Browsing by Author "Roberts, Paul C."

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    Changes in Gene Expression and Cellular Architecture in an Ovarian Cancer Progression Model
    Creekmore, Amy L.; Silkworth, William T.; Cimini, Daniela; Jensen, Roderick V.; Roberts, Paul C.; Schmelz, Eva M. (PLOS, 2011-03-03)
    Background Ovarian cancer is the fifth leading cause of cancer deaths among women. Early stage disease often remains undetected due the lack of symptoms and reliable biomarkers. The identification of early genetic changes could provide insights into novel signaling pathways that may be exploited for early detection and treatment. Methodology/Principal Findings Mouse ovarian surface epithelial (MOSE) cells were used to identify stage-dependent changes in gene expression levels and signal transduction pathways by mouse whole genome microarray analyses and gene ontology. These cells have undergone spontaneous transformation in cell culture and transitioned from non-tumorigenic to intermediate and aggressive, malignant phenotypes. Significantly changed genes were overrepresented in a number of pathways, most notably the cytoskeleton functional category. Concurrent with gene expression changes, the cytoskeletal architecture became progressively disorganized, resulting in aberrant expression or subcellular distribution of key cytoskeletal regulatory proteins (focal adhesion kinase, α-actinin, and vinculin). The cytoskeletal disorganization was accompanied by altered patterns of serine and tyrosine phosphorylation as well as changed expression and subcellular localization of integral signaling intermediates APC and PKCβII. Conclusions/Significance Our studies have identified genes that are aberrantly expressed during MOSE cell neoplastic progression. We show that early stage dysregulation of actin microfilaments is followed by progressive disorganization of microtubules and intermediate filaments at later stages. These stage-specific, step-wise changes provide further insights into the time and spatial sequence of events that lead to the fully transformed state since these changes are also observed in aggressive human ovarian cancer cell lines independent of their histological type. Moreover, our studies support a link between aberrant cytoskeleton organization and regulation of important downstream signaling events that may be involved in cancer progression. Thus, our MOSE-derived cell model represents a unique model for in depth mechanistic studies of ovarian cancer progression.
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    Characterization of Influenza:Streptococcus pneumoniae synergistic disease and potential for disease alleviation via sphingolipid therapy
    Gasser, Amanda Lynn (Virginia Tech, 2013-09-06)
    Influenza A virus (IAV) is generally associated with the seasonal malady that causes brief respiratory illness during the winter months, known simply as "the flu." Most otherwise healthy individuals will suffer from mild fever, congestion, headaches and myalgia that are resolved within 5-7 days of onset. However, there are nearly 500,000 influenza-related deaths that occur world-wide every year. Many of these casualties and patients hospitalized with influenza also test positive for bacterial pneumonia, the most common agent being Streptococcus pneumoniae. Although all individuals are subject to this viral:bacterial synergistic disease, the young, elderly, and immunocompromised are the most susceptible. Previous studies have shown that viral infection creates a prolonged hyper-responsive pro-inflammatory state in the lungs, which increases susceptibility to secondary bacterial infection. Lethality is due to detrimental pulmonary damage from a dysregulated host inflammatory response, known as the "cytokine storm." However, the nature of dual infection has not been well-studied in the elderly demographic. Therefore, we aim to better define this disease synergy in an aged mouse model and explore potential therapeutic alternatives that could be beneficial for the aged and other vulnerable populations. Sphingolipid modulation has emerged as a potential target to ameliorate the excessive inflammation (cytokine storm) elicited by highly pathogenic influenza. There is particular emphasis on sphingosine 1-phosphate (S1P) signaling, as well as control of intracellular S1P levels via sphingosine kinases (SK). Sphingolipids are involved in a multitude of cellular processes, and are tightly regulated by their metabolizing enzymes. We hypothesize that manipulation of sphingolipid signaling and alteration of the internal sphingolipid milieu will diminish the inflammatory response elicited by IAV infection. Using fluorescence-activated cell sorting (FACS), real-time PCR and cytometric bead array (CBA) analysis, we evaluated the immunomodulatory effects of systemic sphingosine analog treatment within the lung microenvironment under homeostatic and influenza-infected conditions. FTY720 treatment caused transient, but significant lymphopenia, influx of neutrophils and efflux of macrophages in the lungs, which was enhanced during a mild influenza infectionGene expression in the lungs was generally unaltered, but protein levels showed increases in specific influenza-induced cytokines, suggesting these treatments may have post-transcriptional effects on cytokine expression. To evaluate sphingolipid modulation in specific pulmonary cell types, we next observed the effects of these compounds and sphingosine kinase (SK) inhibitors in epithelial and alveolar macrophage-like cell lines. SK inhibitors and Enigmol demonstrated anti-viral effects in A549 cells, decreasing viral loads by up to 1.5 logs. Real-time PCR and CBA analysis further demonstrated that these effects were associated with alterations in key cytokine expression, including CCL2, CCL5, CXCL10, IL-6, and IL-8. Collectively, these findings indicate that therapeutic sphingolipid modulation has the potential for creating a protective microenvironment in the lungs that could alleviate or even prevent viral:bacterial synergistic disease.
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    Characterization of Metabolic Differences in Benign, Slow Developing and Tumor Initiating Ovarian Cancers
    Anderson, Angela S. (Virginia Tech, 2013-05-14)
    Ovarian cancer is known as the "silent killer," due to its late diagnosis and frequent recurrence after initial treatment.  Finding a new way to diagnose and treat ovarian cancer in conjunction with current therapies is paramount.  By capitalizing on metabolic changes that occur during cancer progression, interventions can be developed.  The Nobel laureate Otto Warburg is credited with discovering an altered metabolic state within cancer cells known as the Warburg effect.  In the Warburg effect, cancer cells participate in an increased rate of aerobic glycolysis with an excess secretion of lactate, allowing for carbon flux into biosynthetic pathways.  Exactly which metabolic pathways are altered in ovarian cancer and at which stage in the progression of ovarian cancer they are occurring was unknown.  Therefore using the recently established mouse ovarian surface epithelial (MOSE) progression model, we were able to measure metabolic changes in varying states of disease and levels of aggressiveness.  As cells progressed from a benign early stage (MOSE-E), through a transitional intermediate stage (MOSE-I), to an aggressive late stage (MOSE-L), the MOSE cells became more glycolytic and lipogenic, establishing the MOSE model as a valuable model for studying ovarian cancer metabolism.  Treating the MOSE cells with the naturally occurring chemotherapeutic agent sphingosine decreased p-AKT  protein levels in the cell, decreased the glycolytic rate and decreased de novo cholesterol synthesis.  Cancer stem cells are known to be resistant to chemotherapy treatments and targeting their metabolism may be promising for combinatorial treatments.  Therefore, the metabolism of highly aggressive tumor-initiating cells (TIC), harvested from ascites of C57Bl/6 mice injected with MOSE-L cells were characterized.  Although the basal metabolism of the TICs was similar to the MOSE-L cells, TICs were more resistant to cell death as a consequence of external stresses and substrate depletion.  The TICs could also up-regulate oxygen consumption rate (OCR) when uncoupled and increase glycolysis when ATP Synthase was inhibited, highlighting their resiliency.  Taken together, we have identified targets for treatment strategies that could suppress the growth of primary tumors and may be effective against TICs, thereby suppressing tumor recurrence and possibly prolonging the life of women with ovarian cancer.
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    Complete Genome Sequence and Pathogenicity of Two Swine Parainfluenzaviruses Isolated from Pigs in the United States
    Qiao, Dan (Virginia Tech, 2009-05-21)
    Members of the family Paramyxoviridae are non-segmented, negative-strand RNA viruses. A large and diverse host species are infected by paramyxoviruses, including avian, porcine, canine, bovine, equine, ovine, reptiles, aquatic species and humans. In the last few decades, many novel paramyxoviruses have emerged causing catastrophic illnesses in different aquatic and terrestrial species of animals and some of them also made the species jump to humans. Two novel paramyxoviruses 81-19252 (Texas81) and 92-7783 (ISU92) were isolated in the 1980s and 1990s from the brain of pigs that experienced respiratory and central nervous system disease from South and North Central United States. To understand their importance as swine pathogens, molecular characterization and pathogenicity studies were undertaken. The complete genome of Texas81 virus was 15456 nucleotides (nt) and ISU92 was 15480 nt in length consisting of six non-overlapping genes coding for the nucloeo- (N), phospho- (P), matrix (M, fusion (F), hemagglutinin-neuraminidase (HN) and large polymerase (L) proteins in the order 3'-N-P/C/V-M-F-HN-L-5'. The features related to virus replication and found to be conserved in most members of Paramyxoviridae were also found in swine viruses. These include: conserved and complementary 3â leader and 5â trailer regions, trinucleotide intergenic sequences, highly conserved gene start and gene stop signal sequences. The length of each gene of these two viruses was similar except for the F gene, in which ISU92 had an additional 24 nt "U" rich 3â untranslated region (UTR). The P gene of these viruses were predicted to express the P protein from the primary transcript and edit a portion of its mRNA to encode V and D proteins and the C protein was expected to be expressed from alternate translation initiation from the P gene as in Respiroviruses. Sequence specific features related to virus replication and host specific amino acid signatures in P, F, HN and L proteins indicated that these viruses probably originated from bovine parainfluenzavirus 3. Pairwise comparisons of deduced amino acid sequences of swine viral proteins with members of Paramyxoviridae and phylogenetic analysis based on individual genes as well as predicted amino acid sequences suggested that these viruses were novel members of the genus Respirovirus of the Paramyxovirinae subfamily and genotype A of bovine parainfluenzavirus type 3. The mild clinical signs and undetectable gross and microscopic lesions observed in swine parainfluenzavirus (sPIV3)-infected pigs indicate the inapparent nature of these viruses in pigs. Limited seroprevalence studies in serum samples collected from pig farms in Minnesota and Iowa in 2007-2008 by indirect ELISA revealed that sPIV3 are not circulating in these farms. The mild pathogenicity of sPIV3 can facilitate its development as a vaccine vector. The screening ELISA developed by us could be used to detect seroprevalence of sPIV3 in animal and human populations.
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    Cross-protection and Potential Animal Reservoir of the Hepatitis E Virus
    Sanford, Brenton Joel (Virginia Tech, 2012-05-29)
    HEV is an important public health concern due largely to water-borne outbreak. Recent research confirms individual cases of zoonotic transmission due to human exposure to contaminated animal meats. At least four recognized and two putative genotypes of mammalian HEV have been reported: genotypes 1 and 2 are restricted to humans whereas genotypes 3 and 4 are zoonotic. In addition to humans, strains of HEV have been genetically identified from pigs, chickens, rats, mongoose, deer, rabbits and fish. The current experimental vaccines are all based on a single strain of HEV, even though multiple genotypes of HEV are co-circulating in some countries and thus an individual may be exposed to more than one genotype. Therefore, it is important to know if prior infection with a genotype 3 swine HEV will confer protective immunity against subsequent exposure to genotypes 3 and 4 human and swine HEV. In the first study, specific-pathogen-free pigs were divided into 4 groups of 6 each. Pigs in the three treatment groups were each inoculated with a genotype 3 swine HEV, and 12 weeks later, challenged with the same genotype 3 swine HEV, a genotype 3 human HEV, and a genotype 4 human HEV, respectively. Sera from all pigs were tested for HEV RNA and IgG anti-HEV, and fecal samples were also tested for HEV RNA each week. The pigs inoculated with swine HEV became infected as evidenced by fecal virus shedding and viremia, and the majority of pigs also developed IgG anti-HEV prior to challenge at 12 weeks post-inoculation. After challenge, viremia and fecal virus shedding of challenge viruses were not detected, suggesting that prior infection with a genotype 3 swine HEV prevented pigs from developing viremia and fecal virus shedding after challenge with homologous and heterologous genotypes 3 and 4 HEV, respectively. Immunogenic epitopes are located within the open reading frame 2 (ORF 2) capsid protein and recombinant ORF 2 antigens are capable of preventing HEV infection in non-human primates and chickens. In the second study we expressed and purified N-truncated ORF 2 antigens based on swine, rat, and avian HEV strains. Thirty pigs were randomly divided into groups of 6 pigs each and initially vaccinated with 200µg swine ORF 2 antigen, rat ORF 2 antigen, avian ORF 2 antigen, or PBS buffer (positive and negative control groups) and booster with the same vaccine 2 weeks later. At 4 wks, after confirming seroconversion to IgG anti-HEV antibody with ELISA, all groups except the negative control were challenged with swine genotype 3 HEV (administered intravenously). The protective and cross-protective abilities of these antigens were determined following swine genotype 3 challenge by evaluating both serum and fecal samples for HEV RNA using nested RT-PCR and IgG anti-HEV using ELISA. The results from these two studies have important implications for future development of an effective HEV vaccine. As a part of our ongoing efforts to search for potential animal reservoirs for HEV, we tested goats from Virginia for evidence of HEV infection and showed that 16% (13/80) of goat sera from Virginia herds were positive for IgG anti-HEV. Importantly, we demonstrated that selected goat sera were capable of neutralizing HEV in cell culture. Subsequently, in an attempt to genetically identify the HEV-related agent from goats, we conducted a prospective study in a closed goat herd with known anti-HEV seropositivity and monitored a total of 11 kids from the time of birth until 14 weeks of age for evidence of HEV infection. Seroconversion to IgG anti-HEV was detected in 7 out of the 11 kids, although repeated attempts to detect HEV RNA by a broad-spectrum nested RT-PCR from the fecal and serum samples of the goats that had seroconverted were unsuccessful. In addition, we also attempted to experimentally infect laboratory goats with three well-characterized mammalian strains of HEV but with no success. The results indicate that a HEV-related agent is circulating and maintained in the goat population in Virginia and that the goat HEV is likely genetically very divergent from the known HEV strains.
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    Cytokine-bearing Influenza Vaccine: Adjuvant Potential of Membrane-bound Immunomodulators
    Herbert, Andrew S. (Virginia Tech, 2009-04-27)
    Influenza epidemics continue to cause morbidity and mortality within the human population despite widespread vaccination efforts. This, along with the ominous threat of an avian influenza pandemic (H5N1), demonstrates the need for a much improved, more sophisticated influenza vaccine. Our group has developed an in vitro model system for producing a membrane-bound Cytokine-bearing Influenza Vaccine (CYT-IVAC). Numerous cytokines are involved in directing both innate and adaptive immunity and it is our goal to utilize the properties of individual cytokines and other immunomodulatory proteins to create a more immunogenic vaccine. Here we report methodologies for the construction of membrane-bound cytokine fusion constructs in which our cytokine of interest (mouse GM-CSF, mouse IL-2, mouse IL-4) was fused to the membrane anchoring regions of viral Hemagglutinin (HA). Progeny virions, produced from influenza infected MDCK cells expressing membrane-bound cytokines, readily incorporated membrane-bound cytokines during budding and these cytokines on the virus particles retained bioactivity following viral inactivation. In vivo vaccination studies in mice showed enhanced antibody titers and improved protection following lethal challenge in those mice vaccinated with IL-2 and IL-4-bearing CYT-IVAC's compared to the conventional wild-type vaccine without membrane-bound cytokines. In addition, the immune response induced by IL-2 and IL-4-bearing CYT-IVACs was skewed toward Th1 (cellular) mediated immunity compared to the Th2 (humoral) dominated response induced with wild-type vaccination. Cellular mediated immunity afforded by IL-2 and IL-4 CYT-IVACs was manifested as enhanced influenza specific T cell proliferation and activation. In conclusion, we have developed a novel methodology to introduce bioactive membrane-bound cytokines directly into virus particles in order to augment the immunogenicity of inactivated, whole virus influenza vaccines.
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    Development of an Antibiotic Resistance Free Bivalent Vaccine Against Swine Brucellosis and Swine Influenza
    Rajasekaran, Parthiban (Virginia Tech, 2009-12-09)
    Livestock across the world contract several infectious diseases of both bacterial and viral origin. Swine brucellosis caused by Brucella suis and swine influenza caused by Influenza A virus affect both domestic and feral swine populations. Both the diseases have zoonotic potential to cause disease in humans with serious complications apart from inflicting huge economic losses. Infected feral swine can also act as a source of spread and outbreak where the disease is not endemic. At present, there is no vaccine available for swine brucellosis. The currently used swine influenza vaccine may not be effective against influenza strains like the recent H1N1 strain that caused a pandemic. To develop an effective bivalent vaccine for swine against these two diseases, a leucine auxotroph of the USDA approved vaccine B. abortus strain RB51 was constructed along with leuB gene complementing plasmid pNS4 to over-express antigens from Brucella and influenza. This antibiotic resistance free system over-expressed Brucella derived antigens SOD, L7/L12 and WboA in three different constructs. Against a virulent challenge of B. suis, the candidate vaccine strain over-expressing both SOD and WboA protected mice more significantly than the control group and was also found to be better protective than other candidate vaccine strains over-expressing either SOD and L7/L12 together or SOD alone. Immunoassays (ELISA) suggested that the protection afforded is Th1 type mediated immune response, as cytokine IFN-γ and IgG2a antibody sub-isotype was observed in the splenocyte culture supernatant and serum samples respectively. The strain RB51leuB platform was not expressing influenza derived antigens Hemagglutinin (HA) and Nucleoprotein (NP) when screened for expression by immunoblot. Influenza antigens, HA, NP and ectodomain of matrix protein M2e, were not found to be expressing even after optimizing their codon usage to suit Brucella tRNA preference. However, RT-PCR showed that the influenza genes mRNA were produced. In conclusion, this dissertation describes the construction of an environmentally safe antigen over-expression platform and successful employment of the system as a candidate vaccine in protecting mice against B. suis challenge. This new platform is a potential candidate for developing vaccines against other infectious diseases of livestock. This document also discusses alternate strategies for expressing influenza antigens in a Brucella platform.
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    Dielectrophoretic differentiation of mouse ovarian surface epithelial cells, macrophages, and fibroblasts using contactless dielectrophoresis
    Salmanzadeh, Alireza; Kittur, Harsha; Sano, Michael B.; Roberts, Paul C.; Schmelz, Eva M.; Davalos, Rafael V. (American Institute of Physics, 2012-06-01)
    Ovarian cancer is the leading cause of death from gynecological malignancies in women. The primary challenge is the detection of the cancer at an early stage, since this drastically increases the survival rate. In this study we investigated the dielectrophoretic responses of progressive stages of mouse ovarian surface epithelial (MOSE) cells, as well as mouse fibroblast and macrophage cell lines, utilizing contactless dielectrophoresis (cDEP). cDEP is a relatively new cell manipulation technique that has addressed some of the challenges of conventional dielectrophoretic methods. To evaluate our microfluidic device performance, we computationally studied the effects of altering various geometrical parameters, such as the size and arrangement of insulating structures, on dielectrophoretic and drag forces. We found that the trapping voltage of MOSE cells increases as the cells progress from a non-tumorigenic, benign cell to a tumorigenic, malignant phenotype. Additionally, all MOSE cells display unique behavior compared to fibroblasts and macrophages, representing normal and inflammatory cells found in the peritoneal fluid. Based on these findings, we predict that cDEP can be utilized for isolation of ovarian cancer cells from peritoneal fluid as an early cancer detection tool. (C) 2012 American Institute of Physics. [http://dx.doi.org/10.1063/1.3699973] Actual pdf downloaded from NCBI.
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    Evaluation of the actin architecture in dysplastic megakaryocytes expressing the NUP98-HOXD13 leukemic fusion gene
    Okyere, Benjamin (Virginia Tech, 2013-08-30)
    Some myelodysplastic syndrome (MDS) patients present with macrothrombocytopenia due to impaired megakaryocyte (MK) differentiation. Transgenic mice that express the NUP98-HOXD13 (NHD13) fusion gene is a model for MDS and recapitulates the key features of MDS. The study investigated the hypothesis that expression of NHD13 disrupts actin architecture during MK differentiation leading to macrothrombocytopenia. To test the hypothesis, sternums were stained with hematoxylin and eosin, and evaluated by light microscopy to analyze MK morphology in vivo. NHD13 bone marrow (BM) contained many dysplastic MK. BM from wild type (WT) and NHD13 mice were also flushed, cultured in media supplemented with thrombopoietin only or with estrogen to induce proplatelet formation, and MK harvested after 5 days. Harvested MK and BM cores were processed and analyzed by transmission electron microscopy (TEM) to detail the ultrastructural features. TEM of MK revealed that NHD13 leads to formation of an irregular demarcation membrane system and fewer proplatelets. Cultured WT and NHD13 MK were also cytospun onto glass slides, labeled with fluorescent-tagged F-actin, α/β-tubulin and myosin IIa, and their cytoskeleton compared. Interestingly WT MK had actin either distributed evenly or predominantly in the periphery of the cytoplasm, NHD13 MK displayed only the former phenotype. Additionally, proplatelets lacked actin cytoplasmic extensions. The results from the present thesis demonstrate actin expression and architecture are impaired in dysplastic MK expressing the NHD13 leukemic fusion gene and leads to macrothromcytopenia. Understanding the molecular mechanisms of abnormal MK differentiation in MDS is important as many MDS patients die of hemorrhagic complications.
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    The Impact of Adipose-Associated Stromal Cells on the Metastatic Potential of Ovarian Cancer
    Shea, Amanda A. (Virginia Tech, 2014-01-22)
    Obesity is a major global health concern due to its steadily increasing rates and significant contribution to numerous diseases, including cancer. Ovarian cancer specifically, is associated with a 30% increased risk with obesity, although the mechanisms for this are unknown. Waist-to-hip ratio has been especially associated with ovarian cancer, suggesting that visceral fat may be the greatest contributor. Here, we investigated individual visceral fat depots as independent contributors to cancer progression, specifically focusing on adipose tissue-derived stem and progenitor cells, which have previously been shown to be recruited by cancer cells and participate in cancer progression. We confirmed that ovarian cancer tumor burden was indeed significantly increased in mice on a high fat as compared to low fat diet. To further investigate mechanisms, we examined changes in progenitor populations that occurred in intra-abdominal parametrial (pmWAT), retroperitoneal (rpWAT), and omental (omWAT) white adipose tissue (WAT) depots with cancer presence. The greatest tumor burden was evident in omWAT, which also displayed an increase in CD45- cells but a decrease in adipose progenitor cells (APC) and endothelial progenitor cells, suggesting that there was an increase in stromal cells, but that the stem cells were pushed towards differentiation. PmWAT and rpWAT showed remarkably stable progenitor populations. However, a tumor from pmWAT had a significant presence of CD45- cells, actually matching that of its surrounding tissue and differing from the omWAT tumors, indicating that microenvironment has a major influence on tumor stromal cells. We also found that with high fat diet, many cancer-associated changes were exacerbated, such as an increased inflammatory response in all tissues and further decreases in APCs in omWAT. In vitro studies further confirmed that ovarian cancer cells and SVF cells were able to directly interact. Additionally, SVF cells were able to increase the proliferation, mobility, and invasiveness of cancer cells. Conversely, co-culturing also enhanced the proliferation and mobility of SVF cells, providing further evidence that SVF cells may be recruited by cancer cells and that their relationship may be bilateral. Thus, this study provides a good foundation for examining the cellular contributions of adipose tissue to cancer. By further characterizing the mechanism for the association between obesity and cancer development, we could find novel targets to decrease the progress of cancer development in at-risk obese individuals.
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    Incorporation of membrane-bound, mammalian-derived immunomodulatory proteins into influenza whole virus vaccines boosts immunogenicity and protection against lethal challenge
    Herbert, Andrew S.; Heffron, C. Lynn; Sundick, Roy; Roberts, Paul C. (2009-04-24)
    Background Influenza epidemics continue to cause morbidity and mortality within the human population despite widespread vaccination efforts. This, along with the ominous threat of an avian influenza pandemic (H5N1), demonstrates the need for a much improved, more sophisticated influenza vaccine. We have developed an in vitro model system for producing a membrane-bound Cytokine-bearing Influenza Vaccine (CYT-IVAC). Numerous cytokines are involved in directing both innate and adaptive immunity and it is our goal to utilize the properties of individual cytokines and other immunomodulatory proteins to create a more immunogenic vaccine. Results We have evaluated the immunogenicity of inactivated cytokine-bearing influenza vaccines using a mouse model of lethal influenza virus challenge. CYT-IVACs were produced by stably transfecting MDCK cell lines with mouse-derived cytokines (GM-CSF, IL-2 and IL-4) fused to the membrane-anchoring domain of the viral hemagglutinin. Influenza virus replication in these cell lines resulted in the uptake of the bioactive membrane-bound cytokines during virus budding and release. In vivo efficacy studies revealed that a single low dose of IL-2 or IL-4-bearing CYT-IVAC is superior at providing protection against lethal influenza challenge in a mouse model and provides a more balanced Th1/Th2 humoral immune response, similar to live virus infections. Conclusion We have validated the protective efficacy of CYT-IVACs in a mammalian model of influenza virus infection. This technology has broad applications in current influenza virus vaccine development and may prove particularly useful in boosting immune responses in the elderly, where current vaccines are minimally effective.
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    Intra-Abdominal Fat Depots Represent Distinct Immunomodulatory Microenvironments: A Murine Model
    Cohen, Courtney A.; Shea, Amanda A.; Heffron, C. Lynn; Schmelz, Eva M.; Roberts, Paul C. (PLOS, 2013-06-12)
    White adipose tissue (WAT) is a multi-faceted endocrine organ involved in energy storage, metabolism, immune function and disease pathogenesis. In contrast to subcutaneous fat, visceral fat (V-WAT) has been associated with numerous diseases and metabolic disorders, indicating specific functions related to anatomical location. Although visceral depots are often used interchangeably in V-WAT-associated disease studies, there has been a recent subdivision of V-WAT into “true visceral” and non-visceral intra-abdominal compartments. These were associated with distinct physiological roles, illustrating a need for depot-specific information. Here, we use FACS analysis to comparatively characterize the leukocyte and progenitor populations in the stromal vascular fraction (SVF) of peritoneal serous fluid (PSF), parametrial (pmWAT), retroperitoneal (rpWAT), and omental (omWAT) adipose tissue from seven-month old C57BL/6 female mice. We found significant differences in SVF composition between all four microenvironments. PSF SVF was comprised almost entirely of CD45+ leukocytes (>99%), while omWAT contained less, but still almost two-fold more leukocytes than pmWAT and rpWAT (75%, 38% and 38% respectively; p<0.01). PmWAT was composed primarily of macrophages, whereas rpWAT more closely resembled omWAT, denoted by high levels of B1 B-cell and monocyte populations. Further, omWAT harbored significantly higher proportions of T-cells than the other tissues, consistent with its role as a secondary lymphoid organ. These SVF changes were also reflected in the gene expression profiles of the respective tissues. Thus, intra-abdominal fat pads represent independent immunomodulatory microenvironments and should be evaluated as distinct entities with unique contributions to physiological and pathological processes.
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    Investigating dielectric properties of different stages of syngeneic murine ovarian cancer cells
    Salmanzadeh, Alireza; Sano, Michael B.; Gallo-Villanueva, R. C.; Roberts, Paul C.; Schmelz, Eva M.; Davalos, Rafael V. (American Institute of Physics, 2013-01-01)
    In this study, the electrical properties of four different stages of mouse ovarian surface epithelial (MOSE) cells were investigated using contactless dielectrophoresis (cDEP). This study expands the work from our previous report describing for the first time the crossover frequency and cell specific membrane capacitance of different stages of cancer cells that are derived from the same cell line. The specific membrane capacitance increased as the stage of malignancy advanced from 15.39 +/- 1.54 mF m(-2) for a non-malignant benign stage to 26.42 +/- 1.22 mF m(-2) for the most aggressive stage. These differences could be the result of morphological variations due to changes in the cytoskeleton structure, specifically the decrease of the level of actin filaments in the cytoskeleton structure of the transformed MOSE cells. Studying the electrical properties of MOSE cells provides important information as a first step to develop cancer-treatment techniques which could partially reverse the cytoskeleton disorganization of malignant cells to a morphology more similar to that of benign cells. (C) 2013 American Institute of Physics. [http://dx.doi.org/10.1063/1.4788921] Actual pdf downloaded from NCBI.
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    Membrane-bound IL-12 and IL-23 serve as potent mucosal adjuvants when co-presented on whole inactivated influenza vaccines
    Khan, Tila; Heffron, C. Lynn; High, Kevin P.; Roberts, Paul C. (2014-05-03)
    Background Potent and safe adjuvants are needed to improve the efficacy of parenteral and mucosal vaccines. Cytokines, chemokines and growth factors have all proven to be effective immunomodulatory adjuvants when administered with a variety of antigens. We have previously evaluated the efficacy of membrane-anchored interleukins (IL) such as IL-2 and IL-4 co-presented as Cytokine-bearing Influenza Vaccines (CYT-IVACs) using a mouse model of influenza challenge. Findings Here, we describe studies evaluating the parenteral and mucosal adjuvanticity of membrane-bound IL-12 and IL-23 CYT-IVACs in young adult mice. Mucosal immunization using IL-12 and IL-23 bearing whole influenza virus vaccine (WIV) was more effective at eliciting virus-specific nasal IgA and reducing viral lung burden following challenge compared to control WIV vaccinated animals. Both IL-12 and IL-23 bearing WIV elicited the highest anti-viral IgA levels in serum and nasal washes. Conclusions This study highlights for the first time the mucosal adjuvant potential of IL-12 and IL-23 CYT-IVAC formulations in eliciting mucosal immune responses and reducing viral lung burden. The co-presentation of immunomodulators in direct context with viral antigen in whole inactivated viral vaccines may provide a means to significantly lower the dose of vaccine required for protection.
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    Modulation of Alphaviruses by Small RNAs
    Morazzani, Elaine M. (Virginia Tech, 2011-08-31)
    Mosquito-borne diseases remain a significant burden on global public health. Maintenance of mosquito-borne viruses in nature requires a biological transmission cycle that involves alternating virus replication in a susceptible vertebrate and mosquito host. Although infection of the vertebrate host is acute and often associated with disease, continual transmission of these viruses in nature depends on the establishment of a persistent, nonpathogenic infection in the mosquito vector. It is well known that invertebrates rely on small RNA pathways as an adaptive antiviral defense. The canonical antiviral response in these organisms involves dicer enzymes that cleave viral double-stranded RNA replicative intermediates (RIs) into small interfering RNAs (siRNAs; ~21-24 nucleotides). One strand of the siRNA duplex guides the targeting and destruction of complementary viral RNAs when loaded and retained in a multi-protein complex called the RNA-induced silencing complex. Here, we show that mosquito vectors mount a redundant double defense against virus infection mediated by two different small RNA pathways. Specifically, we demonstrate that in addition to a canonical antiviral response mediated by siRNAs, virus infection of the mosquito soma also triggers an antiviral immune pathway directed by ping-pong-dependent PIWI-interacting RNAs (piRNAs; ~24-30 nucleotides). The complexity of mosquito antiviral immunity has important implications for understanding how viruses both induce and modulate RNA-silencing responses in mosquito vectors. In mammals, viral RIs induce a range of relatively nonspecific antiviral responses. However, it remains unclear if viral RIs also trigger RNA silencing in mammals. Mosquito-borne viruses represent an ideal model for addressing this question as their transmission cycles involve alternating replication in mammalian and invertebrate hosts. Although we report identifying a subset of virus-derived small RNAs that appear to be products of RNA silencing in two mammalian cell lines infected with the mosquito-borne chikungunya virus (CHIKV), our studies suggest these small RNAs have little biological relevance in combating virus infections. Thus, while the accumulation of virus-derived siRNAs is essential to the survival of mosquitoes infected with CHIKV, they appear to have little functional significance in mammalian antiviral immunity.
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    New tools for the study of virus-vector interactions in mosquitoes
    Wiley, Michael R. (Virginia Tech, 2012-01-16)
    Mosquito-borne diseases continue to be a burden to global health. The viruses that cause these diseases are maintained in nature through a biological transmission cycle involving susceptible vertebrate and mosquito hosts. While knowledge of the interactions occurring between mosquito-borne viruses and vertebrates is considerable, much less is known about the interactions of these viruses with their disease vectors. Studies with Drosophila melanogaster have been important in understanding how insects respond to viral infections. However, mosquitoes and the viruses they vector have co-evolved during a long period of time. Unfortunately, many of the genetic advantages of a fly model are not available when working with mosquitoes. Nevertheless, a sequenced genome, and molecular tools such as high-throughput sequencing and RNAi knockdown are helping to bridge these gaps. Here we describe several additional tools for the study of virus-vector interactions in the mosquito.
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    The Omental Fat Band as an Immunomodulatory Microenvironment for Ovarian Cancer
    Cohen, Courtney A. (Virginia Tech, 2013-06-11)
    Cancer research is evolving. Historically concerned with the mechanisms by which malignant cells circumvent cell death signaling and maintain unchecked proliferation, focus has shifted to the complex interactions between the tumor cell and the surrounding microenvironment. Ovarian cancer has one of the highest incidence-to-death ratios of all cancers, and is typically asymptomatic until the later stages, often resulting in metastasis prior to discovery. Naturally occurring phenotypes like lactation and child-bearing (parity) reduce ovarian cancer incidence, but the mechanisms are not understood. As the primary site for ovarian cancer metastasis, and a secondary lymphoid organ capable of mounting potent innate and adaptive immune responses, we believe the omental fat band (OFB) provides a unique opportunity to study complex interactions within the tumor microenvironment. Additionally, we hypothesize that once understood, leukocyte populations within the OFB could be modulated to disrupt the pro-tumorigenic cascade. Using fluorescence-activated cell sorting (FACS) and quantitative realtime PCR (qRT-PCR), we comparatively evaluated the changes in the compositional immune profile of the OFB as a result of parity and cancer. Parous mice were associated with a reduction in macrophages and neutrophils in the OFB, resulting in an inherent "protective state" that was refractory to metastatic cancer cell growth after intraperitoneal implantation. This indicates that the leukocyte populations within the   OFB play an important role in tumor development. Therefore we utilized the potent TH1-type immunomodulatory cytokine IL-12 in a membrane-bound form to circumvent reported side effects, such as hepatic and renal damage, cardiotoxicity and death. Targeted IL-12 delivery to the OFB resulted in delayed disease development, although not protection from subsequent challenge. This was also associated with a reduction tumor-associated macrophages (TAMs) and neutrophils (TANs) within the OFB. Kinetic studies demonstrated that these changes were induced by a significant reduction in neutrophil and macrophage chemoattractants early on in the pro-tumorigenic cascade (7 days post-implantation). This work demonstrates that the OFB is a functionally plastic tissue that can be harnessed and re-mobilized to display an anti-tumorigenic microenvironment.
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    The Parity-Associated Microenvironmental Niche in the Omental Fat Band Is Refractory to Ovarian Cancer Metastasis
    Cohen, Courtney A.; Shea, Amanda A.; Heffron, C. Lynn; Schmelz, Eva M.; Roberts, Paul C. (American Association for Cancer Research, 2013-09-10)
    Ovarian cancer is an insidious and aggressive disease of older women, typically undiscovered prior to peritoneal metastasis due to its asymptomatic nature and lack of early detection tools. Epidemiological studies suggest that child-bearing (parity) is associated with decreased ovarian cancer risk, although the molecular mechanisms responsible for this phenomenon have not been delineated. Ovarian cancer preferentially metastasizes to the omental fat band (OFB), a secondary lymphoid organ that aids in filtration of the peritoneal serous fluid (PSF) and helps combat peritoneal infections. In the present study we assessed how parity and age impact the immune compositional profile in the OFB of mice, both in the homeostatic state and as a consequence of peritoneal implantation of ovarian cancer. Using fluorescence-activated cell sorting analysis and quantitative realtime PCR, we found that parity was associated with a significant reduction in omental monocytic subsets and B1-B lymphocytes, correlating with reduced homeostatic expression levels of key chemoattractants and polarization factors (Ccl1, Ccl2, Arg1, Cxcl13). Of note, parous animals exhibited significantly reduced tumor burden following intraperitoneal implantation compared to nulliparous animals. This was associated with a reduction in tumor-associated neutrophils and macrophages, as well as in the expression levels of their chemoattractants (Cxcl1, Cxcl5) in the OFB and PSF. These findings define a pre-existing "parity-associated microenvironmental niche" in the OFB that is refractory to metastatic tumor seeding and outgrowth. Future studies designed to manipulate this niche may provide a novel means to mitigate peritoneal dissemination of ovarian cancer.
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    Regulation of Cytoskeleton Organization by Sphingosine in a Mouse Cell Model of Progressive Ovarian Cancer
    Creekmore, Amy L.; Heffron, C. Lynn; Brayfield, Bradley P.; Roberts, Paul C.; Schmelz, Eva M. (MDPI, 2013-07-16)
    Ovarian cancer is a multigenic disease and molecular events driving ovarian cancer progression are not well established. We have previously reported the dysregulation of the cytoskeleton during ovarian cancer progression in a syngeneic mouse cell model for progressive ovarian cancer. In the present studies, we investigated if the cytoskeleton organization is a potential target for chemopreventive treatment with the bioactive sphingolipid metabolite sphingosine. Long-term treatment with non-toxic concentrations of sphingosine but not other sphingolipid metabolites led to a partial reversal of a cytoskeleton architecture commonly associated with aggressive cancer phenotypes towards an organization reminiscent of non-malignant cell phenotypes. This was evident by increased F-actin polymerization and organization, a reduced focal adhesion kinase expression, increased a-actinin and vinculin levels which together led to the assembly of more mature focal adhesions. Downstream focal adhesion signaling, the suppression of myosin light chain kinase expression and hypophosphorylation of its targets were observed after treatment with sphingosine. These results suggest that sphingosine modulate the assembly of actin stress fibers via regulation of focal adhesions and myosin light chain kinase. The impact of these events on suppression of ovarian cancer by exogenous sphingosine and their potential as molecular markers for treatment efficacy warrants further investigation.
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    Reverse Genetics-based Approaches to Attenuate Porcine Reproductive and Respiratory Syndrome Virus (PRRSV)
    Ni, Yanyan (Virginia Tech, 2013-11-01)
    Porcine reproductive and respiratory syndrome virus (PRRSV) is arguably the most economically-important swine pathogen. As the emergences of novel virulent strains of PRRSV continue to occur worldwide, rapid vaccine development is the key for effective control of ongoing PRRSV outbreaks. With the availability of the PRRSV reverse genetics systems, rapid vaccine development against PRRSV through the manipulation of the reverse genetics becomes feasible. To facilitate the vaccine development effort and study of PRRSV genes, we first established a DNA-launched infectious clone of the passage 14 PRRSV strain VR2385, pIR-VR2385-CA, and identified a spontaneous 435-bp deletion in the nsp2 gene. To characterize the biological and pathological significance of this nsp2 deletion, we restored deleted nsp2 sequence back to pIR-VR2385-CA and constructed another clone pIR-VR2385-R. VR2385-CA and VR2385-R were successfully rescued in vitro. The results from this study indicates that the spontaneous nsp2 deletion plays a role for enhanced PRRSV replication in vitro but has no significant effect on the pathogenicity of the virus. With the availability of the DNA-launched infectious clone of PRRSV, we successfully applied the molecular breeding approach to rapidly attenuate PRRSV. The GP5 envelope genes of 7 genetically divergent PRRSV strains and the GP5-M genes of 6 different PRRSV strains were molecularly bred. DS722 with shuffled GP5 genes and DS5M3 with shuffled GP5-M genes, were successfully rescued in vitro and shown to be attenuated both in vitro and in vivo. Furthermore, DS722, but not DS5M3, still elicit similar protection against PRRSV challenge as its parental virus. This study reveals a unique approach through DNA shuffling of viral envelope genes to attenuate a positive-strand RNA virus. We subsequently utilized the novel synthetic attenuated virus engineering (SAVE) approach to attenuate PRRSV. The GP5 and nsp9 genes of PRRSV were codon-pair deoptimized with the aid of a computer algorithm. SAVE5 and SAVE9 with deoptimized GP5 gene and SAVE9 with deoptimized nsp9 gene, were successfully rescued and shown to be attenuated in vitro. An in vivo pathogenicity study indicated the attenuation of SAVE5 virus in vivo. The results have important implications for rapid vaccine development against PRRSV and other important viruses.