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Requirements for ZNF292 in cortical development and mechanisms of pathogenesis in neurodevelopmental disorders

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NIMH - National Institute of Mental Health

Recent advances in human genetics defined hundreds of causal variants for Autism Spectrum Disorder (ASD) and other neurodevelopmental disorders (NDDs). However, substantial effort is now required to identify downstream disease processes and guide development of interventions. One such new NOD gene is ZNF292: mutations were recently associated with ASD and other NDDs in humans, but ZNF292 requirements for brain development and consequences of pathogenic mutation have not been studied in any animal or human cellular model. Here, we propose a comprehensive mechanistic investigation of ZNF292, using both established cuttingedge workflows and innovative new approaches to study the consequences of both deficiency and pathogenic mutation at the molecular, cellular, structural, and functional and behavioral circuit levels. We use two complementary experimental systems, mouse models and human pluripotent stem cell (hPSC)-derived neurons, to define ZNF292 requirements for neurodevelopment. We focus initially on hPSC models carrying six pathogenic ZNF292 variants identified in patients with ASD, intellectual disability, and other NOD clinical phenotypes (e.g., microcephaly, epilepsy), and comparison with hPSC lines with constitutive or inducible ZNF292 deficiency. Our preliminary work has already demonstrated shared disruptions of neurodevelopment, transcriptional regulation, and neuronal network function stemming from either ZNF292 deficiency or pathogenic mutation in these models. We also developed conditional and non-conditional mouse knockout models of ZNF292 deficiency and demonstrated that these exhibit NOD-relevant circuit disruptions and, accordingly, altered behavior. Further, we developed cutting-edge tools for temporally controlled reversal of ZNF292 deficiency in our hPSC models, enabling us to investigate the effects of restoring ZNF292 gene function either during development or in mature neurons. Related landmark experiments profoundly changed our understanding of other NDDs by demonstrating that a substantial proportion of chronic NOD phenotypes were reversible, thus spurring the development of therapeutics based on either restoring gene expression or reversing its chronic consequences for neuronal function. In complementary efforts, we continue to model additional cases in this rapidly expanding patient population, linking NOD clinical phenotypes to shared, reversible endophenotypes related to altered neuronal network function. Based upon our preliminary data, we hypothesize that impaired circuit and neuronal network function stemming from chronic reduction of ZNF292 activity contributes substantially to NDDs in this patient population. These deficits may be tractable for molecular or pharmacological treatment to develop interventions. Therefore, together, the experiments performed here will elucidate requirements for and mechanisms by which ZNF292 normally controls brain development and function, will determine how these are disrupted by pathogenic ZNF292 mutation, and could also chart a course towards ZNF292-targeted therapies.

Up to $764K
2031-04-30
health research

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

Research and Education Program for Historically Black Colleges and Universities (HBCU) and Tribal Colleges and Universities (TCU)

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Dept of the Army -- Materiel Command

This solicitation invites applications (also referred to as proposals ) for basic research projects. The proposals must align with the research areas of interest to the DoW (which includes the USW(R&E) and the Agencies) and enhance the education of students in areas of STEM that align with the DoW research interests. Information about these areas of interest (including websites) is discussed below. The USW(R&E) Critical Technology Area descriptions are at https://www.cto.mil/wp-content/uploads/2025/11/CTA-One-Pager-Option-Nov2025.pdf. The critical technology priorities rely on innovation and workforce talent. The critical technology areas are: - Applied Artificial Intelligence (AAI) - Biomanufacturing (BIO) - Contested Logistics Technologies (LOG) - Quantum and Battlefield Information Dominance (Q-BID) - Scaled Directed Energy (SCADE) - Scaled Hypersonics (SHY) Basic research projects in research areas of interest to the Agencies are presented in their respective Broad Agency Announcements (BAAs), which are available as follows: Army Research Laboratory combined Broad Agency Announcement is available at: https://www.arl.army.mil/collaborate-with-us/opportunity/arl-baa/. This BAA may also be found on Grants.gov (https://www.grants.gov) by entering the BAA number, W911NF-23-S-0001, in the Search Grants keyword box. Office of Naval Research: https://www.onr.navy.mil/ Select Work With Us, then Funding Opportunities, and then BAAs, FOAs and Special Program Announcements to see the FY26 Long Range Broad Agency Announcement for Navy and Marine Corps Science and Technology, BAA N00014-23-S-B001. This BAA may also be found on Grants.gov (https://www.grants.gov) by entering the BAA number in the Search Grants keyword box. In addition to providing details about the Agencies research interests, the above documents include names and contact information of technical program managers. Principal Investigator and a Co-Principal Investigator (PI/Co-PI) are encouraged to peruse the research interests of each Agency and to contact the respective program managers to discuss mutual research interests. Applications with relevance to the interests of multiple Agencies may receive multiple reviews. Additional information and questions about the critical technology areas should be directed to Agency Contacts identified in Section II.G. of this NOFO. Other research areas that are not aligned with the (OUSW(R&E)/ASW(S&T) critical technology priorities listed in I.B.7 will be considered. The Agencies BAA listed above under I.B.6 provides other research areas of interest to the DoW. NOTE: Use the above-referenced Agency documents only to identify research areas of interest to the Agencies. Disregard instructions contained therein regarding application preparation, content, and submission requirements. Instead, follow the instructions in this NOFO. Projects proposed for funding under this NOFO must be for basic research. As defined by DoW, basic research is systematic study directed toward greater knowledge or understanding of the fundamental aspects of phenomena and of observable facts without specific applications toward processes or products in mind. It includes all scientific study and experimentation directed toward increasing fundamental knowledge and understanding in those fields of the physical, engineering, life sciences, and information sciences related to long-term national security needs. Principal Investigator and a Co-Principal Investigator (PI/Co-PI) are encouraged to consider innovative approaches for their research projects with a view toward enhancing the ability of their institution to develop stronger science and engineering programs that will enable the institution to participate more competitively in a variety of defense research programs, attract and retain good students by exposing them to state-of-the-art research, and encourage them to pursue careers in STEM disciplines. Methods through which these goals can be achieved are varied. Factors such as research capabilities, facilities, and equipment are unique to each institution. Therefore, DoW will not prescribe the approach for a research project; instead, it expects applications to reflect the unique needs and capabilities of the applicant institution.

$100K – $2M
2026-08-11
sciencetechnology

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

Research Experiences for Teachers (RET) in Engineering and Computer Science

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U.S. National Science Foundation

The Directorate for Engineering (ENG) and the Directorate for Computer and Information Science and Engineering (CISE), Research Experiences for Teachers (RET) in Engineering and Computer Science program supports the active involvement of K-12 science, technology, engineering, computer and information science, and mathematics (STEM) teachers and community college faculty in engineering and computer science research in order to bring knowledge of engineering, computer science, and technological innovation into their classrooms. The goal is to help build long-term collaborative partnerships between K-12 STEM teachers, community college faculty, and the NSF university research community by involving the teachers and community college faculty in engineering and computer science research and helping them translate their research experiences and new knowledge into classroom activities. Partnerships with inner city schools or other high needs schools are especially encouraged, as is participation by underrepresented minorities, women, and persons with disabilities. This announcement features two mechanisms for support of in-service and pre-service K-12 STEM teachers and community college faculty: RET supplements to ongoing ENG or CISE awards and new RET Site awards. RET supplements may be included in proposals for new or renewed NSF Directorate for Engineering (ENG) or CISE grants or as supplements to ongoing NSF ENG or CISE funded projects. RET in Engineering and Computer Science Sites are based on independent proposals from engineering or computer and information science departments, schools or colleges to initiate and conduct research participation projects for a number of K-12 STEM teachers and/or community college faculty.

rolling
sciencetechnology

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Research in Disabilities Education

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U.S. National Science Foundation

The Research in Disabilities Education (RDE) program seeks to broaden the participation and achievement of people with disabilities in all fields of science, technology, engineering, and mathematics (STEM) education and associated professional careers. The RDE program has been funding this objective since 1994 under the prior name "Program for Persons with Disabilities." Particular emphasis is placed on contributing to the knowledge base by addressing disability related differences in secondary and post-secondary STEM learning and in the educational, social and pre-professional experiences that influence student interest, academic performance, retention in STEM degree programs, STEM degree completion, and career choices. Projects also investigate effective practices for transitioning students with disabilities across critical academic junctures, retaining students in undergraduate and graduate STEM degree programs, and graduating students with STEM associate, baccalaureate and graduate degrees. Research project results inform the delivery of innovative, transformative and successful practices employed by the Alliances for Students with Disabilities in STEM to increase the number of students with disabilities completing associate, undergraduate and graduate degrees in STEM and to increase the number of students with disabilities entering our nation's science and engineering workforce. RDE projects contribute to closing the gaps occurring for people with disabilities in STEM fields by successfully disseminating findings, project evaluation results, and proven good practices and products to the public.Innovation through Institutional Integration (I3) projects enable faculty, administrators and others in institutions to think and act strategically about the creative integration of NSF-funded awards, with particular emphasis on awards managed through programs in the Directorate for Education and Human Resources (EHR), but not limited to those awards. For Fiscal Year 2010 proposals are being solicited in nine EHR programs that advance I3 goals: CREST, GSE, HBCU-UP, ITEST, LSAMP, MSP, Noyce, RDE, and TCUP.

$200K – $3M
rolling
sciencetechnology

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Resolving cellular and anatomical complexity of the brainstem using single-cell genomics

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NIMH - National Institute of Mental Health

PROJECT SUMMARY The brain is an extraordinarily complex organ containing many millions of neurons and non-neuronal cells that are organized into highly specialized yet intricately integrated circuits controlling various activities, such as sensory perception, motor control, and cognitive processes. The brainstem is a critical region responsible for regulating essential bodily functions, like heart rate, blood pressure, and digestion, and thus maintaining body homeostasis. The individual neurons in brainstem can be classified into types based on shared characteristics like gene expression. Binning individual cells into cell types is fundamental for advancing our understanding of complex biological systems, like the brain, from normal tissue function to disease processes. The characterization of cell types enables creation of tools to gain genetic access to groups of cells, it enables dissection of cellular heterogeneity, identify key players in various contexts like disease and aging, and lay the groundwork for targeted interventions and therapies. We recently built a comprehensive, high-resolution atlas of cell types across the entire adult mouse brain and the cell type diversity in brainstem exceeded our expectations. Brainstem is home to a highly heterogeneous group of neurons that does not share a specific gene module, yet these neurons are highly similar to one another. In addition, these cell types intermingle in various regions and their function is strongly determined by their input/output relationship. This suggests that a high-dimensional combinatorial gene expression code is needed to resolve the unique transcriptomic cell types in this region. Our goal is to create a refined atlas of cell types in brainstem using a combination of single cell transcriptomic profiling, spatial transcriptomic profiling, and mapping of projection patterns to transcriptomic cell types in brainstem. In addition, we will computationally align brain stem cell types from mouse, non-human primate, and human to define a cross-species consensus atlas of brain stem. Cell type homologies across species can be established based on conserved marker expression. This enables inference of cellular properties, such as long- range projection targets, that are difficult to measure in humans. The proposed efforts will lead to a significantly improved understanding of brainstem cell types and their function and lay the foundation for a better understanding of disease processes related to that region.

Up to $1.9M
2028-12-31
health research

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

Retinoic acid signaling and uterine epithelial cell fate

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NICHD - Eunice Kennedy Shriver National Institute of Child Health and Human Development

Project Summary The mammalian female reproductive tract (FRT), consisting of the oviducts, uterus, cervix and vagina, is essential for pregnancy establishment and a frequent site of human disease, including infertility and cancer. The embryonic origin of FRT is the Müllerian ducts, a pair of epithelial tubes with a surrounding mesenchyme. Once formed, the Müllerian duct regionally divides into segments along the anterior- posterior axis with each segment developing into distinct structure (oviduct, uterus, cervix and upper vagina). Classical tissue recombination experiments have shown that the Müllerian duct epithelial cell fate determination along the anterior-posterior axis is mediated by signals from the underlying stroma and retinoic acid (RA) signaling has been proposed to be the stromal cue for uterine epithelial cell fate determination. Despite advances in the molecular understanding of MDE specification during FRT development, there remains a striking knowledge gap in our understanding of how adult uterine cell fate is maintained. Recently a group of uterine epithelial cells at the intersection of luminal and glandular epithelium has been proposed to be a uterine stem cell population capable of differentiating into either luminal or glandular cells. However, little is known how these stem/progenitor cells acquire and maintain uterine cell fate and whether stromal signals are required for their specification. Our preliminary studies provide strong genetic data supporting the idea that RA signaling is continually required to maintain uterine epithelial cell fate during adult uterine homeostasis. In addition, our data suggest a model in which an antagonistic relationship between RA and estrogen signaling regulates Müllerian duct epithelial cytodifferentiation. These hypotheses will be tested in two aims. Aim 1 will examine the cell-autonomous function of retinoic acid receptors in FRT development and in adult uterine cell fate determination. Aim 2 will test the hypothesis that an RA-estrogen antagonism drives FRT cell fate determination both in mouse and in human. Successful completion of these studies may provide novel insights into female infertility and uterine cancer as a result of signaling imbalance between RA and estrogen, which could have a long-lasting impact in multiple research fields including development, fertility and cancer research.

Up to $428K
2028-05-31
health research

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

Revealing the role of vimentin in adult mouse hippocampal neurogenesis

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NINDS - National Institute of Neurological Disorders and Stroke

Project Summary Neural stem cells (NSCs) in the brain generate newborn neurons throughout life, providing an endogenous stem cell pool that can be harnessed to improve cognitive function during aging and neurodegenerative disease. Thus, understanding how adult neurogenesis is regulated may provide new targets and opportunities for therapeutic upregulation in these conditions. Intermediate filament (IF) proteins such as nestin and glial fibrillary acidic protein (GFAP) have been invaluable as markers for NSCs, increasing our understanding of the different cell states and cell types of the neurogenic niche. The IF protein vimentin is also expressed in NSCs, but due to variability in antibody quality and the lack of reporter mouse lines, very little is known about when and where it is expressed in the neurogenesis cascade. Recently, my lab has demonstrated many unique aspects of vimentin’s function and regulation in adult hippocampal NSCs in vitro. We found that vimentin mRNA is stabilized during quiescence, yet translationally repressed through an RNA-binding protein interaction with vimentin mRNA’s 3’UTR. As qNSCs activate, repression is removed, resulting in a rapid increase in vimentin protein. Additionally, as qNSCs activate, they traffic accumulated proteins that need to be degraded to the centrosome to form an aggresome. Vimentin collapses around the aggresome, forming a vimentin cage, bringing with it interacting proteins such as proteasomes. During cell division, the aggresome, vimentin cage, and associated proteins are asymmetrically segregated into one daughter cell. The daughter which inherits these cargoes has a decreased proliferation rate, whereas the non-inheriting daughter has a normal proliferation rate, resulting in a rejuvenative asymmetry between daughter cells. Vimentin is also required for efficient quiescence exit both in vitro and in vivo, further suggesting that vimentin’s role in NSCs is not only as a potential marker, but also as a key component to intrinsic mechanisms of quiescence exit. However, most of these findings were largely performed in vitro, thus we do not know if this process is conserved in the adult brain, nor how this asymmetric inheritance would affect the outcome of daughter cells in the neurogenic niche itself. To address these open questions, we created a novel transgenic mouse with endogenous vimentin fused to linker-mScarlet. We will characterize vimentin-mScarlet expression at the mRNA and protein level in cells of the hippocampus, and through prospective sorting followed by cell behavior analyses, we will reveal when and where vimentin mRNA and protein are expressed in the hippocampus. Importantly, we will also perform chronic in vivo imaging in cranial windows in these mice to visualize vimentin-mScarlet protein during quiescence exit and its asymmetric segregation during divisions, following the consequence of this inheritance in vivo. These studies will not only provide an important novel tool to the scientific community, but also reveal new knowledge on NSC subpopulation dynamics, answering critical questions about how NSCs rejuvenate their niche.

Up to $416K
2028-02-28
health research

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Revealing the Trajectory and Critical Roles of Retinoic Acid in Ameloblast Differentiation

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NIDCR - National Institute of Dental and Craniofacial Research

PROJECT SUMMARY/ABSTRACT Dental enamel is formed by ameloblasts that are derived from dental epithelium. How dental epithelial stem cells (DESCs) commit to ameloblast lineage remains elusive. A potential critical factor that drives the commitment of DESCs to the ameloblast lineage is retinoic acid (RA). The complex system that drives ameloblast lineage commitment and the abundance of molecules that determine the RA signaling system require us to examine the transcriptomics of developing teeth at single-cell and spatial levels, followed by biological validations. Our preliminary data showed the diversifications of DESCs and the continuous differentiation of ameloblasts in a mouse incisor scRNAseq dataset. We sorted the differentiating ameloblasts into novel clusters in both mouse and human incisor scRNAseq datasets and replicated these findings using RNAscope. Our findings also suggest that RA signaling is inhibited in pre-secretory stage ameloblasts but activated when ameloblasts transition into the secretory stage. We identified potential RA response elements (RARE) in genes that are critical for secretory stage enamel formation. Therefore, we hypothesize that the sequential ameloblast differentiation is specified by critical genes through the retinoic acid (RA) signaling. By integrating scRNA-seq data analyses with molecular validations in developing teeth, we can 1) elucidate the differentiation trajectory of ameloblasts and 2) reveal critical roles of RA signaling in ameloblast differentiation. Aim 1. Determine the ameloblast differentiation trajectory. We will integrate the scRNAseq data obtained from 14 studies in different tooth types from mice, rats, and humans. We will conduct cluster analysis within tooth types and species to identify each phase of the continuous differentiation paths predicted by trajectory inference. We will compare the ameloblast differentiation trajectory across tooth types and species, with an emphasis on molecules relevant to RA degradation and signaling activation. To validate the trajectory defined by bioinformatic analyses, we will perform RNAscope HiPlex assay on mouse developing teeth using identified genes. Aim 2. Determine the critical roles of RA signaling at the onset of secretory stage enamel formation. First, we will conduct spatial transcriptomics and consequent bioinformatic analyses to map spatial distributions of molecules involved in RA synthesis, signaling activation, and metabolism, together with potential target genes of the RA signaling, in mouse enamel organ epithelium and adjacent dental mesenchyme. Second, we will perform the CUT&Tag sequencing to identify RAREs in RA signaling targets across the genome in mouse secretory ameloblasts. We will validate these findings by analyzing spatial transcriptomic and existing scRNAseq data. The completion of this project will allow us to identify critical factors in ameloblast differentiation. These insights will shed light on the mechanisms of tooth morphogenesis and congenital tooth disorders. This project will provide essential information to the development of bioengineering strategies for tooth regeneration.

Up to $312K
2028-02-28
health research

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

Reversal of age related demyelination in the auditory brain stem.

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NIDCD - National Institute on Deafness and Other Communication Disorders

Project Summary One of the most common medical conditions in any aging society is presbycusis, or age-related hearing loss. Approximately one third of American adults suffer from this condition typically starting in their middle ages, and about half of adults over 70 years have a substantial hearing impairment. One of the mechanisms of presbycusis happens in the central nervous system and is termed central hearing loss. Older adults with central hearing loss may have normal or near normal audiograms yet have problems carrying on a conversation in acoustically complex environments where multiple sound sources are active at the same time, such as a busy restaurant, a public place, or any situation where background noises are active. The main reason for this difficulty is that affected individuals have trouble perceptually isolating sound sources of interest (e.g., the voice of the speaker they want to listen to) effectively from other sources, presumably because the neural mechanisms that perform this computation are less effective. Our laboratories' recent work suggests that one key age-related subcellular change in the sound localization pathway contributes to this phenomenology: A demyelination of afferent fibers to the sound localization pathway. In Mongolian gerbils, we propose to experimentally isolate this mechanism by re-creating it in young animals – effectively “making young animals old”. Furthermore, we will test an approach using a pharmaceutical agent in combination with sound stimulation to reverse this age-related change – effectively “making old animals young”. Finally, we will investigate the mechanisms driving the age-related demyelination by studying oligodendrocytes, the glia cells that produce myelin, in young and old animals. The expected results from this study will help determine the role of demyelination in central hearing loss, a common medical condition which is still poorly understood. The expected results will also suggest a potential treatment for this condition.

Up to $2.0M
2029-03-31
health research

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

RNF213: Molecular Functions and Moyamoya Disease

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NINDS - National Institute of Neurological Disorders and Stroke

ABSTRACT Moyamoya disease (MMD), a progressive vasculopathy leading to narrowing and ultimate occlusion of the intracranial internal carotid arteries, is an important cause of childhood stroke. Our lack of knowledge of the etiopathogenesis of MMD hampers the development of preventive and therapeutic strategies. MMD can be genetically triggered and is highly genetically heterogeneous. The gene most commonly associated with MMD is RNF213, due to a founder variant in Asian individuals that confers a low penetrant risk of disease. We identified de novo RNF213 rare variants in a limited region of the protein that lead to early onset, severe, and progressive MMD in infants and toddlers. However, the function of the RNF213 protein and its role in MMD pathogenesis is poorly understood. Our prior work supports the hypothesis that incomplete differentiation of smooth muscle cells (SMCs) from neural crest progenitor cells (NCPCs) leads to increased migration into the lumen and proliferation that fills the occlusive lesion. We identified that decreased oxidative phosphorylation is a consequence of incomplete differentiation and that treatments to increase mitochondrial respiration can rescue the differentiation defect in vitro and prevent MMD-like lesions in vivo in a mouse model. Our goals in this study are to assess whether a highly penetrant RNF213 pathogenic variant, p.F4120L, conforms to this hypothesis and to identify specific molecular mechanisms linking RNF213 to SMC phenotype. The best evidence for RNF213 function comes from a study using mCherry- tagged RNF213, which showed localization of the protein to intracellular lipid droplets (LDs). RNF213 prevents localization of the lipolysis enzyme ATGL to LDs and thus regulates LD turnover. NCPCs have highly variable numbers of LDs, and increasing LDs by lipid loading affects both cell fate and cellular metabolism. We therefore hypothesize that RNF213 in NCPCs is required to modulate LDs to permit SMC differentiation and that the RNF213 p.F4120L variant increases lipolysis of LDs, preventing complete SMC differentiation and leading to increased proliferation and migration and thus occlusive lesion formation. We will test this hypothesis in two specific aims by using (1) an in vitro system of genetically edited induced pluripotent stem cells differentiated to NCPCs then SMCs and (2) a novel Rnf213F4120L/+ knock-in mouse model. Completion of these aims will yield novel and critical insights into MMD pathogenesis, RNF213 function, and the role of LDs in SMC differentiation. We will generate resources that will be made freely available to the research community with the goal to accelerate discovery and testing of potential therapeutic options to prevent, diagnose, and treat MMD.

Up to $429K
2028-05-30
health research

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

Robert Noyce Teacher Scholarship Program

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U.S. National Science Foundation

The Robert Noyce Teacher Scholarship Program seeks to encourage talented science, technology, engineering, and mathematics majors and professionals to become K-12 mathematics and science teachers. The Noyce Scholarship Track provides funds to institutions of higher education to support scholarships, stipends, and academic programs for undergraduate STEM majors and post-baccalaureate students holding STEM degrees who earn a teaching credential and commit to teaching in high-need K-12 school districts. The NSF Teaching Fellowship/Master Teaching Fellowship Track supports STEM professionals who enroll as NSF Teaching Fellows in master's degree programs leading to teacher certification by providing academic courses, professional development, and salary supplements while they are fulfilling a four-year teaching commitment in a high need school district. This track also supports the development of NSF Master Teaching Fellows by providing professional development and salary supplements for exemplary mathematics and science teachers to become Master Teachers in high need school districts.Innovation through Institutional Integration (I3) projects enable faculty, administrators, and others in institutions to think and act strategically about the creative integration of NSF-funded awards, with particular emphasis on awards managed through programs in the Directorate for Education and Human Resources (EHR), but not limited to those awards. For Fiscal Year 2010, proposals are being solicited in nine EHR programs that advance I3 goals: CREST, GSE, HBCU-UP, ITEST, LSAMP, MSP, Noyce, RDE, and TCUP.

$75K – $3.3M
rolling
sciencetechnology

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ROBOTICS OUTREACH COMPETITION - ROC

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NASA Ames Research Center

NASA Ames Research Center (ARC) Robotics Alliance Project (RAP) intends to issue a Cooperative Agreement Notice (CAN) soliciting proposals to design and administer the Robotics Outreach Competition (ROC) Program. This announcement, leading to the award of a Cooperative Agreement, will be issued pursuant to title 14 CFR Part 1260 for educational and nonprofit institutions. The ROC addresses the critical shortage in Science, Technology, Engineering and Mathematics (STEM) fields that the Nation is facing by providing hands-on robotics competition events while working with engineers and talented faculty from universities and high schools in the U.S. It is the strategic intent of this program that students will be inspired and motivated to pursue degrees that meet NASA's robotics competency requirements. A draft CAN was released September 23, 2010 and is available electronically through http://nspires.nasaprs.com . Do not submit a proposal in response to the draft notice. It is issued as an acquisition planning tool and as a means of soliciting industry comments for use in developing the final notice. Interested Parties are encouraged to furnish comments by September 29, 2010. The final CAN is expected to be released on or around September 30, 2010 and will be available electronically through http://nspires.nasaprs.com . Eligible organizations may submit proposals that provide evidence of the capability and proven experience necessary to provide both the technical and administrative framework required to implement a national, high caliber outreach program, including a high-quality national level robotics competition experience that leverages hands-on experiences in a technical environment. Electronically submitted Notices of Intent to propose are requested by October 12, 2010. The proposal due date is anticipated to be October 29, 2010. The electronic submission of each proposal in its entirety is required by the due date for proposal submission. Notwithstanding the posting of this opportunity at FedBizOpps.gov, Grants.gov, or at both sites, NASA reserves the right to determine the appropriate award instrument for each proposal selected pursuant to this announcement. Oral communications are not acceptable in response to this notice.

rolling
sciencetechnology

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Role of Force-directed Lipid Metabolism in the Endothelial-to-Hematopoietic Transition

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NIDDK - National Institute of Diabetes and Digestive and Kidney Diseases

Project Summary/Abstract In vertebrates, self-renewing hematopoietic stem cells (HSCs) are produced from a developmental event called endothelial-to-hematopoietic transition (EHT). EHT consists of a cellular and transcriptional reprogramming that allows hemogenic endothelial cells (HECs) from a subset of embryonic arteries to leave the vessel and become blood stem cells. HSCs have the capacity to replace and restore the complete blood system upon transplant, making HSC transplant the only curative therapy available for blood diseases like leukemia and lymphoma. Given this therapeutic need, great effort has focused on the development of in vitro protocols that attempt to recapitulate the conditions of EHT for clinical expansion or de novo production of stem cells in the dish. To date none efficiently produce long-lived multipotent HSCs, suggesting that one or more developmental signals for this process remain to be defined. Mechanical forces from blood flow are an essential cue for HSC production via EHT, and the zebrafish Danio rerio provides an excellent animal model in which to study this contribution to hematopoiesis due to conserved molecular genetics of EHT in this species and the ability to observe live embryos with active circulation. Flow-driven EHT is mediated in part by the Yes-associated protein (YAP) transcription factor (TF), a transcriptional coregulator that has roles in organ growth, nutrient regulation and cell fate specification. YAP can be directed to the nucleus as a direct result of physical forces acting on the cell, but the molecular mechanisms by which this promotes EHT and HSC production are unclear. In preliminary data generated under K01 support, single-cell transcriptional analysis of wildtype, yap -/- and YAP-overexpressing HECs from zebrafish point to a role for YAP in regulating a battery of self-renewal hematopoietic TFs, cell cycling and metabolic processes. In examining these YAP gain- and loss-of-function (GOF/LOF) transcriptomes, gene module scores suggest an impaired glycolysis-to-oxidative phosphorylation rewiring in HECs. Genes related to lipid metabolism are also dysregulated by YAP perturbation and can be identified in ‘no flow’ datasets from mouse models. This R03 application will investigate the role of force-directed lipid metabolism in developmental EHT using zebrafish as a model. We hypothesize that hemodynamic forces alter lipid usage in HE to drive the metabolically intensive process of EHT. In the first aim, an unbiased approach of mass spectrometry-based lipidomic profiling will be used to quantify the abundance of lipid species in wildtype and YAP gain or loss of function (GOF/LOF) whole-embryo and sorted endothelial cell populations to determine those metabolites that are YAP-regulated (as a proxy for a major cellular transducer of mechanical force). In the second aim a candidate pathway, the secreted sphingosine-1-phosphate lipid mediator, will be studied for its role in EHT by live-imaging, chemical perturbation and state-of-the-art genome editing technologies to create tissue-specific LOF zebrafish lines. Findings from this proposal will uncover force-driven metabolic responses that might enhance production of HSCs via EHT and generate critical preliminary data to support R01 applications.

Up to $128K
2027-12-31
health research

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

Role of macrophages and HSC trogocytosis in the bone marrow niche

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NHLBI - National Heart Lung and Blood Institute

Project Summary The ability to migrate is a hallmark of hematopoietic stem cells (HSCs), which travel to different hematopoietic sites during development and continue to be released from the adult bone marrow throughout life. The migratory property of HSCs has facilitated their collection from blood and their transplantation for curative anticancer therapies. Our recent studies revealed that a large subset of HSCs display macrophage-associated markers, including F4/80 and CD169, on their surface. Remarkably, macrophage marker–presenting HSCs are selectively retained in the bone marrow (BM), whereas HSCs without detectable macrophage marker are exclusively mobilized into the peripheral blood upon forced mobilization. We discovered that HSC use trogocytosis – a rapid and highly effective transfer mechanisms enabling acquisition of membrane-bound proteins from adjacent cells – to license their BM residence and retention. Mobilized HSCs are intravenously injected into recipients previously conditioned with irradiation and/or chemotherapy to reestablish hematopoietic system. Homing of HSCs to the BM niche is the first and critical step that precedes successful transplantation. Preliminary data supporting this application provided evidence that BM-resident macrophages interact with HSCs and guide their homing to the BM niche post-transplantation. These results raise important new questions as to how macrophages interact with HSCs to initiate the transfer, what is transferred, and whether macrophages guide HSC homing via transfer-dependent or -independent mechanisms. In the Specific Aim 1, we propose to define the mechanisms of HSC trogocytosis. Our preliminary results suggest that macrophage markers along with retention machinery, including CXCR4, are transferred from macrophages to HSCs and that HSC trogocytic activity strongly correlates with c-Kit levels on HSCs. We will assess the role of CXCR4 transfer and c-Kit signaling in trogocytosis-mediated transfer between macrophages and HSCs using pharmacologic and genetic means. We will elucidate the molecular underpinnings of a putative stem cell synapse with macrophages. In the Specific Aim 2, we will investigate how macrophages interact with HSCs to regulate their homing and/or engraftment post-transplantation. We will use co-culture system in vitro to manipulate the interactions between macrophages and HSCs and test models to explain their functional consequences with respect to stem cell transplantation. We will further investigate the macrophage heterogeneity and their location and interactions with HSCs during homing and engraftment using single cel technologies and immunofluorescent imaging. These studies will provide foundational insights into the macrophage niches and their contributions to HSC homing, retention, and mobilization, all key to improving stem cell transplant therapy for patients with blood disorders.

Up to $521K
2031-02-28
health research

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

Role of RNA-binding protein DDX3X in the endocardium during development and disease

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NHLBI - National Heart Lung and Blood Institute

PROJECT SUMMARY Cardiac development is a complex process that occurs early during embryonic development and requires precise regulation. Early cardiac development, especially of the endocardial and myocardial lineages, is implicated in the development of congenital heart diseases (CHDs). Unfortunately, despite CHDs being the most frequent birth defect affecting approximately one in 100 live births, very few mechanisms are understood about many different forms of CHDs. Proper cardiac development requires precise post-transcriptional regulation, such as alternative splicing, translation initiation, and mRNA modification. These functions are mediated by RNA-binding proteins (RBPs), and unsurprisingly, mutations to many RBPs are implicated in cardiac development and formation of CHDs. One such RBP is DDX3X, which is known from clinical evidence to have implications in CHDs: patients with mutations in DDX3X exhibit DDX3X syndrome, marked by neurodevelopmental disorders and increased risk of CHDs. However, DDX3X has not been well-studied to date in the context of heart development. My proposed research will study the dosage-sensitive effects and mechanisms of DDX3X in the endocardial lineage during cardiac development. In Aim 1 of this proposal, I will determine the effects of reduced DDX3X levels on endocardium formation and function. Using transgenic mice, I will conditionally delete DDX3X in male and female mouse endocardium. Expression level of DDX3X in the endocardium will be quantified using immunofluorescent imaging and flow cytometry. I will then characterize resulting phenotypes by examining phenotypic onset, structural and functional consequences, and cellular and molecular consequences in the heart using a combination of brightfield and immunofluorescent imaging, weight measurements, and echocardiograms. In Aim 2 of this proposal, I will identify the molecular mechanisms of DDX3X in the endocardium. Using immunofluorescent imaging, I will characterize the subcellular localization of DDX3X in the endocardium. I will then identify the direct regulatory network of DDX3X in the endocardial lineage using RNA-seq and Ribo-seq. Targets will be validated against pre-existing eCLIP data as well as in an in vitro system of human pluripotent stem cell-derived endocardial cells. The results of this research will contribute to our understanding about RNA biology, gene dosage, development and disease.

Up to $55K
2030-01-31
health research

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Role of Wnt/β-catenin pathway in alveolar epithelial repair during tuberculosis and its regulation by chronic type I interferon signaling

open

NIAID - National Institute of Allergy and Infectious Diseases

Project Summary Tuberculosis (TB) remains a leading cause of mortality worldwide, with lung damage being a key driver of disease severity and poor outcomes. Alveolar epithelial cells are critical for maintaining lung homeostasis and promoting repair, processes that are tightly regulated by Wnt/β-catenin signaling. Our preliminary data indicate that Mycobacterium tuberculosis (Mtb)-induced inflammation disrupts alveolar epithelial integrity in TB-susceptible mice, leading to impaired surfactant production and defective lung regeneration. Strikingly, this is associated with a significant reduction in β-catenin levels. Notably, inhibition of type I interferon (IFN-I) signaling restores β-catenin expression, suggesting a previously unrecognized role of IFN-I in suppressing Wnt/β-catenin activity and alveolar repair. We aim to investigate how chronic IFN-I signaling impairs Wnt/β-catenin function, leading to defective epithelial repair and exacerbated lung pathology in TB. Specifically, in aim1, we will define the role of Wnt/β-catenin in alveolar epithelial repair following Mtb infection. We will assess how Wnt/β-catenin activation or inhibition influences alveolar type 2 (AT2) cell proliferation, differentiation, and stemness using murine and human primary alveolar cells. Additionally, we will evaluate lung histopathology, epithelial marker expression, and AT2 cell differentiation in TB-resistant and susceptible mice. In aim2, we will determine how IFN-I signaling suppresses Wnt/β-catenin activity during TB-induced lung damage. Using genetic and pharmacological approaches, we will investigate the molecular mechanisms by which IFN-I signaling modulates Wnt/β-catenin function and identify key mediators of IFN-I–Wnt/β-catenin crosstalk as potential therapeutic targets. Finally, in the aim3 we will evaluate the therapeutic potential of targeting Wnt/β-catenin and IFN-I pathways to enhance alveolar repair. We will test Wnt/β-catenin activators, such as GSK3β and Porcupine inhibitors, as well as IFN-I blockade using anti-IFNAR antibodies in murine TB models. Therapeutic efficacy will be assessed through histopathological analysis, epithelial barrier integrity, inflammatory responses, and bacterial burden. This study will provide novel insights into the interplay between IFN-I signaling and Wnt/β-catenin in TB pathogenesis, uncovering mechanisms that impair alveolar repair. By identifying host-directed therapeutic strategies, we aim to enhance lung recovery and improve outcomes for TB patients.

Up to $451K
2028-01-31
health research

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Roles of mRNA transfer in cancer cell-platelet communication

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NCI - National Cancer Institute

The interaction between cancer cells and platelets plays important roles in regulating cancer cell function. Understanding how platelets communicate with cancer cells to modulate cancer cell colonization at distant organs may identify novel strategies to halt cancer spreading. We recently showed that recruitment of platelet to cancer cells is essential for the colonization of circulating tumor cells (CTCs) at the secondary organs. However, the molecular mechanism by which platelets modulate cancer cell function to promote cancer cell colonization remains to be determined. By analyzing RNA-seq data from CTCs and primary tumors, we found that platelet- specific mRNA was significantly enriched in CTCs. RNAscope and Translating Ribosome Affinity Purification (TRAP) analyses showed the delivery of platelet mRNA and translation of platelet-derived mRNA in cancer cells. In vivo functional screening identified multiple platelet-derived mRNAs contribute to colonization of breast cancer cell at distant organs. These results reveal the new role of platelet mRNA in mediating intercellular communication and in promoting cancer cell spreading. The overall objective of this proposal is to define the molecular mechanism by which platelet mRNA is delivered into breast cancer cells and determine roles of platelet mRNA as the signaling molecular in promoting cancer cell colonization at distant organs. We showed that CD9 expression in CTCs correlated with the accumulation of platelet-specific mRNA. Silencing CD9 in breast cancer cells significantly reduced platelet mRNA transferring and colonization of cancer cells. Platelet factor 4 (PF4) is a small cytokine belonging to the CXC chemokine family that is highly expressed in platelets. We showed that the transfer of PF4 mRNA from platelets to breast cancer cells enhanced stemness and colonization of cancer cells. Based on these results, the central hypothesis of this proposal is that the CD9-dependent mRNA transfer mediates the platelet-cancer cell communication and promotes cancer cell stemness. We propose the following two aims to test this hypothesis and achieve our objective. Aim 1. Elucidate the mechanism by which platelet mRNA is transferred into cancer cells. Aim 2. Determine how the transfer of platelet PF4 mRNA in cancer cells promotes cancer metastasis.

Up to $295K
2028-11-30
health research

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Scholarships in STEM Network

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U.S. National Science Foundation

Through this solicitation, NSF seeks to foster a network of S-STEM stakeholders and further develop the infrastructure needed to generate and disseminate new knowledge, successful practices and effective design principles arising from NSF S-STEM projects nationwide. The ultimate vision of the legislation governing the S-STEM parent program[1] (and of the current S-STEM-Net solicitation) is that all Americans, regardless of economic status, should be able to contribute to the American innovation economy if they so desire. To support collaboration within the S-STEM network, NSF will fund several S-STEM Research Hubs (S-STEM-Hub). The S-STEM Network(S-STEM-Net) will collaborate to create synergies and sustain a robust national ecosystem consisting of multi-sector partners supporting domestic low-income STEM students in achieving their career goals, while also ensuring access, inclusion, and adaptability to changing learning needs. The Hubs will investigate evolving barriers to the success of this student population. It will also disseminate the context and circumstances by which interventions and practices that support graduation of domestic low-income students (both undergraduate and graduate) pursuing careers in STEM are successful. The target audience for this dissemination effort is the community of higher education institutions, faculty, scholars, researchers and evaluators, local and regional organizations, industry, and other nonprofit, federal, state, and local agencies concerned with the success of domestic low-income STEM students in the United States. [1] https://www.nsf.gov/pubs/2022/nsf22527/nsf22527.htm

$3M – $15M
rolling
sciencetechnology

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