Jodi M. Wilkowski

MCP-1 protects mice in lethal endotoxemia.

The overzealous production of proinflammatory cytokines in sepsis can result in shock, multiorgan dysfunction, and even death. In this study, we assessed the role of monocyte chemoattractant protein-1 (MCP-1) as a mediator of sepsis in endotoxin-challenged mice. Intraperitoneal administration of LPS to CD-1 mice induced a substantial time-dependent increase in MCP-1 in plasma, lung, and liver. The passive immunization of mice with rabbit antimurine MCP-1 antiserum 2 h before endotoxin administration resulted in a striking increase in LPS-induced mortality from 10% in control animals to 65% in anti-MCP-1-treated animals. Importantly, the administration of anti-MCP-1 antibodies to endotoxin-challenged mice resulted in increases in peak TNF-alpha and IL-12 levels, and also in a trend toward decreased serum levels of IL-10. Conversely, the administration of recombinant murine MCP-1 intraperitoneally significantly protected mice from endotoxin-induced lethality, and resulted in an increase in IL-10 levels, a decrease in IL-12 levels, and a trend toward decreased levels of TNF. In conclusion, our findings indicate that MCP-1 is a protective cytokine expressed in murine endotoxemia, and does so by shifting the balance in favor of antiinflammatory cytokine expression in endotoxin-challenged animals.

Anti-interleukin-12 therapy protects mice in lethal endotoxemia but impairs bacterial clearance in murine Escherichia coli peritoneal sepsis

The overzealous production of proinflammatory cytokines in sepsis can result in shock, multiorgan dysfunction, and even death. In this study we assessed the role of endogenously produced interleukin (IL)-12 in murine models of endotoxemia and Gram-negative peritoneal sepsis. Initial studies indicated that intraperitoneal lipopolysaccharide (LPS) administration to mice induced a significant time-dependent increase in plasma, lung, and liver IL-12 levels. Passive immunization with anti-IL-12 serum intraperitoneally before LPS resulted in a marked reduction in plasma levels of tumor necrosis factor and interferon-γ. Furthermore, we observed an increase in endotoxin-induced mortality in mice transiently overexpressing murine IL-12 using a recombinant adenoviral vector (Ad5 mIL-12) administered intraperitoneally. Neutralization of tumor necrosis factor or interferon-γ in animals overexpressing IL-12 resulted in significant reductions in LPS-induced mortality, suggesting that the mechanism whereby IL-12 increases LPS-induced mortality is primarily mediated by the enhancement of these cytokines. In contrast, we observed no survival benefit in animals passively immunized with anti-IL-12 serum before the intraperitoneal administration of 2 x 108 live Escherichia coli. Interestingly, there was an approximately 70-fold increase in peritoneal fluid E. coli colony-forming units and the early onset of bacteremia in animals treated with anti-IL-12 serum, as compared with control animals. These results indicate that IL-12 is produced in response to LPS exposure, and the neutralization of this cytokine improves survival in endotoxin-challenged animals. However, IL-12 represents an essential component of antibacterial host defense, as anti-IL-12 therapy results in significant impairment in the hosts ability to clear Gram-negative bacterial infection.

INTRAPULMONARY TUMOR NECROSIS FACTOR GENE THERAPY INCREASES BACTERIAL CLEARANCE AND SURVIVAL IN MURINE GRAM-NEGATIVE PNEUMONIA

Tumor necrosis factor alpha (TNF) has been shown to be an essential cytokine mediator of innate immunity in bacterial pneumonia. To augment the expression of TNF within the lung, a recombinant adenoviral vector containing the murine TNF cDNA (Ad5mTNF) has been developed, and the intratracheal administration of this vector resulted in the dose- and time-dependent expression of TNF in the lung, but not systemically. Administration of Ad5mTNF resulted in significant airspace and peribronchial inflammation, with a predominant neutrophil influx by 2 days, and mononuclear cell infiltrates by 4 to 7 days posttreatment. Importantly, the administration of Ad5mTNF at a dose of 1 x 10(8) PFU significantly improved the survival of animals challenged concomitantly with Klebsiella pneumoniae, which occurred in association with enhanced clearance of bacteria from the lung and decreased dissemination of K. pneumoniae to the bloodstream. However, the delivery of higher doses of Ad5mTNF (5 x 10(8) PFU) was not beneficial and in fact the intratracheal administration of a similar dose of control vector (Ad5LacZ) actually enhanced Klebsiella-induced lethality by impairing clearance of K. pneumoniae from the lung. Our studies suggests that the transient transgenic expression of TNF within the lung dose dependently augments antibacterial host defense in murine Klebsiella pneumonia.

Dissection of complex adult traits in a mouse synthetic population

Finding the causative genetic variations that underlie complex adult traits is a significant experimental challenge. The unbiased search strategy of genome-wide association (GWAS) has been used extensively in recent human population studies. These efforts, however, typically find only a minor fraction of the genetic loci that are predicted to affect variation. As an experimental model for the analysis of adult polygenic traits, we measured a mouse population for multiple phenotypes and conducted a genome-wide search for effector loci. Complex adult phenotypes, related to body size and bone structure, were measured as component phenotypes, and each subphenotype was associated with a genomic spectrum of candidate effector loci. The strategy successfully detected several loci for the phenotypes, at genome-wide significance, using a single, modest-sized population (N = 505). The effector loci each explain 2%-10% of the measured trait variation and, taken together, the loci can account for over 25% of a traits total population variation. A replicate population (N = 378) was used to confirm initially observed loci for one trait (femur length), and, when the two groups were merged, the combined population demonstrated increased power to detect loci. In contrast to human population studies, our mouse genome-wide searches find loci that individually explain a larger fraction of the observed variation. Also, the additive effects of our detected mouse loci more closely match the predicted genetic component of variation. The genetic loci discovered are logical candidates for components of the genetic networks having evolutionary conservation with human biology.