Grants

Capoeira Life fiscally sponsored by Shunpike

Capoeira Life, our BIPOC, LGBTQ+, people w/disabilities, community-led group will provide 1 year of free weekly and monthly capoeira programs, and free capoeira participatory events to all members of public, especially underserved, at local recreational facilities, Seattle parks, community centers, schools, and other partner sites.

Capoeira and Arts Association of New England

Caporira Cultural Exchange Batizado and Workshops

NIAID - National Institute of Allergy and Infectious Diseases

Project Summary Capsid assembly is an essential step in production of an infectious herpesvirus, yet little is known on how the process begins and the protein oligomeric states and intermediate interactions required to complete the final mature capsid. Disruptions in capsid assembly result in aberrant capsids unable to assemble or package viral DNA, resulting in noninfectious virus. The major proteins involved in herpesvirus capsid assembly are generally conserved across alpha, beta, and gammaherpesvirus subfamilies which provides an opportunity to develop pan-herpesvirus therapeutics. Yet to date, little has been done to capitalize on this process; furthermore, most capsid assembly research focuses on alphaherpesvirus, HSV-1. This proposal focuses on understanding capsid assembly of gammaherpesvirus, Kaposi sarcoma herpesvirus (KSHV), the leading cause of cancer in HIV positive individuals. I will develop an in-vitro capsid assembly assay to monitor capsid kinetics and oligomeric states required for capsid nucleation and maturation. I hypothesize KSHV capsid assembly is a highly dynamic process requiring multiple conformations of capsid protein intermediates to generate a capsid capable of packaging a large DNA genome. I will purify KSHV capsid proteins via baculovirus expression and systematically determine the proteins required for capsid formation and kinetics via dynamic light scattering and negative stain electron microscopy. In addition, I will evaluate the oligomeric states of capsid proteins individually and protein intermediates to determine 1. The proteins required for capsid nucleation and 2. How KSHV scaffold oligomerizes to produce unique B-capsid morphologies. I further hypothesize that the divergence of SCP between subfamilies is a result of variations in the capsid assembly pathway. For example, it is thought SCP is not required for alphaherpesvirus capsid assembly but is required for gamma and betaherpesviruses. I hypothesize SCP is required for efficient C-capsid assembly, as loss of SCP results in decreased infectious virus and C-capsid formation in alpha, beta, and gammaherpesvirses; however, the exact mechanism is unclear and seems dependent on cellular environment. I will use the in-vitro capsid assemble assay and live virus mutagenesis to study the function of SCP in capsid maturation. I will utilize previously generated KSHV SCP null viruses to quantify capsid structural integrity with atomic force microscopy to determine at what stage capsid assembly stalls, as well as the role of phosphorylation on SCP’s function. These aims will highlight the similarities and difference between alpha and gammaherpevirus viruses, providing the evidence required for inhibitor development and a scalable in-vitro assay for testing inhibitors. I will develop a robust skillset in biophysical techniques which coupled with my expertise in molecular virology will allow me to successful complete these aims and develop the skills required to run my own independent research lab.

Seaport Museum New York

Captive Passage Programming

NIGMS - National Institute of General Medical Sciences

Project Summary/Abstract Chemical separations are foundational to modern chemistry, yet traditional liquid chromatography-mass spectrometry workflows often fail to detect many isomeric and conformational features of biomolecules critical to metabolism, disease, and drug efficacy. To address these limitations, the Clowers Research Group (CRG) at Washington State University is advancing ion mobility spectrometry and mass spectrometry techniques, leveraging gas-phase ion chemistry and high-resolution separations enabled by Structures for Lossless Ion Manipulations (SLIM). SLIM technology’s extended cyclic separations and controlled gas environments allow for the resolution of isomers and intermediates that conventional methods frequently miss. To quantitatively capture isomeric heterogeneity in complex biological systems, the CRG is implementing tailored multiplexed ion strategies such as Phased Ion Mobility Spectrometry. This technique aligns SLIM separations with ultra-performance liquid chromatography timescales, reducing spectral ambiguity and improving the resolution of co-eluting isomers in diverse ‘omics applications. Complementing these strategies, the group is integrating gas-phase labeling techniques, including hydrogen-deuterium exchange (gHDX) and ozone-induced dissociation. These methods provide dynamic insights into molecular interactions by capturing solvent- accessible regions and chemically selective modifications, enhancing the characterization of isomeric and conformational states. The integration of tandem collision-induced unfolding with SLIM and gHDX adds another layer of analytical depth, enabling the isolation and detailed examination of intermediate protein structures. This approach reveals conformational transitions and solvent-accessible regions during unfolding, helping to quantify molecular stability and refine structural models of biopolymers. By combining SLIM-based separations, multiplexing strategies, and gas-phase labeling workflows, the CRG’s research program is redefining bioanalytical approaches. These innovations aim to enhance the detection of isomeric heterogeneity, reduce analytical errors, and provide new insights into metabolomics, lipidomics, and structural biology in support of public health outcomes. 1

NIA - National Institute on Aging

Poor social health (high loneliness, high social isolation, low social support) is associated with heightened risk for Alzheimer's disease and related dementias (AD/ADRDs). Theoretical models posit that social health's long-term effects on cognition result from cumulative risks associated with short-term, dynamic social processes. For example, loneliness may increase AD/ADRD risk by reducing healthy behaviors (physical activity) and increasing unhealthy behaviors (alcohol consumption), impacting momentary cognitive performance and variability – which, themselves, predict future AD/ADRD diagnosis. Digital biomarkers that capture short-term, dynamic associations between social and cognitive health hold promise to detect early clinical signatures of cognitive decline and identify personalized targets for AD/ADRD risk-modifying behavioral interventions. Three major gaps obfuscate mechanisms linking social and cognitive health, stalling digital biomarker development. First, there is a conceptual gap: theoretical models highlight the cumulative impact of daily social experiences in AD/ADRD-related cognitive decline, yet empirical research relies largely on cross-sectional or limited longitudinal designs ill-suited to capture this granularity. Second, there is a measurement gap: ecologically valid tools differentiating the ABCs of social health have yet to be validated for ecological momentary assessment (EMA), hampering interpretation of dynamic, within-person associations. Finally, there is a computational gap: AD/ADRDs are highly heterogeneous, yet current analytic approaches do not adequately accommodate individual differences in AD/ADRD pathogenesis. This project is strategically poised to address these gaps through three aims. We will (1) develop mobile assessments of social health; (2) delineate short-term cognitive impacts of daily social dynamics; and (3) generate individualized models of social determinants of AD/ADRD risk. We hypothesize that, within individuals, cognition will be reduced when social health is low. We further expect to identify social and behavioral mediators of within-person associations between social health and cognition, as well as multiple combinations of social risk factors that predict AD/ADRD risk, consistent with multiple pathways to AD/ADRD. We will test hypotheses in a sample of N=250 adults (45-74 years) who provide intensive longitudinal social and cognitive EMA data. Successful completion of study aims significantly advances measurement, mechanistic understanding, and early risk assessment in AD/ADRDs, with implications for reducing the burden of AD/ADRDs through behavioral intervention. Successful completion of study aims is innovative because it provides the field with novel, open-source EMA scales optimized to measure fluctuations in multiple dimensions of social health. Race and ethnicity will be representative of 2060 United States population projections, ensuring that products of our work–including open-source scales and dynamic modeling insights–will support accurate stratification of midlife risk as population demographics shift.

Maggie Osgood Library

Expand the Maggie Osgood Library Digital Repository (MOLDR) to include oral histories and bring the stories of Lowell and surrounding unincorporated areas to life.

NCI - National Cancer Institute

PROJECT SUMMARY CAR T cell therapy for solid tumors is hindered by a lack of tumor-specific antigens that are safe to target and homogenously expressed throughout the tumor, difficulty infiltrating the tumor due to dense tumor stroma, and suppression of CAR T cell function by the tumor microenvironment (TME). We plan to address these issues using novel meso-FAP CAR-TEAM cells that simultaneously target mesothelin, a solid tumor antigen that has already been proven safe to target in patients, and cancer-associated fibroblasts (CAFs), which inhibit T cell infiltration and suppress T cell function in the TME. The CAFs are targeted with T cell-engaging antibody molecules (TEAMs) secreted from the CAR T cells that bind to CD3 and fibroblast activation protein (FAP), which is highly expressed on CAFs. The TEAM allows for CAF elimination by CAR and non-CAR T cells in the tumor. We have already demonstrated that meso-FAP CAR-TEAM cells kill pancreatic cancer cells and CAFs in vitro, in vivo, and in patient-derived ex vivo models and have superior anti-tumor function compared to meso-CAR T cells alone. For the UG3 phase of this project, we will further optimize meso-FAP CAR-TEAM cells by determining the best mesothelin binder to use (SS1 vs. a novel binder developed by our lab), optimal route of injection (IV vs. IP) for targeting pancreatic tumors, and rationale drug combinations that address CAR T cell limitations in solid tumors. We will improve antigen density using an ADAM17 inhibitor (INCB7839) to prevent mesothelin cleavage from pancreatic cancer cells, optimize CAR T cell killing and persistence using ibrutinib to polarize meso-FAP CAR T cells to a Th1/Th17 phenotype, and further prevent suppression by the tumor microenvironment using a PD1 inhibitor (pembrolizumab). These drugs will be singly combined with meso-FAP CAR-TEAM cells to determine which best promotes efficacy in our preclinical models. Collectively, these results will inform the design of a phase I clinical trial for pancreatic cancer patients with advanced disease. During the UH3 phase, we will determine the safety and tolerability of meso-FAP CAR-TEAM cells. We have chosen pancreatic cancer as our first solid tumor target due to the dismal prognosis of the disease, the high percentage of patients with mesothelin-expressing tumors, and the known role of CAFs in promoting tumor growth. While our primary objective will be to determine safety, we will also monitor patient outcomes (progression and survival) while performing correlative studies to determine CAR T cell phenotype and function. We will also monitor the tumor and tumor microenvironment for mechanisms of response or resistance, such as changes in antigen expression and immunosuppressive cells. Overall, this project will develop a novel CAR-TEAM design to target a solid tumor and its microenvironment while optimizing the trial design through rigorous preclinical testing. If successful, the meso-FAP CAR T cell product could be directly applied to other mesothelin-expressing solid tumors and the knowledge gained from the UG3 phase will inform on the critical aspects of CAR T cell function to optimize prior to initiating a clinical trial.

Chicago Department of Transportation

FFY 2025 STATE/LAKE LOOP ELEVATED

NSF

Access to the genetic information encoded in DNA must be both rapid and under tight control so that a cell can readily adapt to its environment, or rapidly respond to growth signals. One regulatory mechanism that is used in nature is to poise the protein machines that access genetic information at the start of genes, waiting to initiate the process of converting the encoded information into molecules that execute cellular functions. Chemical modifications of these ready-to-go proteins exert timely control over cellular responses to stimuli by dictating the efficiency with which genes are activated. For this project, the investigator will push the boundaries of current technologies to explore the structural responses to chemical modifications that trigger release from pausing and entry into efficient decoding of genetic information. This program addresses a significant gap in our knowledge of how gene expression is regulated. This program will train junior scientists at multiple education levels to seek fundamental insight into the systems and processes from biochemistry, using the principles and quantitative laws from the physical sciences. Among other outreach efforts, the investigator will bring undergraduate students from different schools to Penn State for research opportunities that will enhance their career potential in science and engineering fields. To achieve this project’s objectives, new experimental methodology will be implemented for nuclear magnetic resonance (NMR) spectroscopy of highly flexible proteins. While protons are relatively easy to observe by NMR, the PI has shown that the comparatively more challenging direct-detection of carbon yields more quantitative and complete information for intrinsically disordered polypeptides. Recently, the PI used this technique to demonstrate how serine phosphorylation of RNA polymerase II provides a structural switch that plays a role in regulating the critically important enzyme. RNA Polymerase II pauses at the start of genes before entering into productive elongation and these phosphorylation events are associated with release from the paused state. The PI will now broaden the characterization of pause release by investigating threonine phosphorylation on a required co-regulator of RNA polymerase II, named the DSIF complex, which is a second necessary step for pause release. The phosphorylation patterns on RNA Polymerase II change throughout the process of RNA elongation, so this project will extend characterization of serine phosphorylation to model each of the relevant states in an RNA production cycle. Finally, lysine amino acids in a specific region of RNA polymerase II also acquire methyl groups while the enzyme is active on a subset of genes. These modifications can exert combinatorial control with the previously characterized phosphorylation. Therefore, experiments will be performed to test the hypothesis that addition of methyl groups to the amino acid lysine also induces structural transitions, akin to those the PI has observed in association with phosphate incorporation. As a result, this research and associated training activities will yield fundamental, molecular level insights that provide critical molecular insights into gene regulation. This project is funded by the Molecular Biophysics Cluster in the Division of Molecular and Cellular Biosciences. This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

NHLBI - National Heart Lung and Blood Institute

PROJECT SUMMARY Heart disease is a leading cause of mortality among cancer survivors, significantly impacting over 9% of the 16.9 million adult survivors in the United States. These survivors develop heart conditions post-treatment due to the cardiotoxic effects of chemotherapy agents like anthracyclines. Anthracyclines, such as doxorubicin, are potent chemotherapeutic agents used extensively in cancer treatments. They are administered in approximately 60% of breast cancer and 70% of childhood cancer cases. However, they cause acute cardiotoxicity in about 11% of patients, with detrimental cardiac effects persisting for up to 40 years in childhood cancer survivors. Current cardioprotective therapies, including dexrazoxane, have demonstrated limited long-term efficacy and raise concerns about potential interference with doxorubicin's antitumor effect. This highlights a significant gap in effective cardioprotective therapies due to an insufficient understanding of the molecular mechanisms underlying anthracycline-induced cardiotoxicity (AIC). Recent advancements in human induced pluripotent stem cell- derived cardiomyocytes (iCMs) offer unprecedented opportunities to model human cardiac diseases at an individual level, providing a novel avenue to explore the mechanisms of AIC. Leveraging the iCM model, combined with CRISPR interference/activation (CRISPRi/a) genetic screens, our preliminary studies have identified that inhibition of Carbonic Anhydrase XII (CA12) mitigates AIC in iCMs and in mice treated with doxorubicin. CA12 is involved in regulating intracellular pH and metabolism, potentially enhancing lactate production through glycolysis. Our findings suggest that doxorubicin upregulates glycolysis in iCMs via CA12 activation, leading to increased lactate production and subsequent histone lactylation, specifically at H3K18la - a newly characterized epigenetic modification influencing gene expression and potentially contributing to cardiomyocyte dysfunction. We hypothesize that cardiac-specific knockout of CA12 will reduce doxorubicin- induced glycolysis and lactate production, thereby protecting cardiac function by preventing the activation of cardiac dysfunction genes via histone lactylation. In Aim 1, we will investigate the role of CA12-mediated glycolysis in AIC by assessing whether inhibition of CA12 can protect against AIC in iCMs derived from patients who have experienced doxorubicin-induced cardiotoxicity (DoxTox patients) and in cardiomyocyte-specific CA12 knockout (Car12 cKO) mice. In Aim 2, we will explore the role of glycolysis-mediated histone lactylation in AIC and its relationship with CA12 by examining how increased lactate production leads to histone lactylation at H3K18la, epigenetically activating cardiomyocyte dysfunction genes. Ultimately, these findings have the potential to improve the long-term cardiovascular health of cancer survivors by informing the development of safer chemotherapy regimens and adjunctive therapies that protect cardiac function, thereby addressing a critical unmet need in cardio-oncology.

NHLBI - National Heart Lung and Blood Institute

Project Summary Cystic fibrosis (CF) is a genetic disease causing premature death, primarily due to respiratory failure from increased inflammation and chronic infections. While therapies targeting the dysfunctional protein channel have improved lung function and mucus clearance, infection remains a significant problem. This proposal investigates how impaired microtubule (MT) dynamics and intracellular transport, exacerbated by reduced carbonic anhydrase (CA) expression, contribute to increased bacterial adhesion in CF. The central hypothesis is that reduced CA expression disrupts MT dynamics, leading to impaired intracellular transport and accumulation of pathogen-binding targets on cell membranes. The approach will use advanced live cell imaging, biochemical assays, proteomics, and microbial adherence studies to test hypotheses across three specific aims: 1) Determine the role of CA2 and CA12 in intracellular transport and membrane organization; 2) Identify the binding target and mechanism for increased bacterial adhesion in CA-deficient airway epithelia; and 3) Assess the roles of MTs and CA in the ability to eradicate Pseudomonas aeruginosa among people with CF, determining in vitro response to MT- and CA-targeted agents. This research will provide new insights into the cellular mechanisms of infection in CF and could identify novel therapeutic targets to improve infection control. The significance of this study lies in its comprehensive approach to understanding and addressing infection in CF, which can be applied to other diseases involving defective intracellular transport and cytoskeletal dynamics. This project will also serve as an excellent vehicle for the applicant’s development into an independent investigator. Investigations will be performed in an environment with an established history of successful mentorship of junior faculty to independence. The applicant’s long-term career goal is to become a leading, independent investigator with a translational lab studying cellular mechanisms driving infection and inflammation in the lungs, with a specific focus on host-microbial interactions that modify the landscape of microbiota within the airway. With the support of this award, the applicant will 1) build technical skills in advanced imaging techniques, 3D model systems, and bioinformatics, and 2) develop expertise in interpreting data and translating findings to clinical therapeutics. Future independent studies will focus on the relevant pathways and targets affected by CA and MT disruption to identify possible therapeutic interventions that can be tested in pre-clinical, and ultimately clinical, models.

NHGRI - National Human Genome Research Institute

Nest Genomics has created a software platform to launch, implement, and scale longitudinal genomic programs. It supports patients with hereditary syndromes from risk identification to long term management following the latest guidelines for disease management. As a personalized platform built to support and empower patients over time, Nest is well positioned to address challenges around family sharing and cascade testing. A use case focused on cardiac diagnoses has not been developed nor has the functionality to share and communicate genetic risk information. The objective of this Phase I STTR is the development, adaptation, and refinement of the Nest platform for risk communication and disease management in families with hypertrophic cardiomyopathy (HCM), the most common inherited cardiac condition, using a recursive process between Nest Genomics, Virginia Commonwealth University (VCU), and University of Iowa (UI). The technical merit and feasibility of the proposed research and development efforts will be achieved through three aims: Aim 1: Develop HCM content in the Nest platform. Nest Genomics and its academic partners, VCU and UI will collaborate to develop storyboards for patients with HCM and their family members. Storyboards will include guideline driven action items including clinical screening (e.g., echo, ekg), information for affected persons and at-risk relatives. Aim 2: Build Family Sharing Functionality. Nest Genomics, VCU, and UI, will collaborate to develop family sharing functionality within the Nest platform. These developments will focus on integrating the patient’s pedigree information with their user contact list to develop a family sharing plan. The family sharing plan will allow users to easily identify at-risk relatives and select and share authoritative health information (including genetic test reports) with them. The platform will guide relatives through their genetic risk information and facilitate next steps, including scheduling genetic counseling and/or genetic testing and will facilitate feedback loops to support sustained family engagement. Aim 3: Establish usability and acceptability among families with HCM (patient-relative dyads) and healthcare providers. An iterative “think aloud” process will be used to gather feedback from a representative group of participants (n=20 dyads) and 15 genetic healthcare providers. Data will be analyzed to assess usability and acceptability of the content and family sharing functionality. This user feedback will guide revisions of the platform until an acceptable, user-friendly iteration is achieved. Communication of HCM risk among family members is a critical step to ensure relatives have the option to be screened and treated prior to the development of life-threatening complications. Successful completion of this Phase I project will demonstrate feasibility of the product in a diverse population and provide the functionality and data to advance, test and commercialize the product in a Phase II project. This project also provides pilot data for future R-level studies evaluating and comparing effectiveness of the tool in improving communication and cascade screening in families.

NHLBI - National Heart Lung and Blood Institute

There are approximately three million individuals with perinatally acquired human immunodeficiency virus (pnHIV) worldwide and >150,000 new youth with pnHIV (YpnHIV) annually. The incidence of pnHIV has declined dramatically over the last two decades, yet rates remain high in Eastern and Southern sub-Saharan Africa (SSA) - threefold greater than the global average. Prior studies from SSA have been unable to resolve whether pnHIV increases risk of cardiac or physical dysfunction compared to unexposed children or those with perinatal HIV exposure but who are HIV seronegative (PHEU). Elucidating determinants of cardiac, autonomic and physical dysfunction in the disproportionately affected population of YpnHIV is critical to identify, treat and prevent cardiac comorbidities. Comprehensive phenotyping that combines cardiac imaging, physical function assessment, autonomic dysfunction and molecular profiling represents an innovative approach to fully characterizing the earliest manifestations of subclinical disease thereby enabling early intervention. Thus, the overall objectives of this application are to identify imaging and proteomic determinants of cardiac dysfunction in YpnHIV compared to the HIV unexposed (HU), and to evaluate effects of YpnHIV on physical performance and heart rate variability. Our central hypothesis is that YpnHIV have worse cardiac and physical function compared to HU and PHEU. Our hypothesis builds on our preliminary data which identified a high burden of early cardiac dysfunction on echocardiogram among YpnHIV, and preliminary data linking subclinical cardiac dysfunction among YpnHIV to proteomic profiles indicating cardiac fibrosis, inflammation, and immune activation from a large HIV care program in western Kenya. We will test our central hypothesis through the following Specific Aims: (1) Determine if pnHIV is associated with cardiac dysfunction and abnormal physical performance in children and young adults; (2) Identify mechanisms of subclinical cardiac dysfunction and related biomarkers in YpnHIV using high-throughput proteomic profiling; (3) Measure the effect of HIV status on longitudinal change in cardiac and physical function during a period of rapid adolescent growth. To achieve our Aims, we will conduct a prospective study of a total of >400 YpnHIV, PHEU and HU in western Kenya who are engaged in a long-term, population-based HIV clinical care program – the Academic Model Providing Access to Healthcare (AMPATH) Kenya Program. We will perform echocardiograms, a clinical assessment, six-minute walk testing, heart rate variability assessment and collect biospecimens for molecular profiling through proteomics. In a sub-sample, we will repeat measures at 24 months to determine whether YpnHIV, PHEU and HU status impacts progression of cardiac or physical dysfunction. Our scientific contribution is expected to be significant because we are addressing a dire health comorbidity for YpnHIV with deep clinical, imaging, functional and biomarker phenotyping in an endemic population. As a consequence of the work proposed, we expect to uncover novel insights and a deeper understanding of the pathobiology of contemporary HIV-related cardiovascular comorbidities.

NHLBI - National Heart Lung and Blood Institute

Project Summary Obstructive sleep apnea (OSA) is known to be correlated with cardiovascular diseases (CVD), yet controlled clinical trials showed that CPAP treatment was insufficient to alleviate CVD risk in all patients. Current tools fail to identify the mechanistic pathways involved in OSA-related CVD pathophysiology, and residual CVD risk may persist despite CPAP treatment. Conversely, some studies have identified OSA as possibly protective against myocardial infarction preconditioning consequences, highlighting significant knowledge gaps in understanding the mechanisms linking OSA and CVD. This research project aims to elucidate the complex relationship between OSA and CVD through an innovative "heart-on-a-chip" platform combined with validated intermittent hypoxia (IH) protocols. Specifically, we will develop and validate physiologically relevant IH protocols using endothelial cells, comparing responses against patient tissue samples. These validated protocols will then be applied to our "heart-on-a-chip" model to investigate the direct impact of OSA-induced IH on cardiac structure and function, providing insights into OSA-specific cardiovascular diseases. Additionally, we will examine whether different patterns of OSA-associated IH can provide cardiovascular protection through preconditioning mechanisms prior to ischemic insult and identify the underlying pathways. This comprehensive approach addresses current limitations in OSA research by providing physiologically relevant in vitro models that can directly test competing hypotheses about OSA's cardiac effects. Our research has the potential to identify novel therapeutic targets and improve the clinical management of OSA patients at risk for cardiovascular complications.

NHLBI - National Heart Lung and Blood Institute

Project Summary Familial hypertrophic cardiomyopathy (HCM) is the most common genetic heart disease with an estimated prevalence of 1:500 individuals in the general population. Sarcomere gene mutations result in the characteristic features of HCM include left ventricular (LV) hypertrophy, myocyte disarray, interstitial fibrosis, diastolic dysfunction, and high risk of cardiac arrhythmias and sudden death. Indeed, HCM is the number one cause of sudden cardiac death in young, otherwise healthy adults. Non-invasive treatments for HCM target symptoms and do not prevent or slow disease progression, underscoring the need for new therapies. Recently, a new small molecule negative ionotropic agent has shown promise in treating HCM, but long- term benefits remain to be reported. HCM research has focused primarily on genetics and molecular mechanisms impacting cardiomyocyte and LV structure and function. Hypercontractile sarcomeres accompanied by metabolic dysfunction and energy depletion are considered causal mechanisms. We propose that the aberrant mechanical and metabolic signals produced in HCM hearts are detected by cardiac sensory nerves, with the resulting abnormal reflexes contributing to acute cardiovascular instability, chronic and selective increases in sympathetic nerve activity to the heart, decreased parasympathetic activity, cardiac inflammation, fibrosis, and diastolic dysfunction. We hypothesize that cardiac spinal afferents (CSAs) in HCM exhibit increased chemosensitivity, reflecting increased [H+] produced by myocyte energy depletion/ischemia and increased neuronal expression of acid-sensing ion channel 3 (ASIC3). An alpha tropomyosin mouse model of HCM with cardiac-targeted mutation known to cause HCM in humans will be studied in male and female mice. Specific aims of the project are: 1) Test the hypothesis that HCM mice demonstrate a selective increase in cardiac sympathetic tone mediated by the cardiac spinal afferent reflex and dysfunction of the neuronal norepinephrine transporter, and 2) Test the hypothesis that increased activity of CSAs is mediated by ASIC3 and targeted cardiac ablation of CSAs will improve cardiac and autonomic function in HCM mice.The proposed studies using innovative, targeted, and complementary approaches will close gaps in knowledge regarding mechanisms causing sympathovagal imbalance in HCM prior to heart failure, the influence of cardiac innervation on the HCM heart, and the quest for disease-modifying therapies in HCM. Pursuant to the goals of the Academic Research Enhancement Award (R15), this project will also provide research opportunities in neural-cardiovascular physiology to undergraduate students studying human health at Michigan Technological University.

NHLBI - National Heart Lung and Blood Institute

Project Summary Despite their well-recognized increased risk of overweight and obesity, adults with Down syndrome (DS) have not traditionally been considered at increased risk for “cardiometabolic” conditions such as Type 2 diabetes (T2D) and atheromatous disease. Recent robust epidemiologic data from the UK Clinical Practice Research Datalink suggest adolescence and young adulthood are specific periods of vulnerability for T2D development in this population. Overweight and obesity are clear risk factors, but their intersection with both DS-related co-morbidities [obstructive sleep apnea (OSA), congenital heart defects (CHD), dementia, hypogonadism, cancer survivorship] and demographics [race/ethnicity, aging] recognized to confer increased cardiometabolic risk (CMR) remain undefined. An improved understanding of CMR as well as potentially cardioprotective factors in a large, diverse population of individuals with DS is crucial for defining screening practices and interventions that minimize patient burden while considering the relevance of both traditional T2D complications and the intersection of CMR with established DS- related co-morbidities. This study will leverage de-identified data from a large, Research diverse population of adults with DS captured in the TriNetX Network of multiple health care organizations to 1) describe the prevalence of T2D, dyslipidemia, hypertension, OSA as well quantify HbA1C and lipids (HDL, LDL, TC, TG) by 5-year intervals; 2) examine the relationships of T2D, atheromatous disease, and dyslipidemia with common co-occurring condition in adults with DS (history of CHD, overweight/obesity, OSA, psychiatric medication prescription, dementia, menopause, cancer survivorship) and demographics (age, sex, race/ethnicity), 3) explore microvascular complications in the subset of patients with diabetes and 4) quantify screening practices for co-occurring conditions in adults with DS. This large database effort performed in a diverse, national population of adults with DS will advance our understanding of the prevalence of CMR, vascular complications, and cardiovascular risk factors in DS, a critical step for developing screening guidelines and targeted interventions that minimize patient burden without compromising care. This work will serve as the foundation for a longitudinal study aimed at defining the relevance of T2D and CMR for individuals with DS and to develop interventions to optimize screening for co-occurring conditions.

NHLBI - National Heart Lung and Blood Institute

Abstract Support is requested for a Keystone Symposia conference entitled “Cardiometabolism in Health and Disease,” organized by Drs. Daniel P. Kelly, Rong Tian and William C. Sessa, with scientific programming input from Keystone Symposia. The meeting will take place January 26–29, 2026 at the Keystone Resort in Keystone, Colorado. There has been a groundbreaking surge in knowledge regarding the intertwined health challenges of obesity and cardiovascular disease. Cardiovascular outcomes in recent trials have unveiled an extraordinary, though not fully understood, cardioprotective effect of diabetes and obesity medications. Concurrently, innovative technologies now enable comprehensive real-time analysis of systemic, organ, and cellular metabolism under these treatment regimes. This Keystone Symposia meeting will delve into critical topics in cardiometabolism in both health and disease, including the metabolic foundations of heart and vascular health/disease; the interplay between organs that underpins the synergy among obesity, insulin resistance, and cardiovascular disease; the mechanisms by which new drugs, such as SGLT2 inhibitors and GLP-1 receptor agonists, mitigate cardiovascular events; and the influence of environmental factors, such as diet and circadian rhythms, on cardiovascular health and disease. Conference sessions will highlight presentations from global experts and encourage interactive discussions relevant to the understanding and treatment of the growing unmet health problem of heart and vascular disease in the growing population of patients with obesity and diabetes. Additionally, this conference has been paired with another Keystone Symposia conference, “Obesity Therapeutics: Unlocking Benefits and Minimizing Side Effects,” and will present groundbreaking research from both basic and translational science on the treatment of obesity and cardiometabolic disease. In this regard, this pairing provides greater opportunities for cross-fertilization of ideas and the initiation of novel research directions and collaborations among a multidisciplinary group of leading researchers.

NHLBI - National Heart Lung and Blood Institute

PROJECT SUMMARY / ABSTRACT Atrial fibrillation (AF) contributes to at least 175,000 deaths per year in the US alone, and is a leading cause of stroke. AF is expected to affect twelve million people in the U.S. by 2030. Atrial fibrosis is a key disease feature linked to increased morbidity and mortality in patients with AF. Fibrosis (especially interstitial) creates a substrate for atrial re-entrant arrhythmias and is associated with therapy resistance. Dysfunction of atrial cardiofibroblasts (ACFs) that secrete excessive collagen into the extracellular matrix (ECM) is one of the important mechanisms leading to fibrosis. Our recent studies revealed that calcitonin (CT), a paracrine signaling molecule released by atrial cardiomyocytes (ACMs), suppresses collagen and other profibrotic ECM proteins production by ACFs. The long-term goal of this project is to dissect the molecular and cellular basis of the CT signaling pathway in relation to atrial fibrogenesis in AF in order to uncover new targets for future therapies in AF. The central project hypothesis is that reduced CT production by ACMs, miR-31-dependent downregulation of CT-receptor (CTR) expression, and activated BMP1 signaling downstream of the CTR promote atrial remodeling, fibrogenesis and AF progression. Two Specific Aims will be pursued: Aim 1) Determine whether miR-31-5p, via reduced CTR expression, drives atrial profibrotic remodeling and AF development, and Aim 2) Define the role of BMP1 and MGP in the CT/CTR signaling pathway in AF. This project is supported by a large amount of preliminary data that support the central hypothesis. The proposed studies will be performed in freshly isolated and cultured ACFs obtained from the right and left atria of patients with persistent AF (vs controls in sinus rhythm, or, in some cases, with paroxysmal AF), and from various genetic mouse models of spontaneous AF. Numerous new reagents and innovative multi-disciplinary approaches will be used to dissect the molecular basis of ACF phenotype changes and profibrotic remodeling driven by changes in the CT-CTR-BMP1 signaling axis. Impact: These studies are expected to underpin how suppressed CT/CTR signaling contributes to atrial fibrosis and arrhythmia development, and to serve as a platform for the validation of novel treatment modalities (up- and down-stream of CT/CTR axis) aimed at preventing atrial fibrogenesis and ameliorating AF development.

FDA - Food and Drug Administration

PROJECT SUMMARY Advances in cancer prevention, diagnosis, and treatment have dramatically improved long-term survival of those diagnosed with breast cancer. However, this success has been tempered by a parallel increased incidence of adverse outcomes and chronic conditions in breast cancer survivors, including cardiotoxicity due at least in part to cardiotoxic treatment regimens. Current evidence-based guidelines for preventing and controlling cardiotoxicity in breast cancer survivors are broad, and we lack clear guidance for assessing individualized risks of cardiovascular events. Existing cardiovascular disease (CVD) risk prediction models focus on the general population and rely only on a limited number of variables. Thus, there is a critical need to develop novel AI- powered informatics frameworks to build, maintain, and enhance models predicting cardiovascular risk among breast cancer survivors across diverse health systems. Responding to the RFA-FD-25-015, the objective of this application is to develop and validate a scalable, generalizable, and explainable AI-powered informatics framework, CardioOnco-AI, which innovates on the curation and modeling of real world data (RWD) for individualized prediction of cardiotoxicity among breast cancer survivors. Towards this objective, we propose the following specific aims: 1) Data curation - extract and derive cancer phenotype and non-medical determinant of health (nMDoH) variables to create research datasets for cardiotoxicity risk prediction through novel AI- empowered informatics solutions; 2) EHR-based predictive modeling - develop and evaluate novel cardiotoxicity prediction models for breast cancer survivors across two sites; and 3) Evaluation - assess the generalizability of CardioOnco-AI in two large geographically diverse RWD consortia. This project will deliver a novel, generalizable framework that integrates structured and unstructured RWD to improve cardiotoxicity risk prediction in breast cancer survivors. This work directly aligns with FDA’s regulatory science priorities and supports safer post- treatment survivorship care. The tools and methods developed will be adaptable to other sites, data environments, and oncology drug safety surveillance efforts.

NIDDK - National Institute of Diabetes and Digestive and Kidney Diseases

PROJECT ABSTRACT Compared with dialysis, kidney transplant recipients have significantly better survival and quality of life. In the last 2 decades, short-term posttransplant patient and kidney transplant survival have improved. However, there has not been a similar improvement in long-term survival. Within 10 years after a kidney transplant, about 47% of deceased donor and about 30% of living donor transplants have failed. The 2 most common cause of late kidney transplant failure are: a) premature death despite adequate kidney transplant function; and b) slow progressive decline in function of the transplant, eventually resulting in kidney failure. Our goal is to improve long-term outcomes after kidney transplantation. In the general population, for patients with cardiovascular disease, heart failure and/or chronic kidney disease, a new class of drugs, sodium-glucose cotransporter-2 inhibitors (SGLT2i), significantly reduce death, cardiovascular disease and progression of native kidney disease. Thus, these drugs may have a major impact on the two most common reasons for late posttransplant kidney failure. This class of drugs are now recommended for persons in the general population with heart disease and/or chronic kidney disease. However, for immunosuppressed kidney transplant recipients there has been concern about whether these drugs will have similar benefits, and whether there will be an unacceptable risk of side effects. As a result, kidney transplant recipients have been excluded from large randomized trials of SGLT2is. Because of the concerns about the efficacy and side effects of these drugs in transplant recipients, and the lack of information from large trials, reviews and national and international medical guidelines state that before recommending SGLT2is for transplant recipients, large long-term randomized trials need to be done. We propose a prospective randomized trial (n=900) of a SGLT2i (dapagliflozin), compared with placebo, to study efficacy and safety of this drug in kidney transplant recipients. Enrolled participants will be followed for a minimum of 3 years. Our hypothesis is that dapagliflozin will be safe in kidney transplant recipients and will reduce death and cardiovascular disease while prolonging kidney transplant function. To maximize enrollment and diversity, we plan a pragmatic trial with no extra visits to the transplant center and minimal study-related laboratory tests. This will facilitate participation for those at long distances from a transplant center and/or those with difficulty in finding transportation. This trial represents a unique opportunity to profoundly impact the care of kidney transplant recipients. Showing that dapagliflozin improves survival after a transplant and reduces cardiovascular disease and progression of kidney disease will transform clinical care in this high-risk population.

NHLBI - National Heart Lung and Blood Institute

PROJECT SUMMARY/ABSTRACT Despite being healed from their burn injuries, burn survivors have impaired thermoregulation, decreased pulmonary function with accompanying dyspnea at rest and during exercise, a greater incidence of cardiovascular disease, and higher mortality rates. Regarding the former, grafted skin does not appropriately dissipate heat, resulting in exaggerated increases in core temperature during physical activity in this population. Skin wetting of just the grafted sites blunts the exaggerated increases in core temperature, and perhaps the accompanying increased cardiac and pulmonary stress, though the latter has not been experimentally verified. Therefore, we aim to investigate the efficacy of whole-body skin wetting to mitigate otherwise heightened indices of cardiac and pulmonary stress during physical activity in the heat in well-healed burn survivors. As a secondary exploratory aim to continue to explore the consequences of a severe burn injury on long term health, we aim to investigate the possible effects of an inhalation injury, time on a ventilator, and/or significant torso burns and associated skin scarring on detailed respiratory function and mechanics at rest and during physical activity in well-healed burn survivors. The overarching goal of the proposed work is to identify physiological barriers, and assess a potential mitigation strategy, that likely dissuade burn survivors from achieving the recommended levels of physical activity necessary for their cardio-metabolic health, thereby predisposing burn survivors to the aforementioned greater mortality risk. The expected outcomes from this work will have a direct impact on burn survivors and their caretakers by evaluating the efficacy of a practical cooling strategy that has the potential to decrease cardiac stress and reduce the severity of dyspnea thereby improving exercise “comfortability” in burn survivors. Secondly, establishing a foundation of the effects of a severe burn injury on detailed respiratory mechanics is necessary to develop future studies where interventions (i.e., inspiratory muscle training) can be tested to improve the mechanics of breathing in this population. This research directly supports the mission of the NIH in that we will uncover mechanistic physiological findings from human participants with the goal of translating those findings to guide individuals and caregivers on how to increase exercise tolerance in burn survivors thereby improving their quality of life. To ensure that this study is designed to maximize clinical relevance and my scientific training, I assembled a strong interdisciplinary clinical research/mentoring team consisting of expert integrative physiologists, physician- scientists, and a biostatistician. My primary goals during this fellowship are to complete the proposed project, master several technical skills (i.e., echocardiography), improve my ability to obtain future extramural research funding, and publish research findings in peer-reviewed medical and physiology journals.

NHLBI - National Heart Lung and Blood Institute

PROJECT SUMMARY Cardiovascular disease (CVD) is the leading cause of death in men with prostate cancer (PCa), the most common male cancer in the US. With substantial advancements in PCa care, men with non-metastatic PCa have high 5-year cancer survival rates exceeding 99%. However, in this older male population, non-PCa specific comorbidities are widely prevalent. CVD results in a 1.5-fold greater risk of mortality than PCa itself, accounting for 23% of all deaths. The increased risk of CVD in PCa is due to the high burden of cardiovascular risk factors, prevalent CVD, and exposure to androgen deprivation therapy (ADT). The consequences of these co-morbidities and toxicities in the aging male are that the oncologic benefits of ADT may be outweighed by the substantial CVD risk. To enhance the overall health of men with PCa, we need to effectively understand and manage CVD risk. However, current CVD risk stratification tools, including the widely used ACC/AHA Pooled Cohort Equation (PCE) and most current AHA PREVENT, perform poorly in cancer patients as they do not consider critical determinants of CV risk in cancer, such as ADT, the social determinants of health, or the competing risks of PCa- and non-CVD related mortality. Our long-term goal is to improve upon the overall health outcomes of men with PCa through risk-based CVD management, i.e. tailoring the intensity of CVD prevention and management to the individual patient risk. The overall objective of this R01 proposal is to develop accurate CVD absolute risk prediction models in men with PCa and determine their clinical impact. Our rationale is that current clinical CVD risk prediction tools, developed in non-cancer populations, are fundamentally limited, as they do not incorporate cancer-specific variables, cardiotoxic cancer treatment, or emerging predictors of growing importance, such as the social determinants of health (SDOH). They also do not account for competing risks. The following Specific Aims are proposed: Aim 1: Develop a well-phenotyped, population-based cohort study by augmenting, harmonizing, and validating EMR data from a large, diverse health system (Penn) with SEER-Medicare and medication data (Part D). Aim 2: Derive and externally validate PCa-specific, accurate CVD absolute risk prediction models that incorporate individual patient characteristics, SDOH, clinical and cancer treatment information. Aim 3: Evaluate the impact of model implementation on patient health outcomes using plasmode simulation studies. The expected outcome is a PCa-specific, practical CVD absolute risk prediction tool that can readily be implemented into clinical care. Moreover, our overall strategy in building a robust cohort study to enable accurate absolute risk modeling is highly generalizable to other cancers. This work will have an important positive impact, as it will develop a key risk assessment tool that will advance the overall health of men with PCa and establish a paradigm-shifting, highly rigorous scientific approach widely adaptable to all cancer populations.

NHLBI - National Heart Lung and Blood Institute

Abstract Atherosclerotic cardiovascular disease continues to be a significant health concern worldwide. Improving risk stratification is particularly crucial to identify individuals at risk for near term cardiovascular incidents and detect disease earlier. Using cardiac CT scans for coronary artery calcium (CAC) scoring is a well-established risk assessment method, but the traditional Agatston calcium scoring method lacks sensitivity for near-term and early-stage disease detection. On cardiac CT images, small, low-density, “spotty” calcifications have been linked to high-risk plaque characteristics, like inflammation and stress, and signal an early stage of atherosclerosis before progressing into larger calcifications. Yet, these small calcifications are usually overlooked in standard Agatston scoring due to their low density and/or small size. The objective of the proposed research is to apply advanced computational methods like deep learning to optimize the detection of these “sub-Agatston” calcifications (Sub-Aim 1a) and derive reliable image features that characterize these sub-Agatston CACs and are predictive of cardiovascular risk (Sub-Aim 1b). To gain insights into the mechanisms of atherosclerosis initiation and progression, sub-Agatston calcification features will be causally associated with potential drivers of atherosclerosis, including socioeconomic, clinical, and image-derived-metabolic risk factors (pericoronary and epicardial adipose tissue) (Sub-Aim 2a). Lastly, the predictive value of sub-Agatston calcifications for major adverse cardiac events will be assessed in over 100,000 patients through Cox proportional hazards modeling (Sub-Aim 2b). This proposed research will yield: (1) Improved risk prediction models accounting for new (sub- Agatston) and understudied features (socioeconomic status). (2) New insights into atherosclerosis onset and progression (3) Technical innovations in machine learning and causal inference for medical imaging. (4) Translational software tools suitable for clinical risk assessment. This proposal, levering big CT data analytics, will provide crucial knowledge on the prognostic value of small, low-density calcifications detected on CT images, advance preventative cardiovascular medicine through the early detection of heart disease, and enable a new understanding of atherosclerosis initiation and progression.