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24 grants worth up to $13.4M match your search

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National Institutes of Health

-Purpose. This Funding Opportunity Announcement (FOA) is a program announcement (PA) issued by the National Institute of Neurological Disorders and Stroke (NINDS), National Institutes of Health (NIH). It solicits R01 grant applications from institutions/organizations that intend to perform innovative research that will expand our current knowledge of neurobiological mechanisms underlying the phases of migraine and the role of neuromodulators such as sex hormones, and genetic influences in migraine pathophysiology. -Mechanism of Support. This FOA will utilize the NIH Research Project Grant (R01) award mechanism and runs in parallel with an FOA of identical scientific scope, PA-07-306, Neurobiology of Migraine (R21) , that solicits applications under the NIH Exploratory/Developmental Grant (R21) award mechanism. -Funds Available and Anticipated Number of Awards. Awards issued under this FOA are contingent upon the availability of funds and the submission of a sufficient number of meritorious applications.

rolling

Environmentalsustainability

Free to search & build · $99 one-time to unlock the application pack · No subscription

open

National Institutes of Health

-Purpose. This FOA intends to support modification and enhancement of existing neuroimaging informatics tools and resources that are hosted or being considered for inclusion into the NIH Neuroimaging Informatics Tools and Resources Clearinghouse (NITRC, www.nitrc.org, public release scheduled for October 2007). Examples of such tools include image segmentation, image registration, image processing pipelines, statistical analysis packages, spatial alignment and normalization algorithms, and data format translators. Resources include well-characterized test datasets, data formats, and databases, among others. The proposed work shall significantly improve the interoperability and adoptability of neuroimaging informatics tools and resources and result in enhanced dissemination, adoption, and evolution of such tools and resources by the broader neuroimaging research community. -Mechanism of Support. This Funding Opportunity Announcement (FOA) will utilize the NIH Small Research Grant (R03) award mechanism and runs in parallel with the NIH Notice NOT-EB-07-006 (http://grants.nih.gov/grants/guide/notice-files/NOT-EB-07-006.html) of identical scientific scope that solicits applications under the Administrative Revision (formerly supplement ) mechanism. -Funds Available and Anticipated Number of Awards. The participating organizations intend to commit a total of $950,000 to this FOA. The anticipated total number of awards for this FOA is 5-7 per year. Awards issued under this announcement are contingent upon the availability of funds and the submission of a sufficient number of meritorious applications.

rolling

Education

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Neuroimmune Control of Microbiota-Evoked Hyperinnervation and Pruritus

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NIAMS - National Institute of Arthritis and Musculoskeletal and Skin Diseases

PROJECT SUMMARY/ABSTRACT My goal is to understand the mechanisms underlying pruritus. The ability to sense the environment is essential for survival, with the somatosensory nervous system playing a central role in detecting external stimuli. Despite its evolutionary relevance, the sensation of itch (pruritus) has been historically overlooked, even though it significantly impacts quality of life, particularly in chronic cases. Of note, pruritus affects 15% of the population, yet there are very few FDA-approved treatments, making it a major unmet medical need. Recent studies highlight the crucial interactions between the immune and sensory systems, especially the role of unmyelinated C-fibers in driving both inflammation and pruritus. While C-fiber hyperinnervation is a feature of pruritus, the mechanisms driving this nerve overgrowth and its role in pruritus pathogenesis remain largely unknown. The skin is the primary sensory organ for pruritus and the ecological niche for commensal microbiota. Using a novel TCR transgenic mouse model with T cells specific for Staphylococcus aureus (S. aureus), I previously demonstrated that T cell immunity to commensal S. aureus promotes skin sensory nerve regrowth after injury via the IL- 17A/IL-17RA axis. While host-microbiota interactions are essential for maintaining immune balance and skin homeostasis, disruption of this equilibrium can transform commensals such as S. aureus into pathogenic drivers of inflammation and tissue damage, as observed in psoriasis and atopic dermatitis. Might microbiota- induced cytokines contribute to these outcomes? Building on the neurotrophic effect of microbiota-induced IL- 17A, and considering the established role of type 2 cytokines (IL-3, IL-4, IL-13, IL-31) in itch via sensory nerve activation, my lab is investigating whether IL-17A promotes maladaptive neuronal growth during inflammation, leading to sensory hyperinnervation and pruritus. To test this, we have used two models of skin microbiota (S. aureus and Candida albicans) combined with two inflammatory itch models: IMQ-induced psoriatic itch and MC903-induced atopic dermatitis. We have found that mice in the pruritus group (microbiota + IMQ/MC903) showed both skin hyperinnervation and heightened itch, driven by the IL-17A/IL-17RA axis. Furthermore, snRNA-seq of dorsal root ganglia (DRG) neurons and microscopy revealed a transcriptional signature consistent with axonal growth, including upregulation of Atf3, a key regulator of nerve growth following injury Based on this, I hypothesize that microbiota-induced T cells control skin sensory hyperinnervation upon inflammation, consequently regulating pruritus via the ATF3-IL-17RA axis. To test this hypothesis, I will ask three interrelated but non-dependent aims: Aim 1) How do microbiota-induced T cells control hyperinnervation, Aim 2) To elucidate the transcriptional regulation of IL-17RA- dependent sensory hyperinnervation, and Aim 3) How does ATF3-IL-17RA axis regulate pruritus? This project seeks to establish a novel paradigm of microbiota-driven neuroimmune regulation of sensory neuron plasticity, focusing on hyperinnervation, and long-term effects on pruritus, very relevant to target inflammatory skin conditions.

Up to $581K

2031-03-31

health research

Free to search & build · $99 one-time to unlock the application pack · No subscription

Neuroimmune mechanisms of coronavirus-induced lung inflammation and airway dysfunction

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NHLBI - National Heart Lung and Blood Institute

PROJECT SUMMARY The global impact of the COVID-19 pandemic has been profound, with nearly 800 million infections and seven million deaths worldwide. With the majority of fatalities resulting from respiratory failure, there is a pressing need to understand the factors that promote respiratory dysfunction following infection. The current paradigm centers on immunopathological mechanisms behind disease, but fails to incorporate how sensory neurons change during infection and contribute to the hallmark immune dysregulation and airway inflammation that characterize severe COVID-19. Airway sensory neurons are robustly activated by inflammatory mediators, pathogens and noxious irritants to modulate respiratory tone and initiate defense reflexes like cough, mucus production and bronchoconstriction. They also regulate the immune response to pathogens in the lung and become aberrantly activated during airway inflammation, thereby exacerbating reflex symptoms that contribute to morbidity. However, whether they play a role in the pathogenesis of coronavirus disease has not been studied, despite the potential to impact our understanding of airway physiology and identify new avenues for treatment. This proposal will test the following hypotheses: 1) that lung-innervating sensory neurons regulate the immune response to promote airway inflammation in coronavirus infection and 2) during infection, these cells undergo functional changes that contribute to respiratory dysfunction. Using the MHV-A59 mouse coronavirus infection model, our preliminary data support this hypothesis by demonstrating that the systemic ablation of TRPV1+ sensory neurons improves airway function while attenuating mortality and disease in infected mice. I will expand on these results by performing a specific, targeted ablation of the lung-innervating sensory neurons to elucidate their role in coronavirus disease pathology. I will determine if lung-innervating sensory neurons regulate airway inflammation by learning and performing spectral flow-cytometry to profile and quantify pulmonary immune cells, while separately measuring viral titer, neuropeptide and inflammatory cytokine concentrations in the lungs of infected, airway sensory neuron-ablated and intact mice. To understand how MHV-A59 infection modulates airway sensory neuron function to promote respiratory disease, I will acquire expertise in two-photon calcium imaging and electrophysiology to characterize their phenotypic changes in MHV-A59 infected animals. Lastly, I will measure oxygen saturation, breathing rates, respiratory mechanics and airway hyperreactivity in sensory neuron-ablated and intact mice to understand how these cells contribute to respiratory dysfunction. These studies will define the contribution of lung-innervating sensory neurons to coronavirus disease pathogenesis and lay the groundwork for discovering new treatments for respiratory disease.

Up to $44K

2027-09-29

health research

Free to search & build · $99 one-time to unlock the application pack · No subscription

Neuroimmunology regulating reparative dentinogenesis

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NIDCR - National Institute of Dental and Craniofacial Research

PROJECT SUMMARY/ABSTRACT Deep tooth injuries and inflammation affect millions of Americans, often progressing into pulp necrosis and treated by removing, i.e. devitalizing, and replacing the dental pulp tissue with artificial materials. Vital pulp therapies (VPTs) have the potential to promote cell signaling that stops the infection and restores pulp health, but their effectiveness is limited once pulpitis is established. This is largely due to the large gap in knowledge of what signaling cascades regulate the immune response to defend the pulp versus promote tertiary dentino- genesis to repair the damage. Studies have demonstrated that sensory axons sprout during infection and injury and communicate with immune and stem cell populations during tissue healing. Insights into how neurons pro- tect and enable dentin repair can therefore create therapeutic strategies that harness this axis to heal, rather than remove, the dental pulp tissue. The long-term goal of this project is to understand the cellular mecha- nisms that protect teeth via immune and mineralizing cell responses to inflammation and damage. The applica- tion objective is to determine the role of calcitonin gene-related peptide (CGRP) in activating immune and min- eralizing cells during tooth healing, i.e. reparative dentinogenesis. Our central hypothesis is that neuronal-de- rived CGRP regulates the function of neutrophils & monocytes, surviving odontoblasts and odontoblast progen- itors via its receptor, receptor activity modifying protein 1 (Ramp1), during reparative dentinogenesis. The ra- tionale for this project is that a detailed scientific framework of cellular crosstalk during reparative dentinogene- sis is likely to identify cell-specific mechanisms that sustain and enhance tooth health. The central hypothesis will be tested with the following specific aims: 1) Determine the cell-specific effects of CGRP signaling after deep dentin trauma; 2) Identify the role of CGRP signaling in regulating inflammation and subsequent tertiary dentinogenesis after direct pulp capping procedures; and 3) Evaluate the effect of increased RAMP1 expres- sion and/or exogenous CGRP on promoting pulp healing and homogeneous mineralized tissue barrier for- mation after direct pulp capping. In aim 1, direct pulp capping will be performed on mice with conditional dele- tions of the CGRP receptor, RAMP1, in immune or mineralizing cells. The dentin pulp complex will be analyzed throughout the healing period of 1-56 days for inflammatory and mineralization responses. For aim 2, a model of pulpal inflammation will be created with an initial shallow injury on molars with lipopolysaccharide applied. This will be drilled out and restored 24 hours later, followed by a similar timeline of investigations into pulpal responses. The last aim proposes to enhance RAMP1 and therefore the ability to respond to CGRP released during injury and inflammation to establish whether this can promote pulp healing and tissue barrier formation. The research proposed in this application is innovative because it provides a clinically relevant model of deep dentin damage and repair with which to study cell-specific repair mechanisms. The proposal is significant be- cause it is expected to identify cellular mechanisms that sustain tooth vitality to advance the development of next-generation VPTs.

Up to $690K

2031-02-28

health research

Free to search & build · $99 one-time to unlock the application pack · No subscription

Neuroinflammatory Epitranscriptomic Mechanisms in Parkinson's Disease

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NINDS - National Institute of Neurological Disorders and Stroke

Abstract The accumulation of alpha-synuclein (αSyn) aggregates is a hallmark of various synucleinopathies including Parkinson’s disease (PD) and dementia with Lewy bodies. Neuroinflammation plays a pivotal pathophysiological role in the progression of dopaminergic neurodegenerative processes in PD. Aggregated αSyn has emerged as a predominant pathological trigger for microglial activation and the subsequent release of proinflammatory cytokines and chemokines in the brain. Moreover, the transmission of αSyn aggregates from affected neurons to other brain cells, including microglia, contributes to heightened neuroinflammatory responses. We recently reported that the Fyn-PKCδ kinase signaling axis undergoes rapid activation in microglia upon αSyn fibril (αSynf) stimulation and plays a significant proinflammatory role by activating multiple cyto/chemokine levels including TNF-α, IL-6, and IL-12. Despite these advancements, the exact upstream neurobiological mechanisms regulating the dynamics of various cyto/chemokine synthesis in microglial cells in response to αSynf remain undefined. In the emerging field of epitranscriptomics, N6-methyladenosine (m6A) mRNA modification has been shown to regulate the fate of various transcripts including immune inflammatory factors. In our proteomic analysis, we unexpectedly observed rapid induction of the m6A demethylase ALKBH5 in αSynf-stimulated microglial cells. Since ALKBH5 is a major regulator controlling the rate of cytokine and chemokine transcripts in immune cells, this proposal aims to determine its role in neuroinflammatory processes underlying PD. Interestingly, we found that ALKBH5 is also upregulated in animal models of PD, and more importantly, in postmortem human PD brains. Our preliminary mechanistic studies further identified that phosphorylation of ALKBH5 by PKCδ modulates its subcellular localization and demethylase activity in response to αSynf. Loss-of-function studies revealed a pro-inflammatory role for elevated ALKBH5 in αSynf- stimulated microglia, leading to the novel hypothesis that αSynf induces a proinflammatory response in microglia by upregulating and translocating ALKBH5 in a Fyn-PKCδ-dependent manner. Thus, the following specific aims will be pursued to further expand our novel findings: (1) Characterize the ALKBH5 upregulation and subcellular translocation and their roles in regulating microglial activation using cell and animal models of αSyn-induced neuroinflammation; (2) Determine whether Fyn-PKCδ signaling regulates the proinflammatory function of ALKBH5 in cell and animal models of αSyn-induced neuroinflammation; and (3) Establish the proinflammatory function of ALKBH5 in progressive animal models of α-synucleinopathy and evaluate the translational utility of the Fyn-PKCδ-ALKBH5 signaling axis in neuroinflammatory models of PD. Taken together, our proposal will offer novel mechanistic insights into the progression of neurodegenerative processes in PD and related synucleinopathies. Additionally, it has the potential to translate these mechanistic findings into effective therapies for neurodegenerative diseases.

Up to $1.3M

2029-04-30

health research

Free to search & build · $99 one-time to unlock the application pack · No subscription

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