Putative antibody-mediated rejection with C4d deposition in HLA-identical, ABO-compatible renal allografts.

We sought evidence for non-MHC antibody-mediated rejection in renal allografts by a systematic study of rejected HLA-identical sibling renal allografts. Among 162 recipients of HLA-identical, ABO-compatible sibling donor kidneys transplanted at the Massachusetts General Hospital from 1964 to 2005, we identified 15 grafts that were lost from rejection and two additional grafts with reversible acute rejection, which provided 30 samples for study. All samples were stained for C4d by immunofluorescence in frozen tissue (n = 7) or by immunohistochemistry in paraffin embedded tissues (n = 10). We found that two of 17 grafts had positive C4d staining of peritubular capillaries. Histology revealed acute antibody-mediated rejection in one and acute cellular rejection type 1 in the other. Both grafts were matched at HLA-A, B, and C loci and had a nonreactive mixed lymphocyte response. Genotyping and serological analysis were not available. Compared with a published series, C4d+ irreversible rejection was more common in HLA nonidentical than HLA-identical grafts (75% vs 6.7%, respectively, P < .002). We conclude that antibody-mediated rejection, presumably due to non-MHC antigens other than ABO-blood groups does occur, but infrequently. This may account for some of the HLA antibody negative cases that develop antibody-mediated rejection.

In vivo class II transactivator expression in mice is induced by a non-interferon-gamma mechanism in response to local injury.

BACKGROUND: Tissue injury induces MHC class II expression, which could be important in the recognition of that tissue as an allograft. The class II transcriptional activator (CIITA) is the major regulator of basal and induced MHC class II expression and is essential for antigen presentation. The role of CIITA in the induction of class II by tissue injury is unknown. In this study, we examined CIITA induction in the course of acute ischemic or toxic renal injury in mice, including the role of interferon (IFN)-gamma and of the transcription factor, interferon regulatory factor (IRF)-1. METHODS: Kidneys were injured by ischemia or by gentamicin toxicity and were then studied for changes in gene expression using Northern blot, reverse transcriptase-polymerase chain reaction, radioimmunoassay, and tissue staining. We compared wild-type (WT) mice to IFN-gamma knockout (GKO) or IRF-1 knockout mice. RESULTS: Ischemic injury induced CIITA and class II expression in the kidney, in WT and GKO mice. Gentamicin injury also induced both CIITA and class II expression, independent of IFN-gamma, in WT and GKO mice. After ischemic injury, the induction of class II protein levels and CIITA and class II mRNA levels were induced, to a lesser degree, in IRF-1 knockout mice. CONCLUSIONS: These data indicate that CIITA is induced by tissue injury, and probably accounts for class II induction during tissue injury. CIITA induction by injury is largely IFN-gamma independent but requires IRF-1. The similarities of the pattern of CIITA and class II induction in ischemic and toxic injury suggest that this is a stereotyped response of injured tissue and not a consequence of a particular mechanism of injury.

Strategies to improve the immunologic management of organ transplants.

After a decade of little change, many changes in the immunologic management of organ transplant recipients are now imminent. Basic science is revealing mechanisms and developing new reagents, and clinicians are identifying opportunities for application of this new knowledge. The interaction between the laboratory and the clinic, and the renewed interest in clinical trials, guarantee that transplantation practice will evolve rapidly in the new few years. The examples mentioned here high-light the scope of the possibilities for progress.