C. V. Paya

Solid-organ transplantation is a therapeutic option for many human diseases. Infections are a major complication of solid-organ transplantation. All candidates should undergo a thorough infectious-disease screening prior to transplantation. There are three time frames, influenced by surgical factors, the level of immunosuppression, and environmental exposures, during which infections of specific types most frequently occur posttransplantation. Most infections during the first month are related to surgical complications. Opportunistic infections typically occur from the second to the sixth month. During the late posttransplant period (beyond 6 months), transplantation recipients suffer from the same infections seen in the general community. Opportunistic bacterial infections seen in transplant recipients include those caused by Legionella spp., Nocardia spp., Salmonella spp., and Listeria monocytogenes. Cytomegalovirus is the most common cause of viral infections. Herpes simplex virus, varicella-zoster virus, Epstein-Barr virus and others are also significant pathogens. Fungal infections, caused by both yeasts and mycelial fungi, are associated with the highest mortality rates. Mycobacterial, pneumocystis, and parasitic diseases may also occur.

Posttransplantation lymphoproliferative disorder (PTLD) is an uncommon but often fatal complication of solid organ transplantation that occurs in approximately 3% of patients. To determine the relative importance and relationship of potential risk factors for PTLD before transplantation (i.e., Epstein-Barr virus [EBV] serostatus of the recipient and the cytomegalovirus [CMV] sero-status of the recipient and the potential donor) and the principal risk factor after transplantation (immunosuppression with antilymphocyte antibody), we analyzed the findings for the first 381 consecutive adult nonrenal transplant recipients seen at Mayo Clinic. In the absence of the other risk factors, the incidence rate of PTLD for EBV-seronegative recipients was 24 times higher (95% confidence interval [CI]: 6.2, 89) than that for EBV-seropositive recipients. The additional risk factors of therapy with OKT3 for rejection and CMV seromismatch (i.e., a negative recipient and a positive donor) each further amplified this risk four- to sixfold. Together, all three risk factors acted synergistically to increase the incidence rate of fatal and/or CNS PTLD by a factor of 654 (CI: 368, 1,162) compared with the low incidence rate (.458 cases per 100 person years) when none of these risk factors were present. Pretransplantation determination of recipient EBV and CMV serostatus can identify a subgroup of patients whose risk for severe PTLD may preclude transplantation.

Journal Article Fungal Infections in Solid-Organ Transplantation Get access Carlos V. Paya Carlos V. Paya From the Divisions of Infectious Diseases and Experimental Pathology, Mayo Clinic/Foundation, Rochester, Minnesota Reprints or correspondence: Dr. Carlos V. Paya, Division of Infectious Diseases, Mayo Clinic/Foundation, Rochester, Minnesota 55905. Search for other works by this author on: Oxford Academic PubMed Google Scholar Clinical Infectious Diseases, Volume 16, Issue 5, May 1993, Pages 677–688, https://doi.org/10.1093/clind/16.5.677 Published: 01 May 1993 Article history Received: 20 August 1992 Revision received: 30 November 1992 Published: 01 May 1993

Apoptosis has been proposed to mediate CD4+ T-cell depletion in human immunodeficiency virus (HIV)-infected individuals. Interaction of Fas ligand (FasL) with Fas (CD95) results in lymphocyte apoptosis, and increased susceptibility to Fas-mediated apoptosis has been demonstrated in lymphocytes from HIV-infected individuals. Cells undergoing apoptosis in lymph nodes from HIV-infected individuals do not harbor virus, and therefore a bystander effect has been postulated to mediate apoptosis of uninfected cells. These data raise the possibility that antigen-presenting cells are a source of FasL and that HIV infection of cells such as macrophages may induce or increase FasL expression. In this report, we demonstrate that HIV infection of monocytic cells not only increases the surface expression of Fas but also results in the de novo expression of FasL. Interference with the FasL-Fas interaction by anti-Fas blocking antibodies abrogates HIV-induced apoptosis of monocytic cells. Human monocyte-derived macrophages from healthy donors contain detectable FasL mRNA, which is further upregulated following HIV infection with monocytotropic strains. HIV-infected human macrophages result in the apoptotic death of Jurkat T cells and peripheral blood T lymphocytes. Interruption of the FasL-Fas interaction abrogates the HIV-infected macrophage-dependent death of T lymphocytes. These results provide evidence that human macrophages can provide a source of FasL, especially following HIV infection, and can thus participate in lymphocyte depletion in HIV-infected individuals.