Correlation of mutations of the SH2D1A gene and epstein-barr virus infection with clinical phenotype and outcome in X-linked lymphoproliferative disease.

The purposes of this study were to determine the frequency of mutations in SH2D1A in X-linked lymphoproliferative disease (XLP) and the role of SH2D1A mutations and Epstein-Barr virus (EBV) infection in determining the phenotype and outcome of patients with XLP. Analysis of 35 families from the XLP Registry revealed 28 different mutations in 34 families-large genomic deletions (n = 3), small intragenic deletions (n = 10), splice-site (n = 3), nonsense (n = 3), and missense (n = 9) mutations. No mutations were found in 25 males, so-called sporadic XLP (males with an XLP phenotype after EBV infection but no family history of XLP) or in 9 patients with chronic active EBV syndrome. Of 304 symptomatic males in the XLP Registry, 38 had no evidence of EBV infection at first clinical manifestation. When fulminant infectious mononucleosis (FIM) was excluded, there was no statistical difference in the frequency of EBV infectivity in the other XLP phenotypes. Furthermore, there was no difference at age of first clinical manifestation between EBV(+) and EBV(-) males or in survival when patients with FIM were excluded. In conclusion, it was found that mutations in the SH2D1A gene are responsible for XLP but that there is no correlation between genotype and phenotype or outcome. It was also found that though EBV infection often results in FIM, it is unnecessary for the expression of other manifestations of XLP, and it correlates poorly with outcome. These results suggest that unidentified factors, either environmental or genetic (eg, modifier genes), contribute to the pathogenesis of XLP.

A yeast artificial chromosome (YAC) contig encompassing the critical region of the X-linked lymphoproliferative disease (XLP) locus.

X-linked lymphoproliferative disease (XLP) is characterized by a marked vulnerability to Epstein-Barr virus (EBV) infection. Infection of XLP patients with EBV invariably results in fatal mononucleosis, agammaglobulinemia, or malignant lymphoma. Initially the XLP gene was assigned to a 10-cM region in Xq25 between DXS42 and DXS37. Subsequently, an interstitial, cytogenetically visible deletion in Xq25 was identified in one XLP family, 43. In this study we estimated the deletion in XLP patient 43-004 by dual-laser flow karyotyping to involve 2% of the X chromosome, or approximately 3 Mb of DNA sequence. From a human chromosome Xq25-specific yeast artificial chromosome (YAC) sublibrary, five YACs containing DNA sequences deleted in patient 43-004 have been isolated. Sequence-tagged sites (STSs) from these YACs have been used to identify interstitial deletions in unrelated XLP patients. Three more families with interstitial deletions were found. Two of the patients (63-003 and 73-032) carried an interstitial deletion of 3.0 Mb overlapping the 43-004 deletion. In one XLP patient (30-011) who exhibited the characteristic postinfectious mononucleosis phenotype of XLP with hypogammaglobulinemia and malignant lymphoma, a deletion of approximately 250 kb was detected overlapping the deletion detected in patients 43-004, 63-003, and 73-032. A YAC contig of 2.2 Mb spanning the XLP critical region, whose orientation on chromosome X was determined by double-color fluorescence in situ hybridization and which consists of 15 overlapping YAC clones, has been constructed. A detailed restriction enzyme map of the region has been constructed. YAC insert sizes were determined by counter-clamped homogenous electric field gel electrophoresis. Chimerism of YACs was determined by FISH and restriction mapping. On the basis of lambda subclones, YAC end-derived plasmids, and STSs with an average spacing of 100 kb, a long-range physical map was constructed using 5 rare-cutter restriction enzymes. The STSs and lambda subclones were used in Southern hybridization and PCR analyses. The work presented here substantially refines the critical region for XLP. The YAC contig with the overlapping interstitial deletions constitutes the basis for the construction of a transcriptional map of the critical region and facilitates the identification of the XLP gene.

Simple assay for evaluation of Epstein-Barr virus specific cytotoxic T lymphocytes.

Epstein-Barr virus (EBV)-specific cytotoxic T lymphocytes (CTL) are considered to be one of major defenses against the activation of EBV infection. We have developed a simple assay for evaluation of EBV-CTL by means of culturing peripheral blood mononuclear cells at the concentration of 2 x 10(6) cells/ml infected by B95-8 EBV, in the presence or absence of cyclosporin A (CSA). No lymphoblastoid cell line was established from ten EBV-seropositive healthy individuals in the absence of CSA. In contrast, cell lines were established from ten EBV-seronegative healthy individuals in the absence of CSA, indicating lack of EBV-CTL in these individuals. Methods described herein are simple and correlate well with EBV-CTL activity when compared to conventional methods, such as outgrowth regression or chromium-51 release assays.

Cellular proliferation and genetic events involved in the genesis of Burkitt lymphoma (BL) in immune compromised patients.

A mathematical model simulating lymphomagenesis based on the two-hit theory of carcinogenesis is presented by contrasting the biologic variables responsible for a high risk of developing Burkitt lymphoma (BL) in three immunosuppressed groups with that of nonendemic BL. In this model, the pro-B lymphocyte is considered to be the target for BL-specific translocations such as t(8;14). With repeated mitosis, the target cell pool expands in the high-risk individual, and, thereby, the opportunities for a spontaneous translocation to arise are increased. The chromosomal translocation endows the target cell with survival advantages, and, hence, lymphoma develops. Modeling results demonstrate that this increased cell proliferation is sufficient in accounting entirely for the increase in tumor prevalence. Preventing enhanced cellular proliferation by obviating immune deficiency and treating patients with agents that restore immunity or have antiviral and antiproliferative properties prior to conversion from polyclonal B-cell proliferation to monoclonal malignancy could obviate the development of BL.

X-linked lymphoproliferative disease: prenatal detection of an unaffected histocompatible male.

Chorionic Villous Biopsy (CVS) for diagnosis of XLP was undertaken at 10 weeks gestation in an obligate carrier. The fetus was found to be male by cytogenetic analysis. XLP (Xq25-q26) is closely linked to the RFLP markers DXS10, DXS37 and DXS42, but only DXS10 (distal to XLP) was informative for prenatal diagnosis in this family. RFLP analysis using this marker gave a 7% risk that the fetus was affected, based on the known recombination frequency between DXS10 and XLP. Further investigation was then undertaken to obtain a rapid and more accurate diagnosis using the three highly polymorphic PCR based markers. These were the AC repeat markers DXS424 (XL5A) and DXS425 (XL90A3) and the tetramer repeat marker within HPRT. DX425 is approximately 10 cM proximal to DXS10 and HPRT but is not known with certainty to map proximal or distal to XLP. DXS424 is proximal to DXS10 and HPRT and was inferred to be proximal to XLP on the basis of map distance from HPRT estimated by linkage analysis of data from CEPH pedigrees. This was confirmed by a recombinant in the XLP family between DXS424 and DXS425, placing DXS424 proximal to XLP. Diagnosis by linkage using DXS424 and DXS425, at least one of which is proximal to XLP, and distal markers DXS10 and HPRT, increased the accuracy of diagnosis using flanking marker analysis to greater than 99% that the fetus was unaffected. HLA DR typing of the CVS showed that the fetus was DR identical to a male sibling with XLP. HLA compatibility was confirmed at delivery by full HLA typing and MLC.(ABSTRACT TRUNCATED AT 250 WORDS)

Documentation of Burkitt lymphoma with t(8;14) (q24;q32) in X-linked lymphoproliferative disease.

BACKGROUND: Acquired hypogammaglobulinemia or agammaglobulinemia, aplastic anemia, chronic or fatal infectious mononucleosis (IM), virus-associated hemophagocytic syndrome, and a variety of B-cell malignant lymphomas (ML) develop in boys with X-linked lymphoproliferative disease (XLP) after infection by the Epstein-Barr virus (EBV). They have an inherited immunodeficiency to EBV. Approximately 80% of the patients die during childhood and 100% by the age of 40. The ML occurring in patients with XLP are different from those of other populations in that there is a maternal family history of males with phenotypes of XLP, particularly ML involving the ileocecal region. METHODS: This article describes two brothers with XLP in whom ML developed. Also, a maternally related male cousin had died of aplastic anemia complicating IM. RESULTS: A Burkitt lymphoma (BL)-specific translocation of t(8;14) (q24;q32) was observed in the BL cells of the younger brother. The histopathologic appearance and rapid relapse after complete remission in the patient also are suggestive of this aggressive phenotype. CONCLUSIONS: This tumor in the patient documents that the BL of patients with XLP probably arises from characteristic tumor-specific chromosomal translocations, as hypothesized in 1980.

Epstein-Barr virus-associated lymphoproliferative disorders.

Herein we have provided a panorama of the clinical, histopathologic, and molecular biologic mechanisms of EBV-induced LPD particularly in immunosuppressed individuals. A listing of EBV-related diseases is shown in Table 4. We have stressed the frequent need to use multiple diagnostic methods for detecting EBV genome, particularly in immunodeficient patients who may fail to mount antibody responses to EBV. Given that we now recognize some of the immunocompromised patient populations at high risk for EBV-induced LPD, and have developed techniques for detecting EBV genome and early LPD, we may eventually prevent the occurrence of some of these life-threatening diseases. For example, we have learned to recognize and distinguish hepatic allograft rejection from EBV-induced LPD in hepatic biopsies (154). A periportal and sinusoidal infiltrate of small and large lymphoid cells, immunoblasts, and plasma cells, alert us to stain frozen liver sections for EBNA. Finding EBV guides the clinicians to reducing immunosuppression which then allows the restoration of immunosurveillance against the EBV-infected B cells. Whether an EBV vaccine can be successful in immunosuppressed individuals remains to be seen. As for other vaccines, many logistical problems prevail, such as the early occurrence of EBV infection during infancy in regions where BL is endemic. Surely, with the menacing threat that approximately 10% of patients with AIDS will develop NHL, new anti-viral therapy against EBV and the causative agent of AIDS and HIV, will be developed. The pathologist and virologist play essential roles in the recognition of EBV infection by performing clinical laboratory determinations. The characteristic histopathologic features of EBV-induced LPD are now recognized and when confirmed with molecular hybridization and immunofluorescent techniques will provide a solid diagnostic approach and, thus, a foundation for developing a sound therapeutic strategy.

Hemagglutination and graft-versus-host disease in the severe combined immunodeficiency mouse lymphoproliferative disease model.

In the course of evaluating the severe combined immunodeficiency mouse-human peripheral blood lymphocyte (SCID-PBL) model of lymphoproliferative disease, we noted hemagglutination occurring in peripheral blood smears of mice with serum human immunoglobulin levels greater than 1.0 mg/ml. The hemagglutinating process was mediated by human anti-mouse red cell antibodies of the IgM class, peaked at five to seven weeks post-transfer of 5 to 7 x 10(7) human PBL and was generally self limiting. However, death resulted in some mice when serum immunoglobulin levels were greater than 3.0 mg/ml. The most severely affected mice had hemagglutination induced congestion of liver, lungs and spleen. Several mice also had lesions consistent with graft-versus-host disease (GVHD) including focal hepatic necrosis and destruction of mouse splenic hematopoietic elements. The lesions associated with hemagglutination and GVHD in SCID-PBL mice are distinct from those associated with EBV-induced lymphoproliferation. Recognition of these pathologic processes are required for a thorough understanding of the SCID-PBL model.

Early activation of the proto-oncogene c-fgr during Epstein-Barr virus immortalization.

In an attempt to clarify the chronological relationships between Epstein-Barr virus (EBV) infection, B cell immortalization and c-fgr activation, we evaluated for the presence of EBV-determined nuclear antigen (EBNA), cellular DNA synthesis and expression of c-fgr-specific RNA following infection of human peripheral blood lymphocytes with B95-8 EBV. High expression of c-fgr was observed prior to EBNA detection and cellular DNA synthesis in EBV-infected cells. These results suggest that activation of c-fgr is an essential event during the early phase of EBV immortalization.

Report on the X-linked lymphoproliferative disease in an Australian family.

X-linked lymphoproliferative disease is characterized by immune deficiency, particularly to the Epstein-Barr virus and by a tendency to develop fatal infectious mononucleosis, acquired hypogammaglobulinaemia or malignant lymphoma. This disorder has been diagnosed in three boys, two brothers and a maternally related cousin, residing in Australia. The proband presented at 6 years of age with fulminating infectious mononucleosis. His 9 year old male cousin had developed an ileal Burkitt lymphoma one year earlier. Immunological and molecular genetic evidence is presented to support our view that his younger sibling is also affected with this condition. DNA linkage studies using probes to DXS10 and DXS37 provide confirmatory evidence for the diagnosis in the proband's brother and information on carrier status in female family members.

Autologous bone marrow transplantation for patients with relapsed Hodgkin's disease.

PURPOSE: High-dose therapy and autologous bone marrow transplantation (ABMT) are being increasingly utilized for the management of patients with relapsed Hodgkin's disease. Because patients with relapsed Hodgkin's disease often initially respond to salvage chemotherapy regimens, ABMT is frequently delayed until late in the course of the disease. The optimal timing for ABMT has not been identified. The purpose of this study was to determine the value of ABMT earlier in the course of Hodgkin's disease. PATIENTS AND METHODS: We treated 70 patients between October 1984 and October 1988 with high-dose cyclophosphamide, carmustine, and etoposide, followed by infusion of previously cryopreserved autologous bone marrow, and analyzed the results to determine the impact of timing of ABMT on treatment outcome. One (17 patients), two (24 patients), or three or more (29 patients) chemotherapy regimens had failed in patients before ABMT. RESULTS: The results for all 70 patients included a complete remission rate of 59%, an early death rate of 11%, a 4-year survival of 47%, and 27% of all treated patients alive and in complete remission at 4 years. The median follow-up for patients remaining in complete remission is 56 months (range 26 to 73 months). The frequency of achieving a complete remission was higher in patients in whom fewer regimens had failed before ABMT (i.e., 82% versus 58% versus 45%, p = 0.02), as was the 4-year disease-free survival (i.e., 44% versus 33% versus 21%, p = 0.04). CONCLUSION: ABMT is a more effective therapy when used early for patients with relapsed Hodgkin's disease.

Hematopathologic features of Epstein-Barr virus-induced human B-lymphoproliferation in mice with severe combined immunodeficiency. A model of lymphoproliferative diseases in immunocompromised patients.

The anatomical distribution, morphology, and clonality, of 'non-Hodgkin's lymphomas' in immunocompromised patients are usually distinctly different from NHL occurring in the general population. Mosier DE, Gulizia RJ, Baird SM, Wilson DB: Nature (London) 335:256, 1988 have described lymphoproliferative disease (LPD) of human B cell origin in mice with severe combined immunodeficiency (scid mice) after transfer of human peripheral blood mononuclear cells from Epstein-Barr virus-seropositive individuals. Reported herein is detailed information regarding the morphology, phenotypes, and clonality of LPD lesions in 10 of 18 scid mice that had developed LPD after transfer of peripheral blood mononuclear cells. These lesions were diffuse and monomorphic proliferations of immunoblastoid cells. They were invasive in their growth and often necrotic. Human B cell-related and activation-associated antigens were found on the LPD lesions, although the numbers of cells with the latter antigens were relatively small. Immunofixation electrophoresis for human immunoglobulins in sera of the majority of mice revealed oligoclonal populations, however, phenotypic and cytogenetic analyses showed no definite monoclonality. This scid mouse model is beneficial for understanding the early phases in the pathogenesis of LPD in immunocompromised patients.

Lymphotropic viruses as etiologic agents of lymphoma.

DNA and RNA virus with immortalized lymphocytes are described including Epstein-Barr virus and HTLV-I. The roles of immune deficiency and genetic alterations occurring in a proliferating cell are also considered.

The X-linked lymphoproliferative disease: from autopsy toward cloning the gene 1975-1990.

Although X-linked lymphoproliferative disease (XLP) is rare (1-2 males per 1 x 10(6)), it serves as a model for discerning diverse diseases caused by Epstein-Barr virus (EBV) ranging from agammaglobulinemia to fatal infectious mononucleosis following infection with the virus. The study of patients with XLP has also paved the way to understanding how EBV induce diseases in children with primary immunodeficiency diseases, organ transplant recipients, and those with acquired immunodeficiency syndrome. This review is dedicated to the memory of Gordon Vawter, M.D., who generously provided insights into the causes of pathogenesis of immune deficiency and lymphoproliferative disorders.

Immunoglobulin class and subclass deficiencies prior to Epstein-Barr virus infection in males with X-linked lymphoproliferative disease.

Patients with X-linked lymphoproliferative (XLP) disease are characterized by extreme vulnerability to Epstein-Barr virus (EBV). Following infection with EBV, affected males develop fatal infectious mononucleosis (IM), hypogammaglobulinemia (H), or non-Hodgkin's lymphoma (NHL). In addition, hyper IgM, red cell aplasia, necrotizing lymphoid vasculitis (NLV), and aplastic anemia occur rarely. The recent use of DNA restriction fragment length polymorphism (RFLP) probes in linkage with the XLP gene now permit detection of affected males prior to primary EBV infection. We have measured immunoglobulin class and subclass levels in sera from EBV-negative males who were either positive or negative for the XLP genotype by RFLP analysis. Elevated IgA or IgM and/or variable deficiency of IgG, IgG1, and IgG3 occurred in the sera of 13/13 RFLP-positive, EBV-negative males. No consistent abnormalities were noted in 14 RFLP-negative, EBV-negative males. We conclude that the immune defect in XLP is not solely EBV-specific, although EBV is responsible for most of the morbidity and all of the mortality. Further, serial measurement of Ig levels may provide information regarding status of EBV-negative males at risk where RFLP analysis is uninformative or in families where sporadic cases of fatal IM, acquired hypogammaglobulinemia or NHL have occurred, but wherein the genotype of XLP cannot be documented.

Epstein-Barr viral genome in lymph nodes from patients with Hodgkin's disease may not be specific to Reed-Sternberg cells.

A possible etiologic role for Epstein-Barr virus (EBV) in Hodgkin's disease (HD) was investigated by probing for EBV genome in 52 biopsy specimens involved with HD and 43 hyperplastic lymph node specimens. Using dot-blot hybridization (Bam HIW probe), Southern blot hybridization (Xho I probe), and polymerase chain reaction analyses, 27%, 27%, and 58% of the nodes with HD were positive for EBV genome, respectively, as compared to 16%, 14%, and 43% in the hyperplastic lymph nodes. Clonal and nonclonal episomal EBV and linear replicating EBV genome were present in both conditions. Immunoglobulin heavy chain gene rearrangements were found in two clonal and two nonclonal EBV-positive HD cases, but not in the lymphoid hyperplasia cases. These findings and other recent reports showing EBV genome in benign lymphoid cells by in situ hybridization in Hodgkin's disease suggest that the characteristics of EBV infection in HD could be explained by the reactive cellular milieu, especially in the setting of defective immunity. The identification of EBV genome in Reed-Sternberg cells may, therefore, be a nonspecific phenomenon.

Ideas in pathology. Pivotal role of increased cell proliferation in human carcinogenesis.

Cancer develops secondary to multiple genetic events. Each time a cell divides there is a rare chance that a genetic error related to the carcinogenic process will occur. Thus, environmental agents or disease processes that produce sustained increased cell proliferation can enhance the likelihood of cancer development by providing additional cell divisions, each with an opportunity for spontaneous genetic error. Studies of hereditary cancers and of various DNA-damaging agents, such as radiation and certain viruses and chemicals, have provided insight into identification of the essential genes, but many examples of carcinogenesis in humans do not involve direct DNA damage. Also, most preneoplastic lesions in human carcinogenesis show increased proliferation compared with normal tissues, whether from increased mitotic rate, blocked differentiation, prolonged cell survival, or other mechanisms. Selected examples of proliferation-related carcinogenesis are described, including certain infectious agents, defective immune surveillance, hormonal imbalances, chronic inflammatory-regenerative processes, and exposure to various chemicals. A common biologic mechanism for these diverse stimuli is increased cell proliferation as a prelude to cancer. This mechanism seems essential to the genesis of many cancers in humans.