Alzheimer’s disease (AD) is a progressive neurodegenerative disease characterized by amyloid beta plaques and neurofibrillary tangles in the brain along with inflammation both in the brain and systemically. This has led to the theory of microbial communities or infections as causative in the development of neuroinflammation, immunosenescence, and inflamm-aging seen in AD. Our own research has demonstrated a decrease in gut microbiota with anti-inflammatory properties and higher abundances of pro-inflammatory gut microbiota in AD elders. However, it is unclear how the AD microbiome exerts effects on the central nervous system. To address this gap in knowledge we have performed gut microbiome profiling, analysis of immune cell populations in blood, serum cytokine profiling, and cognitive assessments of AD elders at 90-day intervals. This analysis identified changes in B cell populations with an increased abundance of class-switched and decreased abundance of naïve B cells at levels of greater cognitive impairment. To better understand how the microbiome may control AD progression, we propose to investigate the connection between the AD microbiome and the adaptive immune system with a focus on regulation of the intestinal epithelium by commensal gut bacteria. Specifically, we intend to use stool and plasma samples collected from our AD cohort to measure makers of intestinal permeability and determine whether metabolites secreted by the AD gut microbiome cause disruptions in the intestinal epithelium. We will directly study the disruptive effects of AD stool by applying stool supernatants to intestinal epithelial cells, quantifying changes in epithelial permeability using established assays, and determining whether specific taxa depleted in AD are sufficient to cause epithelial disruption. In our previously published data, we have observed the loss of the phytoestrogen-metabolizing bacteria, Adlercreutzia equolifaciens (AE), in the microbiome of AD elders. My preliminary studies reveal that a metabolic product of AE, (S)-equol, prevents epithelial damage in the setting of inflammation. Therefore, we aim to determine whether AE or its metabolic products protect the intestinal epithelium. To untangle the role of the AD microbiome on our observed changes in class switched and naïve B cells, I have collected preliminary data which demonstrates that colonization of mice with the microbiome of AD elders promotes B cell class switching when compared with colonization of cognitively impaired elders without AD. This application proposes to expand this finding and characterize the changes in the adaptive immune system caused by the AD microbiome. This continuing work will further establish the connection between AD related neurocognitive decline, the microbiome, and immune system.

Certain viruses in the picornaviridae family, specifically enterovirus-D68 (EV68), have emerged as global health concerns over the last decade with severe symptomatic infections with EV68 able to result in long lasting neurological deficits and death. There are currently no US Food and Drug Administration approved drugs for any non-polio enterovirus, highlighting the need to develop strategies against these lethal enteroviral strains. One particularly attractive class of potential drugs are small molecules inhibitors, which can act as direct-acting antiviral (DAA) inhibitors towards the conserved active site of EV68 3C protease. This main viral protease is a cysteine protease conserved in the 3C family, responsible for cleaving eight sites along the viral polyprotein, which is essential for viral propagation. DAAs designed to target 3C proteases can potentially achieve robust inhibition across enterovirus species. However, as drug resistance in viruses can be prevalent, it is paramount to design inhibitors less susceptible to resistance mutations. It was demonstrated previously in the Schiffer Lab that when bound to protease, viral substrates occupy a conserved three-dimensional volume called the substrate envelope. It was also demonstrated that inhibitors that extend beyond the substrate envelope are more susceptible to drug resistance mutations. By utilizing the substrate envelope and cocrystal structures of the proteases, DAAs designed to fit within the three-dimensional consensus volume as naturally occurring substrates will interact primarily with functionally important residues and be less susceptible to drug resistance mutations. The central hypothesis of this proposal is that cocrystallization of EV68 3C protease with its natural substrates will enable the calculation of the substrate envelope to inform on substrate specificity, which will also aid in the design of robust pan-3C-protease inhibitors. In Aim 1, I will determine the cocrystal structures of EV68 3C protease bound to viral substrates. I will then use these structures to elucidate the molecular mechanism of substrate specificity for EV68 3C protease and calculate the substrate envelope. These data will aid in small- molecule design to create DAAs with improved resilience to mutations that can confer drug resistance. In Aim 2, I will design and test novel DAAs that target EV68 3C protease. I will first characterize previously designed inhibitors for other 3C and 3C-like proteases with the substrate envelope to establish a starting compound based on potency. Inhibitors based on the scaffold will be designed, synthesized, and tested in a FRET-based enzyme inhibition assay. Crystallization of novel potent compounds with EV68 3C and their characterization within the substrate envelope will assess inhibitors’ susceptibility to drug resistance mutations. Overall, this study aims to develop a robust, novel compounds with resistance-thwarting protease inhibition against the emerging pathogen that is EV68.

Triple Negative Breast Cancer (TNBC) is an aggressive form of breast cancer with standard therapy involving neoadjuvant chemotherapy, surgical management, and radiation therapy. However, the high recurrence rate and low pathological complete response of TNBC suggest that radioresistance is a critical factor in the diminished therapeutic efficiency of the current treatment strategy. There is limited literature exploring the specific pathways responsible for radiation resistance in TNBC, but most data support the role of limiting reactive oxygen species (ROS) accumulation. Our lab has studied the role of Vascular Endothelial Growth Factor (VEGF) binding to Neuropilin-2 (NRP2) and initiating several cancer stem cell properties. Preliminary data indicate that radiation enriches for NRP2 expressing cells and using a function-blocking antibody specific to VEGF/NRP2 with irradiation decreases cell viability compared to either treatment alone in a TNBC organoid. The central hypothesis of this proposal is that VEGF/NRP2 induces radioresistance by altering redox homeostasis and can be targeted for better therapeutic outcomes in TNBC. This proposal will seek to investigate the possible role of NRP2 in regulating NOS2 transcription and its contribution to mitigating ROS accumulation. I will also use single-cell RNA sequencing technology to identify the subpopulations of TNBC that are radioresistant and whether they utilize the NRP2/NOS2 signaling axis. Another aspect of this proposal is to observe the effectiveness of a function-blocking antibody of NRP2 with radiation using an in vivo model. I plan to identify if this approach reduces the radioresistant clones in TNBC. The completion of this proposal will heighten the understanding of radioresistance in TNBC and identify a novel molecular pathway responsible for this phenotype.

Liver transplantation is the only cure for liver failure, but many patients die waiting for a transplant due to a vast shortage of donor livers. Insufficient donor supply is further diminished by ischemia-reperfusion injury (IRI) during procurement and preservation of liver grafts. IRI-damaged grafts must be discarded because they are dysfunctional following implantation into recipients, causing patient death. Mitigating IRI is critically needed to increase the number of viable donor livers and improve patient survival. The IRI mechanism involves several pathways. After ischemic insult facilitates cellular injury, reperfusion triggers oxidative stress and innate immune pathways that converge to activate apoptosis, the major cell death mechanism in liver IRI. Hepatocyte apoptosis in IRI is mediated by Fas receptor (Fas), and leads to necrosis and inflammation, which cause liver dysfunction. In rats, Fas reduction prior to ischemia reduces liver damage. It may be possible to mitigate IRI-induced liver dysfunction by silencing hepatocyte-specific Fas during the transplantation process. The goal of this proposal is to use small interfering RNA (siRNA) to inhibit IRI and improve quality of liver grafts for transplantation. Chemically-modified siRNAs enable potent, sequence-specific silencing of any target gene in vivo. Modified siRNAs are delivered to hepatocytes when conjugated with N-acetylgalactosamine (GalNAc). GalNAc-siRNA technology is the basis of numerous FDA-approved liver disease drugs. With guidance from Drs. Anastasia Khvorova (siRNA), Paulo Martins (liver transplant), Athma Pai (RNA seq), Gyongyi Szabo (liver IRI), Jacob Bledsoe (liver pathology), and Matthew Gounis (in vivo imaging), this project will develop in vivo and ex vivo approaches using previously-validated GalNAc-siRNA targeting Fas to inhibit IRI and protect liver function. Aim 1 will determine how silencing Fas prior to ischemia perturbs IRI pathways (Aim 1.1), and explore if silencing Fas in combination with other mediators confers greater protection against liver damage (Aim 1.2). GalNAc- siRNAs targeting Fas, alone, or in combination with validated oxidative stress (Hmgb1) and inflammation (Tnfr1) mediators, will be injected into rats, and IRI will be induced using a liver clamp model. Post-reperfusion, target gene expression, liver damage, and IRI transcriptome changes will be assessed. Aim 2 will determine how silencing Fas in liver grafts (ex vivo) affects transplant outcomes in rats. Delivering siRNA during ex vivo preservation, by either static cold storage (SCS) or machine perfusion (MP), leads to uptake into liver grafts. Rat livers will be procured and GalNAc-siRNA targeting Fas will be delivered during SCS or MP. GalNAc-siRNA uptake, Fas expression, and IRI transcriptome changes will be assessed over 24 hours. This experiment will then be repeated, preserving grafts for maximal GalNAc-siRNA uptake/efficacy, transplanting grafts into rats, and measuring liver damage/function and recipient survival. Study findings will characterize how Fas silencing pre- and post-ischemia affects liver IRI pathways, identify in vivo and ex vivo approaches for maximal IRI inhibition, and help develop therapies that increase the donor pool and improve patient survival.

Mitochondrial function declines during aging. The dysfunction is accelerated in age-associated diseases such as Alzheimer’s Disease and Parkinson’s Disease. Thus, therapeutic approaches to maintain or recover mitochondrial function may promote healthy aging or slow age-associated disease progression. Recently, we have shown that the mitochondrial network expansion that occurs during development is an emergent property of the synthesis of highly expressed mitochondrial proteins. Increased mitochondrial import of the highly expressed mitochondrial proteins outcompete the transcription factor ATFS-1, preventing it from entering mitochondria. This allows ATFS-1 to traffic to the nucleus and activate a mitochondrial network expansion transcription program known as UPRmt. These findings suggest an interplay between protein synthesis, mitochondria protein import capacity, and mitochondrial network expansion. The Integrated Stress Response (ISR) is a translation control pathway that reduces overall protein synthesis while preferentially increases translation of ATF-4 in response to diverse stressors including amino acid depletion, ER dysfunction and mitochondrial perturbations. The ISR is mediated by 4 kinases (3 in C. elegans) that all phosphorylate the translation initiation factor eIF2α, which in turn modulates protein synthesis. While considerable work has demonstrated that the ISR is active in response to mitochondrial perturbation, the functional outputs of the ISR related to mitochondrial biology remain unknown. I have obtained or generated several C. elegans strains in which the ISR is impaired. Quite surprisingly, these worms have increased mitochondrial mass and mitochondrial genomes. Intriguingly, these animals also live significantly longer than wildtype worms, suggesting that increased mitochondrial mass is sufficient to extend organismal lifespan. I hypothesize that the ISR matches mitochondrial network expansion with the physiological and environmental inputs that activate the ISR by antagonizing ATFS-1 function. Here, I focus on the role of ISR-dependent translation attenuation or ATF-4 synthesis as direct or indirect regulators of ATFS-1-dependent transcription via the following aims. 1. Determine the mechanisms by which the ISR regulates ATFS-1-dependent mitochondrial biogenesis. 2. Elucidate the mechanisms by which the ISR modulates longevity and healthspan.

Black, Latinx, and Indigenous populations in the US face a disproportionate burden of poor health outcomes. Progress toward eliminating gaps in health outcomes is minimal, despite increasing investments in and awareness of health inequities. Recognizing that those inequities are rooted in the conditions in which we live, grow, work, and learn, there has been increased attention toward social determinants of health. In the past several years, health systems and the federal government, through Medicare and Medicaid, have committed billions of dollars to address health-related social needs such as housing, nutrition, and transportation. Though increasingly recognized as the root cause of unequal mortality and disease burden, structural racism is infrequently considered, poorly understood, and inadequately measured. Using a structural racism framework, this study will create a neighborhood-level structural racism effect index by compositing publicly available data. Including data about housing, transportation, education, wealth and poverty, social cohesion, the built environment, employment, and criminal justice, the structural racism effect index will capture broad and interwoven effects of past and current racist policies. The index will assign a score of 0-100 to each census tract in the US and will be tested against publicly available outcome data such as average area life expectancy and prevalence of select health outcomes. The novel structural racism effect index may be used to predict costs and outcomes, direct resources, and inform decision-making about under-resourced populations. To illustrate the policy implications of a measure for the effects of structural racism, the index will be used to characterize the Medicaid population as a means of providing insight into where investments should be made. Using Massachusetts as a test case, this project will quantify the extent to which structural racism's effects modify the impact of a $149 million program to address the health-related social needs of the Massachusetts Medicaid population. 1

Opioid overdose deaths and other substance-related mortality remain at an all-time high in the United States, and evidence suggests that mortality will continue to worsen without significant changes to the landscape of opioid use disorder (OUD) treatment. Overdose mortality is the leading cause of death in the first two weeks post-release due to a variety of factors including changes in drug tolerance during incarceration and volatility of the illicit drug supply, leading to a more than 100-fold increased risk of overdose death compared to the nonincarcerated population during this period. Despite advances in addiction health services and clinical addiction medicine, many people with OUD do not have access to healthcare or medications for opioid use disorder (MOUD) treatment, which remain the most effective treatment strategies to reduce OUD- related mortality. Correctional facilities such as jails are a critical healthcare access point for people with OUD who may not receive healthcare in other settings. However, MOUD treatment availability in jails is highly variable across the United States, leaving many people with OUD without access to evidence-based treatment while incarcerated. Implementation of MOUD treatment in jails is critical to improve accessibility of MOUD treatment and reduce OUD-related mortality in this vulnerable population. There is need for further research elucidating strategies that lead to successful and sustained implementation of MOUD in jails and other correctional settings. This proposal uses a mixed-methods approach to analyze implementation of MOUD from multiple perspectives. The proposal utilizes data from the Massachusetts Justice Community Opioid Innovation Network (MassJCOIN) study, a type 1 hybrid effectiveness-implementation study of MA Chapter 208, which established a pilot program to expand all FDA-approved forms of MOUD in MA county jails. Aim 1 will qualitatively assess organizational factors related to MOUD implementation in jails and post-release overdose risk through thematic analysis of interviews with jail staff and people who received MOUD while incarcerated in MA jails. Aim 2 will investigate the association between staff perspectives of MOUD and organizational factors such as staff training and readiness for change. Aim 3 will compare MOUD retention outcomes for people who screened positive for OUD while incarcerated between different types of MOUD treatment using the Public Health Data (PHD) Warehouse database created by the Massachusetts Department of Public Health. The proposed research and training plan will provide rigorous education in addiction health services research, which will be integrated with the robust clinical training of UMass Chan Medical School and supported through a multidisciplinary team of mentors with significant expertise in implementation science and OUD research in criminal-legal settings. This proposal will provide valuable insights into strategies that lead to effective and sustained MOUD treatment in jail settings with the goal of increasing accessibility to evidence-based MOUD treatment and reducing opioid-related mortality for people who experience incarceration.

Ulcerative Colitis (UC) is a devastating disease characterized by recurring episodic inflammation of the colonic mucosa that imposes a significant health and monetary burden on the developed world. Currently a significant portion of patients with UC are treated with TNFα inhibiting antibodies. Such treatments are burdensome on the healthcare system financially and pose the risk of significant side effects and frequently lead to the development of anti-drug antibodies, and consequent infusion reactions, and treatment failure. Consequently, researching novel cost effective, low risk approaches for treating ulcerative colitis should be of high priority. One approach is to leverage the microbiome to restore and maintain a non-inflammatory state in the colon, instead of targeting the systemic immune system. Dysbiosis is a hallmark of ulcerative colitis and leads to consequent dysregulation of local host immune pathways such as neutrophil transmigration through the intestinal epithelium, which has been shown to be instrumental in the initiation of mucosal inflammation in UC and its perpetuation through disruption of the intestinal barrier. The dysbiotic microbes in the colon of patients with UC have been shown to decrease P-glycoprotein (P-gp) expression. Under homeostatic conditions P-gp inhibits neutrophil transmigration through maintenance of a transepithelial gradient of endocannabinoids, thereby preventing aberrant inflammation. Thus, increases in intestinal epithelial cell (IEC) P-gp expression promises to limit inflammation in UC by preventing neutrophil transcytosis. To this end we must understand the mechanisms by which intestinal P-gp is regulated. While previous work has shown the microbiome dependence of intestinal P-gp expression, the specific microbial signals and the underlying metabolic networks have not yet been explored. In this proposal I will design an optimized microbial consortium to induce P-gp in IECs and dampen colonic inflammation in ulcerative colitis. Additionally, I study the microbial signals and underlying microbial dynamics that induces P-gp. In Aim 1 I will determine candidate bacterial species with the potential to regulate IEC P-gp. I will then use these strains to design and optimize a commensal consortium to induce P-gp when transferred into mice. The use of such a consortium as a potential bacteriotherapeutic for dampening intestinal inflammation will be studied using murine inflammatory bowel disease models. In Aim 2 I will study the mechanisms by which microbes communicate with each other and the host epithelium to induce P-gp. I will use a targeted and an unbiased approach to determine the bacterial signals and metabolites that upregulate P-gp and study the interactions between bacterial species that encourage P-gp induction on IECs. Overall, this study will provide insight into how the human microbiome regulates neutrophil transmigration and consequently intestinal inflammation. The design of the commensal consortium will serve as a first step in the development of a bacteriotherapeutic for treatment of ulcerative colitis.

Huntington’s disease (HD) is caused by expanded trinucleotide repeats (CAG) in exon 1 of the huntingtin (HTT) gene. Therapies lowering the downstream mutant HTT protein show limited clinical success. New evidence reveals that repeat tract length in the HTT locus, not mutant HTT protein, correlates to disease onset/severity. CAG repeat length is inherited, but further expands due to somatic instability, which contributes to HD. Somatic expansion occurs in non- dividing cells like neurons after transcription, forming a slipped loop that activates mismatch repair (MMR). In MMR, nuclease complexes help recognize the slipped loop and cut the non-slipped strand to create a gap that is filled to expand the repeat. Polymorphisms in MMR complexes are linked to HD onset, and knocking out or altering activity of MMR proteins block expansion or induce contraction in HD models. Yet, the contribution of each MMR protein to CAG expansion, and the effect of their conditional CNS-specific reduction on HD outcomes, is untested. Also, mechanisms favoring contraction over expansion are unknown. This project seeks to define MMR complexes facilitating HTT CAG expansion/contraction using divalent small interfering RNA (siRNA)—which induce potent, CNS-specific silencing of target genes—and antisense oligonucleotides (ASOs)—which can disrupt specific protein-nucleic acid binding in the CNS. Aim 1 will use divalent siRNA to evaluate the effects of MMR silencing on HTT CAG repeat expansion and HD progression. Efficacies of siRNAs targeting each MMR protein have been validated in human and mouse cells. Furthermore, one of these siRNAs was delivered to CNS of an HD mouse model, BAC-CAG (carries human HTT with 120 CAG that undergo expansion), showing target MMR silencing and blocked somatic expansion 2 months later. In Aim 1, divalent siRNA targeting each MMR enzyme will be injected into BAC-CAG mice. Target silencing and HTT CAG repeat expansion will be measured 2 months later. Top siRNA that block expansion will be re- injected into BAC-CAG mice, and the impact on motor behavior, ventricular size, and HD pathology will be explored over 9 months. Aim 2 will develop HTT CAG-targeting ASOs to induce MMR-mediated contraction in HD cells and mice. An initial panel of ASOs targeting HTT CAG repeats was screened in non-transformed HD patient-derived fibroblasts (HDpFs) using a high-throughput format, and ASOs that increase contraction events were identified. To improve contraction rates, ASO chemistries and lengths will be optimized and screened in HDpFs using the same assay. HTT CAG repeat length/instability will be quantified over 40 days to identify leads. Leads will be delivered to HDpFs, in combination with validated siRNA targeting each MMR protein, to identify MMR proteins mediating ASO-induced contraction events. In parallel, in vivo efficacy of leads will be confirmed in BAC-CAG mice. This work will reveal somatic expansion/contraction mechanisms, inform HD therapy design, and provide the fellow with crucial training in therapeutic development, neurobiology, and bioinformatics.

The goal of this proposal is to examine how presynaptic Neurexins (Nrxns) at serotonin (5-HT) synapses impact 5-HT signaling and social behavior. Extensive 5-HT axon terminal innervation throughout the brain corroborates 5-HT’s modulatory role in numerous behaviors including social behaviors, reward, emotion regulation, and learning and memory. Abnormal brain 5-HT levels and function are implicated in Autism Spectrum Disorder (ASD). While 5-HT therapeutics are often used to treat ASD, variable improvements in symptomatology require further investigation of 5-HT-mediated pathology. Many different genes contribute to increased ASD susceptibility and clinical presentation variability. Notably, synaptic dysfunction, specifically dysregulation of synaptic excitation and inhibition, remains a hallmark of ASD pathogenesis. Nrxns are presynaptic cell adhesion molecules that are well characterized in maintaining synapse function for proper neural circuit assembly. The three Nrxn genes transcribed from two promoters (α and β) express six principal Nrxn isoforms (αNrxn1-3, βNrxn 1-3). Additionally, mutations in Nrxn1 and Nrxn2 genes have been reported in ASD. In the current literature, the role of Nrxns at 5-HT synapses has yet to be investigated. Given that aberrant Nrxn and 5-HT function independently contribute to signaling pathology and social behavior impairments, it is critical to understand how Nrxn-mediated 5-HT neurotransmission participates in pathological mechanisms underlying the core deficits of ASD. Here, I will explore how 5-HT signaling mediated through Nrxns regulates social behaviors (Aim 1) and how Nrxns regulate 5-HT circuits relevant to social behaviors (Aim 2). Our group has created a novel mouse model in which the three Nrxn genes are selectively deleted in 5-HT neurons. My preliminary studies indicate that the loss of Nrxns at 5-HT synapses impairs social recognition memory and social reward preference. The hippocampus and nucleus accumbens, respectively, are crucial in these behaviors. In Aim 1, I will determine whether 5-HTergic Nrxns are critical for social behaviors through completion of social (and other complex) behavior studies. In addition, I will explore (i) if and (ii) how 5-HT is necessary for social behaviors using (i) 5-HT therapeutics to augment 5-HT function prior to social behavior studies and (ii) in vivo microdialysis to measure extracellular 5-HT levels during social behavior. In Aim 2, I will perform a mouse breeding and lentiviral rescue approach to determine whether specific Nrxns control social behavior. Furthermore, I will use immunohistochemical and electrophysiological approaches to identity how Nrxn proteins regulate excitatory and inhibitory synapse distribution and physiology. A close examination of Nrxns in 5-HT synaptic function is necessary to shed new light on social behavior disturbances in ASD.

Although commensal and pathogenic bacteria can be recognized by host pattern recognition receptors, intestinal epithelial cells target protective inflammatory responses towards pathogenic organisms through mechanisms that are incompletely understood. Additional mechanisms of pathogen sensing must exist that allow intestinal cells to target inflammatory defenses towards bona fide pathogens during an infection, and not harmless commensal bacteria. Pathogenic bacteria can express virulence determinants. Phenazine toxins are a family of redox active virulence determinants that are produced by a variety of human pathogens, including P. aeruginosa. P. aeruginosa can colonize the intestines of immunocompromised patients and cause fulminant septicemia and subsequent death. The mechanism by which intestinal epithelial cells detect P. aeruginosa, and whether this involves the surveillance of phenazine toxins, is not known. Nuclear hormone receptors (NHR) are transcription factors that program adaptive host responses following recognition of specific exogenous or endogenous ligands. In particular, HNF4⍺ is an NHR expressed in the intestine. In the model organism C. elegans, the HNF4⍺ homolog NHR-86 is required for the transcriptional activation of innate immune effector genes that protect against P. aeruginosa infection. The central hypothesis of this proposal is that intestinal epithelial cells detect infection through the surveillance of pathogen-derived phenazine toxins by NHR-86/ HNF4⍺, which directly activates protective anti-pathogen defenses in the intestinal epithelium. The following key preliminary findings support this central hypothesis: i) P. aeruginosa mutants that cannot make phenazine toxins do not activate C. elegans innate immune defenses; ii) synthetic phenazine toxins can activate immune genes; and iii) induction of immune genes by phenazine toxins is dependent on the expression of NHR-86/ HNF4⍺. In this proposal, Aim 1 will characterize the C. elegans immune response towards bacterial phenazine toxins, and Aim 2 will define the role of intestinal NHR-86/HNF4⍺ in detecting P. aeruginosa infection in C. elegans. The research proposed here will define a new concept of immune activation in intestinal epithelial cells and will also attribute a novel role for NHRs in pathogen sensing in the intestine. Insights from these findings may identify unexplored approaches for the development of anti-inflammatory and anti-infective therapies.

Defects in autophagy, the self-degradation of cellular components, are linked to multiple disorders such as cancer, diabetes and neurodegenerative diseases. Autophagosomes, containing cargo marked for degradation, fuse with lysosomes to recycle cell resources, such as protein aggregates and damaged organelles. However, we know little about the mechanisms that regulate the association between autophagic cargoes and autophagosome formation. Here, I investigate the role of vps13d, an essential gene with relatively unknown function, in context-specific autophagy and cell death in the developing Drosophila intestine. Proteins that regulate autophagy and cell death are of particular interest given the roles they play in tumorigenesis. Previous studies of VPS13D identified a role in the clearance of mitochondria by autophagy, also known as mitophagy. Intriguingly, VPS13D also appears to be involved in dissolution of membrane contacts that are associated with autophagosome formation. Furthermore, little is known about the role of VPS13D in associating autophagy-bound cargo with the site of autophagosome formation, despite having links to the core autophagy machinery. I hypothesize that VPS13D facilitates context-dependent autophagy by associating ubiquitinated cargo with the autophagic machinery and disassembling membrane contact sites at the phagosome assembly site (PAS). Here I propose to determine if VPS13D functions as an autophagy receptor for ubiquitinated cargo and determine the relationship between VPS13D and membrane contact modulator Vacuole Membrane Protein 1 (VMP1). The association of VPS13D and mutations in other factors that regulate autophagic cargo recruitment with human disorders illustrates the importance of studying VPS13D function.

Therapy resistance is a major barrier to long term remission in pediatric T-cell acute lymphoblastic leukemia (T-ALL). The prognosis for children with relapsed or refractory disease is dismal. Leukemia-initiating cells (L-ICs) regenerate disease upon transplantation into mice. They also recapitulate the immunophenotypic complexity of the parent leukemia supporting that, as in normal hematopoiesis, there is a cellular hierarchy among leukemic cells. Our laboratory has previously demonstrated that the L-IC is a committed thymocyte progenitor and resides in the leukemic DN3 population, however, only a fraction of DN3 cells can give rise to disease. L-ICs rely on NOTCH1-induced MYC signaling for survival. Recent studies identified dormant, therapy resistant L-ICs in both murine models and T-ALL patient samples. The role of cell cycle restriction in L-IC latency is incompletely understood. In an effort to uncover pathways that govern L-IC function, we performed single cell RNA sequencing on thymocytes at varying stages of T-cell leukemogenesis using our transgenic Tal1/Lmo2 model. This approach identified a dormant DN3 cluster, marked by low Ki67 expression, which is observed in other murine T-ALL samples. Dormant DN3 cells exhibit high Notch1, but low Myc expression. The transcriptional signature of these cells shows enrichment of genes previously implicated in leukemia initiation or leukemia stem cell function. Dormant DN3 cells show enrichment of the non-canonical Wnt receptor Ryk, which is reported to maintain hematopoietic stem cell self-renewal by limiting proliferation and promoting quiescence. RYK is overexpressed in primary pediatric T-ALL and in Tal1/Lmo2-induced murine T-ALL compared to healthy thymus. This indicates that RYK may not be restricted to this rare subpopulation and moreover, there may be a therapeutic window for RYK inhibition in relapsed T-ALL. The central hypothesis of this proposal is that dormant DN3 cells are quiescent L-ICs that retain proliferative and differentiative capacity, which permits their therapy tolerance and subsequent expansion during relapse. This proposal will identify a gene signature of dormant DN3 cells and uncover the potential role of these cells in T-ALL relapse by evaluating their L-IC function and chemoresistance (Aim 1). Aim 2 will define the non-canonical WNT/RYK signaling network in T-ALL and uncover the role of these pathways in dormant DN3 cells and L-IC function by testing whether inhibition of RYK reduces the L-IC frequency of murine and patient T-ALL cells. Collectively, these studies will provide critical insight to TALL heterogeneity and will lay the foundation for development of L-IC targeted therapy for relapsed disease.

Epigenetic inheritance is a process by which parental exposure to environmental factors influences offspring phenotype. This field of investigation has wide-ranging implications for human health. Epidemiologic studies have shown that exposure of parents or grandparents to starvation, trauma, cigarette smoke, or other stressors alters offspring susceptibility to cardiovascular disease, obesity, lung disease, or other conditions. Research with animal models has mirrored these findings and offers tools for disentangling the underlying mechanisms of epigenetic information transfer from parent to offspring. Such research has been greatly enabled by recent technological advances, including next generation sequencing and fundamental discoveries like microRNA biology. In vitro fertilization experiments demonstrate that sperm carry sufficient information to propagate epigenetic phenotypes across generations, and research with these paternal epigenetic inheritance models has identified sperm-associated small non-coding RNAs (sncRNA) as carriers of information from father to offspring. I have established an epigenetic inheritance model in which paternal influenza infection, with virus elimination and disease recovery prior to mating, results in an adaptive attenuation of disease severity (significantly decreased weight loss) in response to influenza infection in offspring, as well as a maladaptive altered glucose metabolism. While these phenotypes are robust, the underlying mechanism of information transfer to offspring remains to be determined. In preliminary experiments to address the mechanism I have found that influenza infection alters sperm-associated sncRNA. This proposal addresses the hypothesis that influenza virus-induced changes in sperm-associated sncRNA populations alter embryo development resulting in offspring metabolic and immune phenotypes. Aim 1 elucidates the underlying epigenetic inheritance mechanism through kinetic analysis of sperm sncRNA and early embryo development. Aim 2 determines the specificity of the offspring epigenetic inheritance phenotype to the paternal stressor both directly by challenging with a non-cross reactive strain of influenza virus, and indirectly by further metabolic phenotyping to determine if paternal influenza infection alters glucose homeostasis and liver gene expression in the offspring in ways similar to other paternal stressors. This research will provide valuable insight into the mechanism underlying epigenetic inheritance, and do so within the context of a novel epigenetic inheritance model with direct relevance to human health.

The current U.S. opioid epidemic has fueled an increase in injection drug use and, in turn, an alarming surge in new hepatitis C virus (HCV) infections. Between 2010 and 2015, the incidence of HCV increased by 294% nationally, driven primarily by a rise in injection drug use and risky injection behavior – namely syringe sharing. This growing epidemic has disproportionately affected young people who inject drugs (PWID) in rural communities. There is an urgent need to implement tailored and effective harm reduction strategies to rural PWID who are disproportionately impacted by HCV. Although research has shown that syringe services and pharmacy syringe sales (i.e sterile syringe sources) are associated with a reduction in injection-mediated risks and HIV transmission, the evidence for whether these services reduce HCV risk among PWID remains mixed. This proposal will applying the risk environment model to evaluate the influence of sterile syringe sources on the HCV risk environment. Specifically, this proposal will evaluate whether spatial proximity to sterile syringe sources and receptive secondary syringe exchange are associated with HCV serostatus among rural PWID. The aims are: (1) To evaluate the association between road network distance to the nearest sterile syringe source (SSP or pharmacy that sells nonprescription syringes) and HCV serostatus; (2) To use egocentric social network analysis to evaluate the association between receptive secondary syringe exchange and HCV serostatus; (3) to explore and unpack rural PWIDs’ perceptions of and experiences with syringe acquisition and syringe sharing practices through in-depth interviews. These findings could help inform the development of future harm reduction interventions in rural New England, a region of the country that has been particularly hard hit by the opioid epidemic and related HCV infections.

The mechanisms of pathogen sensing and immune effector induction in intestinal epithelial cells are not completely understood. Disruption in the mechanisms of pathogen sensing and immune homeostasis in intestinal epithelial cells can lead to dysbiosis and inflammation, as well as susceptibility to bacterial infection. Key insights into intestinal epithelial cell immunity and host-pathogen interactions have been made using the nematode C. elegans. Nematodes mount innate immune defenses against bacterial infection via conserved immune pathways, but the mechanisms of pathogen detection are unknown in this organism. In nematodes, the family of nuclear hormone receptors (NHRs) has dramatically expanded compared to other metazoans. NHRs are ligand-gated transcription factors that sense endogenous and exogenous signals to induce adaptive transcriptional responses. The C. elegans genome encodes 274 NHRs, of which 260 are homologs of human HNF4α. HNF4α is a key NHR involved in inflammatory bowel disease, though the mechanism through which HNF4α mediates inflammatory bowel disease in humans is unknown. The central hypothesis of this proposal is that C. elegans HNF4α homologs are an ancient family of pathogen sensors whose evolutionary expansion in C. elegans was driven by their function in detecting diverse pathogens. The following key findings support this hypothesis: (i) The nuclear hormone receptor, NHR-86/HNF4α, senses the cellular environment and activates C. elegans intestinal immune defenses; (ii) NHR-86/HNF4α is required for pathogen resistance and immune response towards the gram positive human pathogen E. faecalis; and (iii) A different C. elegans HNF4α homolog is required for pathogen defense and immune effector regulation against the gram negative pathogen P. aeruginosa. In this proposal, Aim 1 will define the role of C. elegans NHR-86/HNF4α in pathogen detection and immune effector induction during E. faecalis infection using a combination of transcriptomics, ChIP- sequencing, tissue-specific rescue and genetic epistasis. Aim 2 will characterize the function of a separate C. elegans HNF4α homolog in pathogen sensing during P. aeruginosa infection. The approach includes: transcriptomics, global NHR binding site identification, tissue specific rescue, and P. aeruginosa genetics. Collectively, these studies will characterize a fundamentally new paradigm of immune activation, which will solve a major conundrum of how pathogens are sensed in C. elegans. These findings will also establish NHRs as evolutionarily ancient pathogen sensors. Ultimately, the expectation is that detailed dissection of this mechanism will shed light on the role of HNF4α in mammalian pathogen sensing and inflammatory bowel disease.

Pulmonary lung fibrosis is a poorly understood process that can arise in pediatric patients with gain-of-function mutations that disrupt the regulation of the cytosolic double stranded DNA sensing pathway, cGAS-STING. This project will define the role that B cells play in mediating lung fibrosis in a mouse model of STING gain-of- function autoinflammation that recapitulates a human disease known as STING Associated Vasculopathy with onset in Infancy (SAVI). The expectation is that the results of these studies will offer insights into the mechanisms by which B cell contribute to fibrotic lung disease and assess, using murine models, whether targeting B cells is a valid strategy for prophylactically treating lung fibrosis.

Alzheimer’s Disease (AD) and Amyotrophic Lateral Sclerosis (ALS) are multifaceted, progressive neurodegenerative conditions that place a monumental burden on patients, providers, and the public healthcare system. No disease-modifying treatments are currently available for either AD or ALS. Although the etiology of each disease is well studied, strategies targeting characteristic features of disease pathogenesis— e.g., beta-amyloid in AD—show limited clinical efficacy. Identification of novel targets that modify progression of neurodegeneration is needed for innovative therapeutic development across neurodegenerative disorders. AD and ALS are caused by genetic and environmental factors that alter downstream pathways like lipid homeostasis. A critical player in systemic and central nervous system (CNS) lipid transport, that is also implicated in the onset and progression of neurodegeneration, is <em>apolipoproteinem> E (ApoE). Genetic deletion of ApoE reduces neuropathology in mice, but also causes atherosclerosis. Thus, despite its implication in disease, the diverse functionality of ApoE in its distinct biological “pools” (i.e. systemic and CNS) makes it a challenging therapeutic target. Reducing individual ApoE pools may circumvent this issue. However, the independent effects of systemic or CNS ApoE silencing on neurodegenerative diseases are unclear. The goal of this proposal is to determine the relationship between systemic and CNS ApoE pools, and their effects on disease progression in AD and ALS mice. The project will take advantage of chemically-stable, self- delivering small interfering RNAs (siRNAs) that enable sustained, <em>tissue-specificem> silencing of target mRNA. GalNAc-siRNAs specifically deliver to liver (site of systemic ApoE production), and divalent (Di)-siRNAs deliver throughout the brain and spinal cord after intra-cerebroventricular (ICV) injection. With guidance from Drs. Anastasia Khvorova (siRNA chemistry), Robert Brown (ALS), Evgeny Rogaev (AD models), Andrew Tapper (animal behavior), and Thomas Smith (neuropathologist), GalNAc- and Di-siRNA will be used to silence hepatic and CNS ApoE, respectively, and the effects on CNS and systemic ApoE pools, and AD and ALS phenotypes, will be examined. In Aim 1, GalNAc-siRNA targeting ApoE will be subcutaneously injected into mice. In Aim 2, Di-siRNA targeting ApoE will be delivered to the CNS via ICV injection. Both aims will utilize the APP/PSEN1 mouse model of AD and the SOD1G93A mouse model of ALS, and will measure systemic and CNS ApoE and cholesterol levels, and AD and ALS neuropathology and behavior two months post injection. These studies will advance the understanding of how ApoE pools interact in the context of neurodegeneration, and the effects on disease progression. Such findings will inform strategies for safe and effective therapeutic targeting of ApoE in AD, ALS, and age-related neurodegenerative disorders.

Atrial fibrillation (AF) is a cardiac rhythm abnormality that currently affects over 6 million Americans. This statistic is expected to double over the next decade given the increasing prevalence of AF risk factors such as advanced age and obesity. Atrial fibrillation confers a 5-fold risk of ischemic stroke, but can be treated effectively with anticoagulation therapy. Despite the efficacy of available treatment options, 1 in 5 patients with AF present with stroke as their initial manifestation of the arrhythmia. This is attributable to the significant challenge in diagnosing AF due to its episodic and sometimes asymptomatic nature. Existing AF monitoring strategies are burdensome or costly and invasive, and thus have low patient adherence and satisfaction. Recently, commercially available wrist-based wearable devices, or smartwatches, have shown to be accurate for AF detection, and may represent a promising tool for identifying AF. However, commercial devices are not primarily designed for use by older adults for arrhythmia detection, and there is a significant research gap in the feasibility of using smartwatches for arrhythmia detection in this population. Furthermore, no previous research has investigated the potential for implementation and integration of smartwatches into the healthcare system and infrastructure. Using data collected from the in-house randomized control trial Pulsewatch, and by conducting qualitative assessments in usability and implementation, this proposal addresses the evidence gap in the feasibility of smartwatches for AF detection with three specific aims: 1) to evaluate individual-level factors associated with adherence of using a smartwatch for AF detection, 2) to explore patient characteristics associated with acceptability of smartwatches and identify specific usability challenges and nuances for older adults, and3) to identify barriers and facilitators of implementing smartwatches for use in a clinical setting. We approach the problem with a user-centered focus and apply rigorous and systematic scientific methods in completing these aims. Knowledge generated from this proposal will provide future researchers and stakeholders with practical evidence in the potential use of smartwatches for detection of AF.

Lung cancer is the leading cause of cancer-related death, accounting for approximately 1.3-million deaths worldwide. The most common type of lung cancer, non-small cell lung cancer (NSCLC), is frequently associated with oncogenic mutations in KRAS, a GTPase that regulates cell growth and division. Oncogenic KRAS mutations constitutively activate Kras protein and result in rapid cell division, even in the absence of growth signals, and thus play a critical role in tumor formation and maintenance. Genetic inactivation of oncogenic Kras reduces tumor size and metastatic potential, but Kras-independent tumors eventually recur and are more aggressive. Preliminary studies suggest that Kras-independent relapse may be mediated by the proto-oncogene, MYC. The MYC mRNA is a known target of the microRNA miR-34a, and treatment with ectopic miR-34a delays Kras-independent relapse. The goal of the proposed project is to understand the roles of Myc and miR-34a in Kras-independent tumor relapse in a mouse model of NSCLC. Aim 1 will investigate the role of miR-34a in delaying relapse. Endogenous levels of miR-34a will be quantified during tumor growth and regression, and during Kras-independent relapse. CRISPR/Cas9 genome editing will be used to mutate the miR-34a binding site in the Myc 3’ untranslated region to test whether miR-34a delays relapse by directly silencing Myc. Findings from this aim will provide insight into the use of microRNA-mediated inhibition as a potential therapeutic strategy to target Myc. Aim 2 will investigate how Myc controls relapse and glucose metabolism in Kras-independent NSCLC cells and mice. To achieve this, a novel doxycycline inducible dual shRNA system will be used to co-silence Kras and Myc expression in vitro. Using the seahorse bioanalyzer system, glucose metabolism will be monitored in both Kras-silenced and Kras/Myc co-silenced NSCLC cells to identify metabolic vulnerabilities of tumors. Using a mouse model of NSCLC, tumor burden will be monitored after Kras and Kras/Myc co-silencing. This aim will result in a novel dual shRNA based strategy to establish the efficacy of co-silencing Myc and Kras as a therapeutic strategy to induce tumor regression and prevent relapse in NSCLC. Taken together, findings from this study will elucidate mechanisms of tumor relapse induced by Kras silencing and identify regulators of tumor development, maintenance, and relapse. Ultimately, this work will aid in the creation of novel therapeutic strategies to improve NSCLC patient outcomes.

Type 2 Diabetes (T2D) is a major public health issue in the United States with approximately 9.3% of the population suffering from the disease. Additionally, 86 million people have prediabetes and the economic impact is staggering, with 1 in 10 health care dollars being spent on T2D and its complications. T2D results from insulin resistance and reduced beta cell mass; thus, strategies to increase functional beta cell mass are critical goals for diabetes research. Although it is well established (from rodent models) that increased beta cell mass results from enhanced beta cell proliferation, new research suggests that beta cell dedifferentiation also contributes to reduced beta cell function. Some proteins involved in the G1/S transition of the cell cycle, especially Cdk4, are critical for the maintenance of beta cell proliferation and mass. Insulin receptor substrate 2 knockout (Irs2 KO) mice develop diabetes due to peripheral insulin resistance and reduced beta cell mass, and we previously found that in vitro re-expression of cyclin D2, which activates Cdk4, rescues the loss of proliferation in beta cells lacking Irs2. Therefore, we hypothesized that expression of a constitutively active form of Cdk4 (Cdk4 R24C) might be able to rescue the diabetic phenotype of Irs2 KO mice. Intriguingly, preliminary results suggest that Cdk4 R24C is able to completely rescue not only beta cell mass, but also insulin secretion and beta cell differentiation. Interestingly, recent studies show that the Cdk4 kinase plays many roles independently of its known activity in the cell cycle. Therefore, the goal of this proposal is to determine the mechanisms behind this rescue and determine what atypical roles cdk4 plays in the beta cell. In Aim 1, we will determine how Cdk4 rescues beta cell proliferation, focusing on both the canonical Cdk4-Rb- E2F pathway, and will also identify novel Cdk4 interactors in the beta cell using BioID. In Aim 2, we will determine if Cdk4 R24C rescues 1st or 2nd phase insulin secretion in Irs2 KO islets using both islet perifusion and hyperglycemic clamps studies. We will also perform molecular studies to determine whether the KATPase Kir6.2, which was previously reported to be a target of the Cdk4-Rb-E2F1 pathway, is increased and is sufficient to rescue insulin secretion in Irs2 KO islets. Finally, in Aim 3 we will explore how Cdk4 R24C is able to restore beta cell differentiation markers. This is surprising and interesting, since it goes against the data showing that when beta cells proliferate they lose differentiation markers, and I think the most likely explanation is that Cdk4 is having effects unrelated to its cell cycle actions. I will investigate how Cdk4 rescues Pdx1 expression, with a focus on FoxO1 and PPARγ, two transcription factors that regulate Pdx1 expression. Using in silico analyses and reading the primary literature, I found that both contain Cdk4 consensus phosphorylate sites. Therefore, I will determine whether Cdk4 acts via either or both of these to maintain beta cell differentiation. If Cdk4 plays atypical roles as a kinase to influence multiple aspects of beta cell biology, this may lead to better therapeutic options for preserving beta cell mass, function and differentiation in T2D.

Hepatoblastoma (HB), the most common pediatric primary liver tumor, affects children from infancy to five years of age. Surgical resection with adjuvant chemotherapy has saved many young lives. However, the five-year survival rate remains at 70%, and is worse for children with unresectable tumors. Meeting the clinical need for HB-targeted therapies requires a better understanding of how HB tumors are formed and maintained. The transcriptional co-regulator YAP1 is hyper-activated in 79% of HB cases, and recent studies suggest that YAP1 and the Wnt/β-catenin pathway act together to initiate HB tumors. But is YAP1 required to maintain HB tumorigenesis? Preliminary studies using a conditional mouse model of HB—driven by doxycycline-inducible hyperactive YAP1S127A and constitutively active β-catenin—suggest that YAP1 is essential for tumor maintenance. In the presence of doxycycline, YAP1 is expressed, and mice develop HB tumors; withdrawing doxycycline turns off YAP1, resulting in >90% tumor regression within 10 weeks. Transcriptional analyses revealed that hepatocyte differentiation factors and liver metabolic genes were induced in regressing tumors.

Breast cancer is the most common cancer diagnosis in women and is also one of the leading causes of cancer-related mortality in women who suffer from this condition. Tumors that originate in the breast consist of heterogeneous populations of cells. Breast cancer stem cells (BSCSs) are a subtype of tumor cells that have properties similar to normal, tissue stem cells such as the ability to divide slowly and give rise to differentiated cellular lineages. Furthermore, BCSCs have been implicated in tumor initiation, therapy resistance and metastasis to distant organs. Given this information, a greater understanding of the biological processes that sustain BCSCs will lead to the development of novel agents directed against this chemo- and radio-resistant population of tumor cells. The proposed work will explore the role of the α6 integrin splicing variants, α6Aβ1 and α6Bβ1, in the genesis of BCSCs, specifically addressing the mechanism of activation of the TAZ transcriptional coactivator. Integrins are a family of cell surface receptors that function in signal transduction and adhesion to the extracellular matrix. The α6Aβ1 integrin variant is expressed in differentiated, epithelial breast cancer cells and inhibits the acquisition of stem cell properties Conversely, the α6Bβ1 integrin variant is expressed in BCSCs and promotes tumor initiation by activating the Hippo signaling pathway transducer TAZ. TAZ has previously been shown to be important in the functioning of BCSCs, but the mechanism is unknown. Therefore, elucidating the relationship between the α6 integrin splicing variants and TAZ activation will provide insight into mechanisms of breast cancer progression. This proposal will use a cellular and molecular biology approach to establish the mechanism by which TAZ is suppressed in the α6Aβ1 expressing non-stem breast cancer cell population (Aim 1). Biochemical studies will also be undertaken with the purpose of connecting mechanisms of TAZ inactivation with classical Hippo pathway signaling in the non-stem breast cancer cell population (Aim 2). In summary, the studies included in this proposal will increase the understanding of integrin regulation of BCSCs. Our results can provide rationale in designing future targeted therapies for treatment resistant subtypes of breast cancer.

Elaborate mechanisms exist to establish and maintain the appropriate balance of excitation and inhibition (E/I balance) in the brain. Defects in E/I balance are hypothesized to underlie many core clinical symptoms seen in ASD including repetitive behaviors and seizures. Concomitant with E/I imbalance are increased markers of inflammation in the periphery and brain. Central to this inflammation are microglia, a resident macrophage of the central nervous system. Whether microglial inflammatory state drives E/I imbalance in neuropsychiatric disease remains a critical open question. In this proposal, I will leverage my primary mentor’s (Schafer) expertise in using mouse models to study microglia function at synapses with my co- mentor’s (Frazier) expertise as a physician scientist studying neuroinflammatory processes in ASD patients to explore whether microglia-derived cytokine signaling modulates E/I balance. I will use a mouse model with altered inflammatory cytokine signaling to assess how microglial inflammatory cytokine production modulates neuronal excitability (aim1). Next, I will use human ASD functional imaging data and data from patient serum to identify pro-inflammatory cytokines that are dysregulated in ASD patients and assess how these ASD-specific cytokines affect E/I balance in our mouse models (aim2). To start, I already have one candidate TNF􏰀-alpha. The results from these experiments will help to identify novel targets for treating ASD with inflammatory modulation.

One out of every three children under the age of five in India are undernourished (48 million); to address this crisis, Indian government established a national program from 2005-2012. This study will apply advanced geospatial and multilevel methods to investigate 1) the changes in child undernutrition in India from 2005 to 2012, 2) individual, household, and community level predictors of child undernutrition, and 3) consequences of undernutrition on development during pre-adolescent (8-11) years. Results from this study can guide effective policymaking and implementation of intervention programs.

The central nervous system is susceptible to many environmental insults and like many organs can be affected by alcohol. Alcohol impacts the brain in a variety of ways including short-term cognitive changes, development of dependence, memory deficits, neuronal loss and initiation of neuroinflammation. An emerging mechanism being studied in the field of central nervous system (CNS) inflammation, extracellular vesicle communication, has not yet been investigated in alcohol-related neuroinflammation and offers the potential for therapeutic intervention. Key components of alcohol-induced neuroinflammation, the cytokines IL-1β and HMGB1, are thought to be released from cells via extracellular vesicles. This study will explore the hypothesis that alcohol alters the release of extracellular vesicles within the CNS and that these vesicles contain content critical to the inflammatory process. Our Preliminary Data reveals that EVs are released by CNS cell types and can be taken up by unstimulated cells. First, we examined the effect of alcohol exposure on microglia and astrocytes in vitro and found that exosomes were stimulated for release at either 50 or 100mM alcohol. These findings were confirmed with western blot against exosome marker CD63 in the supernatant. Next, we used the membrane dye PKH26 to label membranes of microglia which were then stimulated to release EVs by alcohol. Those EVs were transferred to untreated/unlabeled cells and the dye was seen to incorporate in recipient cells, suggesting that those EVs were taken up by the untreated cells. Specific Aim 1 will investigate the effect of alcohol on extracellular vesicle release from primary mouse CNS cells (neurons, microglia or astrocytes) in single cell-type cultures in vitro. Nanoparticle tracking analysis will be used to measure released vesicles size, which will allow for quantification of the two types of released vesicles: exosomes (<150nm diameter) or microvesicles (150nm-1μm). Proinflammatory cytokines IL-1β and HMGB1 will then be measured in vesicles secreted from CNS cell types after alcohol exposure. These experiments will provide important knowledge regarding alcohol's impact on vesicle release as well as vesicle content. As extracellular vesicles are believed to transmit intercellular signals, Specific Aim 2 will explore the effect of transferring alcohol-induced vesicles onto naïve cells. First, extracellular vesicle uptake by primary CNS cell types will be measured. Next brain slices maintained in culture will be exposed to vesicles derived from alcohol-exposed cells and activation of inflammatory pathways will be examined. Finally, IL-1β or HMGB1 will be individually knocked down or overexpressed in CNS cell types and alcohol-induced vesicles will be transferred onto brain slices. These experiments will test the effect that alcohol-induced extracellular vesicles have on other cells, as well as the contribution made by cargo cytokines. Specific Aim 3 will elucidate the impact that alcohol-induced vesicles have on the brain in vivo. First, we will investigate the concentrations of EVs required for intracranial injection and uptake in the brain by using fluorescently-labeled vesicles. Next, vesicles will be stimulated in vitro from primary mouse CNS cells exposed to alcohol. After isolating those vesicles, they will be injected into the brains of naïve mice. Brain tissue will b examined for increases in immune cell activation and upregulation of inflammatory signals. This experiment will provide important information regarding the impact of extracellular vesicles on inflammation in vivo. The first year of this fellowship will be dedicated to quantifying and qualifying the vesicles released by CNS cells after alcohol exposure. Specific Aim 2 will be investigated in years two and three of the fellowship, while Specific Aim 3 will be completed in year three. The final two years of the fellowship will be dedicated to completing the clinical rotations for my MD training as well as any necessary follow up experiments needed for publishing this proposed work.

Approximately 7.2% of adults in the United States in 2012 suffered from an Alcohol Use Disorder, as defined by the American Psychiatric Association. Alcohol is responsible for a number of severe diseases, including alcoholic liver disease, alcohol related dementia and fetal alcohol syndrome. Past research has focused on organs such as the liver, or brain, but it has become increasingly evident that alcohol has significant effects on nearly all tissue in the body. One tissue that has garnered recent attention in part due to the rapid rise in obesity, is adipose tissue. Recent studies have provided compelling evidence relating the dysfunction of adipose tissue to the progression of many diseases, including liver disease. The interaction between ethanol and adipose tissue, particularly brown adipose tissue, has been understudied. There is little known about how ethanol impacts brown adipose tissue function, and further understanding of this relationship may prove crucial in elucidating origins of systemic changes seen in chronic alcoholics. This proposal will investigate the effects of ethanol on brown adipocyte development and function, elucidate mechanisms involved, and study the consequences of these effects on metabolic homeostasis. Both an in vitro and an in vivo model will be used. An in vitro model will be used to investigate whether ethanol interferes with the development of brown adipocytes. Brown preadipocytes isolated from wild-type C57BL/6J mice will be differentiated into mature brown adipocytes with or without exposure to 100mM ethanol. RNA and protein isolates will be collected from the differentiated cells. Markers of adipocyte character and function will be evaluated by qRT-PCR and western blot. Additionally, proteins involved in the mTOR pathway will be evaluated via western blot and immunoprecipitation to elucidate mechanisms that may be involved with brown adipocyte function. A similar approach will be applied to mature brown adipocytes. These studies are the focus of specific aims 1 and 2. An in vivo model will be used to study the effects of chronic ethanol intake on brown adipose tissue function, and to relate these effects with whole body metabolism. Wild-type C57BL/6J mice will be given a chronic ethanol diet. Groups of mice will be exposed to conditions that have been shown to mediate brown adipose tissue activity, including cold habitat, beta adrenergic injection, high fat diet (al 3 increase BAT activity), and thermoneutral habitat (decrease BAT activity). Weight and temperature will be recorded throughout the study, and mice will be sacrificed for collection of tissue. Various depots of adipose tissue will be collected, along with liver and muscle. These tissues will be evaluated for both functional markers, and markers of brown/beige/white adipocyte fate. These experiments are the focus of specific aim 3.

Down syndrome (DS), or trisomy 21, is the leading genetic cause of intellectual disability in children, with approximately 1 in 700 live births carrying an extra copy of chromosome 21. Compared to less common single gene disorders, DS pathogenesis is still poorly understood. Treatment for DS would require either identification of molecular pathways to target with conventional therapies or, potentially, chromosomal therapy to silence the many possibly disruptive genes on the trisomic chromosome. One window of therapeutic intervention lies in the Alzheimer’s disease pathology that almost all DS patients suffer from in middle age. Recently, the extra chromosome has been silenced in an inducible manner by targeted insertion of a transgene for the XIST gene into human induced pluripotent stem cells (iPSC). XIST normally silences one X chromosome in females, providing a natural mechanism of dosage compensation. Chromosomal silencing in DS cells provides a powerful isogenic and isoepigenetic model for studying DS pathology and marks the first step towards the goal of chromosomal therapy for DS patients. The proposed work will investigate the effect of silencing the extra chromosome on DS iPSC-derived neuronal cells, investigating both DS and Alzheimer- specific phenotypes. Aim 1: In order to investigate the effect that chromosomal silencing has on DS neural phenotypes in vitro, iPSCs will be differentiated into neurons using conventional two-dimensional neuronal culturing techniques and three-dimensional organoids. Cerebral organoids are a recently-developed tool that have been shown to be a useful model for human brain development, and have been used to study disorders of brain development. Neurons derived from iPSCs with two and three functional copies of Chr.21 will be compared for phenotypes that DS neural cells are thought to possess. These include an increased glia:neuron ratio, altered dendritic spine morphology, and altered mitochondrial morphology. Three-dimensional cultures will be used to investigate less well-explored pathologies such as alterations in cortical lamination. This aim will also address the important therapeutic question of whether post-mitotic cells can support chromosomal silencing. Aim 2: The same chromosomal silencing system will be used to investigate Alzheimer’s-associated neuronal phenotypes. These include intra and extracellular amyloid deposition as well as intracellular hyperphosphylated tau deposition. Due to its relatively late onset compared to general intellectual disability, the Alzheimer’s disease component of DS is most suitable for therapeutic intervention. Studying the effect of chromosomal silencing on Alzheimer’s phenotypes provides a strong model for Alzheimer’s pathogenesis while also bringing this novel strategy one step closer to therapeutics. This proposal seeks to utilize a novel chromosomal silencing technique to better model human neural phenotypes in DS and associated AD.

The goal of this proposal is to understand how the Beclin 1/vacuolar protein sorting-associated protein 34 (VPS34) complex contributes to breast cancer progression and to determine how to sensitize tumor cells that are deficient in Beclin 1/VPS34 function to drugs that promote tumor cell death. Breast cancer is the most commonly diagnosed cancer among women worldwide and the second leading cause of cancer related mortality. Despite the availability of targeted therapeutics, the overall survival rate for stage I metastatic disease remains 23%. Therefore, there is a need to develop novel approaches for the treatment of advanced stage breast cancer. The applicant hypothesizes that one such approach could exploit Beclin 1/VPS34 function in breast cancer progression. Beclin 1 is monoallelically deleted in 40% of human breast cancer and there is an inverse correlation between Beclin 1 expression and poor prognosis in ER negative subtypes of breast cancer. In addition, low Beclin 1 expression serves as an independent predictor of patient survival. Beclin 1 interacts with and activates VPS34, the mammalian Class III phosphatidylinositol, to regulate multiple membrane trafficking pathways including autophagy, growth factor receptor trafficking and cytokinesis. The individual contribution of each of these trafficking pathways to cancer is unknown and needs to be investigated to understand the impact of Beclin 1 loss on breast cancer progression. Previous studies in the applicant's lab have shown that loss of Beclin 1 expression is associated with a sustained increase in AKT and ERK signaling downstream of the IGF and EGF receptors. In addition, loss of Beclin 1 expression in breast carcinoma cells leads to increased invasion. These preliminary findings suggest that VPS34 inhibitors, which are currently in clinical trials, may negatively impact tumor treatment. The work that the applicant proposes here will explore how the Beclin 1/VPS34 complex contributes to breast cancer progression. The applicant hypothesizes that inhibiting the Beclin1/VPS34 complex will lead to the upregulation of specific pathways that promote tumor growth and progression and that targeting these pathways in tumors with low Beclin 1 expression or in combination with VPS34 inhibition will suppress tumor cell viability. The goal with this proposal is to dissect out the roe of each Beclin 1/VPS34 complex in breast cancer progression with respect to tumor growth, metastasis, and tumor metabolism both in vitro and in vivo (Aim 1). Furthermore, mechanisms that sensitize breast cancer cells to death upon Beclin 1/VPS34 inhibition will be identified as a means to target Beclin 1 deficient tumors and optimize VPS34 inhibitors as potential therapeutic agents (Aim 2). The studies in this proposal will enhance our understanding of the role of Beclin 1 in breast cancer and can give insight into novel therapies for advanced stage breast cancer disease.

Melanoma is the leading cause of skin cancer death in the United States, with the 5-year survival rate of 20% for patients with advanced disease. Despite improvements in therapy, many patients receive minimal survival benefit and often develop resistance to standard-of-care therapies. Furthermore, a population of patients exist who do not have the appropriate mutations or tumor characteristics to be eligible for new targeted and immunotherapies. In order to provide adequate treatment options for patients who develop resistance or are ineligible for current cutting-edge therapies, new therapeutic targets must be identified. Our lab has discovered a novel melanoma oncogene, growth differentiation factor 6 (GDF6), a secreted bone morphogenetic protein (BMP) ligand that promotes melanoma by regulating expression of specific neural crest factors, which has the dual effect of preventing differentiation and suppressing apoptosis9. In addition to these specific factors, we found GDF6 more broadly promotes a gene expression signature that mimics that of the embryonic neural crest. Neural crest identity has previously been identified as a key feature involved in melanoma initiation, progression, and therapeutic resistance. Our studies show knockdown of GDF6 suppresses expression of many of these neural crest genes. Taken together, these data indicate GDF6 is an optimal target for melanoma therapy. As a secreted extracellular protein, GDF6 is amenable to targeting by antibodies. We produced a panel of monoclonal antibodies to target the C-terminal binding region of GDF6 and developed multiple in vitro and in vivo assays to assess candidate antibodies with the most potent action against GDF6 and evaluate their effectiveness as potential melanoma therapeutics. I hypothesize that a subset of antibodies will effectively block GDF6 activity leading to increase differentiation and cell death of melanoma cells in vitro and in vivo. I further hypothesize that blocking GDF6 will suppress neural crest identity in melanoma cells, leading to less aggressive tumor cell characteristics and sensitizing previously resistant cells to standard-of-care therapy. I will evaluate a pre- screened panel of 42 monoclonal antibodies for in vitro and in vivo activity against GDF6 in melanoma cells to identify top candidates with the most potent activity, in parallel with characterizing pharmacokinetic and dynamic properties of the antibodies in vivo. I will further characterize the effects of GDF6 inhibition by these antibodies on neural crest expression profiles and key features of advanced melanoma such as therapeutic resistance, invasiveness, and anchorage independent growth. Additionally, I will analyze potential combinatorial therapies in vitro and in vivo to assess changes in pathway activity for known therapeutic resistance mechanisms. Results of this study will identify lead candidate anti-GDF6 antibodies for first-in-human (FIH) studies and provide appropriate pre-clinical safety data for submission of an FIH application. Furthermore, these data will provide broad insight into the tumorigenic features that are connected to neural crest identity and the result of reversing neural crest characteristics in established melanomas.

The bacteria that live in our body (microbiota) help us metabolize different nutrients and chemicals from our diet, including the medications we take. Thus, these bacteria can influence our response to treatments, like chemotherapy, by converting drugs into more or less toxic forms. Understanding the mechanisms by which bacteria influence our response to drugs is critical to design better treatments that maximize therapeutic effects and minimize adverse effects. The nematode C. elegans and its bacterial diet provide a suitable model to explore host-microbe drug interactions because both host and microbe are amenable to high throughput drug screening and genetic screening. I propose to use the nematode C. elegans as a model to study host-microbe-drug interactions in cancer chemotherapy drugs. In Aim 1, I will test ~ 200 cancer chemotherapy drugs for developmental or fecundity phenotypes in C. elegans animals fed two different bacteria. Additionally, I will test the role of active bacterial metabolism in the observed host-microbe-drug interactions. Then, I will use genetic screening and metabolomics, in the host and in the bacteria, to characterize the mechanisms responsible for the observed drug response. In summary, this project will generate a set of host and bacterial genes that contribute to the response to cancer chemotherapeutic agents.

Promising emerging therapies for Huntington's disease target mutant but not wild-type huntingtin mRNA with small interfering RNAs. However, our limited understanding of allele-specific mRNA processing restricts the design of allele-specific therapeutics. The purpose of this project is to elucidate differences in wild-type and mutant mRNA processing to improve the specificity, and thus effectiveness, of small RNA treatments for Huntington's Disease.

Learning and memory are dynamic processes that require alterations in the connections among neurons. Synapses, the structures through which neurons communicate with one another, undergo biochemical and morphological changes in response to neuronal activity in a process known as synaptic plasticity. Disturbed synaptic plasticity is the basis for several diseases such as dementia, schizophrenia, and Alzheimer's disease. Local translation of mRNAs in dendrites is essential for regulating certain forms of synaptic plasticity. Impairment of this process is the cause of several neuropathies such as the Fragile-X Syndrome and other disorders linked to autism. Modulation of cytoplasmic mRNA poly(A) tail length is one mechanism that controls local translation in dendrites. It is estimated that ~7% of brain RNAs are regulated by this process in response to stimulation, which underscores its importance in synaptic plasticity and therefore higher cognitive function. Because poly(A) tails lengthen as well as shorten, there are likely to be several enzymes involved in this process. Several factors responsible for poly(A) elongation have been identified, but the enzyme(s) responsible for shortening the poly(A) tail remains unknown. The proposed research seeks to identify this deadenylating enzyme, which is likely to act as a negative regulator of dendritic translation and learning and memory. The proposed research focuses on CNOT7, a major mammalian deadenylase, in the brain and seeks to test whether (1) knockdown or mutation of CNOT7 alters poly(A) tails in cultured neuronal dendrites, (2) CNOT7 controls specific mRNA deadenylation in dendrites, and (3) knockdown of CNOT7 alters various forms of synaptic plasticity. This work will further our understanding of the process of learning and memory and disorders affecting these important processes.

About 1.2 million Americans are hospitalized annually with acute coronary syndrome (ACS), and most are discharged alive. Although post-ACS mortality and clinical morbidity have been improving patients may be living longer but not better. In fact, many patients suffer substantial declines in quality of life and functional status after discharge with ACS. Because of critical gaps in our understanding how health status evolves over time for ACS patients, important opportunities for prevention and intervention are potentially being missed. The proposed research takes a systematic approach to examining the association of demographic, psychosocial, clinical, and neighborhood factors on trajectories of health-related quality of life after discharge for ACS. Our study will leverage the availability of rich data already collected for the NHLBI-funded TRACE- CORE, a longitudinal prospective cohort study of 2,183 patients hospitalized with ACS. This study includes data from interview, medical record abstraction, linked administrative databases, and geo-coded census tracks. Specific aims are to: (1) Determine associations between individual level socio-economic, clinical, in- hospital and psychosocial factors and trajectories of patient health status post-ACS discharge, both generic (SF-36) and disease specific (Seattle Angina Questionnaire with domains of physical limitations, angina stability, angina frequency, treatment satisfaction and angina specific quality of life); (2) Determine how neighborhood deprivation is associated with trajectories of patient health status; and (3) Identify the extent to which trajectories of generic quality of life and disease-specific quality of life at baseline, one month, 3 months and 6 months predict mortality or readmission 6 months to 1 year post-ACS discharge. This pre-doctoral fellowship proposal also includes a carefully training plan for me to become an independent physician scientist able to fully exploit the potential of patient-reported outcomes to improve the lives of patients with cardiovascular disease.

In many types of cancer, less differentiated tumors are more strongly associated with a poor patient prognosis. These tumors tend to be more aggressive: they have higher proliferation rates, a greater propensity for invasion and metastasis, and increased resistance to therapy compared to more differentiated tumors. Less differentiated tumors, by their nature, share characteristics with their embryonic cells of origin. In melanoma, these less differentiated tumors are associated with a neural crest identity that is acquired during early stages of tumor initiation and is present through tumor progression. Previous studies have shown that acquisition of a neural crest identity is a necessary step during initiation of early melanoma lesions and supports fundamental properties of aggressive tumors such as invasion and metastasis. However, the mechanisms of generating a neural crest identity are unknown. Recently, our lab has identified growth differentiation factor 6 (GDF6) as a novel melanoma oncogene. GDF6, a bone morphogenetic protein (BMP) ligand, is recurrently amplified in both human and zebrafish melanomas, and expressed in tumors but not normal melanocytes. We have shown GDF6 acts to prevent differentiation and suppress apoptosis in established melanomas, both in vitro and in vivo. Additionally, we have found that GDF6 regulates expression of multiple neural crest and melanocyte factors previously implicated in melanoma. Upon knockdown of GDF6, we observed downregulation of select neural crest factors coupled with upregulation of melanocyte differentiation factors, leading to melanoma cell differentiation and ultimately cell death. These results suggest that GDF6 plays a role in regulating oncogenic neural crest identity. Here, we look to identify the role of GDF6 and BMP signaling in establishing a neural crest identity during melanoma initiation and explore oncogenic characteristics imparted by GDF6 during melanoma progression. I hypothesize that GDF6-depenent BMP signaling acts to initiate a neural crest identity in melanomas to promote tumor initiation and aggressive tumor characteristics. I further hypothesize that loss of BMP activity leads to differentiation (and in tumors death of differentiating cells), making GDF6 an attractive target for differentiation therapy in melanoma.

“Alcohol abuse has been attributed to 3.2% of the world's disease burden. Chronic abuse manifests as reversible steatosis, steatohepatitis and/or irreversible cirrhosis. Regardless abstinence, 5-15% of patients with steatohepatitis still progress to cirrhosis and hepatocellular carcinoma (HCC). Studies have demonstrated the role of miR-122 as a mediator of hepatic metabolism, cellular differentiation and the development of HCC. Our laboratory has shown decreased miR-122 in a four-week chronic-alcohol mouse model. The role of miR-122 in ALD is unknown. Bioinformatic miRNA target prediction tools suggest Hypoxia-Inducible Factor 1-� (HIF1�) is a primary target of miR-122. HIF1� is critical to the progression of ALD. Specific Aim 1 will study the role of miR-122 in the pathogenesis of chronic alcohol-induced hepatitis. C57Bl/6 mice will be transfected using a hepatocyte-tropic adeno-associated virus serotype 8 (rAAV) vector to either knockdown or overexpress miR-122 via tough decoy (TuD) or the miR-122 respectively. Mice will be maintained on Lieber-DeCarli diet for 28 days. On day 28 mice will be withdrawn from alcohol and given 150- mg/kg acetaminophen (APAP). Mice will be sacrificed on day 30 to assess regeneration. Livers sections will be analyzed histologically for morphological changes, lipid accumulation, and regeneration. In addition, we will determine the impact on miR-122 modulation on hepatic inflammation and differentiation through expression analysis of inflammatory cytokines and cell cycle regulators associated with ALD. MiR-122 has been correlated with a network of Liver Enriched Transcription Factors (LETFs). Collectively, these LETFs function as master regulators of hepatic function. HNF6�, specifically, has been shown to function in a positive feedback loop with miR-122. Specific Aim 2 will examine the effect of miR-122, its overexpression and knockdown, on HNF6� in a chronic-alcohol model. We will also examine if miR-122 can reduce ALD through enhancement of HNF6� and the LETF network. The rAAV8 vector stated above will deliver anti- HNF6� shRNA or rHNF6 in vivo. The mice will be treated and assayed as described above. During the first year of this fellowship we aim to examine the effect of miR-122 on the severity of ALD development using gene therapy. The remaining two years of my Ph.D. (funding yrs 2 & 3) will be spent studying the effect miR-122 and HNF6� regulation of the LETF network in the progression of ALD. During years 4 and 5 of funding I shall complete my M.D. training while finalizing any work required for publication. Collectively, we propose to examine two potential avenues by which miR-122 may serve as a potential therapeutic modality. First, is the development of steatosis though inhibition of HIF1� and secondly, is the regeneration after alcohol and APAP-induced liver injury.”

Hepatitis C virus (HCV), a pathogen that infects over 150 million people worldwide, is the leading cause of chronic hepatitis, liver cirrhosis and hepatocellular carcinoma. HCV is a genetically diverse virus with 6 known genotypes with genotypes 1 and 3 being the most prevalent. This genetic diversity makes HCV infection difficult to treat. In the last few years, the advent of direct-acting antivirals (DAAs) has remarkably improved therapeutic options and treatment outcomes. However, despite highly potent inhibitors against multiple proteins, drug resistance is a major problem in all drug classes. Drug resistance is a loss of inhibitor potency while maintaining substrate processing. Though NS3/4A protease inhibitors are highly potent, they are not efficacious against all genotypes and are susceptible to drug resistance. Underlying differential inhibitor potency are the molecular mechanisms of drug resistance and genotypic differences. Elucidating these are key to developing protease inhibitors that avoid drug resistance and are effective against all HCV genotypes. Specifically most protease inhibitors in clinical development contain P2 moieties that contact unessential residues of the protease, which while increasing potency also increases their susceptibility to single site mutations that confer drug resistance. I hypothesize that protease inhibitors that avoid contact with these residues while leveraging contact with unexploited areas in the active site will result in inhibitors with enhanced potency and higher barriers to drug resistance. To investigate this hypothesis, using computational techniques, I will design a panel of novel protease inhibitors with extended P4 groups. I will then synthesize and enzymatically assay these protease inhibitors. Top leads will be co-crystalized with the protease and structurally analyzed to optimize the computational designs and initiate iterative rounds of inhibitor design. This project will provide molecular insights about the mechanisms of drug resistance as well as new strategies for the design of novel protease inhibitors for the effective treatment of HCV infection.

The respiratory mucosa employs the innate and adaptive immune system to protect normal respiratory function from invading organisms. However, when there is a defect in one of these defenses the host becomes vulnerable to Aspergillus fumigatus (Af). This ubiquitous fungus enters the airways as a spore, or resting conidium but is generally cleared by intact respiratory defenses. However, when individuals are immunocompromised, Af conidia are more likely to germinate and form filamentous structures called hyphae. As this morphotype, Af can become invasive particularly in persons with low neutrophil counts. An estimated 200,000 people are diagnosed with invasive aspergillosis annually worldwide, and up to 90% die from the infection. Af can also colonize the airways of those who suffer from asthma or cystic fibrosis causing allergic bronchopulmonary aspergillosis (ABPA), which affects over 4 million people annually worldwide. Studies proposed here seek to further understand the intact innate immune response to Af conidia, particularly the involvement of interleukin-23 (IL-23) and interleukin-17 (IL-17). A better understanding of this response may uncover nuances associated with the host defects that predispose to infection with Af, as well as potentially inform rational vaccine design and immunotherapies against Af. Af conidia elicit IL-23 and IL-17 production from the host airways within the first 24 hours of infection. These cytokines are known to be important for the adaptive TH17 response. However their role in innate immunity against Af is largely unknown. IL-23 has been shown to augment IL-17 production, and in turn IL-17 elicits neutrophil recruitment. The relationship between IL-23 and IL-17 is referred to as the IL-23/IL-17 axis and this proposal aims to systematically characterize each portion of this axis in the innate response against Af conidia, and test whether this response is required for protection against this mycosis. In order to characterize the temporal production pattern of IL-23, we will measure levels of this cytokine at regular intervals in the fist 72 hours of infection by ELISA. From a preliminary screen, we have uncovered candidate cell types that may be involved in the production of IL-23. We aim to confirm these sources by in vivo and ex vivo intracellular cytokine staining. To test whether IL-23 production is protective against mortality in Af infection, the survival rates of wild-type (WT) mice will be compared to a functional IL-23 knock-out strain (IL-23p19-/-). Finally, we propose to create mixed bone marrow chimeras to test whether any specific cellular source of IL-23 is required for protection against Af (Specific Aim 1). The temporal pattern of production for IL-17 and its source will also be characterized in the first 72 hours of infection with Af using methods described above. To test whether IL-23 augments IL-17 production innately in response to Af, IL-17 levels will be assessed in IL-23p19-/- mice and WT mice. In addition, we have evidence that IL-23 and IL-17A are co-produced by one innate cell type in response Af, we propose to test and dissect any potential autocrine mechanisms in this cell type. Finally, the role of IL-17 in protection against f infection will also be tested by monitoring the survival of IL-17RA-/- mice and WT mice (Specific Aim 2). Because many at risk for IA are transplant patients who are iatrogenically immunosuppressed, knowledge of the factors leading to protection against aspergillosis could also inform development of targeted immunosuppressive agents that keep defenses against opportunistic infections intact.

Breast Cancer is the most frequent malignancy diagnosed in women in the United States and the second leading cause of cancer related mortality in women. Metastasis to distant organs continues to be the greatest obstacle to eradication of this malignancy. Greater understanding of the biological processes that contribute to tumor progression will lead to development of effective therapies against this disease. The insulin receptor substrate (IRS) proteins are important signaling intermediates downstream of the Insulin-like growth factor (IGF-1) receptor and they play a crucial role in the response of tumor cells to IGF-1 stimulation. The two IRS proteins expressed in mammary epithelial cells, IRS1 and IRS2, play different roles in breast cancer. Specifically, tumors that express IRS2 are highly metastatic in comparison to IRS-1 expressing tumors. In addition, IRS2 staining at the membrane in patient tumor samples correlates with decreased overall survival. Studies from our group have identified an IRS2-specific interaction with the microtubule cytoskeleton and demonstrated that disruption of microtubules leads to a decrease in PI3K/Akt activation downstream of IRS2. These findings in conjunction with our preliminary data suggest that the subcellular localization of the IRS proteins plays an important role in their cellular functions. Te work the applicant proposes will explore the potential role of IRS2-microtubule interactions in breast cancer progression, specifically addressing the requirement of this interaction for invasion, glycolysis, PI3K/Akt signaling and tumor metastasis. Our goal with this proposal is to take a molecular biology approach to elucidate the importance of IRS2-microtubule interactions in IRS2 mediated functions (Aim 1). Furthermore, we will use animal models to study the significance of this interaction for tumor progression to metastasis and the impact of IRS2 function on tumor response to IGF-1 receptor inhibitors (Aim 2). The studies proposed in this application will enhance our understanding of the importance of IRS2 in breast cancer progression. Additionally, our results can provide the rationale for the development of novel therapeutic approaches for the treatment of IRS2-dependent malignancies.

This proposal has two primary aims: (1) to improve the understanding of the association between patient- reported functional health, comorbidity, and sociodemographic factors and other cause mortality in older men newly diagnosed with prostate cancer; (2) to develop a prototype tool for calculating individualized risk of other cause mortality in this population. Prostate cancer is the most common non-cutaneous cancer in American men and primarily afflicts those age 65 and older. However, most men are diagnosed at early stages with tumors that most often have an indolent course. Guidelines recommend that patients only pursue aggressive treatment if they have >10 year overall life expectancy. Within 5 years of diagnosis, only 11% of American men die due to their prostate cancer, while the majority of patients diagnosed with prostate cancer die of other causes. While validated calculation tools have been developed for clinical use in predicting prostate cancer related mortality, no validated tool has been developed from existing models that identify variables associated with the risk of dying of other causes (OCM). As men in the U.S. live longer and the population above age 65 is rapidly growing, individualized predictions of life expectancy are necessary given the substantial heterogeneity in individual health status. Nearly three quarters of this aging population may have multiple comorbid conditions. Previous work has shown that decrements in patient-reported functional health may be more strongly associated with OCM than the presence of most individual comorbidities. These findings have promise for improving the approach to accounting for the impact of multiple conditions. This predoctoral research training proposal seeks funding to explore the generalizability of prior work demonstrating the association of patient-reported functional health and OCM. The proposed work will help to identify the variables most strongly associated with OCM in older men with prostate cancer, utilizing data from 4,510 subjects in the linked Surveillance Epidemiology and End Results- Medicare Health Outcomes Study (SEER-MHOS) database. This database contains detailed information on cancer characteristics, treatment, cause of death, baseline comorbidities, sociodemographic information, and functional health measures. This proposal will evaluate and improve upon the performance of other cause mortality prediction models through modern statistical techniques to assess predictive model performance. After identifying key predictors of OCM, we propose to develop a prototype clinical risk-calculation tool that estimates personalized risk of 10-year OCM, adapting validated techniques for developing risk calculators. This study will help to establish the utility of patient- reported functional health measures in improving the accuracy of OCM risk estimation in older men newly diagnosed with prostate cancer and will make progress towards a clinically useful OCM risk estimation tool. Completion of this work will help to better identify older patients who would most likely benefit from aggressive treatment vs. those who may not, as they may be more likely to die of other causes.

Adverse health consequences of tobacco use are the leading cause of preventable mortality worldwide, resulting in approximately 6 million deaths per year. The addictive component of tobacco is nicotine, a tertiary alkaloid that binds and activates nicotinic acetylcholine receptors (nAChRs), ligand-gated ion channels that are normally activated by the endogenous neurotransmitter acetylcholine (ACh). Neuronal nAChRs are pentamers assembled from various combinations of receptor subunits and different subunit combinations confer different affinities and functionalities to the receptor subtypes. Eleven subunits, ¿2- ¿7, ¿9, ¿10 and ¿2- ¿4, have been identified in mammalian neuronal nAChRs. Interestingly, chronic nicotine or cigarette smoke exposure results in the upregulation of nAChRs in the brain, including structures within the mesocorticolimbic dopaminergic (DAergic) pathway that is implicated in reward and addiction. While not completely understood, nicotine- induced upregulation of nAChRs is thought to contribute to addiction by altering the neural network, possibly resulting in increased tolerance or altered sensitivity to nicotine. While there are many proposed mechanisms for nAChR upregulation, it is largely believed that multiple forms of posttranscriptional regulation is responsible for this phenomenon. Currently, there is not much known about posttranscriptional regulation of mammalian nAChR subunit expression by microRNAs (miRNAs), small single stranded RNA molecules that function as negative regulators of gene expression. However, there is emerging evidence that miRNA expression is decreased in various rodent tissue types in response to nicotine exposure. In addition, recent studies have found that miRNA dysregulation in response to exposure to various drugs of abuse, including cocaine, can influence rewarding properties of the drug and alter addiction-associated behaviors. We have recently generated preliminary data suggesting that a novel regulatory mechanism involving miRNAs may be at work in the nicotine-mediated upregulation of nAChRs. Preliminary experiments from our lab have identified several miRNAs that are predicted to target nAChR subunit mRNA transcripts, in particular miR-494 and miR-542-3p that target ¿4 and ¿2 transcripts, respectively. In Aim 1, I will determine if ¿4 and/or ¿2 are modulated by miR- 494 and/or miR-542-3p in primary midbrain neuronal cultures. In Aim 2, I will determine if miR-494 and/or miR- 542-3p are modulators of nicotine reward-associated behavior in mice. Through these aims, I hope to achieve a better understanding of the role of miR-494 and miR-542-3p in nicotine reward-associated behaviors, possibly revealing new targets for the development of tobacco cessation aids.