1 / 26

Neural Development

Neural Development. How do cells become nerve cells? Environmental factors Inductive events Genetic factors Competence Cell lineage Timing. 1. Focus on the cortex. 2. The cortex has 6 layers---how do they develop?. superficial. deep. 3. Cortex Development: Formation of layers

gabby
Download Presentation

Neural Development

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Neural Development How do cells become nerve cells? • Environmental factors • Inductive events • Genetic factors • Competence Cell lineage Timing 1

  2. Focus on the cortex 2

  3. The cortex has 6 layers---how do they develop? superficial deep 3

  4. Cortex Development: Formation of layers • neural progenitors rapidly divide in the ventricular zone • they keep dividing to produce more progenitors OR • they undergo terminal differentiation and migrate to • final cortical destination • migrating neurons move along radial glia radial glia marginal zone cortical plate intermediate zone ventricular zone http://www.stanford.edu/group/skmlab/movies/qtmovies/rad_migr.mov 4

  5. At mitosis, precursor self-renews or differentiates Choice point for the precursor Cell cycle precursor neuron precursor precursor precursor precursor 5

  6. How do layers of the cortex form? Are there different kinds of progenitors? (layer 1-specific progenitor) Does one progenitor make all cell layers? LINEAGE MODEL 1 2/3 4 5 6 6

  7. Basic Techniques in Neurobiology: • Neuronal Birthdating with 3H-thymidine • 3H-thymidine is incorporated into the DNA during replication • It marks all mitotic cells • It disappears in ~2-4 generations. time 3H-thymidine 7

  8. Basic Techniques in Neurobiology: • Lineage Tracing • Use retrovirus (incorporated into a cell’s genomic DNA but not infectious) • The virus DNA will be inherited by all the daughter cells (it doesn’t become diluted) time virus 8

  9. 1 CP 2 3 IZ 4 5 VZ 6 Are there layer-specific progenitors? Expt: Use lineage tracing to label single neurons and follow their progeny. Result: Single cells generate neurons in multiple layers. This result disqualifies the lineage model. 10

  10. Different layers form at different developmental times “Inside First-Outside Last” development of cortical layers 1 2/3 4 5 6 Post-natal Day 2 (P2) Embryonic Day 26 (E26) Born Last Born First Dev Time 10

  11. OBSERVATION: A single progenitor first produces layer 6 neurons, later produces layer 1 How does one progenitor produce different cell fates? 11

  12. Does the environment instruct the layer fate? Expt: Transplant Progenitor cells from early stage to late stage What would they normally become? What do they become when the host environment is changed? E36 = Early P2 = Later Early into Later Most are layer 4 Most are layer2/3 Most are layer 2/3 Early cells can take on later fate Model: Environment influences cell-fate 12

  13. Does the environment instruct the layer fate? Expt: Transplant Progenitor cells from late stage to early stage What would they normally become? What do they become when the host environment is changed? Early Earlier Early in to earlier 13

  14. Summary of many transplantation experiments Put early progenitor into late host environment, takes on late fate Put late progenitor into early host environment, takes on late fate Both the environment and the progenitor determine cell fate A) the age of the environment restricts cell-fate B) the age of the progenitor restricts cell-fate MODEL OF PROGRESSIVE RESTRICTION 14

  15. Eventsinside the cell and outside influence layer decision

  16. One extracellular cue that influences cortex formation • Reeler mutant mice (missing Reelin protein) • Identified because of severe movement disorders • Mutation in an extracellular matrix protein (?) • Cortex is built outside in • 26 human disorders associated with cortex malformation • One form of lisencephaly (smooth brain) is a Reelin mutant 16

  17. Cortex development in Reeler mutant mice • Precursor cells never separate from the cortical plate • Grows Top down instead of Bottom up Normal Reeler Model: Reelin is an important extracellular cue that separates verticular zone from marginal zone 17

  18. Decision point for the precursor Cell cycle neuron precursor precursor 18

  19. General Principle: An intracellular timing mechanism regulates cell fate decisions • At mitosis, precursor continues to self-renew or differentiates Choice point for the precursor Cell cycle precursor neuron precursor precursor precursor precursor 5

  20. A Timing Mechanism for Neural vs Glial Fate precursor 19

  21. A single precursor cell will first produce neurons then glia Neural markers Glial markers 20

  22. A single neuroblast clone will produce many different cells • In Drosophila, sequential expression of transcription factors • induces different fates • Expression of transcription factors is controlled by cell cycle Transcription factors 22

  23. Every cell in C elegans is determined by lineage Sydney Brenner 2002 Nobel Prize Genetics of Development in C elegans “In late 1962, Francis Crick and I began a long series of conversations about the next steps to be taken in our research. Both of us felt very strongly that most of the classical problems of molecular biology had been solved and that the future lay in tackling more complex biological problems.” 23

  24. Why C. elegans? • Reproduce sexually and asexually • Each worm makes 200 eggs • Develops from egg to larvae in 12 hrs • Total number of cells is 1000 • Total number of neurons is 300 24

  25. Neurons 1-25 in C. elegans Name Cell divisions Cell fate ADAL AB.plapaaaapp Ring interneuron ADAR AB.prapaaaapp Ring interneuron ADEL AB.plapaaaapa Anterior deirid, sensory neuron ADER ABprapaaaapa Anterior deirid, sensory neuron ADFL AB.alpppppaa Amphid neuron ADFR AB.praaappaa Amphid neuron ADLL AB.alppppaad Amphid neuron ADLR AB.praaapaad Amphid neuron AFDL AB.alpppapav Amphid finger cell AFDR AB.praaaapav Amphid finger cell AIAL ABplppaappa Amphid interneuron AIAR AB.prppaappa Amphid interneuron AIBL AB.plaapappa Amphid interneuron AIBR AB.praapappa Amphid interneuron AIML AB.plpaapppa Ring interneuron AIMR AB.prpaapppa Ring interneuron AINL AB.alaaaalal Ring interneuron AINR AB.alaapaaar Ring interneuron AIYL AB.plpapaaap Amphid interneuron AIYR AB.prpapaaap Amphid interneuron AIZL AB.plapaaapav Amphid interneuron AIZR AB.prapaaapav Amphid interneuron ALA AB.alapppaaa Neuron, sends processes laterally ALML AB.arppaappa Anterior lateral microtubule cell ALMR AB.arpppappa Anterior lateral microtubule cell 25

  26. Lessons in Development • Lineage is an important factor in development • (Different cell fates can be determined by cell division) • 2. The cortex develops through the • process of progressive restriction • cues in the environment and within the cell • determine its fate • 3. The time in which you are born will • determine what you become 26

More Related