Prevention of cytomegalovirus infection-enhanced experimental obliterative bronchiolitis by antiviral prophylaxis or immunosuppression in rat tracheal allografts.

In this study, the prevention of rat cytomegalovirus (RCMV) infection-enhanced experimental obliterative bronchiolitis in rat tracheal allografts was investigated. RCMV infection markedly enhanced cell proliferation and histological changes of obliterative bronchiolitis, a form of chronic rejection after lung transplantation. These alterations were linked to increased interleukin (IL)-2 and tumor necrosis factor-alpha (TNF-alpha) immunoreactivity, and reduction of IL-10 expression. In recipient rats with acute RCMV infection, prophylaxis with either ganciclovir (DHPG) or hyperimmune serum (HIS) totally prevented RCMV infection-enhanced tracheal occlusion. DHPG treatment initiated during acute RCMV infection also reduced lesion development but markedly less than DHPG prophylaxis. Treatment of acute RCMV infection with HIS alone or in combination with DHPG had no significant effect on tracheal occlusion. Inhibition of the transcription of cytokines by high doses of cyclosporine A significantly reduced RCMV infection-enhanced tracheal obliteration. In rats with chronic RCMV infection, obliterative alterations were prevented by DHPG prophylaxis initiated at the time of transplantation. Prophylaxis either with DHPG or HIS did not affect the amount of infectious RCMV recovered from host salivary glands, nor were there differences seen in RCMV major immediate early DNA expression in tracheal allografts between different antiviral drug regimens. Immunohistochemical analysis of allografts revealed that inhibition of tracheal occlusion by antiviral prophylaxis was associated with a reduction in the number of ED1(+) macrophages and cells staining for Th1 cytokines and TNF-alpha, while immune modulation by cyclosporine A up-regulated IL-10 production. In conclusion, the results of the present study suggest that the CMV infection-enhanced chronic rejection develops independently of viral load but requires both immune activation and simultaneous CMV gene expression beyond immediate early genes.

Role of nitric oxide in experimental obliterative bronchiolitis (chronic rejection) in the rat.

The role of nitric oxide in obliterative bronchiolitis development, i.e., chronic rejection, was investigated in the heterotopic rat tracheal allograft model. An increase in the intragraft inducible nitric oxide synthase (iNOS) mRNA and mononuclear inflammatory cell iNOS immunoreactivity was demonstrated during progressive loss of respiratory epithelium and airway occlusion in nontreated allografts compared to syngeneic grafts. In nontreated allografts, however, intragraft nitric oxide production was decreased, most likely because of loss of iNOS epithelial expression. Treatment with aminoguanidine, a preferential inhibitor of inducible nitric oxide synthase, was associated with enhanced proliferation of alpha-smooth muscle actin immunoreactive cells and the intensity of obliterative bronchiolitis early after transplantation. Aminoguanidine treatment did not affect iNOS mRNA synthesis or intragraft nitric oxide production, but decreased iNOS immunoreactivity in smooth muscle cells. Treatment with L-arginine, a precursor of nitric oxide, significantly reduced obliterative changes. L-arginine supplementation enhanced intragraft iNOS mRNA synthesis and iNOS immunoreactivity in capillary endothelial and smooth muscle cells as well as intragraft nitric oxide production. Immunohistochemical analysis of allografts showed that neither iNOS inhibition nor supplementation of the nitric oxide pathway affected the number of graft-infiltrating CD4+ and CD8+ T cells, ED1+ and ED3+ macrophages, immune activation with expression of IL-2R or MHC class II, or production of macrophage or Th1 cytokines. In contrast, L-arginine treatment was associated with increased staining for Th2 cytokines IL-4 and IL-10. In conclusion, this study demonstrates that nitric oxide has a protective role in obliterative bronchiolitis development in this model, and suggests that nitric oxide either directly or indirectly inhibits smooth muscle cell proliferation and modulates immune response towards Th2 cytokines.