Hodgkin's disease with a B-cell phenotype often shows a VDJ rearrangement and somatic mutations in the VH genes

The nature of Hodgkin and Reed-Sternberg (HRS) cells remains in question. Immunophenotypic studies favor a relation to the lymphoid lineage with the existence of B- and T-cell types. However, studies on the detection of antigen (Ag) receptor gene rearrangements provided inconsistent results. They concur in that rearranged Ig and T-cell receptor (TCR) genes are not demonstrable in most Hodgkin's disease (HD) cases. To clarify whether this is because of the insensitivity of the method of detection or a real absence of clonal Ig heavy chain (IgH) rearrangements, a polymerase chain reaction (PCR) method with high sensitivity was applied, allowing the detection of less than 50 cells with clonally rearranged IgH genes in a mixture of 100,000 germline or individually rearranged cells. In 67 cases of HD, most of those (67%) with B-Ag+ HRS cells express clonal VDJ rearrangements of the IgH gene. No cases with T-cell Ag+ HRS cells harbored detectable clonal VDJ rearrangements. Of 10 sequenced rearranged IgH genes, the VH segment of six contained considerable somatic mutations. These results suggest that the demonstrated VDJ rearrangements stem from the HRS cells themselves and that the HRS cells of cases with rearranged IgH genes are B-cell related and correspond in their differentiation stage either to naive pregerminal center B cells or (more commonly) to germinal center/postgerminal center-derived memory B cells.     

Hodgkin and Reed-Sternberg-like cells in B-cell chronic lymphocytic leukemia represent the outgrowth of single germinal-center B-cell-derived clones: potential precursors of Hodgkin and Reed-Sternberg cells in Hodgkin's disease

In rare cases of B-cell chronic lymphocytic leukemia (B-CLL), large cells morphologically similar to or indistinguishable from Hodgkin/Reed-Sternberg (HRS) cells of Hodgkin's disease (HD) can be found in a background of otherwise typical B-CLL. To test these HRS-like cells for a potential clonal relationship to the B-CLL cells, single cells were micromanipulated from immunostained tissue sections, and rearranged immunoglobulin genes were amplified from HRS-like cells and B-CLL cells and sequenced. The same variable (V) gene rearrangements with shared and distinct somatic mutations were found in HRS-like and B-CLL cells from 1 patient, which indicates derivation of these cells from 2 distinct members of a germinal-center B-cell clone. Separate clonal V gene rearrangements were amplified from HRS-like and B-CLL cells from 2 other patients, showing concomitant presence of 2 distinct expanded B-cell clones. Epstein-Barr virus (EBV) was detected in the HRS-like cells of these 2 latter cases, indicating clonal expansion of an EBV-harboring B cell in the setting of B-CLL. There is evidence that HRS-like cells in B-CLL, like HRS cells in HD, derive from germinal-center B cells. In all cases, somatic mutations have been detected in the rearranged V genes of the HRS-like cells, and in 1 of the EBV-positive HRS-like cell clones, somatic mutations rendered an originally functional V gene rearrangement nonfunctional. We speculate that the HRS-like cells in B-CLL represent potential precursors for HRS cells causing HD.     

Detection of clonal T-cell receptor gamma-chain gene rearrangements in Reed-Sternberg cells of classic Hodgkin disease

Recent molecular single-cell studies have shown that in approximately 95% of cases, Reed-Sternberg cells of classic Hodgkin disease (HD) are derived from B cells of germinal center origin. Attempts to determine the cellular nature of the remaining cases have so far failed. To clarify whether they are derived from T cells, this study examined 791 single CD30(+) Hodgkin and Reed-Sternberg (HRS) cells from 13 T-cell marker-positive cases and from 6 cases with null-cell phenotype for rearranged T-cell receptor-gamma (TCR-gamma) genes by single copy polymerase chain reaction. Monoclonally rearranged TCR-gamma genes were detectable in 2 of the 13 classic HD cases with T-cell marker-positive HRS cells, with none detectable in the null-cell cases. Eight of the T-cell marker-positive cases and all 6 null-cell cases were also studied for rearrangements of immunoglobulin genes. Six of the 8 T-cell marker-positive cases harbored clonal immunoglobulin gene rearrangements. The 2 cases without rearranged immunoglobulin genes were those that contained clonal TCR-gamma rearrangements and lacked expression of the B-cell-specific activator protein. From these findings we conclude that cases of classic HD with T-cell-derived HRS cells definitely exist, although their overall incidence at 1% to 2% is very low. Even within the T-cell marker-positive cases only a minority (15%) were derived from T cells. The majority (85%) originated from B cells, indicating that the T-cell antigens expressed by HRS cells are, in contrast to those expressed in non-Hodgkin lymphoma, not lineage specific.     

Molecular single-cell analysis of the clonal relationship of small Epstein-Barr virus-infected cells and Epstein-Barr virus-harboring Hodgkin and Reed/Sternberg cells in Hodgkin disease

Epstein-Barr virus (EBV) can be detected in the tumor cells of approximately 40% of cases of classical Hodgkin disease (cHD). Clonality studies suggest that infection of the neoplastic Hodgkin and Reed/Sternberg (HRS) cells occurs before tumor clone expansion. In EBV-positive cases, variable numbers of EBER-positive small B cells are sometimes also observed that immunohistologically differ from the neoplastic cells by lack of CD30 and latent membrane protein 1 expression. To analyze the clonal relationship between these EBV(+) cells and the HRS cells, single EBV-infected CD30(-) B cells, as well as HRS cells from 3 cases of EBV-positive cHD were micromanipulated, their immunoglobulin gene rearrangements amplified and then compared with each other. In 2 cases, all small EBV-infected cells were clonally unrelated to the HRS cells. In a third case, 2 of 29 small CD30(-) cells were found to carry HRS cell-specific rearrangements. Thus, small CD30(-) EBV-infected B cells in cHD belong to the HRS tumor clone rarely, if at all. In all cases, small clones unrelated to the HRS cell clones were identified among the small EBV(+) CD30(-) cells. The vast majority of small EBV(+) CD30(-) B cells was found to carry somatically mutated V region genes, indicating that in lymph nodes of patients with HD, like in the peripheral blood of healthy individuals, EBV persists in memory B cells.     

Hodgkin disease: Hodgkin and Reed-Sternberg cells picked from histological sections show clonal immunoglobulin gene rearrangements and appear to be derived from B cells at various stages of development.

Hodgkin disease (HD) is characterized by a small number of putative malignant cells [Hodgkin and Reed-Sternberg (HRS) cells] among a background of lymphocytes and histiocytes. The lineage of HRS cells is still elusive and a clonal origin of these rare cells has not formally been demonstrated. We isolated HRS cells by micromanipulation from histological sections of three cases of Hodgkin lymphoma (each representing a distinct subtype of the disease) and analyzed individual cells for immunoglobulin variable (V) gene rearrangements by PCR. In each of the three cases a single heavy-chain V (VH) (and in one case, in addition, a kappa light-chain) gene rearrangement was amplified from the HRS cells, identifying these cells as members of a single clone. A potentially functional VH rearrangement was obtained from a case of nodular sclerosis HD. Somatic mutations and intraclonal diversity in the VH genes indicate a germinal center B-cell origin of the HRS cells in a case of lymphocyte-predominant HD, whereas in a case of mixed-cellularity HD the sequence analysis revealed only nonfunctional V gene rearrangements, suggesting a pre-B-cell origin. This indicates that HRS cells can originate from B-lineage cells at various stages of development.     

Analysis of BCL-6 mutations in classic Hodgkin disease of the B- and T-cell type

BCL-6 is essential for germinal center formation and thus for affinity maturation of immunoglobulin (Ig) genes by somatic mutations. The 5'-noncoding region of the BCL-6 gene is even a target for the mutation machinery. Translocations of the BCL-6 gene to heterologous promoters and mutations of its 5'-noncoding regulatory region were reported to be potential mechanisms for deregulating BCL-6 expression and for playing a role in the genesis of non-Hodgkin lymphoma. In line with this hypothesis is the observation that B-cell lymphoma with somatic mutations, such as diffuse large B-cell lymphoma and follicular lymphoma, also carry BCL-6 mutations, some of which are recurrently detectable. Classic Hodgkin disease (cHD) is also derived from B cells with high loads of somatic mutations and thus a further candidate for BCL-6 mutations. To determine the presence and potential role of BCL-6 mutations in cHD, the 5'-noncoding BCL-6 proportion of single Hodgkin and Reed-Sternberg (HRS) cells from 6 cases of cHD and 6 cases of HD-derived cell lines was analyzed. All B-cell-derived HD cases and cell lines harbored BCL-6 mutations. In contrast, both T-cell-derived HD cases and cell lines were devoid of BCL-6 mutations. With only one exception, there were no lymphoma-specific recurrent BCL-6 mutations detected, and BCL-6 protein was absent from the HRS cells of most cases. In conclusion, (1) somatic BCL-6 mutations are restricted to cHD cases of B-cell origin, and (2) the BCL-6 mutations represent mostly irrelevant somatic base substitutions without consequences for BCL-6 protein expression and the pathogenesis of cHD.     

Clonal relation in a case of CLL,ALCL, and Hodgkin composite lymphoma

Large cell lymphomas and Hodgkin disease may develop during the course of chronic lymphocytic leukemia (CLL). In some cases the transformed cells are Epstein-Barr virus (EBV)-positive and not clonally related to the CLL cells. In other cases the transformed cells have the same clonal rearrangements as the CLL cells. Here we describe a composite lymphoma in a patient with CLL that exhibits a combination of CLL/small lymphocytic lymphoma, large cell lymphoma with anaplastic morphology, and Hodgkin lymphoma (HL). Although the large cell lymphoma cells are CD45R0 and TIA-1-positive, suggesting a T- or 0-cell anaplastic large cell lymphoma (ALCL), the genetic analysis demonstrates immunoglobulin heavy chain (IgH) gene rearrangements for both alleles, carrying the same somatic mutations as observed in the CLL component. The Reed-Sternberg (R-S) cells in the Hodgkin component also strongly express TIA-1 but differ from the anaplastic large cells by the expression of CD15 and TARC and the presence of a prominent lymphocytic infiltrate. The ALCL and HL components both are EBV negative. Analysis of the IgH gene rearrangements in micromanipulated R-S cells revealed identical Ig gene rearrangements carrying the same somatic mutations as the CLL and the large cell components. The findings indicate transformation of the CLL cells into a large cell lymphoma with anaplastic morphology and a Hodgkin component.     

Mutation of the p53 gene is not a typical feature of Hodgkin and Reed-Sternberg cells in Hodgkin's disease.

Point mutations of the p53 tumor suppressor gene are a frequent finding in human carcinomas and are thought to be an important oncogenic event. In non-Hodgkin lymphomas, p53 mutations occur in a minor fraction of cases. However, conclusive data are still lacking for Hodgkin's disease (HD) where the analysis meets technical problems. The neoplastic tumor cell clone in HD is represented by the large Hodgkin and Reed-Sternberg (HRS) cells, which account for only a minority of all cells in the tumor tissue (often <1%). To identify putative HRS cell-specific mutations, single HRS cells were micromanipulated from frozen tissue sections of HD biopsy specimens. Exons 4 to 8 of the p53 gene (in which more than 90% of p53 mutations associated with human neoplasms occur) were amplified from these single cells and sequenced. Mutations of p53 were not found in HRS cells of any of 8 cases of HD analyzed. We conclude that mutation of the p53 gene is only rarely, if at all, involved in the pathogenesis of HD.     

Off-targeting oft-targeted CD20 in cHL

We now think of classical Hodgkin lymphoma (cHL) as derived from "crippled" germinal center B cells that have frequently acquired rearranged and somatically mutated Ig genes.1,2 Despite their B-cell origin, the malignant Hodgkin and Reed-Sternberg (HRS) cells have lost most of the superficial trappings of B cells and therefore have been hidden from investigators' lenses for decades, prompting an arduous but persistent race to uncover the mystery of the HRS cell.     

Cellular origin and clonality of classic Hodgkin's lymphoma: immunophenotypic and molecular studies.

The cellular origin of Hodgkin and Reed-Sternberg (HRS) cells, the neoplastic cells of classic Hodgkin's lymphoma (HL), resisted clarification until the second half of this decade. One major obstacle to successful experimental investigations was the rarity of the HRS cells in the tissue affected by HL. Immunophenotypical studies using monoclonal antibodies already pointed in the early 1980s towards a lymphocytic origin for HRS cells, but were not definitive because of the usually variable expression of B-cell and/or T-cell antigens, and the additional expression of markers typical for other cell lineages, especially dendritic cells. Attempts to elucidate the cellular derivation of HRS cells by demonstrating the clonal rearrangements of the immunoglobulin (Ig) or T-cell receptor (TCR) genes in the DNA of whole-tissue extracts also remained inconclusive due to inconsistent results. In frustration with whole-tissue DNA studies, genetic approaches were turned to the single cell level. Among the techniques developed for the isolation of HRS cells, the extraction of single CD30+ HRS cells from immunostained frozen sections by means of hydraulic micromanipulation proved to be the most suitable. Using this method, monoclonal Ig gene rearrangements were detected in the HRS cells in 36 of 38 (95%) HL cases. Sequence analysis demonstrated high loads of somatic mutation in the rearranged variable regions. Molecular investigation of three cases of HL occurring in association with non-Hodgkin's lymphomas (NHLs) showed that all of the lymphoma lesions had an identical precursor with the molecular features of a germinal center B cell. In summary, these findings indicate that (1) approximately 95% of classic HLs originate from B cells; (2) the direct cellular precursors of the HRS cells are germinal center B cells; (3) the transforming event that causes HL leads to the complete morphologic and immunophenotypical change of the HRS cell precursors; and (4) the HRS cell population of a given case exclusively arises from a single transformed cell and expands by clonal growth. It remains to be shown whether the 5% of HLs for which a B-cell derivation could not be demonstrated are T-cell related.     

Comparison of miRNA profiles of microdissected Hodgkin/Reed-Sternberg cells and Hodgkin cell lines versus CD77+ B-cells reveals a distinct subset of differentially expressed miRNAs

Classical Hodgkin lymphoma (cHL) is characterized by the presence of malignant Hodgkin and Reed Sternberg (HRS) cells. The scarcity of tumour cells in lymphoma biopsies has hampered genetic analyses of HRS cells, including microRNA (miRNA) expression profiling. We determined the expression of 360 miRNAs in microdissected HRS cells from nine cHL patients. These miRNA profiles were compared to those from four cHL cell lines and CD77⁺ B-cells, yielding a distinct cHL signature of 12 over- and three underexpressed miRNAs. Our data suggest that miRNAs are implicated in the pathogenesis of Hodgkin lymphoma and prompt further investigations concerning their role in cHL.     

Genetic lesions of the TRAF3 and MAP3K14 genes in classical Hodgkin lymphoma

Hodgkin and Reed/Sternberg (HRS) cells in classical Hodgkin lymphoma (cHL) show constitutive activation of nuclear factor (NF)‐κB. Several genetic lesions contribute to this deregulated NF‐κB activity. Here, we analysed two further NF‐κB regulators for genetic lesions, the inhibitory factor TRAF3 and the key signalling component of the alternative NF‐κB pathway, MAP3K14 (NIK). Single nucleotide polymorphism (SNP) array analysis of cHL cell lines revealed a uniparental disomy of the long arm of chromosome 14 associated with a biallelic deletion of TRAF3 located on this chromosome in cell line U‐HO1. Cloning of the deletion breakpoint showed a 123 371 bp deletion. No inactivating mutations of TRAF3 were found in six other cHL cell lines or in microdissected HRS cells from seven cHL. However, in primary cHL samples interphase cytogenetic analyses revealed signal patterns indicating monoallelic deletion of TRAF3 in 3/20 other cases. SNP array analysis revealed a gain of copy number for MAP3K14 in three cHL cell lines. Gains of MAP3K14 were detected in 5/16 cases of primary cHL. In conclusion, in rare instances, HRS cells harbour inactivating mutations of the TRAF3 gene and recurrently show gains of MAP3K14, indicating that more components of NF‐κB signalling show genetic lesions in HRS cells than previously known.     

Interleukin 6 expression by Hodgkin/Reed-Sternberg cells is associated with the presence of 'B' symptoms and failure to achieve complete remission in patients with advanced Hodgkin's disease

Interleukin 6 (IL-6) is a potent immunomodulatory cytokine that has pathogenic and prognostic significance in a number of disorders. Previous studies in Hodgkin's disease (HD) have demonstrated the association between elevated serum levels of IL-6 and unfavourable prognosis, including advanced stage and the presence of 'B' symptoms and with reduced survival. Although IL-6 expression has been demonstrated in both the malignant Hodgkin/Reed-Sternberg (HRS) cells and in the various non-malignant cells present in HD biopsies, a relationship between expression of IL-6 by the tumour and outcome measures has not been established. The study group comprised of 97 patients with advanced HD who were recruited to two related clinical trials. IL-6 expression was determined on paraffin-wax sections of biopsy material by means of an immunohistochemical assay. Of the 97 patients, 27 (28%) showed staining for IL-6 in HRS cells. IL-6 expression by HRS cells was significantly correlated with a decreased likelihood of achieving a complete response to chemotherapy (P = 0.02) and with an increased prevalence of 'B' symptoms (P = 0.04). IL-6 expression by HRS cells was not associated with Epstein-Barr virus status (P = 0.57). In summary, the results suggest that IL-6 expression by HRS cells may contribute to the presence of 'B' symptoms and to a decreased likelihood to achieve a complete remission in HD patients.     

Autocrine- and paracrine-activated receptor tyrosine kinases in classic Hodgkin lymphoma

The pathogenesis of Hodgkin lymphoma (HL) is still largely unknown. Based on a search for footprints of pathogenetic mechanisms in global RNA expression data of Hodgkin/Reed-Sternberg (HRS) cell lines, we analyzed the expression and activation of 6 receptor tyrosine kinases (RTKs) in classic HL. Immunohistochemistry revealed that the RTKs platelet-derived growth factor receptor A (PDGFRA), DDR2, EPHB1, RON, TRKB, and TRKA were each expressed in HRS cells in 30% to 75% of patients. These RTKs were not expressed in normal B cells, the origin of HRS cells, or in most B-cell non-Hodgkin lymphoma (NHL). In the majority of patients at least one RTK was expressed, and in most patients several RTKs were coexpressed, most prominently in Hodgkin lymphoma of the nodular sclerosis subtype. Phosphotyrosine-specific antibodies revealed exemplarily the activation of PDGFRA and TRKA/B and an elevation of cellular phosphotyrosine content. Immunohistochemistry for RTK ligands indicated that DDR2 and TRKA are likely activated in a paracrine fashion, whereas PDGFRA and EPHB1 seem to be activated by autocrine loops. Activating mutations were not detected in cDNA encoding the RTKs in HRS cell lines. These findings show the unprecedented coexpression of multiple RTKs in a tumor and indicate that aberrant RTK signaling is an important factor in HL pathogenesis and that it may be a novel therapeutic target.