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BCS/NSC 249 Developmental Neurobiology Mary Wines-Samuelson

This course provides an overview of the development of the nervous system, covering topics such as neural induction, regionalization, neurogenesis, migration, differentiation, and regulation of neurogenesis. It explores the historical concepts of development and the origins of developmental biology, and discusses the role of genetics and signaling in cell fate determination and embryonic patterning. The course also examines the development and disease relationship in neurobiology.

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BCS/NSC 249 Developmental Neurobiology Mary Wines-Samuelson

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  1. BCS/NSC 249 Developmental Neurobiology Mary Wines-Samuelson Email: mary_wines-samuelson@urmc.rochester.edu Textbook: Development of the Nervous System Sanes, Reh, and Harris Lectures on Blackboard; non-textbook reading materials

  2. NSC 249--first part Jan. 16: Course overview and a discussion of gene regulation as it applies to neural development NO CLASS ON 1/21/19 (MLK Day) Jan. 23: Neural induction and regionalization I Jan. 28: Neural induction and regionalization II Jan. 30: Neurogenesis, migration and differentiation in the nervous system I Feb. 4: Neurogenesis, migration and differentiation in the nervous system II Feb. 6: Neurogenesis, migration and differentiation in the nervous system III Feb. 11: Regulation of neurogenesis in primate brain Feb. 13: Neurite outgrowth and pathfinding I Feb. 18: Neurite outgrowth II End of material for Exam I Feb. 20: EXAM I

  3. Key points of today’s lecture: -Historical concepts of development -Fate restriction vs. pluripotency -Genetic control of differentiation (intrinsic fate) -Extrinsic fate determinants (morphogens) -Cell polarity and asymmetry -Intro to gastrulation as prerequisite for neural development

  4. Development and disease: on the battlefront

  5. Patient’s own hemato- poietic stem cells returned after chemo to reboot immune system

  6. The origins of developmental biology -Hippocrates in 5th cent BC: “heat, wetness, solidification” -Aristotle in 4th cent BC: How are different parts formed? a) Preformationism b) Epigenesis (“upon formation”), or sequential generation of new structures *This debate lasted for over 2000 years! FINALLY… cell theory developed (1820-1880) Schleden (botanist) & Schwann (physiologist): All living things are derived from cells

  7. Early debates regarding development centered on preformationism vs. epigenesis Homunculus in sperm head (1694) 

  8. Weismann’s mosaic theory Radical idea: germ cells determine embryo characteristics (somatic vs. germline) -believed that nuclei divided asymmetrically to give rise to lineages with different cell fates… New debate! *a botanist monk would show that chromosomes determine inheritance of traits (Boveri & Sutton)

  9. Initial experiment by Roux supported the mosaic model -”killed” one blastomere  half-embryo; thus, critical fate determinants missing

  10. Later work by Dreisch was inconsistent with mosaic model *1st demonstration of regulation: embryo’s ability to develop normally despite missing or rearranged parts

  11. Repression of genetic expression can be reversed by changing the cytoplasmic environment *Thus, development must also involve some ability of cells to respond to a new context= plasticity (or adaptability) *Development = a progression of fate restrictions?

  12. Fate restriction over time during brain development

  13. Genes are turned on/off by protein complexes bound to promoter Transcription requires: 1) open chromatin conformation state; 2) TATA box for RNA polymerase; 3) activators binding to enhancer elements in the 5’ UTR; and 4) RNA polymerase.

  14. Correct spatial and temporal control of gene expression and protein synthesis is essential during development

  15. Regulatory regions (promoters) determine tissue-specific gene expression pancreas pituitary -mouse transgene with GH (pituitary) under the control of the mouse elastase gene (in pancreas) turns on GH in pancreas

  16. Neural fate determination via: a) extrinsic signal, b) autocrine/paracrine signal, c) receptor-mediated signal transduction, & d) intrinsic determinant

  17. Sequestration of signaling factors determines fate after mitosis

  18. Mechanisms of cell fate determination

  19. Direct cell-cell (lateral) signaling can occur by: • Diffusible ligand-receptor interaction • Transmembrane ligand-receptor interaction • Direct diffusion of factors across gap junctions

  20. Glucocorticoid receptor binding to hormone activates nuclear translocation & transcription *estrogen/tamoxifen-ER: used to generate inducible transgenics

  21. Another level of control: one TF (gene) can activate or repress other genes, depending on promoter context

  22. One mode of maintaining gene activation: positive autoregulation

  23. Inducing signals and competent tissue present during gastrulation *results are time-sensitive!

  24. How does the embryo know its head from its tail? D R P A L V Key: A= anterior P= posterior D= dorsal V= ventral A: Organizers

  25. Localized determinants and asymmetric cell divisions establish the body plan of the early embryo

  26. Gastrulation initiates at the blastopore (posterior), & extends anteriorly

  27. Development of the amphibian from the blastula to neurula blue= mesoderm red= neurectoderm Axis/germ layer specification

  28. Mesoderm induces neural signaling in ectoderm; default is epidermis

  29. Neural crest arises from the dorsal seam of the newly-formed neural tube

  30. Spemann and Mangold implicate the dorsal lip of the blastopore in neural induction

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