MACROPHAGE IN THE DEVELOPMENT OF EXPERIMENTAL CRESCENTIC GLOMERULONEPHRITIS - STUDIES USING TISSUE-CULTURE AND ELECTRON-MICROSCOPY

Abstract

The role played by the macrophage in the development of injury in rabbit nephrotoxic nephritis (NTN) was assessed by EM and glomerular culture of renal tissue obtained by several biopsies during the course of the disease. These observations were correlated with the other immune, cellular, and biochemical events occurring in the glomerulus, i.e., deposition of immunoglobulin and complement, proteinuria, polymorphonuclear leukocyte (PMN) exudation, fibrin deposition, crescent formation, and renal failure. A biphasic macrophage accumulation was detected, corresponding to the heterologous and autologous phases of the disease. In the autologous or crescentic phase, macrophages accumulated within the glomerular tuft from Day 5; their appearance coincided with the accumulation of PMN and development of proteinuria. Fibrin deposition in Bowman''s space, which commenced on Days 6 and 7, was rapidly followed by the migration of macrophages from the glomeruli into Bowman''s space. Within Bowman''s space, macrophages were observed to phagocytose fibrin, transform into epithelioid and giant cells, and accumulate to form a substantial proportion of the cells forming the crescent. The inflammatory process of PMN exudation, macrophage accumulation, fibrin deposition, and crescent formation and the degree of renal failure reached a maximum by Days 12 to 14. Thereafter, resolution of the inflammatory process occurred so that by Day 40 macrophages had disappeared from the glomeruli. Varying degrees of glomerular damage and renal failure persisted, occurring largely as a result of glomerulosclerosis and sclerosis of crescents. The tissue culture studies also demonstrated mesangial cell proliferation during the inflammatory process but did not show any abnormality of epithelial cell activity. The macrophages participate in NTN by accumulating in damaged glomeruli then migrating into Bowman''s space (probably in response to fibrin deposition) where they undergo granulomatous transformation and accumulate, contributing to crescent formation.