Determining how neurons are correctly specified and assembled into functional circuits will provide insight into developmental disorders of the nervous system and may suggest therapeutic approaches to promote nerve regeneration. Slit and Netrin, and their Robo and Fra/DCC receptors, are evolutionary conserved families of signaling molecules that play important roles in regulating neuronal development; however, the understanding of how these receptors are regulated and how they signal to direct axon growth and guidance is incomplete. These are important questions because perturbations of these signaling pathways are implicated in diseases of nervous system development. Slits, Netrins and their receptors also play essential roles outside of the nervous system and disruptions of these pathways are associated with several kinds of cancer. Our research program focuses on three broad areas related to the roles and regulation of these molecules in neuronal development using the genetically tractable Drosophila embryonic nervous system as a model. First, we are working to define functional and molecular links between conserved transcriptional regulators that impart neuronal subtype identity and the Robo and Fra/DCC receptors that coordinate axon guidance and dendrite morphogenesis in response to Slit and Netrin. Here, we will use genetic and molecular screening approaches, including Fluorescence Activated Cell sorting (FACs) of defined subsets of motor neurons, together with transcript profiling in wild type and mutant backgrounds, to systematically identify additional effectors of these transcriptional programs. Second, we are characterizing a newly discovered mechanism through which the Frazzled/DCC receptor intracellular domain (ICD) itself can act in the nucleus as a transcriptional activator to regulate commissureless expression to ensure that commissural axons avoid premature responses to midline repellent Slit. Here, we will use genetic and molecular approaches to identify factors that cooperate with the Fra ICD to regulate transcription and transcript profiling methods to identify additional targets of the Fra ICD. In addition, we will explore whether signaling from the nucleus is a common property of axon guidance receptors and through collaboration we will test if this is a conserved property of guidance receptors. Third, we are determining the molecular mechanisms underlying Robo and Fra/DCC receptor signaling during axon guidance using molecular, genetic, biochemical and cell biological approaches. Specifically, we use in vivo genetic manipulation, together with fluorescently tagged receptors and reporters of signaling molecule activity in vitro, to define the cell biological outputs of receptor activation with sub-cellular resolution. Our research program will define new concepts in the molecular biology of axon guidance, inform studies of related proteins in mammalian systems and will likely enhance our understanding of neural developmental disorders.

Public Health Relevance

Understanding how neurons are correctly assembled into functional circuits will provide critical insight into developmental disorders of the nervous system and may inform strategies to promote neuronal repair in cases of injury or disease. The current knowledge of the molecular genetic pathways that control neuronal development is incomplete. Our research program addresses three major questions related to the assembly of neural circuits: 1) How do transcription factors that control neuronal subtype identity coordinate the expression of axon guidance molecules that control wiring specificity? 2) What are the signaling mechanisms that allow conserved families of guidance receptors to control direction-selective axon growth and targeting? 3) How do navigating axons coordinate their responses to the diverse array of cues present during development to ensure assembly of functional circuits? Disruption of the function of many axon guidance molecules has been implicated in a number of human neuronal developmental disorders, as well as in various kinds of cancer. Thus, understanding the signaling mechanisms of these molecules in the context of normal development will be instrumental in understanding how their perturbation leads to pathogenesis.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Unknown (R35)
Project #
3R35NS097340-05S1
Application #
10045309
Study Section
Special Emphasis Panel (ZNS1)
Program Officer
Riddle, Robert D
Project Start
2016-12-15
Project End
2024-11-30
Budget Start
2021-02-01
Budget End
2021-11-30
Support Year
5
Fiscal Year
2021
Total Cost
Indirect Cost
Name
University of Pennsylvania
Department
Neurosciences
Type
Schools of Medicine
DUNS #
042250712
City
Philadelphia
State
PA
Country
United States
Zip Code
19104
Russell, Samantha A; Bashaw, Greg J (2018) Axon guidance pathways and the control of gene expression. Dev Dyn 247:571-580
Arbeille, Elise; Bashaw, Greg J (2018) Brain Tumor promotes axon growth across the midline through interactions with the microtubule stabilizing protein Apc2. PLoS Genet 14:e1007314
Santiago, Celine; Bashaw, Greg J (2017) Islet Coordinately Regulates Motor Axon Guidance and Dendrite Targeting through the Frazzled/DCC Receptor. Cell Rep 18:1646-1659
Hernandez-Fleming, Melissa; Rohrbach, Ethan W; Bashaw, Greg J (2017) Sema-1a Reverse Signaling Promotes Midline Crossing in Response to Secreted Semaphorins. Cell Rep 18:174-184