Detection of chimaeric transcripts of the immunoglobulin heavy chain and BCL6 genes by reverse-transcriptase polymerase chain reaction in B-cell non-Hodgkin's lymphomas

Association of Ig/BCL6 translocations with germinal center B lymphocytes in human lymphoid tissues: implications for malignant transformation

Chromosomal translocations (CTs) between immunoglobulin (Ig) genes and the BCL6 proto-oncogene are frequently associated with diffuse large B-cell lymphomas (DLBCLs) and follicular lymphomas (FLs) and are implicated in the development of these lymphomas. However, whether Ig/BCL6 translocation per se is sufficient to drive malignant transformation is not clear. To understand the biology of Ig/BCL6-translocated cells prior to their malignant transformation, we developed a system capable of detecting 1 to 3 Igmu/BCL6 CT cells in 1 million mixed cells through the detection of chimeric Imu-BCL6E2 and BCL6E1-Cmu1 transcripts that reflect reciprocal Igmu/BCL6 translocations. The chimeric transcripts that existed in the vast majority of normal lymphoid tissues are due to Igmu/BCL6 CT and were not generated from trans-splicing. Both Imu-BCL6E2 and BCL6E1-Cmu1 transcripts were coexpressed in the same cell populations. The Ig/BCL6 recombination junctions themselves were isolated from B-cell subpopulations expressing the Imu-BCL6 transcripts. The appearance of Igmu/BCL6 CT was associated with cells expressing germinal center but not naive B-cell markers. This study shows that Ig/BCL6 translocations occur in germinal center-stage B cells in healthy humans, and that Ig/BCL6 CTs per se are not likely sufficient to cause the malignant transformation in the context of human B cells.

Two patterns of chromosomal breakpoint locations on the immunoglobulin heavy-chain locus in B-cell lymphomas with t(3;14)(q27;q32): relevance to histology

The t(3;14)(q27;q32) is the most common translocation involving BCL6 in B-cell lymphoma. Although this translocation was predominantly associated with diffuse large B-cell lymphoma (DLBCL), recent studies have shown that it can also be found in follicular lymphomas (FL), often associated with a large cell component. To further investigate the relationship that might exist between this translocation and the phenotype of the tumors, we studied 34 lymphomas with a t(3;14)(q27;q32). Twenty cases were DLBCL, 14 FL and most cases, regardless of histology, were negative for the expression of CD10 (26/32, 81%). We identified the IGH switch region involved in the translocation for 32 cases. Our data indicate that in DLBCL most breakpoints involve the switch mu (17/19; 89%), whereas in FL most involve a switch gamma (9/13; 70%) (P=0.0016, Fisher's exact test). This correlation between the histology and the structure of the translocated allele suggests that the lymphomas with Smu and Sgamma translocations may originate from different cells, or that the substituted regulatory regions that come to deregulate BCL6 may affect the presentation of the disease.

Intronic BCL-6 mutations are preferentially targeted to the translocated allele in t(3;14)(q27;q32) non-Hodgkin B-cell lymphoma

Translocations and somatic mutations are common genetic alterations of the BCL-6 gene on chromosome 3q27 in B-cell lymphoma, with implications for lymphomagenesis. The 2 events may have linked origins and can influence juxtaposed loci. To evaluate this further, we compared mutations occurring within the major mutation cluster region of the translocated and untranslocated BCL-6 alleles in 7 t(3;14)(q27;14q32) lymphomas. In 6 of 7 cases, the translocated allele revealed significantly higher mutations (mean, 5.8 x 10-2 bp-1) than did the untranslocated allele (mean, 5.3 x 10-3 bp-1; P <.01). The increase mapped to der(14q32), which retains the BCL-6 promoter and is transcriptionally active, as revealed by fusion transcripts and ongoing somatic mutations, absent in the der(3q27) region. These results indicate that enhanced mutational activity at the translocated allele may be a consequence of loss of cis regulatory elements or gain of IgH enhancer elements. Junctional sequences indicate translocation origins from earlier BCL-6 mutations and switch recombinase events.

P-Glycoprotein Expression on Normal and Abnormally Expanded Natural Killer Cells and Inhibition of P-Glycoprotein Function by Cyclosporin A and Its Analogue, PSC833

P-glycoprotein (P-gp), a transmembrane efflux pump encoded by theMDR1 gene, has been found to be expressed in many normal bone marrow and peripheral blood cells. Among normal leukocytes, CD3−CD16+ or CD3−CD56+ lymphocytes, ie, natural killer (NK) cells, express relatively high levels of P-gp, but little is known about P-gp in abnormally expanded NK cells. In this study, we examined the expression and activity of P-gp on NK cells derived from three normal donors, six patients with indolent NK cell-lineage granular lymphocyte-proliferative disorder (NK-GLPD), three patients with aggressive NK cell tumors (one NK cell leukemia and two nasal NK cell lymphoma), and two NK cell lines. By flow cytometric analysis using the monoclonal antibody (MoAb) MRK16 and rhodamine 123 dye (Rh123), P-gp expression and the efflux of Rh123 were found in all NK samples except one NK cell line. The Rh123 efflux of NK cells was inhibited by cyclosporin A (CsA) and its analogue PSC 833, but the aggressive NK tumor cells were less inhibited than were the other NK cells. The percent inhibition of efflux in the normal NK cells, indolent NK-GLPD cells and aggressive NK cell tumors was 81.8% ± 0.9%, 93.4% ± 3.1% and 36.9% ± 11.7%, respectively, by 1 μmol/L CsA, and 80.2% ± 3.6%, 91.7% ± 2.6% and 32.7% ± 10.1%, respectively, by 1 μmol/L PSC833. In reverse transcription-polymerase chain reaction (RT-PCR) analysis, the low inhibitory effect of P-gp modulators in aggressive NK cell tumors did not correlate to the expression level of MDR1 gene, multidrug resistance-associated protein gene, or human canalicular multispecific organic anion transporter gene. This phenomenon could be related to the presence of other transporters or to unknown cellular or membrane changes. Some patients with NK cell tumors have been reported to show a highly aggressive clinical course and to be refractory to chemotherapy, and this could be related to the expression of P-gp on NK cells. Our results suggest that, although the inhibitors for P-gp have been used in combination with chemotherapy in some hematologic tumors, these inhibitors may be less effective against aggressive NK cell tumors.

P-Glycoprotein Expression on Normal and Abnormally Expanded Natural Killer Cells and Inhibition of P-Glycoprotein Function by Cyclosporin A and Its Analogue, PSC833

P-glycoprotein (P-gp), a transmembrane efflux pump encoded by theMDR1 gene, has been found to be expressed in many normal bone marrow and peripheral blood cells. Among normal leukocytes, CD3−CD16+ or CD3−CD56+ lymphocytes, ie, natural killer (NK) cells, express relatively high levels of P-gp, but little is known about P-gp in abnormally expanded NK cells. In this study, we examined the expression and activity of P-gp on NK cells derived from three normal donors, six patients with indolent NK cell-lineage granular lymphocyte-proliferative disorder (NK-GLPD), three patients with aggressive NK cell tumors (one NK cell leukemia and two nasal NK cell lymphoma), and two NK cell lines. By flow cytometric analysis using the monoclonal antibody (MoAb) MRK16 and rhodamine 123 dye (Rh123), P-gp expression and the efflux of Rh123 were found in all NK samples except one NK cell line. The Rh123 efflux of NK cells was inhibited by cyclosporin A (CsA) and its analogue PSC 833, but the aggressive NK tumor cells were less inhibited than were the other NK cells. The percent inhibition of efflux in the normal NK cells, indolent NK-GLPD cells and aggressive NK cell tumors was 81.8% ± 0.9%, 93.4% ± 3.1% and 36.9% ± 11.7%, respectively, by 1 μmol/L CsA, and 80.2% ± 3.6%, 91.7% ± 2.6% and 32.7% ± 10.1%, respectively, by 1 μmol/L PSC833. In reverse transcription-polymerase chain reaction (RT-PCR) analysis, the low inhibitory effect of P-gp modulators in aggressive NK cell tumors did not correlate to the expression level of MDR1 gene, multidrug resistance-associated protein gene, or human canalicular multispecific organic anion transporter gene. This phenomenon could be related to the presence of other transporters or to unknown cellular or membrane changes. Some patients with NK cell tumors have been reported to show a highly aggressive clinical course and to be refractory to chemotherapy, and this could be related to the expression of P-gp on NK cells. Our results suggest that, although the inhibitors for P-gp have been used in combination with chemotherapy in some hematologic tumors, these inhibitors may be less effective against aggressive NK cell tumors.