and residual Notch NICD, that sets the boundary for somite border formation

Question 50

What does Notch coordinate?

Answer 50

cyclic expression among PSM cells, synchronizing the clock and the spread of expression

Question 51

What does the Wnt, FGF and RA threshold represent?

Answer 51

Represents the wavefront with Wnt3a

High levels (above threshold): clock on
Low levels (below threshold): clock off

Question 52

What happens to cells at the correct phase of cycling?

Answer 52

Cells at the correct phase of cycling are competent to respond to the wavefront, switching on Mesp2 and stopping cycling

Question 53

What do Mesp2, Tbx6 and Notch do?

Answer 53

Mesp2, Tbx6 and Notch interact to promote somite border formation and cranio-caudal somite compartments

Question 54

In the WT, what does RA do?

Answer 54

Prevents PSM lateralization

Question 55

What happens in raldh2 -/-?

Answer 55

lateralization and asymmetric segmentation

Question 56

What does Mutation of Human Orthologs of the Segmentation Clock Genes Leads to ?

Answer 56

Congential scoliosis

Question 57

Name some dull, annoying Human mutations

Answer 57

Spondylocostal dysostoses
Multiple vertebral segmentation defects
Often with rib defects

DLL3 (Bulman et al, 2003)
Notch ligand

LFNG (Sparrow et al, 2006)
Notch modulator

MESP2 (Whittock et al 2004)

No1cares (Khadija et al 2017)