Early-Stage Alzheimer’s Disease (ESAD) is characterized by the development of beta-amyloid aggregates (Aβ42) and phosphorylated tau (pTau) leading to mild cognitive decline and variable personality changes. Because specific diagnostic criteria have not yet been established for ESAD at middle age, there is no way of knowing who might be susceptible and who might be resilient to more severe neuropathology and dementia in later years. The geroscience concept assumes pathways associated with aging are also associated with age-related diseases including ESAD. Therefore, a simple skin biopsy procedure shown to predict resilience to aging in middle-aged mice should be able to predict resilience to ESAD in middle-aged mice. An adeno-associated-viral (AAV) vector system carrying pathogenic components of AD, Aβ42, and pTau, was used to induce ESAD in 23-month-old C57BL/6 mice. Before receiving the AAV vector, 2 mm ear punch biopsies were performed, and the rate of closure was measured over 3 weeks. The study ended when mice were 26 months of age, and the closure rate for each mouse was calculated and correlated with behavioral and neuropathological features of EASD. Preliminary observations will help address the question of whether the healing rate of a simple skin wound can predict susceptibility to the burden of AAV-mediated ESAD. It is expected increases in physical resilience will be associated with increased wound closure, and thus, mice with increased wound closure will have greater resilience to the onset of ESAD neuropathology. This could have highly impactful implications for the early treatment of ESAD in human patients thus preventing the irreversible and fatal progression of dementia associated with late-stage AD. In addition, DNA from skin biopsy cores could be used to obtain DNA methylation signatures for determining biological age thus providing an enriched, translationally relevant data set.
 

It is well documented that pet cats develop age-related diseases similar to humans with chronic age-related diseases, including Alzheimer’s disease (AD). Since pet cats live in the same environment as their owners and by extension are subjected to the same environmental stressors, older pet cats are an excellent mammalian model to study therapeutic targets to slow or reverse brain aging. However, aging within the brains of pet cats is not well characterized, partly because valid reagents have not been identified. This study was designed to test several human-specific antibody reagents that identify non-neuronal cells, aging pathways, and Aβ amyloid and phosphorylated tau (pTau) seen at autopsy in brains from patients with AD. Archived brain samples, collected from pet cats at autopsy, were graciously provided by the veterinary pathology departments at University of California Davis campus and University of Pennsylvania. Immunohistochemistry staining was done to detect: 1) Microglia, a non-neuronal inflammatory reactive cell type, using an IBA1-specific marker; 2) An inflammatory pathway using an MCP-specific marker; 3) Amyloid plaques using E610, an Aβ42-specific marker; and 4) pTau fibrillary tangles using AT8, a pTau-specific marker. A digital imaging software program was used to generate a heat map to visualize staining and quantify results. It was found that brain samples from older pet cats had increased inflammation as determined by high staining intensity of microglia and MCP1. Brains from several cats showed evidence of amyloid plaques and pTau tangles. These observations suggest that the human-based reagents tested can identify analogous cell types, pathways, and pathogenic components of AD in brains from pet cats. These prototype reagents can now be used to begin the task of characterizing neuropathology in deceased pet cats donated to the Cat Alzheimer’s disease Program at the University of Washington.

Alzheimer’s Disease (AD) is a progressive brain disorder that debilitates memory, learning, and decision-making. Early-stage AD represents the initial phase where individuals are still able to function independently, but with increasing age, their condition steadily progresses to dementia and loss of independence. Because a significant number of the aging population is affected by AD, understanding the neuroinflammatory processes would help develop more effective strategies for treatment. Examining markers such as MCP-1 and TNF-alpha, known to be associated with inflammatory response, will help identify the modulatory processes that lead to mild cognitive impairment associated with early-stage AD. Subsequently, higher levels of inflammation markers within the brain leads to mild cognitive impairment. This research study involved 40 C57BL/6 mice, 20 males and 20 females (21 months old), retro-orbitally infected with 80 µL of neurotrophic AAV-AD vector or AAV-Sham for a duration of 2 months before humane euthanasia. Brains were collected, and specific regions were examined by immunohistochemistry (IHC) and digital imaging to assess the expression levels and distribution of the inflammation markers. Preliminary observations showed that hippocampal regions of the brain from mice with early-stage AD had higher staining intensity for MCP-1and TNF-alpha compared to respective areas in Sham mice, suggesting increased inflammation is a very early lesion that develops in the presence of AD pathogenic components that might be controlled by anti-inflammatory drugs. The preliminary data suggests that the characteristics of AD manifest in part due to the neuroinflammatory response of brain factors that change with onset AD.

Brain-derived neurotrophic factor (BDNF) plays a critical role in neuronal function with potential implications for cognitive health, including involvement in adult neurogenesis. A decline in BDNF levels is associated with mild impairments in learning and memory. The hippocampus, known for its involvement in learning and memory processes, serves as a focal point for investigation in the brain due to its responsiveness to environmental stimuli, including exercise. There is an existing knowledge gap concerning whether running promotes an increase in BDNF levels within the hippocampus at very old ages, despite BDNF's importance in neuronal function and its potential implications for cognitive health. This study was designed to investigate whether physical exercise influences BDNF levels in the hippocampus of aged mice. Aged C57BL/6 mice were allowed access to running wheels, or locked running wheels, for three days, after which their brains were collected, post-euthanasia for neuropathology assessment. Immunohistochemistry (IHC) was performed with an anti-BDNF antibody by measuring BDNF presence, since lack of BDNF levels signifies lost neurons. QuPath digital imaging techniques were employed to provide a quantitative measure of the potential impact of running on hippocampal BDNF expression. Both the average and the variance of total distance run during voluntary wheel running decreased with age. Elevated BDNF levels were observed in the hippocampus of running mice compared to sedentary counterparts. The study provides insight into the potential impact of exercise on neurotrophic support in the aging brain. Such findings suggest a beneficial effect of exercise on neurotrophic support in the aging brain, and indicates the need for further investigations into lifestyle stratergies for promoting resilience to brain aging and cognitive decline in older adults.

Plants utilize cell surface protein receptors to recognize insect herbivory through the detection of Herbivore Associated Molecular Patterns (HAMPs) Following the detection of HAMPs, plants initiate specific immune responses, often measured by the increased production of the hormone ethylene gas and by Reactive Oxygen Species (ROS). The Inceptin Receptor (INR), which is specific to legume plants, recognizes the HAMP Inceptin11 (In11). The binding of In11 to INR initiates a signaling cascade, leading to an immune response. However, the signaling mechanism activated by INR is unknown. The Receptor-Like Cytoplasmic Kinase (RLCK) gene Herbivore Induced Kinase 1 (HIK1) is upregulated by In11 treatment in the bean species Phaseolus vulgaris. The goal of this research is to determine if HIK1 and other RLCKs are downstream proteins required for INR signaling. Because of the genetic intractability of P. vulgaris, I transform Arabidopsis thaliana with RLCK genes using Agrobacterium tumefaciens infiltration. Isolated genetic lines are then used to analyze the effect each RLCK has on immune signaling. Transgenic plants are treated with bacterial associated molecular patterns to trigger an immune response, then tissue samples of the leaves are measured for ROS and ethylene gas production. Results are then compared with ROS and ethylene gas production of wildtype plants. If the studied RLCKs are involved in downstream INR signaling, the transgenic plants will have increased ROS and ethylene gas production. I anticipate HIK1 to have the strongest increase in ROS and ethylene gas production due to the upregulation of HIK1 after In11 treatment in P. vulgaris. Understanding the INR signaling pathway is vital for engineering of plants that are resistant to insect herbivory without the use of pesticides.

Plants recognize herbivore-associated molecular patterns (HAMPs) during herbivory that activates signaling to induce immune defenses. Caterpillar oral secretions contain Inceptin 11 (In11) which is a HAMP recognized by legumes such cowpea via Inceptin Receptor (INR). Thus, In11 and INR are a model system to study proteins involved in HAMP induced defenses, including Kunitz trypsin inhibitors (KTIs). It is known that KTIs are serine protease inhibitors with anti-herbivore activity; however, the precise role of In11 induced KTIs and the effect of cysteine content variation in cowpea KTIs remains unknown. Here, we show that selective removal of cysteines has a negative effect on KTI function in cowpea experiencing herbivory from the fall armyworm (Spodoptera frugiperda). We found that cowpea KTIs act as antiherbivore proteins against the fall armyworm when expressed in Nicotiana benthamiana, as we saw reduced weight gain on larvae feeding on leaves expressing wildtype KTI. Furthermore, we found that KTI function was negatively affected by the removal of cysteines, and larvae fed leaves expressing any of the mutant gained more weight than those feeding on wildtype. We hypothesize that these findings are due to reduced protein stability because we did not detect mutant KTIs in frass samples by westernblot. Understanding KTI protein structure and how it influences protein function is important for designing and selecting antiherbivore proteins to be used for plant defense in agriculture.

Alzheimer's disease (AD) is a neurodegenerative age-related disease characterized by the presence of amyloid-beta aggregates and hyperphosphorylated tau tangles. It has been well documented that cognitive decline and changes in age-related pathways are associated with disease progression. Mitochondria play an important role in degradation of amyloid protein through a mitochondrial protein-mediated quality control system. This pathway can break down with increasing age and lead to the overwhelming presence of amyloid, disrupting normal mitochondrial activity. This damage leads to the formation of more Aβ plaques and neuroinflammation, contributing to the pathogenesis of AD. Mitochondrial regulators may be potential therapeutic drug targets but models are needed to help identify and characterize them. In this regard, an Adeno-Associated-Viral (AAV) vector was used to induce AD protein expression in the brains of old mice. 40 Male and 40 Females mice aged 24 months were infected with either the AAV-AD or AAV-SHAM vector and given 3 months for expression of the proteins to build. Mice were euthanized and brain tissue collected into formalin, with the hippocampus cut into slides for immunohistochemistry (IHC). Data generated from these mice has shown trends in decreased synaptic integrity, increased inflammation and DNA damage associated with expression of the vector proteins. Utilizing the same model, this experiment aims to understand how expression of the AAV-AD proteins may be associated with known roles of mitochondria and characterized pathways in the early stages of AD. IHC was performed using antibodies specific for PITRM1, a mitochondria protein degradation regulator, and PINK1, responsible for mitochondrial-mediated cell death (mitophagy). Imaging software “ImageJ” will be used for quantitative analysis of the stains. This study will help clarify an association between varying levels of AD protein expression and mitochondrial regulation, providing valuable information for enhancing therapies aimed at preventing the progression of early stage AD.

Alzheimer's Disease (AD) is incredibly complex such that development of neuropathology and cognitive impairement is driven by multiple pathways. Therefore, targeting these pathways simultaneously, could provide a more effective treatment for AD compared to any single drug. Rapamycin, acarbose, and phenylbutyrate each have independent but overlapping effects on multiple pathways involved in cellular respones to pathogenic beta amyloid such as inflammation, glucose homeostasis, synaptic integrity, autophagy, and DNA damage. To test the safety and effectiveness of a cocktail of these three drugs, a proof of concept experiment was undertaken in transgenic mice carrying mutations for genes associated with early onset AD (5xFAD). These mice express neuronal amyloid plaques, a major feature of AD neuropathlogy. Transgenic and wild type mice were given either a control feed or feed containing the drug cocktail starting at 4 months of age and continued until 12 months of age. Medicated transgenic mice showed significantly less cognitive impairement in a spatial navigation learning task and reduced amyloid plaque levels in the hippocampal brain region compared to untreated transgenic mice. Immunohistochemistry will be used to identify specific biomarkers for inflammation, synaptic integrity, glucose homeostasis, autophagy, and DNA damage in the hippocampus of treated and untreated transgenic mice. Observation from this study will suggest the need to conduct additional preclincial experiments testing this specfic drug combination for a successful approach to treat Alzheimer's Disease. 

Plants' defense mechanism against herbivory and disease is integral to both natural ecological balance as well as global food supply. Induced plant responses to these threats are often triggered by specific molecules such as Herbivore Associated Molecular Patterns (HAMPS) and Pathogen Associated Molecular Patterns (PAMPS). In this project, we are refining a Luciferase Reporter Assay (LRA) and then using that assay to categorize novel HAMPS and PAMPS. This assay’s first main part is the HAMP/PAMP Receptor (HPR). By inoculating a Nicotiana benthamiana (NB) leaf with an Agrobacterium containing a Plasmid with an HPR, we are expressing specific HPRs. We are then using the second part of the LRA, a Luciferase Reporter, whose promoter is tied to an immune response related gene to measure levels of immune activity without the need for Transcriptomic Analysis. After we have infiltrated the NB leaf with the vector containing Agrobacterium and induced a response by adding a HAMP/PAMP, we are measuring Luminescence as a proxy for immune response via an imaging machine, then using R to run an analysis on the levels of immune response, helping us characterize an HPR and its signal pathway. We recently optimized time points for HPR and Luciferase imaging and have found that infiltration by Agrobacterium only takes 24 hours for sufficient plasmid integration. As such we are using this assay to run an experiment on the molecular mechanisms of an HPR in only a few days. Refining this LRA and the information we have gathered has helped shed light on the underlying mechanisms used in induced plant defense. In the future, we are planning on expressing genes of interest using this technique to seek novel activators and suppressors helping us further understand mechanisms of plant defense.

On the morning of September 10th, 1990, the body of seventeen-year-old Maria Soledad-Morales was found on the outskirts of San Fernando de Valle, the capital city of Catamarca province in Argentina. What followed in the aftermath of the murder and botched investigation was the Catamarcazo, one of the largest and most publicly salient protest movements in the decades following the Argentinian Dirty War, the military dictatorship that murdered 30,00 people between 1977 and 1983. In this project, I examine genealogies of resistance among women-led protest movements in Argentina from 1977 to 1992 and argue that linkages between movements contributed to a modern Argentinian understanding of gendered violence in the present day. Through analysis of newspapers, interview transcripts, and photographs, I link activist strategies of the 1977 - 1983 Mothers of the Plaza de Mayo with the Catamarcazo movement of 1990 - 1991. I discuss how the Catamarcazo drew and built upon the strategies of Las Madres and introduced consciousness of gendered violence to the Argentinian public in the first nationally acknowledged protest movement centered on violence against women. The purpose of this study is to establish and recognize the continual development of feminist activism within Argentinian history and shed light on the subversive, revolutionary tactics used to combat state repression and gendered violence. By analyzing histories of feminist activism in Argentina, we can gain a greater understanding of how the strategies of feminist movements are built upon and expanded over time, and how the strategies of a past movement can be modified to serve a current movement.

In place of an adaptive immune system, pattern recognition receptors (PRRs) that perceive host-derived herbivore-associated molecular patterns (HAMPs) induce immune signaling cascades in plants. Inceptins are a class of proteolytic peptides that originate from chloroplastic ATP synthase that are produced in the oral secretions of all studied species of caterpillars in the order Lepidoptera. Upon introduction to the plant, inceptin-11 (+ICDINGVCVDA−) binds to Inceptin Receptor (INR), triggering a signaling cascade to up-regulate defensive hormones, specialized metabolite toxins, and other direct resistance mechanisms against herbivores. However, the full ecological extent of the effects of the INR signaling cascade is poorly understood. Here, we show that inceptin-11 signaling in common bean (Phaseolus vulgaris) can mediate the attraction of predatory wasps (Polybia sp., Polistes sp.) as an added, indirect line of defense against herbivore threats. Using a near-isogenic line of P. vulgaris containing a 103 base pair deletion in the INR locus, we found that Polybia and Polistes preferentially forage on sibling lines with wild-type INR that respond to herbivore threats. Siblings with fully functioning INR produce nearly three-fold more (E)-4,8-Dimethyl-1,3,7-nonatriene (DMNT), an established volatile wasp attractant, than the deletion line. Our results demonstrate that INR can leverage cross-kingdom predator-prey relationships to aid in defense of the plant. Moreover, our near-isogenic line of P. vulgaris provides a genetic resource for studying the role of pattern-triggered immunity in indirect defenses.

Chemical communication is the oldest and most widespread form of communication across the tree of life, and markedly present among lizards. However, the drivers of chemical profile variations in this group remain for the most part uninvestigated. In South American lizards of the Tropiduridae family, semiochemicals are produced by epidermal gland organs called α-glands, exclusively found on the ventral side of male individuals of at least 40 species from four genera. The chemicals produced by these glands are hypothesized to interact with their environments in different ways since chemical species are naturally reactive and tend towards their lowest energetic state. Thus, the intrinsic properties of a semiochemical impact its survival and efficacy for communication. Given the diverse ecology and broad geographical distribution of tropidurids, we investigated whether variation in the chemical composition of α-gland secretions correlates with temperature, humidity, and habitat openness. We performed liquid chromatography-mass spectrometry (LCMS) to obtain the metabolomes of three different sample types. We sampled male skin containing the α-glands, undifferentiated male skin, and female skin. Environmental and chemical property data were extracted from online databases, literature, and field observations. Preliminary tests were done by making Venn diagrams comparing the metabolomes of each sample type. These revealed differences in metabolite compositions, notably between males and females as well as between glandular and undifferentiated skin. From the metabolomes of α-glands, we expect to see chemical species with properties that confer greater survival given the specificities of the environment. For example, given a lizard from a hot and humid environment, we expect the metabolome of the α-glands to contain higher molecular weight species with less functional group complexity. Understanding how environmental parameters drive the chemical composition of α-glands is expected to provide a deeper understanding of the evolutionary history of chemical signaling in terrestrial vertebrates.

Lizards in the family Tropiduridae have ventral epidermal gland organs that are involved in chemical signaling and whose secretory mechanism is entirely unknown. This is because, like other epidermal generation glands, 'alpha-glands' lack a pore through which their secretion can be exerted. Chemical signaling is a valuable aspect of tropidurid lizards' social and ecological interactions, and some have been observed territorially scraping their alpha-glands against the substrate. This process has been hypothesized to facilitate the release of chemical signals via abrasion. To investigate this abrasion hypothesis, we analyzed 74 skin samples from 27 tropidurid species, using light microscopy and scanning electron microscopy (SEM). The SEM revealed incredible surface variability in epidermal glands, providing morphological insight. We found that the exposed glandular mass of each gland scale rests atop the oberhautchen layer of the skin's subjacent generation, which indicates that the secretion of chemicals involves exposing a mostly solid glandular material on the outside of the scales. Histological sectioning of gland scales revealed morphological consistency, indicating that the same secretory mechanism is shared across the tropidurid phylogeny. Imaging of histology samples also revealed that the shedding process which exposes the glandular material may be facilitated by the clear layer, found directly above the glandular mass during development. Characterization of morphological patterns in the formatted SEM images and comparison with histological data should provide evidence for or against taxon-specific or ecology-specific alpha-gland structures, and further support the idea of chemical secretion requiring epidermal exposal of glandular material. Investigations of the morphology and functional mechanism of this unique organ provide insight into the behavior and evolution of tropidurid lizards and shed light on factors influencing the evolution of chemical signaling in terrestrial organisms. 

Mycobacterium abscessus are non-motile bacilli that cause soft-tissue and pulmonary infections, commonly in healthcare settings or patients with cystic fibrosis. Though it is considered an opportunistic pathogen, its many virulence factors signal its potential for evolution into a true pathogen. Upon infection, the bacilli are internalized by macrophages, forming granulomas to contain the infection. Macrophages can harbor bacilli during infection stages and induce drug resistance by expelling toxins through ABC transporters. Treatment is often challenging as M. abscessus is intrinsically resistant to many antibiotics. Current treatment uses a combination of two or more intravenous drugs and one or more oral antibiotics over several months. Treatment success is challenged by patient adherence and may also be impacted by drug efflux by macrophage ABC transporters. Transporters identify certain drugs as toxic to the body and try to flush them out of the cell. Since Mycobacteria infect macrophages, these channels pose a significant disadvantage to treatment since the cell will actively efflux the drug, preventing the drug's intracellular concentration from increasing to an effective level against the bacilli inside. Certain drugs are known to inhibit ABC transporters, and the addition of these inhibitors in treatment could increase bacteriocidal activity and reduce the development of drug tolerance. First, we will determine the drug's minimum inhibitory concentrations to each inhibitor to see if there is an intrinsic activity on M. abscessus. Next, we will use the Human THP-1 cell line infect with Mycobacterium abscessus and treat with known ABC transport inhibitors in concert with a current therapeutic drug, Clarithromycin. They will then be plated at various time points to determine the colony-forming units. If efflux by macrophage transporters reduces the efficacy of Clarithromycin, bacteriocidal activity will increase between the combination therapy and the clarithromycin-only treatment. These results may improve the current treatment regimens for M. abscessus.

More than 53 million adults or 22% of the US suffer from chronic inflammation. Along with being a critical factor in the onset and progression of aging and cell senescence of the central nervous system, inflammation is also a central hallmark of neurodegenerative diseases and brain injury. Modulation of neuroinflammation has the therapeutic potential to decelerate aging processes in the brain. Studies consistently show that cytokines such as Interleukin (IL)-6, Tumor Necrosis factor (TNF)-α, Monocyte Chemoattractant Protein -1 (MCP-1), and their receptors, are upregulated in aged tissues and cells. This study investigated effects of GHK-Cu, a naturally occurring peptide that has regenerative properties, as a potential therapeutic measure to reduce the expression of these proteins. Mouse SIM-A9 microglial cells and N2A neuroblastoma cells were used as a model system, and bacterial endotoxin (Lipopolysaccharide, designated as LPS) was used as a stressor to trigger an inflammatory response. Cell morphology, viability, and cytokine ELISA assays including IL-6, MCP-1, and TNF-α, provided data suggesting that GHK-Cu peptide is a potent factor in enhancing resistance of neuronal and microglial cell lines to LPS-induced stress by reducing the expression of key inflammatory cytokines.Understanding the mechanisms by which GHK-Cu modulates inflammation can pave the way for the development of novel treatments targeting inflammation-associated diseases, aging mechanisms and various forms of dementia.

Mild cognitive decline with increasing age commonly affects millions of people beginning as early as middle age. It can progress to more severe levels of cognitive impairment including dementia associated with Alzheimer’s disease and irreversible brain damage with eventual death. Therefore, treatment before the onset of dementia would be the most effective way to prevent the devastating loss of normal daily living and death as an outcome. However, few drugs have been shown to be successful in preventing the progression of mild cognitive decline to more severe cognitive dysfunction. One candidate drug we are testing is the naturally occurring peptide GHK (glycyl-L-histidyl-L-lysine), which is known to have regenerative and anti-inflammatory properties in the brain. In order to test this peptide, we treated middle-aged male and female C57BL/6 mice with GHK as a copper complex (GHK-Cu) or saline using a novel intranasal atomizer daily for two months. We then conducted behavioral tests to assess learning and memory, and then mice were euthanized to collect brain samples for special stains for biomarkers of brain aging including the presence of non-neuronal microglia, brain-derived neurotrophic factor, and synapse integrity. Our preliminary observations from behavioral tests show that mice treated with intranasal GHK-Cu performed better in learning and memory tests than mice treated with intranasal saline. The brain aging biomarker tests I completed show that the neuropathology markers associated with aging are less severe in mice treated with intranasal GHK-Cu. Such a positive outcome provides the rationale to do further preclinical testing as a way to move toward clinical studies designed to treat mild cognitive decline and prevent the devastating progression of irreversible neurodegeneration.

Pregnant individuals infected with influenza A viruses (IAV) have higher risks of mortality, hospitalization, preterm birth, and stillbirth. The objective was to determine how the transcriptional program induced by IAV infection in the lung differs between pregnant and non-pregnant states. I hypothesized that a cluster of genes linked to aggravation of influenza disease would be upregulated in the pregnant lung early in IAV infection versus the non-pregnant lung. We used a non-human primate model [NHP; pregnant (N=10), non-pregnant (N=10); Macaca nemestrina, pigtail macaque] to investigate the transcriptional response in the lung of pregnant versus non-pregnant NHPs infected with the IAV CA/04/2009 (H1N1) strain. Maternal lung tissues were collected from the animals at necropsy 5 days after infection. mRNA-Seq was performed by first extracting mRNA from tissues, preparing mRNA libraries, and aligning raw sequencing data, using Spliced Transcripts Alignment to a Reference (STAR), to the macaque genome. I performed normalization of the raw gene count matrix using EdgeR in R Studio and alignment to the macaque reference genome. Next, I performed a single gene analysis using Limma-voom to determine differentially expressed genes (DEG). A total of 115 genes were significantly differentially expressed (>2-fold change, p<0.05) with 77 upregulated and 38 downregulated. Remarkably, genes linked to aggravation of influenza A viral disease, tissue injury, or acidification were upregulated in the infected pregnant versus non-pregnant lung 5 days after infection (MMP8, ATP12A, LGR4, NUP58, KBTBD6; log2fold change 1.28 - 2.8, all p<0.05). Next steps include gene set enrichment analysis and ingenuity pathway analysis to further investigate the gene networks linked to these upregulated genes. In summary, pregnancy was associated with upregulation of genes in the lungs 5 days after IAV infection that may predispose to greater tissue injury versus the non-pregnant lung.