Kathleen M. Shields

IL-22 Induces an Acute-Phase Response

IL-22 is made by a unique set of innate and adaptive immune cells, including the recently identified noncytolytic NK, lymphoid tissue-inducer, Th17, and Th22 cells. The direct effects of IL-22 are restricted to nonhematopoietic cells, its receptor expressed on the surface of only epithelial cells and some fibroblasts in various organs, including parenchymal tissue of the gut, lung, skin, and liver. Despite this cellular restriction on IL-22 activity, we demonstrate that IL-22 induces effects on systemic biochemical, cellular, and physiological parameters. By utilizing adenoviral-mediated delivery of IL-22 and systemic administration of IL-22 protein, we observed that IL-22 modulates factors involved in coagulation, including fibrinogen levels and platelet numbers, and cellular constituents of blood, such as neutrophil and RBC counts. Furthermore, we observed that IL-22 induces thymic atrophy, body weight loss, and renal proximal tubule metabolic activity. These cellular and physiological parameters are indicative of a systemic inflammatory state. We observed that IL-22 induces biochemical changes in the liver including induction of fibrinogen, CXCL1, and serum amyloid A that likely contribute to the reported cellular and physiological effects of IL-22. Based on these findings, we propose that downstream of its expression and impact in local tissue inflammation, circulating IL-22 can further induce changes in systemic physiology that is indicative of an acute-phase response.

A zymogen-like factor Xa variant corrects the coagulation defect in hemophilia

Effective therapies are needed to control excessive bleeding in a range of clinical conditions. We improve hemostasis in vivo using a conformationally pliant variant of coagulation factor Xa (FXaI16L) rendered partially inactive by a defect in the transition from zymogen to active protease. Using mouse models of hemophilia, we show that FXaI16L has a longer half-life than wild-type FXa and does not cause excessive activation of coagulation. Once clotting mechanisms are activated to produce its cofactor FVa, FXaI16L is driven to the protease state and restores hemostasis in hemophilic animals upon vascular injury. Moreover, using human or murine analogs, we show that FXaI16L is more efficacious than FVIIa, which is used to treat bleeding in hemophilia inhibitor patients. FXaI16L may provide an effective strategy to enhance blood clot formation and act as a rapid pan-hemostatic agent for the treatment of bleeding conditions.Effective therapies are needed to control excessive bleeding in a range of clinical conditions. We describe a surprisingly useful approach to improve hemostasis in vivo using a variant of coagulation factor Xa (FXaI16L). This conformationally pliant derivative is partially inactive due to a defect in transitioning from zymogen to protease 1,2. Using mouse models of hemophilia, we show that FXaI16L has a prolonged half-life, relative to wild-type FXa and does not cause excessive activation of coagulation. Once clotting mechanisms are activated to produce its cofactor FVa, FXaI16L is driven to the protease state and restores hemostasis in hemophilic animals upon vascular injury. Moreover, using human or murine analogs, we show that FXaI16L is more efficacious than FVIIa which is used to treat bleeding in hemophilia inhibitor patients3. Because of its underlying mechanism of action, FXaI16L may provide an effective strategy to enhance blood clot formation and act as a rapid pan-hemostatic agent for the treatment of bleeding conditions.

A monoclonal antibody against RAGE alters gene expression and is protective in experimental models of sepsis and pneumococcal pneumonia.

The RAGE (receptor for advanced glycation end products) is believed to play a role in sepsis by perpetuating inflammation. The interaction of RAGE with a variety of host-derived ligands that accumulate during stress and inflammation further induces the expression of RAGE. It was previously shown that a rat anti-RAGE monoclonal antibody protected mice from lethality in a cecal ligation and puncture model. We studied the effects of a humanized anti-RAGE monoclonal antibody in the murine pneumococcal pneumonia model of sepsis. Moreover, a gene expression analysis was performed in lung tissue of animals that underwent cecal ligation and puncture and treated with the rat anti-RAGE monoclonal antibody, compared with controls. Administration of humanized anti-RAGE mAb 6 h after intratracheal infection with Streptococcus pneumoniae improved mortality in BALB/c mice whether a 7.5 mg/kg (P < 0.01) or a 15 mg/kg dose (P < 0.01) was administered in combination with antibiotics. Gene expression analysis showed that many of the genes modulated by treatment with the anti-RAGE antibody were those that play an important role in regulating inflammation. Anti-RAGE monoclonal antibody offered a survival advantage to septic mice. This protective role in treated animals is supported by the observed gene expression profile changes of genes involved in sepsis and inflammation.

Expression of the cysteine protease legumain in vascular lesions and functional implications in atherogenesis

OBJECTIVE The present study was conducted to characterize the expression of the cysteine protease legumain in murine and human atherosclerotic tissues, and to explore the molecular mechanisms by which legumain may contribute to the pathophysiology of atherosclerosis. METHODS AND RESULTS Using microarray analysis, legumain mRNA expression was found to increase with development of atherosclerosis in the aorta of aging Apolipoprotein E deficient mice while expression remained at low level and unchanged in arteries of age-matched C57BL/6 control mice. In situ hybridization and immunohistochemical analysis determined that legumain was predominantly expressed by macrophages in the atherosclerotic aorta, in lesions at the aortic sinus and in injured carotid arteries of Apolipoprotein E deficient mice as well as in inflamed areas in advanced human coronary atherosclerotic plaques. In vitro, M-CSF differentiated human primary macrophages were shown to express legumain and the protein could also be detected in the culture media. When tested in migration assays, legumain induced chemotaxis of primary human monocytes and human umbilical vein endothelial cells. CONCLUSIONS Legumain is expressed in both murine and human atherosclerotic lesions. The macrophage-specific expression of legumain in vivo and ability of legumain to induce chemotaxis of monocytes and endothelial cells in vitro suggest that legumain may play a functional role in atherogenesis.