Jay Parrish - US grants

DESCRIPTION (provided by applicant): Dendrite arborization patterns are a hallmark of neuronal type and a critical determinant of neuronal function, influencing the type and number of inputs that a neuron can receive as well as the ability of a neuron to process multiple inputs. As animals grow, dendrite arbors of many neurons must expand proportionally to sustain proper connectivity and maintain coverage of their receptive field. Likewise, large portions of dendrite arbors in adult neurons are stable over extended periods of time to maintain receptive field coverage and patterns of connectivity. However, little is known about how dendrite arbors are actively maintained. Using genetic screens, we have identified mutants that phenotypically define different modes of extrinsic regulation of dendrite maintenance in Drosophila sensory neurons. With this proposal, we aim to test the hypotheses that (1) localized adhesive contacts ensure coordinated expansion of dendrites and their receptive field during times of growth, (2) substrate-derived signals restrict dendrite structural plasticity, preventing dendrite growth beyond normal receptive field boundaries, and (3) substrate-derived trophic signals are continuously required to support dendrite maintenance. In Aim 1, we will define roles of dendrite-epithelial contacts in coordinating dendrite arbor and receptive field expansion, and identify factors that modulate these contacts. We will monitor these contacts in vivo using a genetically-encoded fluorescence-based proximity sensor, characterize the contacts at high resolution using electron microscopy, test the functional relevance of the contacts by modifying the distribution of the contact sites in the epithelium, and analyze genetic mutants that likely disrupt these contacts. In Aim 2, we will define roles of substrate extracellular matrix (ECM) modification in restricting dendrite growth and ensuring maintenance of receptive field coverage. We will use genetically encoded markers and electron microscopy to delineate changes in ECM organization and distribution during normal development and in maintenance-defective mutants. Additionally, we will identify substrate-derived factors required for ECM modifications. In Aim 3, we will define a neuron non-autonomous pathway that regulates trophic signaling for dendrite maintenance. Altogether, these studies will elucidate mechanisms by which growth of dendrites and their substrate are coordinated during growth, ensuring maintenance of dendrite coverage. Although defects in dendrite morphology are associated with a variety of developmental and degenerative disorders, including mental retardation, epilepsy, schizophrenia, and Parkinson's disease, little is known about how dendrite arbors are maintained. Basic insights gained from this work are expected to be of significance for understanding the normal developmental role of different types of extrinsic signals in dendrite maintenance as well as the consequences of perturbing these extrinsic signals. PUBLIC HEALTH RELEVANCE: The proposed research is relevant to public health because dendrite defects are widely associated with developmental and progressive neurological disorders, including mental retardation, epilepsy, schizophrenia, and Parkinson's disease. Remarkably, in many of these disorders, dendrite defects appear after a normal period of early development, suggesting that defects in dendrite maintenance underlie disease pathology. The proposed research will provide understanding of mechanisms involved in maintaining dendrite arbors, and this understanding is essential for developing therapeutic strategies to treat dendrite pathologies in human disease.

DESCRIPTION (provided by applicant): Dendrite arborization patterns are a hallmark of neuronal type and a critical determinant of neuronal function, influencing the type and number of inputs that a neuron can receive as well as the ability of a neuron to process multiple inputs. As animals grow, dendrite arbors of many neurons must expand proportionally to sustain proper connectivity and maintain coverage of their receptive field. Likewise, large portions of dendrite arbors in adult neurons are stable over extended periods of time to maintain receptive field coverage and patterns of connectivity. However, little is known about how dendrite arbors are actively maintained. Using genetic screens, we have identified mutants that phenotypically define different modes of extrinsic regulation of dendrite maintenance in Drosophila sensory neurons. With this proposal, we aim to test the hypotheses that (1) localized adhesive contacts ensure coordinated expansion of dendrites and their receptive field during times of growth, (2) substrate-derived signals restrict dendrite structural plasticity, preventing dendrite growth beyond normal receptive field boundaries, and (3) substrate-derived trophic signals are continuously required to support dendrite maintenance. In Aim 1, we will define roles of dendrite-epithelial contacts in coordinating dendrite arbor and receptive field expansion, and identify factors that modulate these contacts. We will monitor these contacts in vivo using a genetically-encoded fluorescence-based proximity sensor, characterize the contacts at high resolution using electron microscopy, test the functional relevance of the contacts by modifying the distribution of the contact sites in the epithelium, and analyze genetic mutants that likely disrupt these contacts. In Aim 2, we will define roles of substrate extracellular matrix (ECM) modification in restricting dendrite growth and ensuring maintenance of receptive field coverage. We will use genetically encoded markers and electron microscopy to delineate changes in ECM organization and distribution during normal development and in maintenance-defective mutants. Additionally, we will identify substrate-derived factors required for ECM modifications. In Aim 3, we will define a neuron non-autonomous pathway that regulates trophic signaling for dendrite maintenance. Altogether, these studies will elucidate mechanisms by which growth of dendrites and their substrate are coordinated during growth, ensuring maintenance of dendrite coverage. Although defects in dendrite morphology are associated with a variety of developmental and degenerative disorders, including mental retardation, epilepsy, schizophrenia, and Parkinson's disease, little is known about how dendrite arbors are maintained. Basic insights gained from this work are expected to be of significance for understanding the normal developmental role of different types of extrinsic signals in dendrite maintenance as well as the consequences of perturbing these extrinsic signals.

Epidermal cells provide the first point of contact for sensory stimuli and are innervated by somatosensory neurons (SSNs) that shape our experience of the world. Both SSNs and epidermal cells are of great clinical relevance; SSNs are mediators of physiological and pathological pain, and some pathological skin conditions are associated with debilitating pain and itch. However, our understanding of roles that epidermal cells play in SSN development and function, particularly nociception, remain limited aside from a few well-studied examples. Characterizing these important intercellular interactions is complicated by the heterogeneity and complexity of vertebrate nervous systems. Drosophila provides an appealing system to close this gap in our knowledge, offering a wealth of genetic resources, ready imaging access of SSNs/epidermis with single cell resolution, a compact nervous system, and evolutionary conservation of key regulators of SSN development/function. In this project we will use an integrated approach to study an evolutionarily conserved intracellular interaction that involves the wrapping of SSN neurites by epidermal cells. The conservation of this intercellular interaction and the preferential ensheathment of nociceptors compared to other SSNs suggest that these sheaths may play key roles in development and function of nociceptive SSNs. Here, we test the hypothesis that epidermal ensheathment of SSNs functionally couples epidermal cells to SSNs. We will test this hypothesis using three lines of experimentation. First, we will characterize the response properties of Drosophila epidermal cells and identify epidermal sensory channels that mediate epidermal responses to noxious stimuli. Second, we will test requirements for sheaths in epidermal activation of nociceptors, define the neuronal substrates for epidermally-gated behavior responses, define the SSN repertoire functionally coupled to epidermal stimulation, and quantify contributions of epidermal activation to sensory-evoked behaviors. Third, we will identify signaling mechanisms linking epidermis and C4da neurons in the periphery and identify circuit- level effects of ensheathment. Given the enormous impact of pathological pain on quality of life ? chronic pain affects more Americans than diabetes, heart disease, and cancer combined ? understanding how epidermal cells modulate nociceptive SSN function is of great interest for development of novel therapeutics for pain management. Successful completion of this project will provide insight into a fundamental component of somatosensation that represents a novel control point for nociception that could define a new entry point for pain management.