Project description:Bacterial superinfections are a primary cause of death during influenza pandemics and epidemics. Type I interferon (IFN) signaling contributes to increased susceptibility of mice to bacterial superinfection around day 7 post-influenza A virus (IAV) infection. Here we demonstrate that the reduced susceptibility to methicillin-resistant Staphylococcus aureus (MRSA) at day 3 post-IAV infection, which we previously reported was due to interleukin-13 (IL-13)/IFN-? responses, is also dependent on type I IFN signaling and its subsequent requirement for protective IL-13 production. We found, through utilization of blocking antibodies, that reduced susceptibility to MRSA at day 3 post-IAV infection was IFN-? dependent, whereas the increased susceptibility at day 7 was IFN-? dependent. IFN-? signaling early in IAV infection was required for MRSA clearance, whereas IFN-? signaling late in infection was not, though it did mediate increased susceptibility to MRSA at that time. Type I IFN receptor (IFNAR) signaling in CD11c(+) and Ly6G(+) cells was required for the observed reduced susceptibility at day 3 post-IAV infection. Depletion of Ly6G(+) cells in mice in which IFNAR signaling was either blocked or deleted indicated that Ly6G(+) cells were responsible for the IFNAR signaling-dependent susceptibility to MRSA superinfection at day 7 post-IAV infection. Thus, during IAV infection, the temporal differences in type I IFN signaling increased bactericidal activity of both CD11c(+) and Ly6G(+) cells at day 3 and reduced effector function of Ly6G(+) cells at day 7. The temporal differential outcomes induced by IFN-? (day 3) and IFN-? (day 7) signaling through the same IFNAR resulted in differential susceptibility to MRSA at 3 and 7 days post-IAV infection.Approximately 114,000 hospitalizations and 40,000 annual deaths in the United States are associated with influenza A virus (IAV) infections. Frequently, these deaths are due to community-acquired Gram-positive bacterial species, many of which show increasing resistance to antibiotic therapy. Severe complications, including parapneumonic empyema and necrotizing pneumonia, can arise, depending on virulence factors expressed by either the virus or bacteria. Unfortunately, we are unable to control the expression of these virulence factors, making host responses a logical target for therapeutic interventions. Moreover, interactions between virus, host, and bacteria that exacerbate IAV-related morbidities and mortalities are largely unknown. Here, we show that type I interferon (IFN) expression can modulate susceptibility to methicillin-resistant Staphylococcus aureus (MRSA) infection, with IFN-? reducing host susceptibility to MRSA infection while IFN-? increases susceptibility. Our data indicate that treatments designed to augment IFN-? and/or inhibit IFN-? production around day 7 post-IAV infection could reduce susceptibility to deadly superinfections.

Project description:The reason why severe localized or systemic virus infections enhance and aggravate bacterial superinfection is poorly understood. Here we show that virus-induced IFN type I caused apoptosis in bone marrow granulocytes, drastically reduced granulocyte infiltrates at the site of bacterial superinfection, caused up to 1,000-fold higher bacterial titers in solid organs, and increased disease susceptibility. The finding that the innate antiviral immune response reduces the antibacterial granulocyte defense offers an explanation for enhanced susceptibility to bacterial superinfection during viral disease.

Project description:Bacterial co-infections represent a major clinical complication of influenza. Host-derived interferon (IFN) increases susceptibility to bacterial infections following influenza, but the relative roles of type-I versus type-II IFN remain poorly understood. We have used novel mouse models of co-infection in which colonizing pneumococci were inoculated into the upper respiratory tract; subsequent sublethal influenza virus infection caused the bacteria to enter the lungs and mediate lethal disease. Compared to wild-type mice or mice deficient in only one pathway, mice lacking both IFN pathways demonstrated the least amount of lung tissue damage and mortality following pneumococcal-influenza virus superinfection. Therapeutic neutralization of both type-I and type-II IFN pathways similarly provided optimal protection to co-infected wild-type mice. The most effective treatment regimen was staggered neutralization of the type-I IFN pathway early during co-infection combined with later neutralization of type-II IFN, which was consistent with the expression and reported activities of these IFNs during superinfection. These results are the first to directly compare the activities of type-I and type-II IFN during superinfection and provide new insights into potential host-directed targets for treatment of secondary bacterial infections during influenza.

Project description:Downregulation of the alveolar macrophage (AM) receptor with collagenous structure (MARCO) leads to susceptibility to postinfluenza bacterial pneumonia, a major cause of morbidity and mortality. We sought to determine whether immunomodulation of MARCO could improve host defense and resistance to secondary bacterial pneumonia. RNAseq analysis identified a striking increase in MARCO expression between days 9 and 11 after influenza infection and indicated important roles for Akt and Nrf2 in MARCO recovery. In vitro, primary human AM-like monocyte-derived macrophages (AM-MDMs) and THP-1 macrophages were treated with IFNγ to model influenza effects. Activators of Nrf2 (sulforaphane) or Akt (SC79) caused increased MARCO expression and a MARCO-dependent improvement in phagocytosis in IFNγ-treated cells and improved survival in mice with postinfluenza pneumococcal pneumonia. Transcription factor analysis also indicated a role for transcription factor E-box (TFEB) in MARCO recovery. Overexpression of TFEB in THP-1 cells led to marked increases in MARCO. The ability of Akt activation to increase MARCO expression in IFNγ-treated AM-MDMs was abrogated in TFEB-knockdown cells, indicating Akt increases MARCO expression through TFEB. Increasing MARCO expression by targeting Nrf2 signaling or the Akt-TFEB-MARCO pathway are promising strategies to improve bacterial clearance and survival in postinfluenza bacterial pneumonia.

Project description:ObjectivesAdipose tissue plays a fundamental role in glucose homeostasis. For example, fat removal (lipectomy, LipX) in lean mice, resulting in a compensatory 50% increase in total fat mass, is associated with significant improvement in glucose tolerance. This study was designed to further examine the link between fat removal, adipose tissue compensation and glucose homeostasis using a peroxisome proliferator-activated receptor ? (PPAR ?; activator of adipogenesis) knockout mouse.Material and methodsThe study involved PPAR? knockout (FKO?) or control mice (CON), subdivided into groups that received LipX or Sham surgery. We reasoned that as the ability of adipose tissue to expand in response to LipX would be compromised in FKO? mice, so would improvements in glucose homeostasis.ResultsIn CON mice, LipX increased total adipose depot mass (~60%), adipocyte number (~45%) and changed adipocyte distribution to smaller cells. Glucose tolerance was improved (~30%) in LipX CON mice compared to Shams. In FKO? mice, LipX did not result in any significant changes in adipose depot mass, adipocyte number or distribution. LipX FKO? mice were also characterized by reduction of glucose tolerance (~30%) compared to shams.ConclusionsInhibition of adipose tissue PPAR? prevented LipX-induced increases in adipocyte expansion and produced a glucose-intolerant phenotype. These data support the notion that adipose tissue expansion is critical to maintain and/or improvement in glucose homeostasis.

Project description:Peroxisome proliferator-activated receptor-? (PPAR?) has been implicated in a potent anti-inflammatory activity. However, no information is available on whether PPAR? can affect signal transducers and activator of transcription proteins (STATs) in acute liver damage. Thus, this study was aimed to investigate the in vivo role of PPAR? in elevating STATs as well as oxidative/nitrosative stress in a model of lipopolysaccharide (LPS)-induced acute hepatic inflammatory injury. Using age-matched Ppara-null and wild-type (WT) mice, we demonstrate that the deletion of PPAR? aggravates LPS-mediated liver injury through activating STAT1 and NF-?B-p65 accompanied by increased levels of pro-inflammatory cytokines. Furthermore, the activities of key anti-oxidant enzymes and mitochondrial complexes were significantly decreased while lipid peroxidation and protein nitration were elevated in LPS-exposed Ppara-null mice compared to WT. These results indicate that PPAR? is important in preventing LPS-induced acute liver damage by regulating STAT1 inflammatory signaling pathways and oxidative/nitrosative stress.

Project description:The role of TIMP3 in the context of cardiovascular remodeling is relatively unexplored when considering classical risk factors such as hypercholesterolemia, diabetes and hypertension. To learn more the role of TIMP3 in the progression of cardiovascular disease we combined genetics, metabolomics and in vivo phenotypical analysis using the hypercholesterolemic ApoE null mice to generate ApoE-/-Timp3-/- mice, the latter showing increased atherosclerosis, increased mortality and arrhythmias compared to ApoE-/- mice. We have previously described Timp3-/-mice in ( Fiorentino, L., et al., Regulation of TIMP3 in diabetic nephropathy: a role for microRNAs. Acta Diabetol, 2013) . To generate ApoE-/-Timp3-/- knockout animals we crossbred the 2 strains. Offsprings were then backcrossed into ApoE animals for 6 generations to generate a pure lineage. Collectively, metabolite profiles, gene and protein expression consistently suggested a role for TIMP3 to underlie a decreased activation of PPARα/AMPK to dampen fatty acids β-oxidation eventually leading to atherosclerotic plaque composition vulnerability and perturbation of heart metabolism. mRNA profiling in ApoE-/-Timp3-/- mice revealed a TIMP3 effect to regulate Apelin, which we found decreased in the circulation due to its specific downregulation at the myocardial level but not in other well known sites of expression such as the adipose tissue. mRNA sequencing of the heart of ApoE-/-Timp3-/- mice vs ApoE-/- littermates controls.

Project description:Histone deacetylases (HDACs) have emerged as epigenetic regulators of risk factors associated with the metabolic syndrome (MetS), and certain botanical extracts have proven to be potent HDAC inhibitors. Understanding the role of dietary procyanidins in HDAC inhibition is important in exploring the therapeutic potential of natural products.C57BL/6 mice were gavaged with vehicle (water) or grape seed procyanidin extract (GSPE, 250 mg/kg) and terminated 14 h later. Liver and serum were harvested to assess the effect of GSPE on HDAC activity, histone acetylation, Ppar? activity and target-gene expression, and serum lipid levels.GSPE increased histone acetylation and decreased Class I HDAC activity in vivo, and dose-dependently inhibited recombinant HDAC2 and 3 activities in vitro. Accordingly, Ppar? gene and phosphorylated protein expression were increased, as were target genes involved in fatty acid catabolism, suggesting increased Ppar? activity. Serum fibroblast growth factor 21 (Fgf21) was elevated, and triglyceride levels were reduced by 28%.GSPE regulates HDAC and Ppar? activities to modulate lipid catabolism and reduce serum triglycerides in vivo.

Project description:The role of TIMP3 in the context of cardiovascular remodeling is relatively unexplored when considering classical risk factors such as hypercholesterolemia, diabetes and hypertension. To learn more the role of TIMP3 in the progression of cardiovascular disease we combined genetics, metabolomics and in vivo phenotypical analysis using the hypercholesterolemic ApoE null mice to generate ApoE-/-Timp3-/- mice, the latter showing increased atherosclerosis, increased mortality and arrhythmias compared to ApoE-/- mice. We have previously described Timp3-/-mice in ( Fiorentino, L., et al., Regulation of TIMP3 in diabetic nephropathy: a role for microRNAs. Acta Diabetol, 2013) . To generate ApoE-/-Timp3-/- knockout animals we crossbred the 2 strains. Offsprings were then backcrossed into ApoE animals for 6 generations to generate a pure lineage. Collectively, metabolite profiles, gene and protein expression consistently suggested a role for TIMP3 to underlie a decreased activation of PPARα/AMPK to dampen fatty acids β-oxidation eventually leading to atherosclerotic plaque composition vulnerability and perturbation of heart metabolism. mRNA profiling in ApoE-/-Timp3-/- mice revealed a TIMP3 effect to regulate Apelin, which we found decreased in the circulation due to its specific downregulation at the myocardial level but not in other well known sites of expression such as the adipose tissue.

Project description:SARS-CoV-2 superinfection and reinfection with three different strains