Frequent T and B cell oligoclones in histologically and immunophenotypically characterized angioimmunoblastic lymphadenopathy

The identification of clonal rearrangements of T cell receptor (TCR) genes is central to the diagnosis of T cell lymphomas. However, in angioimmunoblastic lymphadenopathy (AILD), first described as a nonneoplastic proliferation associated with immunodeficiency, the heterogeneity of TCR and IgH gene rearrangements suggest that some cases may harbor multiple lymphoid clones. In this study we have isolated DNA from archival paraffin biopsy material from 22 cases of AILD identified on the basis of classical histological and immunohistochemical features with the aim of establishing the occurrence of clones and oligoclones, the frequency of TCR and immunoglobulin heavy chain (IgH) variable (v) gene use, and the relationship of these findings to the presence of Epstein-Barr virus. DNA extracted from the biopsies was amplified using the polymerase chain reaction (PCR) and sequenced to detect functional and nonfunctional gene rearrangements. Epstein-Barr virus-encoded short RNA species (EBERs) were detected using in situ hybridization combined with immunochemistry to identify the phenotype of the Epstein-Barr virus-infected cells. Fifty-seven clonal products were found in 20/22 patients: TCRgamma clonal products were identified in 16/22, TCRbeta clonal products in 16/22 and IgH clonal products in 6/22 cases. Oligoclonal PCR products were seen for TCR in 3/22 and for IgH in 3/22 cases. In one biopsy PCR products from all reactions were polyclonal. Sequence analysis revealed functional TCRgamma, TCRbeta, and IgH sequences in 6/12, 9/11, and 8/8 cases, respectively. Functional TCR and/or IgH oligoclones were detected in 6/20 (30%) cases. In addition, nonfunctional TCR and IgH sequences were found in 11 cases. EBERs were identified in 18/20 cases varying from occasional to 25 to 30% nuclei staining and were associated with both T and B cells, although the majority were of indeterminate phenotype. The presence of EBERs was not associated with all clonal IgH gene rearrangements but was associated with B cell oligoclones. Patterns of gene recombinations indicated that the majority of TCRgamma recombinations used GV1 and GJ1S3/2S3 genes. Six out of eleven cases used TCR BV4S1 or BV2S1 genes associated with various BJ and BD1/2 genes. No common IgH gene usage was identified, but 8 clones had varying degrees of replacement and silent mutations (0.6-10.1%), consistent with B cell clones having undergone somatic mutation in the germinal center, and 3 clones harbored unmutated V genes, consistent with naive B cells. Our data do not support the concept of AILD as a clearly defined peripheral T cell lymphoma (PTCL). Rather, they suggest that AILD as defined by histology and immunohistochemistry is either a heterogeneous entity or represents a lymphoproliferation associated with immunodeficiency in which clonal T cell or B cell proliferation may occur.     

血液系统肿瘤患者外周血细胞IgH基因和TCRγ基因的检测及意义

检测各种血液系统肿瘤患者外周血细胞免疫球蛋白重链基因 (IgH )和T细胞受体γ基因 (TCRγ )克隆性重排并探讨其意义。通过多聚酶链式反应 (PCR )方法检测 32例非霍奇金淋巴瘤 (NHL )、 18例急性髓性白血病 (AML )、 2 4例多发性骨髓瘤 (MM )、 8例急性淋巴细胞白血病 (ALL )及 6例慢性淋巴细胞白血病 (CLL )患者外周血细胞IgH及TCRγ克隆性基因重排。结果表明 ,NHL、AML、MM、ALL及CLL患者中IgH克隆性重排率分别为 37 5 0 %、 2 2 2 2 %、 83 33%、 12 5 0 %和 16 6 7% ;TCRγ基因克隆性重排率分别为 6 2 5 0 %、 5 0 0 0 %、 5 4 17%、 5 0 0 0 %及 5 0 0 0 %。在B型、T型NHL中 ,IgH克隆性重排率分别为 31 5 8%及 6 6 6 7% ;TCRγ克隆性重排率分别为 47 37%及 6 6 6 7%。AML中IgH克隆性重排阳性者的初治完全缓解率(CR ) (5 0 0 0 % )与IgH重排阴性的初治CR率 (5 0 0 0 % )无显著差异 (P >0 0 5 )。TCRγ克隆性重排阳性者与阴性者的初治CR率 (均为 44 44 % )亦无显著差异 (P >0 0 5 )。IgH及TCRγ基因克隆性重排不具有细胞谱系的特异性 ,但通过检测外周血IgH、TCRγ克隆性基因重排对NHL有辅助诊断意义 ,并且可作为监测微小残留病壮 (MRD )的手段。     

Comparative analysis of immunoglobulin polymerase chain reaction and flow cytometry in fine needle aspiration biopsy differential diagnosis of non‐Hodgkin B‐cell lymphoid malignancies

Single primer pair polymerase chain reaction (PCR) assays for the detection of clonal immunoglobulin heavy chain (IgH) gene rearrangements and immunophenotyping by flow cytometry have been proved as useful techniques in the diagnosis of lymphoid disorders in fine needle aspirates. However, a comparative analysis of both ancillary techniques in the same samples has not been previously performed. To compare the sensitivity of flow cytometry and PCR techniques, we made a wide prospective study of 77 fine needle aspiration biopsy (FNAB) samples from lymph nodes and extranodal lymphoid infiltrates. The adjunctive values of a single primer pair PCR amplification of IgH genes and of the immunophenotyping by flow cytometry were evaluated comparing their results with the final clinicopathological diagnosis of each patient supported by histological features and clinical follow up. Among the 24 B‐cell non‐Hodgkin lymphomas, monoclonal IgH bands were detected in 22 cases by PCR, and 21 cases were correctly considered B‐cell lymphoma by flow cytometry. A monoclonal IgH band was also detected in 1 of the 53 reactive lymphoid disorders. When both ancillary techniques were combined with morphological findings, 23 of the 24 B‐cell lymphomas were correctly diagnosed but one reactive lymphoid disorder was also considered a B‐cell lymphoma. We demonstrate a similar level of detection of B‐cell lymphomas by single round PCR and flow cytometry techniques, and a strong adjunctive value when combined with morphological findings to diagnose correctly lymphoproliferative disorders by FNAB. However, we must be cautious with PCR results since false‐positive cases can occur. Diagn. Cytopathol. 2009. © 2009 Wiley‐Liss, Inc.     

The polymerase chain reaction in the demonstration of monoclonality in T cell lymphomas.

AIMS--To evaluate polymerase chain reaction (PCR) amplification of T cell receptor (TCR) beta and gamma chain genes as a means of demonstrating monoclonality in T cell lymphomas using histological samples; to compare the performance of PCR with Southern blot analysis. METHODS--TCR-beta, TCR-gamma and immunoglobulin heavy chain (IGH) genes were analysed using PCR in 55 cases of T cell lymphoma (28 frozen tissue and 27 paraffin wax embedded samples), diagnosed using morphological and immunohistochemical criteria. The 28 frozen samples were subjected to Southern blot analysis using TCR-beta, TCR-gamma and IGH gene probes. Twenty five B cell lymphomas and 21 non-neoplastic lymphoid tissue samples were used as controls. RESULTS--Using TCR-beta PCR, monoclonality was detected in 24 (44%) of 55 T cell lymphomas compared with 43 (78%) of 55 using TCR-gamma PCR and in 82% with both techniques. Five (9%) of 55 T cell lymphomas were IGH PCR positive. None of the non-neoplastic lymphoid control samples were PCR positive. All B cell lymphomas showed a polyclonal pattern with TCR-beta PCR while a single B cell lymphoma was positive using TCR-gamma primers. With TCR-beta PCR, a monoclonal result was seen in 12 (43%) of 28 frozen samples of T cell lymphoma, compared with 23 (82%) of 28 using Southern blot analysis. With TCR-gamma PCR, 19 (68%) of 28 frozen tissue samples were positive, compared with 26 (93%) of 28 using Southern blot analysis. A single case showed IGH rearrangement by Southern blot analysis. CONCLUSION--TCR-gamma PCR should be the method of choice for analysis of clonality in paraffin wax embedded sections of lymphoproliferative lesions, as TCR-beta PCR has a high false negative rate. Southern blot analysis remains the most successful technique when sufficient fresh tissue samples and resources are available.     

VJ REARRANGEMENTS OF THE TCRγ LOCUS IN PERIPHERAL T-CELL LYMPHOMAS: ANALYSIS BY POLYMERASE CHAIN REACTION AND DENATURING GRADIENT GEL ELECTROPHORESIS

Using Southern blotting for the diagnosis of clonality in peripheral T-cell lymphomas (PTCLs), analysis of the T-cell receptor (TCR) γ gene rearrangement was shown to be more informative than that of the TCR β gene rearrangement. In order to amplify every VJγ rearrangement, a polymerase chain reaction (PCR) procedure using newly designed GC-clamp primers has been developed. All primers can be mixed in a single multiplex PCR. PCR products are analysed by denaturing gradient gel electrophoresis (DGGE), providing tumour-specific imprints inasmuch as the procedure characterizes N sequence polymorphism at the VJ junctions. In a series of 30 PTCL cases, the PCR procedure demonstrated 27 cases to be clonally rearranged and failed in three cases. PCR was more accurate than Southern blotting, showing 47 rearranged γ alleles, four of which were undetectable on the Southern blot. When lymphomas were studied at different sites and at relapse, the DGGE pattern remained unchanged. In PTCL, the proposed PCR is helpful for the diagnosis and staging of the disease and should improve the follow-up monitoring. The undetectability of clonal rearrangements in a few cases is discussed in the light of concepts of lymphomagenesis and T-cell differentiation.     

Sensitivity of PCR in detecting monoclonal B cell proliferations.

AIMS--To evaluate the rapid detection of various forms of monoclonal B cell proliferations by using the polymerase chain reaction (PCR) to identify clonal immunoglobulin heavy chain genomic rearrangements. METHODS--Thirty four B cell lymphomas defined by morphology, immunophenotyping, and positive immunoglobulin heavy chain gene rearrangements detected by Southern blot analysis were examined. An additional 22 cases representing miscellaneous lymphoproliferative and non-lymphoproliferative disorders were also studied. RESULTS--Monoclonal rearrangements were identified in 19 (56%) cases of B cell lymphoma. The method was less sensitive in the detection of follicular centre cell lymphomas (15 of 28, or 54%) than non-follicular centre cell lesions (four of six, or 67%). Monoclonal rearrangement was not identified in 19 control cases, including T cell lymphomas, Hodgkin's disease, reactive lymphadenopathy and metastatic carcinoma. Three cases showed positive immunoglobulin gene rearrangement by PCR but were negative on Southern blotting. Two of these cases had definite clinical, morphological, and immunophenotypic evidence of monoclonal B cell proliferation suggesting that PCR could, on occasion, pick up cases missed by Southern blotting and that the two methods are complementary in clonal lymphoproliferative disease diagnosis. The third case represented a "false positive" PCR reaction involving a colonic adenocarcinoma. CONCLUSIONS--PCR analysis, using the primer sequences outlined in this study, will detect about 55% of clonal lymphoproliferative proliferations with increased sensitivity for non-follicular centre cell lesions. With these levels of detection in mind, this testing strategy can still be especially useful in cases which prove diagnostically problematic with standard morphological and immunophenotypic analysis, and in instances where the quantity and type of diagnostic material is limiting (needle aspirates and cellular fluids).     

Polymerase chain reaction screening of immunoglobulin heavy chain and T cell receptor γ gene rearrangements: A practical approach to molecular DNA analysis of non-Hodgkin's lymphoma in a surgical pathology laboratory

Characterization of the clonality of non-Hodgkin's lymphoma (NHL) by the rearranged segments of immunoglobulin heavy chain (Ig(H)) or T cell receptor (TCR) genes is not only useful in the confirmation of the diagnosis but also for the future assessment of how a secondary lymphoma, such as a recurrence or another primary lymphoma, occurs. As a practical approach to obtaining and registering this information in a surgical pathology laboratory, FR3 and FR1 regions of Ig(H) gene and TCRgamma gene were concurrently amplified by polymerase chain reaction (PCR) using each pair of consensus primers and the same PCR protocol. Examined samples consisted of 134 primary NHL (phenotypically, 108 B cell and 26 T cell NHL), 19 reactive lymphadenopathies, as well as five secondary lymphomas whose primary lesions were included in this study. Among the primary NHL, the combined PCR analysis disclosed the clonality in 103 of 134 NHL (77%), by FR3 PCR in 77 B cell and two T cell NHL, by FR1 PCR in 59 B cell and one T cell NHL, and by TCRgamma PCR in 11 B cell and 17 of 26 T cell NHL, but in none of the reactive lymphadenopathies. Among the secondary lymphomas, the same pattern of PCR analysis was obtained in two cases (the durations between first and second lymphomas; 6 and 10 months), which suggested recurrence. In contrast, different results were obtained in three cases (17-37 months), which indicated another primary or emergence of the subclones. The results of Southern blot analysis were concordant with the PCR results of the first and the secondary lymphomas. Although the combined PCR analysis cannot replace Southern blot hybridization because of its lower detection rate, it can select those cases suitable for further Southern blot analysis thus reducing the number of unnecessary examinations by nearly 75%. This approach may also be useful in the comparative evaluation of primary and secondary lymphomas.     

Combined analysis of T cell receptor gamma and immunoglobulin heavy chain gene rearrangements at the single-cell level in lymphomas with dual genotype

By prospectively studying immunoglobulin heavy chain gene (IgH) and T cell receptor gamma (TCRgamma) gene rearrangements in 398 lymphoma cases, a dual genotype was observed in 13% of B cell and 11% of T cell lymphomas. According to histological subtype, the highest incidence was observed for mantle cell lymphomas (32%) and lymphoplasmacytic lymphoma (21%) among B cell lymphomas, and for angioimmunoblastic lymphoma (AILT) (46%) and Sézary syndrome (SS) (50%) among T cell lymphomas. To determine whether the dual genotype corresponds to the presence of two distinct monoclonal populations or to the presence of both rearrangements within the same lymphoma cells, single-cell microdissection was used after immunohistochemistry and a single-cell combined IgH and TCRgamma gene analysis was designed after a whole-genome amplification step. This protocol was applied to the study of two nodal B cell lymphomas (one diffuse large B cell lymphoma and one mantle cell lymphoma) and two cutaneous T cell lymphomas (one AILT and one SS). Two cases (SS and mantle cell lymphoma) were true bigenotypic lymphomas, as both IgH and TCRgamma monoclonal rearrangements were detected in the same cells. Conversely, in the diffuse large B cell lymphoma and AILT cases, large CD22+ single cells exhibited only the monoclonal IgH rearrangement but not the TCRgamma gene that was detected in CD3+ single cells. Such an approach allows the identification of true bigenotypic lymphoma among dual genotypic lymphoma. Specific genetic alterations may be further amplified from microdissected cryopreserved material, such as the t(11;14) breakpoint detected in bigenotypic B cells of the mantle cell lymphoma case.     

B淋巴细胞增生性疑难病例中IgH基因克隆性重排的分析

目的 探讨IgH基因克隆性重排对B淋巴细胞增生性疑难病变的辅助诊断价值.方法 检测77例B淋巴细胞增生性疑难病例中IgH基因的克隆性重排情况,均采用BIOMED-2系统IgH克隆性试剂盒中FR1、FR2、FR3三组家族引物进行PCR及聚丙烯酰胺凝胶电泳,硝酸银染色后观察,并对照最终病理诊断进行分析.结果 77例病变的最终病理诊断:B淋巴细胞反应性增生12例,不能排除B淋巴细胞不典型增生或淋巴瘤20例,B细胞性淋巴瘤45例.三组中FR1、FR2和FR3至少有一个为阳性的比值分别为2/12、11/20(55%)和36/45(80%).B细胞性淋巴瘤中,FR1、FR2和FR3的阳性率分别为60%(27/45)、60%(27/45)、56%(25/45),其类型有边缘区B细胞性淋巴瘤20例(其中黏膜相关淋巴组织型结外边缘区淋巴瘤18例,结内边缘区淋巴瘤2例),弥漫性大B细胞淋巴瘤7例,滤泡性淋巴瘤7例,套细胞性淋巴瘤1例,Burkitt淋巴瘤1例,浆细胞瘤4例,不能分型5例.FR1、FR2和FR3三者检测均为阴性但仍诊断为淋巴瘤9例(20%),其中1例后来出现肝脏B细胞淋巴瘤.对IgH基因重排阳性的B淋巴细胞反应性增生和不典型增生14例的随访结果,4例重新取活检后诊断为B细胞性淋巴瘤,其中3例IgH基因重排检测为阳性.结论 联合检测IgH基因FR1、FR2和FR3克隆性重排对B淋巴细胞增生性疑难病变诊断有重要的辅助价值;对形态改变和免疫表型诊断淋巴瘤依据不足而基因重排阳性者,重取活检或随访有一定价值;对阴性病例有必要补充IgH基因重排及IgK和IgL基因重排的检测以提高检测敏感性.     

Biclonality of gastric lymphomas

The pathogenesis and clonal evolution of gastric diffuse large B-cell lymphoma (DLBCL) and its relationship to extranodal marginal zone B-cell lymphoma (MZBL), mucosa-associated lymphoid tissue (MALT) type, are still controversial. The aim of this study was to establish the clonality of morphologically distinct areas of gastric lymphomas as well as their genetic relationship to each other. Six gastric lymphomas, consisting of two MZBL, MALT type, two DLBCL, and two "composite" lymphomas were subjected to laser capture microdissection and subsequent PCR-based amplification of the immunoglobulin heavy chain gene. One DLBCL showed a biclonal pattern of rearranged immunoglobulin heavy chain (IgH) genes of two different areas without evidence of a common origin. Two composite DLBCL with areas of extranodal MZBL, MALT type, were also biclonal and displayed different IgH gene rearrangements in the small-cell and in the large-cell components, respectively. Sequencing of the CDR3 region revealed unique VH-N-D and D-N-JH junctions, thus corroborating the presence of two genuinely distinct tumor clones in each of these three cases. In contrast, the remaining three gastric lymphomas (one DLBCL and two MZBL, MALT type) showed IgH gene rearrangements in which CDR3 regions were identical in the different tumor areas. Our results suggest that gastric DLBCL may be composed of more than one tumor cell clone. Further, DLBCL may not necessarily evolve by transformation of a low-grade lymphoma, but may also originate de novo. An ongoing emergence of new tumor clones may considerably hamper molecular diagnosis and follow-up of gastric DLBCL.     

Differentiation between actinic reticuloid and cutaneous T cell lymphoma by T cell receptor gamma gene rearrangement analysis and immunophenotyping.

AIMS: Differentiation between actinic reticuloid and cutaneous T cell lymphoma can be extremely difficult. Demonstration of clonal T cell receptor (TCR) gene rearrangements has been suggested as a potential diagnostic criterion, but the results obtained thus far have been conflicting. This study investigated whether TCR gamma gene rearrangement analysis, using polymerase chain reaction (PCR) in combination with denaturing gradient gel electrophoresis (DGGE) and immunohistochemistry, can serve as a diagnostic criterion. METHODS: PCR/DGGE was performed on skin, peripheral blood mononuclear cells, and/or lymph nodes of seven patients with actinic reticuloid, 11 patients with Sézary syndrome, and 15 patients with a benign form of erythroderma. The results of PCR/DGGE and Southern blot analysis of TCR beta gene rearrangements were compared. In addition, CD4:CD8 ratios in skin and peripheral blood samples were investigated. RESULTS: Clonal T cell populations were detected in 19 of 21 samples obtained from patients with Sézary syndrome but were not detected in any of the 12 samples from patients with actinic reticuloid. Clonal T cells were detected in the peripheral blood of only one of 15 patients with a benign form of erythroderma. PCR/DGGE and Southern blot analysis gave concordant results in 28 of 29 samples. Immunophenotypic analysis demonstrated increased proportions of CD8+ T cells in skin (seven of seven cases) and peripheral blood (four of seven cases) of patients with actinic reticuloid. CONCLUSION: The results of this study demonstrate that gene rearrangement analysis, in combination with immunohistochemistry, may be an important adjunct in differentiating between actinic reticuloid and cutaneous T cell lymphoma. In patients suspected of having actinic reticuloid, application of both techniques is recommended.     

Complexities in the diagnosis of large B-cell lymphomas,classic Hodgkin lymphomas and overlapping peripheral T-cell lymphomas simplified: An evidence-based guide

The diagnosis of a large B-cell lymphoma and classic Hodgkin lymphoma (CHL) is often straightforward. However, in select circumstances, these simple diagnoses can be quite complex. In part, diagnostic difficulty may be due to uncertainty in the evaluation of morphologic and immunophenotypic features along a biologic continuum, or alternatively arise from uncertainty in predicting the behavior and outcomes of patients. Here, we systematically discuss and review areas of diagnostic difficulty in the diagnosis of large B-cell lymphomas (LBCL), classic Hodgkin lymphomas (CHL) and peripheral T-cell lymphomas (PTCL). We provide careful data-driven analyses and evidence-based approaches to help guide pathologists and clinicians. We discuss: 1) marginal zone lymphomas with increased large cells versus diffuse large B-cell lymphoma (DLBCL), 2) chronic lymphocytic leukemia with expanded proliferation centers versus diffuse large B-cell lymphoma (DLBCL), 3) chronic lymphocytic leukemia with Hodgkin/Reed-Sternberg-like cells versus CHL arising from chronic lymphocytic leukemia, 4) complex cases of follicular lymphoma versus DLBCL, 5) PTCL with large B-cell proliferations versus PTCL with LBCL, 6) PTCL with Hodgkin/Reed-Sternberg-like cells versus CHL, and finally 7) blastoid/pleomorphic mantle cell lymphoma versus DLBCL. Our evidence and data driven approach may serve as a useful diagnostic guide.     

Sequential development of diffuse large B-cell lymphoma in a patient with angioimmunoblastic T-cell lymphoma

Lymphoma of different histologic type can occur in the same patient. Here, we describe a 64-year-old male patient with angioimmunoblastic T-cell lymphoma (AITL) who subsequently developed diffuse large B-cell lymphoma (DLBCL). At the time of initial diagnosis, histologic examination of a left inguinal lymph node of the patient and a monoclonal pattern of TCRβ gene rearrangement showed typical features of AITL, and there was no evidence of a monoclonal B-cell population. Twenty-six months later, he had generalized lymphadenopathy and organs involvement by DLBCL. A monoclonal IgH gene rearrangement proved de novo development of secondary B-cell lymphoma and excluded relapse of a primary composite lymphoma. The in situ hybridization analysis showed Epstein-Barr-encoded RNA (EBER) sporadic positivity in sample collected from AITL but extensive positivity in the immunoblasts collected from DLBCL. Our observation supports the hypothesis that Epstein-Barr virus (EBV) is etiologically related to AITL in this case. Clonal expansion of EBV-associated DLBCL is a secondary event in AITL via EBV infection or reactivation.     

Analysis of T cell receptor-gamma gene rearrangements by denaturing gradient gel electrophoresis of GC-clamped polymerase chain reaction products. Correlation with tumor-specific sequences.

We describe a modified denaturing gradient gel electrophoresis (DGGE) procedure with a 40-nucleotide GC clamp in the polymerase chain reaction to improve resolution in amplifying T cell receptor-gamma (TCR-gamma) rearrangements. DNA from 46 cases of lymphoblastic leukemia/lymphoma, 5T cell lines, 2 B cell lines, 7 normal lymphocytes, and 3 cases of Hodgkin's disease was amplified by polymerase chain reaction. In addition, 20 cases of paraffin-embedded T cell lymphomas and 5 cases of reactive hyperplasia were also studied. Clonal TCR-gamma rearrangements were identified on DGGE by the presence of a predominant band. Results obtained from 5 T cell lines and 12 lymphoblastic leukemia/lymphomas containing known TCR-gamma gene rearrangements revealed 100% concordance in detecting clonal rearrangements between DGGE and traditional Southern blot analysis. Of the remaining 34 lymphoblastic leukemia/lymphoma cases studied by DGGE alone, 30 were positive. DGGE analysis of 10 lymphoblastic leukemia/lymphoma cases with known group IV gamma to J gamma 1 or J gamma 2 rearrangement sequences confirmed that the electrophoretic migration was dependent on the tumor-specific rearranged TCR-gamma sequence. In addition, 17 of 20 cases of paraffin-embedded T cell lymphomas were positive by DGGE, 6 of which had the clonal population also identified in fresh tissue DNA. DGGE analysis of GC-clamped polymerase chain reaction products can provide a way to more accurately detect TCR-gamma clonality of lymphoid tumors and can be applied to archival tissues.     

Absence of clonal beta and gamma T-cell receptor gene rearrangements in a subset of peripheral T-cell lymphomas.

The authors describe a set of seven peripheral T-cell lymphomas that lack detectable rearrangements of T-cell receptor (TCR) genes. All cases showed antigenic profiles consistent with T-cell lymphoma, including expression of Leu-5 (CD2) antigen. However, few other T-lineage markers were found, and none of the cases tested (6 of 7) bound antibody recognizing the constant region of the beta TCR protein. Each case showed exclusively germline configurations of DNA for the beta TCR genes in Southern blot analyses with the use of several different combinations of restriction enzymes and DNA hybridization probes. One case contained clonal rearrangements of the gamma TCR gene and of the immunoglobulin heavy chain gene. Our results suggest that certain cases of peripheral T-cell lymphoma may lack rearrangements of TCR genes--particularly those cases expressing restricted numbers of T-lineage antigens. In view of these findings, failure to detect rearrangements of TCR genes by Southern blot analyses is not necessarily inconsistent with malignant lymphocytic proliferations in T-lineage neoplasia.     

Polymerase chain reaction (PCR) detection of B cell clonality in Sjögren's syndrome patients: a diagnostic tool of clonal expansion

Sjögren's syndrome (SS) is an autoimmune disease characterized by clonal B cell attack of the exocrine glands and dysregulated expression of B cell‐activating factor (BAFF). Based upon the current data of increased rates of lymphoid malignancy, as non‐Hodgkin's lymphoma (NHL) is associated with SS, we propose the detection of clonal rearrangements of immunoglobulin heavy chain (IgH) gene in those patients as a predictor of malignant clonal expansion. To test our proposal, we examined the IgH clonal rearrangements in SS patients (60) and healthy control subjects (42) having chronic non‐specific sialadenitis, to determine the presence of clonal B cells in minor labial salivary glands (MSG) of SS patients. Clonal B cell expansion was assessed by two polymerase chain reaction (PCR) assays: (i) semi‐nested PCR, against sequences encoding framework regions FR3, FR2 and FR1c of the variable chain IgH gene in B cells present in the MSG infiltrate; and (ii) the PCR–enzyme‐linked immunosorbent assay (ELISA) technique, against the major and minor breakpoint regions of the Bcl‐2 oncogene coupled with a variable segment of the IgH to assess the Bcl‐2/JH translocation. When FR3, FR2 and FR1c primers were employed, we detected B cell monoclonality in 87% of the SS patients and 19% of the control subjects. The association between inflammation severity of the MSG pattern and the presence of B cell clonality was found to be statistically significant (P < 0·01). We concluded that the presence of B cell clonality in MSG can be used as a index of an altered microenvironment favouring the development of lymphoma in SS patients.     

TET2 mutations in B cells of patients affected by angioimmunoblastic T‐cell lymphoma

Angioimmunoblastic T‐cell lymphomas (AITLs) frequently carry mutations in the TET2 and IDH2 genes. TET2 mutations represent early genetic lesions as they had already been detected in haematopoietic precursor cells of AITL patients. We show by analysis of whole‐tissue sections and microdissected PD1⁺ cells that the frequency of TET2‐mutated AITL is presumably even higher than reported (12/13 cases in our collection; 92%). In two‐thirds of informative AITLs (6/9), a fraction of B cells was also TET2‐mutated. Investigation of four AITLs by TET2 and IGHV gene sequencing of single microdissected B cells showed that between 10% and 60% of polyclonal B cells in AITL lymph nodes harboured the identical TET2 mutations of the respective T‐cell lymphoma clone. Thus, TET2‐mutated haematopoietic precursor cells in AITL patients not only give rise to the T‐cell lymphoma but also generate a large population of mutated mature B cells. Future studies will show whether this is a reason why AITL patients frequently also develop B‐cell lymphomas. Copyright © 2017 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Clinicopathological features of double‐hit B‐cell lymphomas with MYC and BCL2, BCL6 or CCND1 rearrangements

Double‐hit (DH) lymphomas are B‐cell lymphomas characterized by chromosomal rearrangements, specifically of MYC and either BCL2, BCL6 or CCND1. We reviewed 22 cases of DH lymphomas. BCL2/MYC DH lymphomas constituted the majority of these DH lymphomas (17 cases; 77%), followed by BCL6/MYC (2 cases; 9%) lymphomas. Assessing morphological features using the 2008 World Health Organization classification system, 15 cases (68%) were determined to be B‐cell lymphoma, unclassifiable with features intermediate between diffuse large B‐cell lymphoma (DLBCL) and Burkitt lymphoma (BCLU) (10 cases; 45%), or as DLBCL (5 cases; 23%), and 2 cases (9%) were classified as morphologically untransformed follicular lymphoma. Burkitt lymphoma was rare (1 case; 5%) among DH lymphomas. Nineteen cases were treated with R‐CHOP or a high dose chemotherapy regimen. After a median follow‐up of 11 months, 7 patients had died, and the 1‐year survival rate was 62.5%. High dose chemotherapy did not improve the outcome. We suggest that screening of genetic variations to detect DH lymphomas is required in diagnosing all lymphomas, even those determined morphologically to be follicular lymphoma.     

Discordant bone marrow involvement in diffuse large B-cell lymphoma: comparative molecular analysis reveals a heterogeneous group of disorders

Discordant bone marrow (BM) involvement in patients with a diagnosis of large-cell non-Hodgkin's lymphoma (NHL) is characterized by marrow infiltrates predominantly composed of small lymphoid cell, cytologically compatible with low-grade NHL. Although this phenomenon is well described morphologically, molecular data concerning the relationship of the two lesions are lacking. The aim of the study was to investigate the clonal relationship of discordant lymphoma manifestations by using immunoglobulin heavy chain gene (IgH), as well as bcl-2 rearrangements, as molecular markers. IgH rearrangements were amplified by PCR with consensus primers directed against framework regions 3 or 2 (FR3 and FR2), followed by automated fragment length analysis and sequencing in selected cases. Rearrangements of the bcl-2 gene were identified with primers against the major breakpoint region. Small BM infiltrates were isolated by laser capture microdissection. In addition, immunohistochemistry was performed on paraffin sections using antibodies against CD3, CD10, CD20, bcl-2, bcl-6, p53, and the Ki67 antigen. Paraffin-embedded tissues of 21 cases diagnosed as diffuse large B-cell lymphoma (DLBCL) with discordant BM involvement and no previous history of low-grade B-cell NHL were analyzed. After review of immunohistochemical stains, 5 cases were excluded either as concordant BM infiltrates by large-cell lymphoma with abundant reactive T-cells (2 cases) or as benign, reactive lymphoid infiltrates (3 cases), as confirmed by a polyclonal pattern in the IgH analysis. Of the remaining 16 cases, a common clonal origin was confirmed in 8 cases by the presence of an identical clonal IgH rearrangement or bcl-2 rearrangement. In 4 cases, identification of distinct IgH or bcl-2 rearrangements gave evidence for the presence of two clonally unrelated neoplasms. The remaining 4 cases were not evaluable for technical reasons. Morphological, phenotypical, and molecular findings were compatible with a lymphoma of germinal center origin in the majority of cases. However, in 4 cases, flow cytometric analysis of the BM infiltrates revealed a B-cell chronic lymphocytic leukemia phenotype. Two of these cases were clonally related to the DLBCL and thus represented Richter's transformation. In summary, discordant BM infiltrates in DLBCL represent a heterogeneous group of disorders, encompassing cases with a clonally related, clinically occult small-cell component, as well as cases with two clonally distinct, unrelated B-cell neoplasms presenting synchronously at different locations.