Abstract

The long-term goal of the proposed experiments is the repair of damaged or degenerated cortico-spinal circuitry via i) induction of neurogenesis of new cortico-spinal motor neurons (CSMN) from endogenous precursors (""""""""stem cells""""""""); ii) support of their survival, and iii) recruitment into functional synaptic circuitry with the lower motor neuron population. Recently, we have manipulated endogenous precursors in situ in the adult mouse to undergo neurogenesis (birth of new neurons) de novo in adult mouse neocortex, where it does not normally occur. In collaborative work, we induced behaviorally functional neuronal replacement in situ in songbirds by homologous avian endogenous precursors. These experiments demonstrated that there exists a sequence and combination of molecular signals by which the birth of new neurons can be induced, even in the adult neocortex where neurogenesis does not normally occur. Even more directly relevant to this proposal are our recent findings that 1) endogenous precursors can also be specifically induced to differentiate in situ into cortico-spinal motor neurons (CSMN) with projections to the spinal cord; and 2) that we can isolate, FACS purify (to >99.5% purity), and culture CSMN at distinct developmental stages for analysis of lineage-specific controls over survival and differentiation, particularly rate / extent of axon elongation. We hypothesize that we can substantially increase the number of newly recruited CSMN by enhancing the survival of the newborn neurons and/or their rate and extent of axonal outgrowth to supportive spinal cord targets. We also hypothesize that newborn neurons can differentiate precisely into new functional CSMN, receive afferent synapses, and become synaptically integrated. Our five Aims will test these and related hypotheses directly, in vitro and in vivo. The proposed research will:
Aim 1) undertake a more complete analysis of lineage-specific differentiation of the induced adult-born CSMN, and a more detailed characterization of the time course of induced neurogenesis, neuronal differentiation, connectivity, and long-term survival of newborn CSMN);
Aims 2, 3) investigate in vitro a select set of candidate growth and neurotrophic factors enabling potentially stage-specific enhanced survival and/or enhanced outgrowth and circuit connectivity of CSMN, employing FACS purification of CSMN at distinct developmental stages, and bath vs. localized factor application;
Aim 4) manipulate and increase the induced adult CSMN neurogenesis and spinal projections by intraventricular infusion of highly selected candidate growth factors from the in vitro experiments and Aim 5) investigate the precision of CSMN differentiation and potential afferent and efferent synapse formation using ICC and retroviral GFP-barley lectin expression. Together, this work aims toward the ultimate goal of repair of cortico-spinal motor neuron circuitry by manipulation of endogenous neural precursors in situ, without transplantation.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS049553-02
Application #
6923718
Study Section
Special Emphasis Panel (ZRG1-CNNT (01))
Program Officer
Kleitman, Naomi
Project Start
2004-07-15
Project End
2008-04-30
Budget Start
2005-05-01
Budget End
2006-04-30
Support Year
2
Fiscal Year
2005
Total Cost
$398,825
Indirect Cost

  Institution

Name
Massachusetts General Hospital
Department
Type
DUNS #
073130411
City
Boston
State
MA
Country
United States
Zip Code
02199

  Publications

Wuttke, Thomas V; Markopoulos, Foivos; Padmanabhan, Hari et al. (2018) Developmentally primed cortical neurons maintain fidelity of differentiation and establish appropriate functional connectivity after transplantation. Nat Neurosci 21:517-529
Fame, Ryann M; Dehay, Colette; Kennedy, Henry et al. (2017) Subtype-Specific Genes that Characterize Subpopulations of Callosal Projection Neurons in Mouse Identify Molecularly Homologous Populations in Macaque Cortex. Cereb Cortex 27:1817-1830
Sances, Samuel; Bruijn, Lucie I; Chandran, Siddharthan et al. (2016) Modeling ALS with motor neurons derived from human induced pluripotent stem cells. Nat Neurosci 19:542-53
Woodworth, Mollie B; Greig, Luciano C; Liu, Kevin X et al. (2016) Ctip1 Regulates the Balance between Specification of Distinct Projection Neuron Subtypes in Deep Cortical Layers. Cell Rep 15:999-1012
Fame, Ryann M; MacDonald, Jessica L; Dunwoodie, Sally L et al. (2016) Cited2 Regulates Neocortical Layer II/III Generation and Somatosensory Callosal Projection Neuron Development and Connectivity. J Neurosci 36:6403-19
Greig, Luciano C; Woodworth, Mollie B; Greppi, Chloé et al. (2016) Ctip1 Controls Acquisition of Sensory Area Identity and Establishment of Sensory Input Fields in the Developing Neocortex. Neuron 90:261-77
Kishi, Noriyuki; MacDonald, Jessica L; Ye, Julia et al. (2016) Reduction of aberrant NF-?B signalling ameliorates Rett syndrome phenotypes in Mecp2-null mice. Nat Commun 7:10520
Galazo, Maria J; Emsley, Jason G; Macklis, Jeffrey D (2016) Corticothalamic Projection Neuron Development beyond Subtype Specification: Fog2 and Intersectional Controls Regulate Intraclass Neuronal Diversity. Neuron 91:90-106
Jara, Javier H; Genç, Bar??; Cox, Gregory A et al. (2015) Corticospinal Motor Neurons Are Susceptible to Increased ER Stress and Display Profound Degeneration in the Absence of UCHL1 Function. Cereb Cortex 25:4259-72
Sohur, U Shivraj; Padmanabhan, Hari K; Kotchetkov, Ivan S et al. (2014) Anatomic and molecular development of corticostriatal projection neurons in mice. Cereb Cortex 24:293-303

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