Pathogenic roles of CD14, galectin-3, and OX40 during experimental cerebral malaria in mice.

An in-depth knowledge of the host molecules and biological pathways that contribute towards the pathogenesis of cerebral malaria would help guide the development of novel prognostics and therapeutics. Genome-wide transcriptional profiling of the brain tissue during experimental cerebral malaria (ECM ) caused by Plasmodium berghei ANKA parasites in mice, a well established surrogate of human cerebral malaria, has been useful in predicting the functional classes of genes involved and pathways altered during the course of disease. To further understand the contribution of individual genes to the pathogenesis of ECM, we examined the biological relevance of three molecules -- CD14, galectin-3, and OX40 that were previously shown to be overexpressed during ECM. We find that CD14 plays a predominant role in the induction of ECM and regulation of parasite density; deletion of the CD14 gene not only prevented the onset of disease in a majority of susceptible mice (only 21% of CD14-deficient compared to 80% of wildtype mice developed ECM, p<0.0004) but also had an ameliorating effect on parasitemia (a 2 fold reduction during the cerebral phase). Furthermore, deletion of the galectin-3 gene in susceptible C57BL/6 mice resulted in partial protection from ECM (47% of galectin-3-deficient versus 93% of wildtype mice developed ECM, p<0.0073). Subsequent adherence assays suggest that galectin-3 induced pathogenesis of ECM is not mediated by the recognition and binding of galectin-3 to P. berghei ANKA parasites. A previous study of ECM has demonstrated that brain infiltrating T cells are strongly activated and are CD44(+)CD62L(-) differentiated memory T cells [1]. We find that OX40, a marker of both T cell activation and memory, is selectively upregulated in the brain during ECM and its distribution among CD4(+) and CD8(+) T cells accumulated in the brain vasculature is approximately equal.

Cellular inflammatory response to flaviviruses in the central nervous system of a primate host.

Flaviviruses such as tick-borne encephalitis virus, Japanese encephalitis virus, West Nile virus, and St. Louis encephalitis virus are important neurotropic human pathogens, typically causing a devastating and often fatal neuroinfection. Flaviviruses induce neuroinflammation with typical features of viral encephalitides, including inflammatory cell infiltration, activation of microglia, and neuronal degeneration. Development of safe and effective live-virus vaccines against neurotropic flavivirus infections demands a detailed knowledge of their neuropathogenesis in a primate host that is evolutionarily close to humans. Here, we used computerized morphometric analysis to quantitatively assess the cellular inflammatory responses in the central nervous system (CNS) of rhesus monkeys infected with three antigenically divergent attenuated flaviviruses. The kinetics, spatial pattern, and magnitude of microglial activation, trafficking of T and B cells, and changes in T cell subsets within the CNS define unique phenotypic signatures for each of the three viruses. Our results provide a benchmark for investigation of cellular inflammatory responses induced by attenuated flaviviruses in the CNS of primate hosts and provide insight into the neuropathogenesis of flavivirus encephalitis that might guide the development of safe and effective live-virus vaccines.

Naturally occurring murine norovirus infection in a large research institution.

Murine norovirus (MNV) is a recently discovered infectious agent in mice and may be the most common naturally occurring infection of laboratory mice in North America. In 2005, we surveyed the Swiss Webster female sentinel mice in our institute's research facilities. Of the 4 facilities surveyed, 3 had sentinel mice that were positive for MNV antibodies, whereas our largest facility (which only receives mice directly from select vendors or by embryo rederivation directly into the facility) was apparently MNV-free. However, testing of sentinel mice in this large facility 1 y later found that 2% of the animals had developed MNV-specific antibodies. In a recently opened fifth facility, a serologic survey in 2006 identified MNV-antibody-positive Tac:SW sentinel mice that had received bedding from experimental mice on the same rack quadrant. Reverse transcription- polymerase chain reaction analysis of feces from the cages of these mice showed evidence for shedding of MNV. These sentinel mice were used to study the fecal excretion, antibody development, gross lesions upon necropsy, histopathology, and immunohistochemistry of the viral infection. None of the MNV-antibody-positive sentinel mice exhibited clinical signs or gross lesions, but these mice excreted virus in feces and developed antibodies to MNV. Histopathologic lesions consisted only of a few hepatic inflammatory foci in each liver section, some of which were immunoreactive with antibodies to MNV. MNV viral antigens also were present in the mesenteric lymph nodes.

Immunohistochemical markers for the rodent immune system.

The responses to insults including chemical toxins, irradiation and infectious agents involve morphologic, biochemical and molecular changes in the immune system. The changes in specific tissues and cells often can be detected by histopathology and its associated field of immunohistochemistry (IHC). Cells normally express specific proteins (antigens) that can be detected by IHC. When responses to xenobiotics occur, cells often up or down regulate proteins. The art of IHC requires specialized procedures for detection of antigens. Fixation, tissue processing, immunoreactions and antigen retrieval methods are important elements of IHC. We review the antibodies, their sources, use of frozen or fixed paraffin-embedded tissues and specific IHC methods including antigen retrieval and illustrate how they can be effectively used to characterize the immunotoxicologic effects of agents.