Posttransplant lymphoproliferative disorders in lung transplant patients: the Cleveland Clinic experience.

PTLD is a well-recognized complication of organ transplantation. Large series of heart, renal, and liver transplants have been examined for the incidence and behavior of PTLD. However, reports of the incidence and characteristics of PTLDs in lung transplant (LTx) patients are few. We report our experience with PTLDs in a large series of LTx recipients at a single institution and compare them to other solid organ transplant recipient PTLDs seen at our institution. Twenty-eight patients were found to have PTLD, of whom 8 were lung transplant recipients. We evaluated nine PTLD specimens from these 8 patients for their histology, immunophenotype (CD20, CD3, EBV-LMP1), EBER status by in situ hybridization, and clinical features. The incidence of PTLD was 3.3% (8/244 patients). The time to development of PTLD, after transplant, was short (median time, 7 mo). All were of B-cell lineage. Overall, EBV was demonstrated in 77.7% (7 of 9 specimens) of PTLDs. All specimens tested for clonality were found to be monoclonal. Five patients died, with a median time to death of only 4.6 months. PTLDs in LTx patients are EBV-associated B-cell, predominantly monoclonal lymphoid lesions similar to other solid organ transplant PTLDs. Compared with other solid organ transplant recipients with PTLD at our institution, PTLDs in LTx patients have a propensity to involve the transplanted organ (P =.001, Fisher's exact test), occur earlier after transplant (P =.003, Wilcoxon test), and have a shorter survival (P =.002, log rank test). Reasons for this may include the relatively higher level of immunosuppression required in these patients and limited options in decreasing it. Although the incidence is low, careful early monitoring of lung transplantation patients is warranted because of the poor prognosis of patients developing this complication.     

Primary central nervous system posttransplant lymphoproliferative disorders

Posttransplant lymphoproliferative disorders (PTLDs) represent a spectrum ranging from Epstein-Barr virus (EBV)-driven polyclonal lymphoid proliferations to EBV+ or EBV- malignant lymphomas. Central nervous system (CNS) PTLDs have not been characterized fully. We reviewed the clinical, radiologic, and pathologic features of 12 primary CNS PTLDs to define them more precisely. Patients included 10 males and 2 females (median age, 43.4 years) who were recipients of kidney (n = 5), liver (n = 2), heart (n = 2), peripheral blood stem cells (n = 2), or bone marrow (n = 1). All received immunosuppressive therapy. CNS symptoms developed 3 to 131 months (mean, 31 months) after transplantation. By neuroimaging, most showed multiple (3 to 9) intra-axial, contrast-enhancing lesions. Histologic sections showed marked expansion of perivascular spaces by large, cytologically malignant lymphoid cells that were CD45+, CD20+, EBV+ and showed light chain restriction or immunoglobulin gene rearrangement. In distinction to PTLDs in other organ systems, CNS PTLDs were uniformly high-grade lymphomas that fulfilled the World Health Organization criteria for monomorphic PTLDs. Extremely short survival periods were noted for each CNS PTLD that followed peripheral blood stem cell transplantation. Survival of others with CNS PTLD varied; some lived more than 2 years.     

Post-transplant lymphoproliferative disorders

Post-transplant lymphoproliferative disorders (PTLD) are the second most frequent neoplasia in transplant patients after skin carcinomas. They occur following both solid organ transplants (SOT) and haematopoietic stem cell transplants (HSCT). Most PTLD in solid organ recipients are of host origin, whereas in HSCT recipients they are most often of donor origin. The EBV status of the recipient and the donor, the type of transplant, the type of immunosuppressive therapy used, and the time after transplant are all important parameters that have been associated with the incidence and the type of PTLD. Although most PTLD are B-cell lesions up to 15% may be T-cell or NK-cell type. Most PTLD are associated with EBV, but EBV-negative PTLD are also clearly recognized. In the 2008 WHO classification of lymphoid neoplasms (ref) PTLD are subclassified according to their histological and immunophenotypic characteristics into early lesions, polymorphic type, monomorphic type, and classical Hodgkin lymphoma-type. Overall PTLD mortality rates are around 50%, but new therapies that include early treatment with rituximab and novel anti-EBV therapies promise better outcomes.     

EBV-associated B- and T-cell posttransplant lymphoproliferative disorders following primary EBV infection in a kidney transplant recipient

Posttransplant lymphoproliferative disorders (PTLDs) usually are of B-cell lineage and associated with Epstein-Barr virus (EBV). PTLDs of T-cell lineage are much less common and infrequently associated with EBV. We report a rare case of a girl in whom B-cell and T-cell PTLDs developed following 2 EBV-negative kidney transplants. Within 2 years of the second transplantation, the originally EBV-negative patient developed both an EBV-associated clonal B-cell PTLD involving lymph nodes and an EBV-positive T-cell PTLD involving bone marrow and liver. These proliferations occurred concurrently with evidence of primary EBV infection and high plasma viral load. The patient eventually died of multiorgan failure 5 years after the initial transplant (3 years after the second transplant). To our knowledge, only 4 cases of both B-cell and T-cell PTLDs have been reported. Only 2 cases have been proven to be monoclonal and EBV-associated, as in this case, the first following kidney transplantation.     

Anaplastic T large cell lymphoma diagnosed by exfoliative cytology in a post renal transplant patient

In the last two decades posttransplant lymphoproliferative disorders (PTLDs) have been recognized as a complication of organ transplantation with immunosuppression. The reported incidence of PTLDs in renal transplant patients ranges between 0.3-3% (Birkeland et al., Transplantation 1999;67:876-881). In contrast to the reported incidence of PTLDs in post bone marrow transplant, it is 1% in HLA-matched recipients and up to 20% in HLA mismatched T-cell depleted bone marrow recipients (Curtis et al., Blood 1996;94:2208-2216). In cardiac transplant recipients the reported incidence of PTLDs is between 1.8-9.8 (Mihalov et al., Clin Transplant 1996;10:248-255). PTLDs are predominately extranodal. They have varied morphologic patterns and clonality, but almost all are associated with Epstein-Barr virus (EBV). The vast majority are of B cell lineage; only about 10% are of T-cell origin. We report a T-cell anaplastic large cell lymphoma (ALCL) presenting with bilateral pleural effusion and liver involvement in a renal transplant recipient.     

Molecular characterization of post‐transplant lymphoproliferative disorders of donor origin occurring in liver transplant recipients

Post‐transplant lymphoproliferative disorders (PTLDs) represent a frequent complication of solid organ transplantation. Although most PTLDs arise from recipient lymphoid cells, a considerable fraction of cases may arise from donor B‐cells. In an attempt to clarify the histogenesis and pathogenesis of PTLDs derived from donor B‐cells, monoclonal PTLDs occurring in liver transplant recipients were chosen as a model to compare donor (D‐PTLDs) versus recipient PTLDs (R‐PTLDs). The tumour panel included nine D‐PTLDs and six R‐PTLDs. D‐PTLDs were early‐onset, EBV‐infected lymphoproliferations classified as polymorphic PTLD (P‐PTLD; n = 7) or diffuse large B‐cell lymphoma (DLBCL; n = 2) with tumour localization confined to the hepatic hilum. All R‐PTLDs were late‐onset DLBCLs and showed extrahepatic localization. A BCL‐6^?/MUM1⁺/CD138^+/? phenotype, consistent with a post‐germinal centre (GC) stage of pre‐terminal B‐cell differentiation, was observed in all D‐PTLDs and in 2/6 R‐PTLDs, whereas a BCL6⁺/MUM1^?/CD138^? profile, reminiscent of GC B‐cells, was detected in 4/6 R‐PTLDs. The presence of somatic IGHV hypermutation was observed in 6/9 D‐PTLDs and in 4/6 R‐PTLDs, suggesting derivation from antigen‐experienced B‐cells. IGHV4‐39 was the IGHV gene most frequently encountered, being rearranged in 3/9 D‐PTLDs. Among IGHV‐mutated PTLDs, a mutational profile suggesting antigen stimulation and/or selection was observed in 4/6 D‐s and in 2/4 R‐PTLDs. The presence of ongoing IGHV mutations was detected in 2/4 D‐PTLDs. Aberrant SHM was detected in 10/15 (66.7%) PTLDs, including 6/9 D‐PTLDs and 4/6 R‐PTLDs. Our findings suggest that (i) D‐PTLDs show a clinical presentation distinct from R‐PTLDs; (ii) immunophenotypic and genetic features of D‐PTLDs are consistent with mature, GC‐experienced B‐cells; (iii) transformed donor‐derived B‐cells may experience antigen‐driven stimulation and selection, and may acquire genetic lesions during neoplastic expansion in the recipient environment; and (iv) EBV infection and expression of viral oncoproteins may be relevant in the pathogenesis of D‐PTLDs. Copyright © 2009 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Post-transplant lymphoproliferative disorder subtypes correlate with different recurring chromosomal abnormalities

Although cytogenetic analysis advanced the understanding of the pathogenesis of primary non-Hodgkin lymphoma and led to improved clinical management, there have been no large cytogenetic studies of post-transplant lymphoproliferative disorder (PTLD). We examined the karyotypes of 36 PTLD cases and correlated them with clinical, laboratory, and pathologic findings. The cases included 2 early lesions, 13 polymorphic PTLDs, and 21 monomorphic PTLDs (18 B-cell and 3 T-cell proliferations). Cytogenetic abnormalities were identified in 72% of monomorphic B-cell PTLDs and in all T-cell PTLDs, but in only 15% of polymorphic PTLDs and in no early lesions. The most frequent clonal abnormalities in monomorphic PTLD were trisomies 9 and/or 11 (5 cases), followed by rearrangements of 8q24.1 (4 cases), 3q27 (2 cases), and 14q32 (2 cases). MYC rearrangement (8q24.1) and T-cell-associated chromosomal abnormalities correlated with poor outcome and short survival. PTLD with trisomy 9 and/or 11 developed early after transplant, presenting as Epstein-Barr virus-positive large B-cell lymphoma with prolonged survival.     

Detection of Epstein-Barr virus DNA in sera from transplant recipients with lymphoproliferative disorders

Early diagnosis of Epstein-Barr Virus (EBV)-associated posttransplant lymphoproliferative disease (PTLD) is important because many patients respond to reduction in immunosuppression, especially if PTLD is detected at an early stage. Previous studies have found elevated EBV DNA levels in blood from patients with PTLD, but these assays required isolation of cellular blood fractions and quantitation. We evaluated the presence of cell-free EBV DNA in serum from solid-organ transplant recipients as a marker for PTLD. Five of 6 transplant recipients with histopathologically documented PTLD had EBV DNA detected in serum at the time of diagnosis (sensitivity = 83%), compared with 0 of 16 matched transplant recipients without PTLD (specificity = 100%) (P < 0.001 [Fisher's exact test]). Furthermore, EBV DNA was detected in serum 8 and 52 months prior to the diagnosis of PTLD in two of three patients for whom stored sera were analyzed. Detection of EBV DNA in serum appears to be a useful marker for the early detection of PTLD in solid-organ transplant recipients. Further studies to define the role of such assays in evaluating solid-organ transplant patients at risk for PTLD are warranted.     

Heart allograft involvement with Epstein-Barr virus-associated posttransplant lymphoproliferative disorder.

We describe a 60-year-old man who underwent heart transplant and died 5 months later. At autopsy, the patient was found to have posttransplant lymphoproliferative disorder (PTLD), which was not suspected ante mortem. The PTLD involved the lung, lymph nodes, spleen, and kidney and the intima of right coronary artery of the transplanted heart. Epstein-Barr virus infection was demonstrated on direct gel and dot blot after polymerase chain reaction amplification. In situ hybridization for Epstein-Barr virus DNA confirmed the presence of Epstein-Barr virus-infected lymphocytes in the intima of the right coronary artery of the cardiac allograft. To our knowledge, this case represents the first report of involvement of a heart allograft by PTLD in which Epstein-Barr virus infection of the atypical cells is documented. Although primary allograft involvement by PTLD has rarely been reported in heart transplant recipients, recognition that this may occur is important, since the lymphoid infiltrate of PTLD must be distinguished from the lymphoid infiltrate of acute rejection to avoid inappropriate therapy.     

Post-transplant lymphoproliferative disorder associated with immunosuppressive therapy for renal transplantation in rhesus macaques (Macaca mulatta)

Human post-transplant lymphoproliferative disorder (PTLD) is an abnormal lymphoid proliferation that arises in 1–12% of transplant recipients as a consequence of prolonged immunosuppression and Epstein–Barr viral infection (EBV). Nonhuman primates, primarily rhesus macaques (Macaca mulatta), have been used extensively in research models of solid organ transplantation, as the nonhuman primate immune system closely resembles that of the human. Lymphocryptovirus of rhesus monkeys has been characterized and shown to be very similar to EBV in humans in regards to its cellular tropism, host immune response, and ability to stimulate B lymphocyte proliferation and lymphomagenesis. Thus, it appears that the NHP may be an appropriate animal model for EBV-associated lymphoma development in humans.The clinical management of post-transplant nonhuman primates that are receiving multiple immunosuppressive agents can be complicated by the risk of PTLD and other opportunistic infections. We report 3 cases of PTLD in rhesus macaques that illustrate this risk potential in the setting of potent immunosuppressive therapies for solid organ transplantation.     

Epstein‐Barr virus related post‐transplant lymphoproliferative disorder prevention strategies in allogeneic hematopoietic stem cell transplantation

Epstein‐Barr virus associated post‐transplant lymphoproliferative disorders (EBV PTLD) are recognized as a significant cause of morbidity and mortality in patients undergoing allogeneic hematopoietic stem cell transplantation (alloHSCT). The number of patients at risk of developing EBV PTLD is increasing, partly as a result of highly immunosuppressive regimens, including the use of anti‐thymocyte globulin (ATG). Importantly, there is heterogeneity in PTLD management strategies between alloHSCT centers worldwide. This review summarizes the different EBV PTLD prevention strategies being utilized including the alloHSCT and T‐cell depletion regimes and the risk they confer; monitoring programs, including the timing and analytes used for EBV virus detection, as well as pre‐emptive thresholds and therapy with rituximab. In the absence of an institution‐specific policy, it is suggested that the optimal pre‐emptive strategy in HSCT recipients with T‐cell depleting treatments, acute graft vs host disease (GVHD) and a mismatched donor for PTLD prevention is (a) monitoring of EBV DNA post‐transplant weekly using plasma or WB as analyte and (b) pre‐emptively reducing immune suppression (if possible) at an EBV DNA threshold of >1000 copies/mL (plasma or WB), and treating with rituximab at a threshold of >1000 copies/mL (plasma) or >5000 copies/mL (WB). There is emerging evidence for prophylactic rituximab as a feasible and safe strategy for PTLD, particularly if pre‐emptive monitoring is problematic. Future management strategies such as prophylactic EBV specific CTLs have shown promising results and as this procedure becomes less expensive and more accessible, it may become the strategy of choice for EBV PTLD prevention.     

Cytogenetic analysis of B-cell posttransplant lymphoproliferations validates the World Health Organization classification and suggests inclusion of florid follicular hyperplasia as a precursor lesion

Cytogenetic abnormalities in B-cell posttransplant lymphoproliferative disorders (PTLD) have not been well characterized. We thus performed cytogenetic analysis of 28 cases of B-cell PTLD, 1 infectious mononucleosis (IM)-like lesion, 9 polymorphic PTLD, 17 monomorphic PTLD, and 1 classical Hodgkin lymphoma (HL), and correlated the karyotypic findings with the phenotype, Epstein-Barr virus infection status, and clinical outcome. Karyotypes of 19 cases of posttransplant florid follicular hyperplasia (FFH) were also analyzed. Informative karyotypes were obtained in 20 (71.4%) of 28 PTLDs and 18 (94.7%) of 19 FFHs. Clonal karyotypic abnormalities were detected in 13 (65%) of 20 PTLDs, including 9 (75%) of 12 monomorphic PTLDs, 2 (33.3%) of 6 polymorphic PTLDs, 1 IM-like lesion, and 1 HL, and 2 (11.1%) of 18 FFHs. Recurrent chromosome breaks at 1q11-21 (n = 6, including 1 FFH), 14q32 (n = 3, including 1 FFH), 16p13 (n = 3), 11q23-24 (n = 2), and 8q24 (c-MYC) (n = 2); gains of chromosome 7 (n = 4), X (n = 3), 2 (n = 3), 12 (n = 2); and loss of chromosome 22 (n = 2, including 1 IM-like lesion) were identified. The presence of cytogenetic abnormalities did not correlate with PTLD phenotype, Epstein-Barr virus infection, or clinical outcome. We describe novel karyotypic aberrations in PTLD and report clonal cytogenetic abnormalities in posttransplant FFH and an IM-like lesion for the first time. Our findings provide validation of the current World Health Organization classification of PTLD and also suggest incorporation of FFH as the earliest recognizable precursor of PTLD.     

The clinical spectrum, pathology, and clonal analysis of Epstein-Barr virus-associated lymphoproliferative disorders in heart-lung transplant recipients

This study presents the clinical and laboratory observations on posttransplant lymphoproliferative disorders (PTLDs) occurring in 5 of 53 heart-lung transplantation recipients. Cervical lymph nodes, tonsils, lungs, and gastrointestinal tract were the common sites of involvement by PTLDs. The histopathologic findings showed a spectrum of lymphoid and immunoblastic proliferation ranging from diffuse hyperplasia to malignant lymphoma, immunoblastic or large cell type. All cases were associated with a primary Epstein-Barr virus infection, and viral DNA was demonstrated within the lesional tissue in three cases. Immunohistochemical and immunoglobulin gene rearrangement studies revealed a B-cell proliferation that was monoclonal in three cases and polyclonal in two cases. Compared with PTLDs arising in other organ transplant recipients, this series is remarkable for a high incidence of PTLDs (9.4%), a short interval to tumor diagnosis (2.2 months, mean), involvement of the primary allograft in three cases (60%), and the frequent development of bronchiolitis obliterans. Possible reasons for this distinct clinicopathologic profile are discussed.     

Extranodal posttransplant plasmacytic hyperplasia with subsequent posttransplant plasmacytic malignancy: six-year interval case report and review of the literature

Posttransplant lymphoproliferative disorders (PTLDs) represent a morphologic, immunophenotypic, and genotypic spectrum of disease. Most recently, Knowles et al divided PTLDs into 3 distinct categories: (1) plasmacytic hyperplasia, (2) polymorphic B-cell hyperplasia and polymorphic B-cell lymphoma, and (3) immunoblastic lymphoma and multiple myeloma. Although one form of PTLD may progress to another form, only 1 previous case has been reported in which multiple myeloma developed 14 months after an original diagnosis of plasmacytic hyperplasia. The type of solid organ transplant was not specified in that case. We report a post--cardiac transplant plasmacytic hyperplasia developing 7 years posttransplant. Six years subsequent to the plasmacytic hyperplasia, the patient developed a posttransplant plasmacytic malignancy, supported by morphology, flow cytometric immunophenotyping, and genotypic studies. Since we have no data to support disseminated bony disease or an abnormal serum protein, we have not used the term "multiple myeloma" for this case.     

The expression of Epstein-Barr virus latent proteins is related to the pathological features of post-transplant lymphoproliferative disorders.

Transplant recipients are at increased risk for the development of post-transplant lymphoproliferative disorders (PTLDs). PTLDs harbor genomes of the Epstein-Barr virus, a herpesvirus that immortalizes B cells in vitro. At least five viral proteins are required for immortalization. Two of them are particularly important. Latent membrane protein (LMP) has transforming activity in fibroblasts, and Epstein-Barr antigen (EBNA)2 transactivates the expression of numerous cellular and viral genes. To determine whether the expression of EBNA2 and LMP is related to the histological and clinical presentation of PTLD, we tested their expression in 14 Epstein-Barr virus-positive cases. Using monoclonal antibodies to EBNA2 and LMP on paraffin sections, we found an expression of both proteins in 2 of 3 polymorphic PTLD and in 7 of 8 cases of monomorphic, large cell PTLD, without plasmacytic differentiation. One polymorphic and one large cell PTLD expressed LMP only. LMP and EBNA2 were found particularly in immunoblasts. The number of positive cells was extremely variable in the different cases as well as within the same biopsy. Three cases of PTLD had morphological and phenotypical features of plasmacytomas and did not stain for EBNA2 or LMP. This suggests that the expression of EBNA2 and LMP is related to the differentiation stage of the infected cells and that other viral or cellular proteins may contribute to tumor growth.     

Plasma Epstein-Barr viral load predicting response after chemotherapy for post-transplant lymphoproliferative disease

Transplant patients are particularly at risk of developing B post-transplant lymphoproliferative disease (PTLD) related to intensive immunosuppressive treatment to prevent graft rejection. In EBV-positive PTLDs, EBV-DNA can be found in the patients' peripheral blood. Several methods have been described to assess peripheral blood EBV viral load. We report a case of a 13-year-old child who developed EBV-positive PTLD after renal transplantation. We assessed EBV plasma viral load by quantitative PCR and we found that the clearance of EBV-DNA correlated well with response to treatment.     

Use of quantitative competitive PCR to measure Epstein-Barr virus genome load in the peripheral blood of pediatric transplant patients with lymphoproliferative disorders.

A quantitative competitive PCR (QC-PCR) assay for Epstein-Barr virus (EBV) has been developed to provide accurate measurement of EBV genome load in pediatric transplant recipients at risk for developing posttransplant lymphoproliferative disorder (PTLD). The assay quantifies between 8 and 5,000 copies of the EBV genome in 10(5) lymphocytes after a 30-cycle amplification reaction. For 14 pediatric patients diagnosed with PTLD, the median EBV genome load was 4,000, and 13 of the 14 patients had values of >500 copies per 10(5) lymphocytes. Only 3 of 12 control transplant recipients not diagnosed with PTLD had detectable viral genome loads (median value, 40). This median was calculated by using the highest value obtained by PCR testing on each of these patients posttransplantation. PCR values of >500 copies per 10(5) lymphocytes appear to correlate with a diagnosis of PTLD. By a modified protocol, the EBV genome copy number in latently infected adults was estimated to be <0.1 copy per 10(5) lymphocytes.     

Cytologic features of post-transplant lymphoproliferative disorder

Post-transplant lymphoproliferative disorders (PTLD) are Epstein-Barr virus (EBV)–associated lymphoid proliferations which affect approximately 2% of organ allograft recipients. Although the histologic features of PTLD are well described, they have been described only rarely in cytologic specimens. The cytomorphologic features of PTLD in body fluid specimens, needle aspirations, and a gastric brushing specimen from seven patients with histologically confirmed PTLD were therefore reviewed. In the cytologic specimens, PTLD was characterized by a mostly polymorphous population of lymphoid cells containing many large transformed lymphocytes, occasional immunoblast-like atypical lymphocytes, necrosis, and, frequently, obvious plasmacytoid differentiation. The presence of EBV was documented in five of the seven cases in the corresponding tissue biopsies. The four patients with PTLD in a body fluid specimen all died within 3 months of detection of the PTLD in the body fluid. The three remaining patients are alive with resolution of PTLD (follow-up of 7, 8, and 14 months). The diagnosis of PTLD should be suggested when cytologic specimens from organ allograft recipients show a polymorphous atypical lymphoid proliferation, frequently with plasmacytoid differentiation and necrosis. Cytologic samples may provide the initial diagnosis of this potentially fatal disease and allow appropriate intervention. The presence of PTLD in a body fluid specimen is a poor prognostic indicator. Diagn. Cytopathol. 16:489–496, 1997. © 1997 Wiley-Liss, Inc.     

Determining virological, serological and immunological parameters of EBV infection in the development of PTLD

Post-transplant lymphoproliferative disease (PTLD) in Epstein-Barr virus (EBV) seronegative solid organ transplant recipients remains a significant problem, particularly in the first year post-transplant. Immune monitoring of a cohort of high-risk patients indicated that four EBV seronegative transplant recipients developed early-onset PTLD prior to evidence of an EBV humoral response. EBV status has been classically defined serologically, however these patients demonstrated multiple parameters of EBV infection, including the generation of EBV-specific CTL, outgrowth of spontaneous lymphoblastoid cell lines, and elevated EBV DNA levels, despite the absence of a classic EBV antibody response. As EBV serology is influenced by both immunosuppression and cytomegalovirus immunoglobulin treatment, both the EBV-specific CTL response and elevated EBV levels are more reliable indicators of EBV infection post-transplant.     

Epstein-Barr virus infection in paediatric liver transplant recipients: detection of the virus in post-transplant tonsillectomy specimens.

AIMS: Post-transplant lymphoproliferative disease (PTLD) is an important and serious complication in transplant patients. Recent studies have suggested that quantitative assessment of Epstein-Barr virus (EBV) infection in transplant patients might help to identify those at risk of developing PTLD. Therefore, tonsils from paediatric liver transplant recipients were studied for evidence of EBV infection. METHODS: Tonsils were studied by in situ hybridisation for the detection of the small EBV encoded nuclear RNAs (EBERs). The phenotype of EBV infected cells was determined by double labelling in situ hybridisation and immunohistochemistry. The expression of viral latent and lytic antigens was determined by immunohistochemistry. Tonsils from patients without known immune defects were studied as controls. RESULTS: Tonsils from transplant patients showed pronounced follicular hyperplasia and minor paracortical hyperplasia. In situ hybridisation revealed variable numbers of EBV infected B cells in the tonsils from transplant patients (range, 2-1000/0.5 cm(2); mean, 434/0.5 cm(2); median, 105/0.5 cm(2)). Lower numbers were detected in the control tonsils (range, 1-200/0.5 cm(2); mean, 47/0.5 cm(2); median, 9/0.5 cm(2)). The latent membrane protein 1 (LMP1) of EBV was not detected and there were only rare cells in two cases showing expression of the EBV encoded nuclear antigen 2 (EBNA2). There was no evidence of lytic infection. None of the patients developed PTLD within a follow up period of up to five years. CONCLUSIONS: These data indicate that tonsillar enlargement in paediatric liver transplant patients does not necessarily imply a diagnosis of PTLD. Furthermore, the presence of increased numbers of EBV infected cells in tonsils from liver transplant recipients by itself does not indicate an increased risk of developing PTLD.