Abstract
Organ transplantation has become a therapeutic option for the replacement of malfunctioning tissues and organs. Since the advent of the first combined heart-lung transplant in 1981, there has been a rapid growth in the popularity of lung transplantation for a number of end-stage pulmonary disorders. Interestingly, these lung transplant patients experience more complications of acute and chronic allograft rejection compared with recipients of other solid organs. These episodes of rejection are related to a complex series of events that depend on the interaction of many cells and soluble mediators leading to cellular and tissue injury. The histopathology of lung allograft rejection has been actively studied and is associated with the sequestration of activated mononuclear phagocytes, T and B lymphocytes. These cells secrete a number of soluble mediators, that is, cytokines, that participate in the evolution of the immune response via autocrine, paracrine, or endocrine mechanisms. The interaction of cytokines with their targets leads to cellular activation, proliferation, and differentiation. In this study, we postulated that interleukin-6 (IL-6) may have a central role in the pathogenesis of acute lung allograft rejection. To test this hypothesis, we employed an unmodified RT1-incompatible rat lung allograft model and assessed the time course and major tissue compartment(s) of IL-6 production during the evolution of lung allograft rejection. The expression and production of IL-6 during the pathogenesis of lung allograft rejection was measured at the whole-animal, organ, cellular, and molecular levels. The expression of IL-6 was found to be bimodal in character, initially related to the reimplantation response and finally to the maximal allograft rejection. In contrast to the bimodal expression of IL-6 in the allogeneic transplant, IL-6 production measured from syngeneic control lung isografts was maximal only during the reimplantation period. Interestingly, plasma levels of IL-6 from lung allograft recipients failed to display a bimodal pattern of expression. These findings support the compartmentalized production of IL-6 to the lung during allograft rejection and may provide interesting insight into the use of novel and specific therapeutic interventions during periods of lung allograft rejection.