Lecture 9 Blastulation.pptx

Transcript

Blastulation,
partitioning, and MBT
Lecture 9
Weismann’s theory of determinative
development

1880s started as a Lamarckian, became a
Darwinist
Famous for elucidation of germ plasm
theory – cleavage partitions different
ingredients to different daughter cells.
Roux’s evidence for mosaic
development

conclusion that frog cleavage divisions
are strictly mosaic – NOT!
If you tie a loop of baby hair and tighten
slowly to separate blastomeres, both
develop normally, but ½ regular size
Driesch’s evidence for regulative development
(1890s-1910)

Conclusion that sea urchin cleavage is
regulative
But half regular size – entelechy – vitalist
perspective – some life force divided
Why the discrepancy?
One possibility is that sea urchins and frogs use different strategies
for cell fate determination
Other possibility is that observed differences are due to differences
in experimental procedure
TH Morgan repeated Dreisch’s sea urchin experiment – but this time
on frog
 both blastomeres developed into complete embryos
Mosaic vs regulative development
Regulative – cell fate is established later, via cell – cell interactions
predominates in late cleavage divisions in most animals
Mosaic or determinative – cell fate is established/restricted at each
cell division
C. elegans
Most organisms develop by a mix of both strategies.
C. elegans lineage restriction (mosaic
development)
Mid-blastula transition
Transition from maternal control of development to
zygotic control
Most evident in animals that have large eggs (birds, fish,
fruit flies, amphibians)
transition from early blastula
Cleavage divisions that are rapid, lack gap phases
Absence of transcription
mRNAs and proteins deposited in egg during
oogenesis carry out all cellular processes
… to late blastula
Slowing of cell cycle, introduction of gap phases, G1,
G2
Asynchronous divisions
Zygotic transcription
Many maternal mRNAs are actively destroyed
MBT in fly, frog, mouse
Mechanism of MBT
What controls timing of MBT?
counting cleavage divisions?
counting time from first cleavage division?
Diminution of critical stores of cytoplasmic or nuclear materials?
Experiment #1
Remove cytoplasm from egg but leave
nucleus:
Smaller embryo undergoes normal
cleavage divisions but enters MBT early
(fewer cell divisions and cell number)
Experiment #2
Addition of cytoplasm only
Larger embryo undergoes normal cleavage, but MBT
occurs later (more cell divisions, and consequently
more cells)
Experiment #3:
Create a haploid frog embryo
Cleavage divisions occur as normal
even though each cell has half the
normal amount of DNA
MBT occurs later with more cells

Experiment #4
Inject surplus of non-frog DNA
Cleavage divisions occur as normal
even though each cell more DNA
than normal
MBT occurs earlier with more cells
Mechanism of MBT
Studies in Xenopus and Drosophila  MBT triggered when
Nuclear/Cytoplasmic ratio reaches critical point
A possible model:
A critical factor is deposited into the egg maternally and is “used up” by
dividing nuclei
Drosophila MBT – best understood at molecular level
1st 14 embryonic cell cycles are within a common
cytoplasm
- 8 minutes/ cycle
- nuclear divisions start slowing down at ~ cycle 10
- MBT at cycle 14
dramatic slowing of cell cycle
zygotic transcription activated, maternal mRNAs
destroyed
Exhaustion of Cellular Stores

Cell cycle depends on Cyclin dependent kinases (Cdk)
-activated by cyclin binding - cyclin is degraded after each cell division
-activated by Cdc25
Probably involves consumption of histone stores as well
Mitotic cyclins are present in egg before fertilization
Each mitosis in embryo, overall mitotic cyclin levels go down
due to being destroyed after use. By cycle 11 overall cyclin
levels drop enough to get slowing of cell cycle
 longer gap between cell divisions  some genes able to be
transcribed
 Transcription of genes that promote destruction of Cdc25
 even longer gap in cell division  allows time for most genes
to be transcribed
 these genes include genes involved in maternal mRNA
degradation, genes required for gastrulation
Compaction in mammals

In mammals – transition from blastula to morula
High level expression of E-cadherin – cell-cell adhesion molecule
 all cells begin to associate tightly with each other
 cells become polarized – outer surface = apical contains microvilli
 compaction results in outer and inner cells
- cells on inside will contribute to embryo
- outer cells will contribute to placenta
Compaction begins
Inner vs outer cells have distinct fates after
compaction
Completion of the cleavage divisions

fish blastoderm

mouse blastocyst
frog blastula
Blastula stage
Also known as blastoderm or blastocyst depending on
organism
Completion of cleavage divisions, just before gastrulation
In most cases the result is an asymmetric embryo
Cells at different locations will give rise to different cell types
eg. mammals
inner cell mass  embryo proper + some extra-embryonic
trophoectoderm  extra-embryonic
Cavitation to create fluid filled centre – the bastocoel