Increased ferroportin-1 expression and rapid splenic iron loss occur with anemia caused by Salmonella enterica Serovar Typhimurium infection in mice.

The Gram-negative intracellular bacterium Salmonella enterica serovar Typhimurium causes persistent systemic inflammatory disease in immunocompetent mice. Following oral inoculation with S. Typhimurium, mice develop a hematopathological syndrome akin to typhoid fever with splenomegaly, microcytic anemia, extramedullary erythropoiesis, and increased hemophagocytic macrophages in the bone marrow, liver, and spleen. Additionally, there is marked loss of iron from the spleen, an unanticipated result, given the iron sequestration reported in anemia of inflammatory disease. To establish why tissue iron does not accumulate, we evaluated multiple measures of pathology for 4 weeks following oral infection in mice. We demonstrate a quantitative decrease in splenic iron following infection despite increased numbers of splenic phagocytes. Infected mice have increased duodenal expression of the iron exporter ferroportin-1, consistent with increased uptake of dietary iron. Liver and splenic macrophages also express high levels of ferroportin-1. These observations indicate that splenic and hepatic macrophages export iron during S. Typhimurium infection, in contrast to macrophage iron sequestration observed in anemia of inflammatory disease. Tissue macrophage export of iron occurs concurrent with high serum concentrations of interferon gamma (IFN-γ) and interleukin 12 (IL-12). In individual mice, high concentrations of both proinflammatory (tumor necrosis factor alpha [TNF-α]) and anti-inflammatory (IL-10) cytokines in serum correlate with increased tissue bacterial loads throughout 4 weeks of infection. These in vivo observations are consistent with previous cell culture studies and suggest that the relocation of iron from tissue macrophages during infection may contribute to anemia and also to host survival of acute S. Typhimurium infection.

Practical murine hematopathology: a comparative review and implications for research.

Hematologic parameters are important markers of disease in human and veterinary medicine. Biomedical research has benefited from mouse models that recapitulate such disease, thus expanding knowledge of pathogenetic mechanisms and investigative therapies that translate across species. Mice in health have many notable hematologic differences from humans and other veterinary species, including smaller erythrocytes, higher percentage of circulating reticulocytes or polychromasia, lower peripheral blood neutrophil and higher peripheral blood and bone marrow lymphocyte percentages, variable leukocyte morphologies, physiologic splenic hematopoiesis and iron storage, and more numerous and shorter-lived erythrocytes and platelets. For accurate and complete hematologic analyses of disease and response to investigative therapeutic interventions, these differences and the unique features of murine hematopathology must be understood. Here we review murine hematology and hematopathology for practical application to translational investigation.

Urinary MCP1 and Microalbumin increase prior to onset of Azotemia in mice with polycystic kidney disease.

Urinary biomarkers may offer a more sensitive and less invasive means to monitor kidney disease than traditional blood chemistry biomarkers such as creatinine. CD1(pcy/pcy) (pcy) mice have a slowly progressive disease phenotype that resembles human autosomal dominant polycystic kidney disease with renal cyst formation and inflammation. Previous reports suggest that dietary protein restriction may slow disease progression in mice and humans with polycystic kidney disease. Accordingly, we fed pcy mice either a standard chow (22.5% protein) or a protein-restricted (11.5% soy-based protein) diet from weaning until 34 wk of age. Every 6 wk we measured markers of kidney disease, including serum creatinine, BUN, and serum albumin as well as urinary monocyte chemoattractant protein 1 (MCP1), microalbumin, and specific gravity. Progression of kidney disease was equivalent for both diet groups despite dietary protein restriction. Urinary biomarkers proved useful for early detection of disease, in that urinary microalbumin was elevated as early as 22 wk of age and urinary MCP1 was increased by 28 wk of age, whereas increases in serum creatinine and BUN were detected later (at 34 wk of age) in both diet groups. Thus, urinary microalbumin and MCP1 analyses provided earlier, noninvasive indicators for detection of kidney disease and disease progression in pcy mice than did serum creatinine and BUN.