2C) 5, but was completely absent on retinal inflammatory macropha

2C) 5, but was completely absent on retinal inflammatory macrophages in peak stage EAU; remarkably, CRIg expression on macrophage returned and in increase amounts in the resolving stages of EAU (Fig. 2F). Whether this change in expression was due to reprogramming of resident macrophages or represented de novo recruitment EPZ 6438 of macrophages at different stages of disease is unclear. What

is clear is that CRIg+ macrophages may belong to the “suppressive” variety of macrophage and may play important roles in tissue homeostasis. They may also be involved in the resolution of inflammation probably by promoting the clearance of apoptotic cells 21, 23. One of the homeostatic roles of the choroidal CRIg+ macrophage might be to prevent tissue overt complement activation. When the tissue is inflamed (such as in EAU), tissue-resident CRIg+ macrophages are quickly consumed or negatively regulated

by inflammatory cytokines, and the newly recruited macrophages do selleck screening library not express CRIg. The lack of CRIg molecules allows complement activation proceeding uncontrolled in EAU. When exogenously administering the soluble form of CRIg i.e. CRIg-FC, complement activation is blocked resulting in reduced C3a/C5a production, which may indirectly affect inflammatory cytokine production. It is also possible that CRIg-Fc may inhibit pro-inflammatory CRIg− macrophages and suppress NO, TNF-α, and other mediators including complement components (such

as CFB) production. The effect of CRIg-Fc on Th1/Th17 cytokine production observed in this study may be indirectly resulted from the suppression of the pro-inflammatory macrophage activation, or C5a production (as a result of reduced complement activation). Further mechanistic studies on the suppressive effect of CRIg-Fc on macrophages and dendritic cells, the possible unknown receptors for CRIg-Fc, and the signalling pathways will be important to understand the immune regulation roles of CRIg and such experiments are undergoing in the investigators’ laboratory. In summary, in this study we show that the AP complement activation plays detrimental roles in retinal pathology. Blocking AP-mediated complement activation with CRIg-Fc reduces retinal inflammation. CRIg-Fc not only selectively blocks the AP complement activation, but also suppresses inflammatory macrophage function and reduces crotamiton disease severity in EAU. CRIg-Fc could be a good candidate for uveitis therapy. Female C57BL/6 mice, 8- to 12-wk old, 18–24 g, were supplied by the Medical Research Facility of the University of Aberdeen (Scotland, UK). All animals were managed in accordance with the Association for Research in Vision and Ophthalmology Statement for the Use of Animals in Ophthalmic and Vision Research (Rockville, MI) and under the Home Office Regulations for Animal Experimentation (UK). The animal work was approved by the Ethic Committee of the University of Aberdeen.

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