Usefulness of Bcl-2 Expression and the Expression of Cytoplasmic Immunoglobulin Light Chains in the Differentiation Between B-Cell Lymphoma and Reactive Lymphocytic Proliferations in FNA

Flow cytometry is helpful in differentiating between B-cell lymphoma (BCL) and reactive lymphocytic proliferation (RLP) in FNA biopsies. However; the presence of inconclusive surface immunoglobulin light chains (sIg LC) poses a problem. We investigated the usefulness of additional tests; namely Bcl-2 expression and expression of cytoplasmic Ig LC (cIg LC), mainly on samples with inconclusive sIg LC. Both tests were performed on 232 FNA samples from lymph nodes. Bcl-2 alone was determined qualitatively and quantitatively on 315 samples. The quantitative test was correctly positive in 76% of cases and falsely negative in 24%. The correctly positive results of the qualitative test were 11% points lower. cIg LC correctly identified 65% of BCL with dual positive sIg LC; 36% of BCL with difficult to interpret sIg LC and only 7% of BCL with negative sIg LC. The best results in differentiating between BCL and RLP were obtained when all three tests were used together. In samples with inconclusive sIg LC and additional monoclonal or polyclonal populations the κ:λ ratios did not differentiate between RLP and BCL. We propose that in case of inconclusive sIg LC Bcl-2 test is used first. The addition of cIg LC test is sensible only in cases with dual positive and difficult to interpret sIg LC.

Acquisition of Mannoses on the Surface Immunoglobulin Binding Site Reveals Functional Status and Cell of Origin in Diffuse Large B Cell Lymphomas

Acquisition of mannosylated glycans in the surface immunoglobulin (sIg) variable region (sIgV) antigen-binding site is a unique tumor-specific structural change of certain lymphomas, including all follicular lymphomas (FL) and ~40% diffuse large B-cell lymphomas (DLBCL). Mannosylation of the sIgV allows binding to environmental lectins including DC-SIGN (Coelho V et al, PNAS 2010). SIgV engagement is generally required for survival of DLBCL cells (Young RM et al, PNAS 2015), but how sIgV mannosylation distributes and affects behavior in the two germinal center B-cell-like (GCB-like) or activated B-cell-like (ABC-like) DLBCL subsets is unknown. While the mannosylation of the sIgV is tumor specific and irreversible, there are other natural N-glycosylation sites in the sIg constant region (sIgC). In secreted IgM these are mainly fully glycosylated and that is seen in sIgM of normal B cells (Krysov S et al, Blood 2010). However, engagement of sIgM by anti-IgM leads to expression ofan immature (mannosylated) form in both tumor and normal B cells. This conversion is dynamic, and tumor B cells restore expression of sIgC with mature glycans following BCR disengagement in vitro(Krysov S et al, Blood 2010). In this study, the glycosylation patterns of sIgV and sIgC were analyzed in GCB-like (n=6) vs ABC-like DLBCL lines (n=2) and primary samples (n=8) by IGHV-D-J sequencing, DC-SIGN binding and immunoblot of the biotinylated sIg following digestion by EndoH (specific for the mannosylated sugars) or by PNGase (removes all sugars). We found acquisition of N-mannosylation sequence motifs in the IGHV-D-J transcripts of all GCB-DLBCL lines with t(14;18), indicating a likely relationship with FL. In contrast, neither of the ABC-DLBCL lines had acquired sites, confirming a separate origin. DC-SIGN binding, which is specific for mannosylated IgV structures on the tumor cells, was observed in all GCB-DLBCL and not in the ABC-DLBCL, confirming that the acquired sites were glycosylated. These results allowed us to discriminate DLBCL cases into "DC-SIGN binders" (DB-DLBCL) vs "DC-SIGN non-binders" DLBCL (NB-DLBCL). Analysis of the carbohydrate structures on the sIgC revealed that the immature form was confined to the NB-DLBCL lines (2/2), while the DB-DLBCL expressed a mature fully glycosylated form (6/6). Consistent with the nature of ABC-DLBCL, these results revealed an activated BCR status of the NB-DLBCL. This was confirmed in the 8 primary samples (5/8 DB, 3/8 NB), which expressed an immature (activated) sIgC in 3/3 NB-DLBCL and a mature sIgC in 5/5 DB-DLBCL. However, engagement of anti-IgM F(ab')2 polyclonal antibody converted the inactive sIg form of DB-DLBCL into an activated sIg with relative increase of the immature sugars. It was evident that the mannosylated sites on the sIgC were not available for DC-SIGN binding, which is confined to the sIgV sites. We verified BCR activation status by investigating constitutive phosphorylation of SYK, BTK and PLCγ2, which are recruited to the membrane upon BCR activation, prior to endosome formation (Phelan JD et al, Nature 2018), in 2 DB-DLBCL lines (NU-DHL1 and SU-DHL6) and 2 NB-DLBCL (HBL-1 and TMD8). Basal phosphorylation of SYK, BTK and PLCγ2 was higher in the NB-DLBCL, consistent with the activated status associated with an immature sIgC. Our results reveal a functional dichotomy in DLBCL, which indicates: first, the cell of origin dictates whether sIgV carries mannoses in the antigen-binding site; second, reversible sIgC mannosylation associates with activation via sIg. Interestingly, this feature of activation is in ABC-DLBCL, which lacks IgV mannosylation. It is consistent with the suggestion that occupation of the antigen-binding sites with mannoses blocks further engagement of the receptor by 'antigen'. However, acquisition of mannoses in the sIgV sites appears to confer an ability to interact with environmental lectins such as DC-SIGN, whereas the sIgC sites fail to do this, suggesting an alternative function. Clearly, the post-translational modification targets several sites in sIg. Sites in the sIgC have a similar, possibly maturational, function in normal B cells, but in tumor cells the irreversible addition of mannoses to the sIgV adds a tumor-specific function. Disclosures Packham: Aquinox: Research Funding. Forconi:Abbvie: Consultancy; Janssen-Cilag: Consultancy.

Critical influences on the pathogenesis of follicular lymphoma

The development of follicular lymphoma (FL) from a founder B cell with an upregulation of B-cell lymphoma 2 (BCL2), via the t(14;18) translocation, to a proliferating clone, poised to undergo further transformation to an aggressive lymphoma, illustrates the opportunistic Darwinian process of tumorigenesis. Protection against apoptosis allows an innocent cell to persist and divide, with dangerous accumulation of further mutational changes, commonly involving inactivation of chromatin-modifying genes. But this is not all. FL cells reflect normal B cells in relying on expression of surface immunoglobulin. In doing so, they add another supportive mechanism by exploiting the natural process of somatic hypermutation of the IGV genes. Positive selection of motifs for addition of glycan into the antigen-binding sites of virtually all cases, and the placement of unusual mannoses in those sites, reveals a posttranslational strategy to engage the microenvironment. A bridge between mannosylated surface immunoglobulin of FL cells and macrophage-expressed dendritic cell–specific ICAM-3–grabbing nonintegrin produces a persistent low-level signal that appears essential for life in the hostile germinal center. Early-stage FL therefore requires a triad of changes: protection from apoptosis, mutations in chromatin modifiers, and an ability to interact with lectin-expressing macrophages. These changes are common and persistent. Genetic/epigenetic analysis is providing important data but investigation of the posttranslational landscape is the next challenge. We have one glimpse of its operation via the influence of added glycan on the B-cell receptor of FL. The consequential interaction with environmental lectins illustrates how posttranslational modifications can be exploited by tumor cells, and could lead to new approaches to therapy.