Leukotriene B4-receptor-1 mediated host response shapes gut microbiota and controls colon tumor progression.

Inflammation and infection are key promoters of colon cancer but the molecular interplay between these events is largely unknown. Mice deficient in leukotriene B4 receptor1 (BLT1) are protected in inflammatory disease models of arthritis, asthma and atherosclerosis. In this study, we show that BLT1-/- mice when bred onto a spontaneous tumor (ApcMin/+) model displayed an increase in the rate of intestinal tumor development and mortality. A paradoxical increase in inflammation in the tumors from the BLT1-/-ApcMin/+ mice is coincidental with defective host response to infection. Germ-free BLT1-/-ApcMin/+ mice are free from colon tumors that reappeared upon fecal transplantation. Analysis of microbiota showed defective host response in BLT1-/- ApcMin/+ mice reshapes the gut microbiota to promote colon tumor development. The BLT1-/-MyD88-/- double deficient mice are susceptible to lethal neonatal infections. Broad-spectrum antibiotic treatment eliminated neonatal lethality in BLT1-/-MyD88-/- mice and the BLT1-/-MyD88-/-ApcMin+ mice are protected from colon tumor development. These results identify a novel interplay between the Toll-like receptor mediated microbial sensing mechanisms and BLT1-mediated host response in the control of colon tumor development.

T cell-mediated antitumor immune response eliminates skin tumors induced by mouse papillomavirus, MmuPV1.

Previous studies of naturally occurring mouse papillomavirus (PV) MmuPV1-induced tumors in B6.Cg-Foxn1nu/nu mice suggest that T cell deficiency is necessary and sufficient for the development of such tumors. To confirm this, MmuPV1-induced tumors were transplanted from T cell-deficient mice into immunocompetent congenic mice. Consequently, the tumors regressed and eventually disappeared. The elimination of MmuPV1-infected skin/tumors in immunocompetent mice was consistent with the induction of antitumor T cell immunity. This was confirmed by adoptive cell experiments using hyperimmune splenocytes collected from graft-recipient mice. In the present study, such splenocytes were injected into T cell-deficient mice infected with MmuPV1, and they eliminated both early-stage and fully formed tumors. We clearly show that anti-tumor T cell immunity activated during tumor regression in immunocompetent mice effectively eliminates tumors developing in T cell-deficient congenic mice. The results corroborate the notion that PV-induced tumors are strongly linked to the immune status of the host, and that PV antigens are major anti-tumor antigens. Successful anti-PV T cell responses should, therefore, lead to effective anti-tumor immune therapy in human PV-infected patients.

MmuPV1 infection and tumor development of T cell-deficient mice is prevented by passively transferred hyperimmune sera from normal congenic mice immunized with MmuPV1 virus-like particles (VLPs).

Infection by mouse papillomavirus (PV), MmuPV1, of T cell-deficient, B6.Cg-Foxn1(nu)/J nude mice revealed that four, distinct squamous papilloma phenotypes developed simultaneously after infection of experimental mice. Papillomas appeared on the muzzle, vagina, and tail at or about day 42days post-inoculation. The dorsal skin developed papillomas and hair follicle tumors (trichoblastomas) as early as 26days after infection. Passive transfer of hyperimmune sera from normal congenic mice immunized with MmuPV1 virus-like particles (VLPs) to T cell-deficient strains of mice prevented infection by virions of experimental mice. This study provides further evidence that T cell deficiency is critical for tumor formation by MmuPV1 infection.

Epidemiological and phylogenetic analysis of institutional mouse parvoviruses.

Mouse parvoviruses (MPVs) are small, single-stranded, 5 kb DNA viruses that are subclinical and endemic in many laboratory mouse colonies. MPVs cause more distinctive deleterious effects in immune-compromised or genetically-engineered mice than immuno-competent mice. At the University of Louisville (U of L), there was an unexpected increase of MPV sero-positivity for MPV infections in mouse colonies between January 2006 and February 2007, resulting in strategic husbandry changes aimed at controlling MPV spread throughout the animal facility. To investigate these MPVs, VP2 genes of seven MPVs were cloned and sequenced from eight documented incidences by PCR technology. The mutations in these VP2 genes were compared to those found at the Genbank database (NCBI; http://www.ncbi.nlm.nih.gov) and an intra-institutional phylogenetic tree for MPV infections at U of L was constructed. We discovered that the seven MPV isolates were different from those in Genbank and were not identical to each other. These MPVs were designated MPV-UL1 to 7; none of them were minute virus of mice (MVMs). Four isolates could be classified as MPV1, one was classified as MPV2, and two were defined as novel types with less than 96% and 94% homology with existing MPV types. Considering that all seven isolates had mutations in their VP2 genes and no mutations were observed in VP2 genes of MPV during a four-month time period of incubation, we concluded that all seven MPVs isolated at U of L between 2006 and 2007 probably originated from different sources. Serological survey for MPV infections verified that each MPV outbreak was controlled without further contamination within the institution.

Host gene expression signatures discriminate between ferrets infected with genetically similar H1N1 strains.

Different respiratory viruses induce virus-specific gene expression in the host. Recent evidence, including those presented here, suggests that genetically related isolates of influenza virus induce strain-specific host gene regulation in several animal models. Here, we identified systemic strain-specific gene expression signatures in ferrets infected with pandemic influenza A/California/07/2009, A/Mexico/4482/2009 or seasonal influenza A/Brisbane/59/2007. Using uncorrelated shrunken centroid classification, we were able to accurately identify the infecting influenza strain with a combined gene expression profile of 10 selected genes, independent of the severity of disease. Another gene signature, consisting of 7 genes, could classify samples based on lung pathology. Furthermore, we identified a gene expression profile consisting of 31 probes that could classify samples based on both strain and severity of disease. Thus, we show that expression-based analysis of non-infected tissue enables distinction between genetically related influenza viruses as well as lung pathology. These results open for development of alternative tools for influenza diagnostics.