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Amino acid replacement mutations in certain chronic lymphocytic leukemia (CLL) stereotyped B cell receptor (BCR) immunoglobulins (IGs) at defined positions within antigen-binding sites strongly imply antigen selection. Prime examples of this are CLL subset 4 BCR IGs using IGHV4-34/IGHD5-18/IGHJ6 and IGKV2-30/IGKJ2 rearrangements. Conspicuously, and unlike most CLL IGs, subset 4 IGs do not bind apoptotic cells. By testing the (auto)antigenic reactivities of subset 4 IGs toward viable lymphoid-lineage cells and specific autoantigens typically bound by IGHV4-34+ IGs, we found that IGs from both subset 4 and non–subset 4 IGHV4-34–expressing CLL cases bound naïve B cells. However, only subset 4 IGs reacted with memory B cells. Furthermore, subset 4 IGs did not bind DNA nor i or I carbohydrate antigens that are common targets of IGHV4-34-utilizing antibodies in systemic lupus erythematosus and cold agglutinin disease, respectively. Notably, we found that subset 4 IG binding to memory B lymphocytes depends on an aspartic acid at position 66 of FR3 in the rearranged IGKV2-30 gene; this amino acid residue is acquired by somatic mutation. Our findings illustrate the importance of positive and negative selection criteria for structural elements in CLL IGs and suggest that autoantigens driving normal B cells to become subset 4 CLL cells differ from those driving IGHV4-34+ B cells in other diseases.
Considerable evidence suggests that normal B cells ushered into the leukemic state in chronic lymphocytic leukemia (CLL) are selected by the structure of their surface membrane immunoglobulin (IG) antigen-binding site (1–3). Probably the most dramatic evidence for this is that about one-third of CLL cases exhibit “stereotyped” B cell receptor (BCR) IGs, characterized by very similar VH CDR3 amino acid sequences, usually encoded by specific combinations of IGHV-IGHD-IGHJ genes. The concept of stereotyped BCR IGs in CLL has evolved from a scientific enigma (4–6) to a defined entity (7,8) to a paradigmatic principle (9–11) that supports the concept that leukemic B cell clones are selected for transformation based on structural restrictions in their antigen-binding domains (1,12,13).
This principle has been further elaborated in certain CLL stereotyped subsets for which specific amino acid replacement mutations have been found at defined positions within the leukemic B cell’s antigen-binding site (14). A prime example of this is subset 4, a group of patients originally defined by the use of IGHV4-34/IGHD5-18/IGHJ6 and IGKV2-30/IGKJ2 rearrangements (7,9). The CLL clones in this group are always IgG isotype switched and always exhibit IG somatic mutations (IGHV-mutated CLL, M-CLL). Of note, the IG mutations in the clones of many subset 4 patients are shared, focusing on specific positions in the H and L chain rearrangements and often introducing the same or chemically similar amino acids at those sites (14). Finally, subset 4 BCR IGs can continue to acquire somatic mutations over time (15,16), implying that antigen selection operates during clonal evolution.
Clinically, patients in subset 4 follow indolent clinical courses, faring even better than patients with mutated IGHV genes (16). This is surprising, because subset 4 patients often develop the disease at an earlier age than other patients who fall into other stereotyped subsets or with CLL in general (16). One possible explanation for their long and relatively benign clinical courses is the frequent inability to signal through the BCR (17,18), since in other patients such signaling can correlate with poor survival (19).
We 20,21 and others (22) have shown that the mAbs expressed by the leukemic B cells of ~50% of CLL patients bind molecules on the surface of apoptotic human T and B lymphocytes. It is likely that such reactivity is directed toward antigens that are usually intracellular and become accessible on the surface membrane during apoptosis 20,21. However, a distinguishing feature of subset 4 IGs mAbs is their inability to react with apoptotic cells 20,21.
In this study, we evaluated the (auto)antigenic specificities of subset 4, using three mAbs belonging to the subset. Specifically, we evaluated the ability of these mAbs to bind viable human lymphoid cells as well as other autoantigenic targets that are often bound by mAbs using the IGHV4-34 gene. By comparing these results with appropriate control mAbs, we determined that subset 4 mAbs bind viable human naïve and memory B cells. We also found that, remarkably, binding to memory B cells is dependent on the acquisition, via somatic mutation, of a single amino acid at a defined position in the rearranged IGKV2-30 gene. Furthermore, we determined a surprising loss of subset 4 antibody reactivity with two autoantigens commonly bound by IGHV4-34-expressing mAbs, namely DNA and the I/i carbohydrate antigens. Taken together, these findings suggest that the autoantigens driving the clonal evolution of normal B cells to become subset 4 CLL cells are distinct from those usually associated with IGHV4-34 IG binding in other disease settings. In the broader picture, this detailed characterization of antigenic specificity of subset 4, a prototype for clinically indolent, good prognosis CLL, advances our understanding of how positive and negative selection for specific structural elements in CLL BCRs shape clonal behavior and ultimately patient outcome.
Targeted mutagenesis of the IGHV-IGHD-IGHJ and IGKV-IGKJ sequence of CLL mAbs was performed by GENEWIZ.
Apoptosis in cell lines was induced by γ-irradiation (4000–5000 R) for ~15 h before staining. Cells were then incubated with CLL mAbs (5–50 μg/mL) for 1 h at 4°C and binding detected by FITC-conjugated F(ab’)2 goat anti-human IgG (Southern Biotech), or by streptavidin PE-Cy7 (eBioscience) when biotin-conjugated mAbs (sulfo-NHS-LC-biotin, Thermo Scientific) were used. Apoptosis was measured by staining with annexin V-PE (BD Pharmingen) as recommended by the vendor.
Cells isolated from tonsil were stained using exclusively biotin-conjugated CLL-derived mAbs. To distinguish different lymphocyte populations in tonsil samples, the following Abs were used: Pacific Blue mouse anti-human IgM (BioLegend, clone MHM-88), FITC goat F(ab’)2 anti-human IgD (Southern Biotech), Alexa Fluor 700 mouse anti-human CD38 (eBioscience, clone HIT2), and AmCyan mouse anti-human CD3 (clone SK7), PerCP mouse anti-human CD19 (clone 4G7), APC mouse anti-human CD27 (clone L128) and PE mouse anti-human CD24 (clone ML5) (all BD Biosciences). Samples were acquired using an LSRII flow cytometer (Becton Dickinson) and analyzed using FlowJo (LiveTree) software.
To determine mAb binding to double- and-single stranded DNA, QUANTA LiteTM dsDNA and QUANTA LiteTM ssDNA enzyme-linked immunosorbent assay (ELISA) kits (INOVA Diagnostics) were used. mAbs were tested following the manufacturer’s instructions at 25 ug/mL. The signal-to-unit conversion was calculated and positive cutoff values were determined according to the manufacturer’s instruction.
Two hexasaccharides, pLNH and pLNnH, from Dextra and an octasaccharide, LNnO, from Elicityl were analyzed as lipid-linked glycan probes, neoglycolipids (NGLs) derived by conjugation to a phospholipid L-1,2-dihexadecyl-sn-glycero-3-phosphoethanolamine (DHPE) (24). A ceramide-linked octasaccharide I-octa was isolated from human red cells (gift of Peter Hanfland). The glycan sequences are given in Figure 3. These NGLs and glycolipids were part of a microarray of 79 NGL and glycolipid probes encompassing blood groups A, B, H, Lea, Leb, Lex and Ley related sequences based on linear and branched backbones (collectively designated CLL array Set 1, which is described in detail elsewhere). These lipid-linked probes were robotically arrayed in duplicate at 2 and 5 fmol per spot on nitrocellulose-coated glass slides using a noncontact instrument as described (25).
Microarray binding analyses were performed at 4°C essentially as described (26). In brief, after blocking with 3% w/v bovine serum albumin (Sigma-Aldrich) in HEPES-buffered saline (5 mM HEPES, pH 7.4, 150 mM NaCl, 5 mM CaCl2), the microarrays were probed with the following CLL mAbs: 141, 282, 183, 240 and 342, all at 10 μg/mL. The five mAbs were used in their native configuration as well as precomplexed with anti-human IgG to render the native molecule multimeric; this resulted in increased avidity of binding to ligands and allowed comparisons to IgM molecules. Data obtained with precomplexed and native bivalent IGs were the same. As positive controls, human IgM anti-i and anti-I sera from the Feizi laboratory collection, designated anti-i P1A ELL (27) and anti-I Ma (27), respectively, were analyzed at 1:100 dilution; moreover, a mouse IgM culture supernatant designated Fc10.2 (28) was tested undiluted. Binding was detected using biotinylated anti-human IgG (Vector Laboratories, anti-H + L chain), or biotinylated anti-human IgM (Vector Laboratories, μ-chain specific), or biotinylated anti-mouse IgM (Sigma-Aldridge, μ-chain specific), all at 1:200 dilution, followed by Alexa Fluor-647–labeled streptavidin (Molecular Probes, Thermo-Fisher Scientific) at 1 μg/mL. Imaging and data analysis were as described 24,29. Binding signals for pLNH, pLNnH and LNnO were probe-dose–dependent. Results shown are at 5 fmol/spot.
To understand the unexpected lack of binding of subset 4 mAbs to apoptotic cells 20,21, we tested three mAbs from CLL clones belonging to this stereotyped subset (mAbs 183, 240 and 342) for reactivity with viable and apoptotic human lymphoid cells. These results were compared with those obtained using two different CLL clones whose mAbs either use the same IGHV4-34 gene without a stereotyped rearrangement (mAb141), or use a different IGHV gene and belong to a different stereotyped subset (no. 1) with a distinct BCR IG encoded by IGHV1-3/IGHD6-19/IGHJ4 and IGKV1(D)39/IGKJ2 gene rearrangements (mAb360).
γ-irradiated Ramos B and Jurkat T cell line cells were exposed to the above mAbs under nonpermeabilizing conditions, and binding to the cell surface was detected by flow cytometry. Notably, each of the mAbs belonging to subset 4 (nos. 183, 240 and 342) bound to live B cells and, to a much lesser degree, to live T cells (defined as annexin V–) compared to apoptotic/dead B and T cells (defined as annexin V+) (Figure 1A, three right panels). Meanwhile, as predicted from our previous studies 20,21, the subset 1 mAb360 bound to apoptotic cells and minimally to viable cells (Figure 1A). In addition, mAb141, which uses IGHV4-34 but without a stereotyped rearrangement and therefore with a different VH CDR3 structure, showed low-level binding to annexin V– cells (Figure 1A and references 20,21). Figure 1B shows the binding of mAbs 183, 240 and 342 to live B and T cells (based on an average of four independent experiments).
These data indicate that subset 4 IGs display selective reactivity with viable human lymphocytes, with this reactivity being much greater for B than for T cells. Hence, the antigens recognized by subset 4 mAbs are constitutively present on the surface of viable B cells, unlike those antigens brought to the cell surface membrane during apoptosis that are recognized by most other CLL mAbs.
To verify that the above reactivity of subset 4 mAbs with viable human B cells was not limited to transformed Ramos B cells, we analyzed the binding characteristics of these mAbs with human B lymphocytes from tonsillectomy samples. CLL IGs bound well to CD19+ (Figure 2A, right column) but minimally, at best, to CD3+ (Figure 2A, left column) tonsil cells, in agreement with the findings above.
Intriguingly, the CLL subset 4 mAbs distinguished two subpopulations of CD19+ cells, one with low and another with higher mAb binding (Figure 2A). In contrast, the IGHV4-34+ non–subset 4 mAb141 recognized predominantly a single CD19+ population.
To further characterize the two tonsillar B cell subpopulations that the subset 4 IGs selectively bound to and determine which of the two subset 4–reactive populations were bound by the IGHV4-34+ non–subset 4 mAb141, we exposed the tonsil samples to a panel of mAbs and polyclonal Abs (pAbs) that distinguish naïve from memory human B cells. Gating on the CD19+/CLL subset 4 mAbbright population indicated that these cells were mostly CD27–/IgD+/CD38l°w (Figure 2B), a phenotype compatible with that of naïve B cells. These cells also expressed surface membrane (sm) IgM (Figure 2B) and were CD24+ (data not shown). In contrast, the majority of the CD19+/CLL subset 4 mAbdim cells exhibited a CD27+/IgD–/IgM–/+/CD38high phenotype (Figure 2B), consistent with memory B cells. Finally, when analyzing the B-lymphocyte subpopulation bound by mAb 141, it became clear that the IGHV4-34+ non–subset 4 mAb bound the corresponding CD19+/CLL subset 4 mAbbright naïve B cell population (CD27–/IgD+/IgM±/CD38l°w; Figure 2B).
These data confirm that subset 4 IGs have a favored reactivity for viable human B lymphocytes. Furthermore, the data indicate that subset 4 mAbs bind both naïve and memory B cells. This latter finding differs from the nonstereotyped IGHV4-34 mAb tested (141) and the mAbs (30) and pAbs described by others in other contexts (31–33) that preferentially react with naïve B cells (34).
It is well documented that many IGHV4-34–encoded antibodies bind to poly-N-acetyllactosaminoglycans (NALs) of the i- and I- antigen type (35) found on the surfaces of human erythrocytes (36) and lymphocytes 31,37. On human B lymphocytes, the autoantigenic epitope is predominantly a linear NAL of i antigen type present on CD45 (38–40). We therefore tested if CLL subset 4 mAbs react with CD45+ and CD45– cells of the B cell lineage.
To do this, we used U266, a myeloma cell line, which, although predominantly CD45–, has a definable subpopulation of CD45+ cells. After exposing U266 cells to mAb240, we observed that the mAb bound both the CD45– and CD45+ populations within the clone (Supplementary Figure 1). This was the case even when we tested binding to U266 after presorting the cell line into CD45+ and CD45– subpopulations (data not shown). Thus, the autoantigenic target for subset 4 is not limited to the CD45 antigen and need not be the linear NAL i epitope.
Next, we directly tested binding of the subset 4 mAbs to a microarray of blood group–related carbohydrate sequences. Figure 3 illustrates microarray binding data for the 3 CLL subset 4 mAbs (183, 240 and 342), the IGHV4-34+ non–subset 4 mAb141 and a control CLL subset 2 (IGHV3-21/IGLV3-21) mAb282, each at a 10 μg/mL concentration. These IGs were used in their normal bivalent state as well as multimers, created by preincubation with anti-human IgG pAbs. The microarray included the two linear i-active probes with type 2 (Galβ-4GlcNAc-) termini: the hexasaccharide NGL pLNnH, Galβ-4GlcNAcβ-3Galβ-4GlcNAcβ-3Galβ-4Glc-DH, and the octasaccharide NGL LNnO, Galβ-4GlcNAcβ-3Galβ-4GlcNAcβ-3Galβ-4GlcNAcβ-3Galβ-4Glc-DH. Also included was a branched I-active probe with two type 2 termini, one of which is linked to the C6 position of the polylactosamine backbone, Galβ-4GlcNAcβ-6(Galβ-4GlcNAcβ-3)Galβ-4GlcNAcβ-3Galβ-4Glc-Cer. The isomeric hexasaccharide glycan probe pLNH with type 1 (Galβ-3GlcNAc-) terminus, Galβ-3GlcNAcβ-3Galβ-4GlcNAcβ-3Galβ-4Glc-DH, which lacks i-type antigen reactivity but expresses an antigen recognized by the murine IgM mAb Fc10.2 directed at fetal endoderm, was also included (Figure 3A). The subset 4 mAbs did not bind to the i- and I-type glycans, nor the FC10.2 antigen analog (Figure 3B), nor to other blood group–related sequences in the array (results not shown). Moreover, the CLL IGs did not react with these targets if precomplexed to create multimeric structures resembling IgM (Figure 3C). However, IGHV4-34+ CLL mAb141, bivalent or multimeric, bound well to the representative i-antigen–expressing probes in the array, pLNnH and LNnO. As controls, human sera containing anti-i (P1A ELL) and anti-I (Ma) IgM antibodies and murine IgM mAb Fc10.2 27,28 reacted well with their respective target carbohydrate antigens: the anti-i with pLNnH and LNnO, the anti-I with I-octa and Fc10.2 with pLNH. These findings validate the structures of the poly LacNac sequences displayed on the array.
Together, the above results indicate that CLL subset 4 mAbs have an autoreactivity distinct from that described in other malignant and autoimmune conditions (13–16,23), since they do not interact with the carbohydrate autoantigen classically recognized by nonstereotyped IGHV4-34 IGs. In this regard, the non–subset 4 IGHV4-34+ mAb141 binds the classical epitopes (Figure 3).
Next, we tested the reactivity of subset 4 mAbs with nuclear and cytoplasmic autoantigens by exposing the three CLL mAbs to HEp-2 cells and detecting binding using goat anti-human IgG pAbs conjugated with a fluorochrome. The three subset 4 mAbs showed negligible binding to permeabilized HEp-2 cells compared with a subset 8 mAb (no. 114; IGHV4-39/IGKV1(D)-39) that binds well to cytoplasmic structures and compared with a non–subset mAb (no. 255) that binds nuclear constituents (Figure 4A). The lack of binding to nuclear structures within HEp-2 cells is inconsistent with the previously described reactivity with DNA and other nucleic acid–protein conjugates defined for nonstereotyped IGHV4-34–expressing antibodies in autoimmune settings (31–33). This lack of DNA binding was confirmed directly by ELISA (Figure 4B). Thus, an antigenic reactivity that would be expected of IGHV4-34–expressing human Abs is absent in CLL subset 4 IGHV4-34+ mAbs.
To examine structural aspects of subset 4 antibody binding, we attempted to inhibit binding to viable human B cells by preincubating the CLL IGs with the IGHV4-34-reactive mAb, 9G4. This did not result in an appreciable decrease in binding. However, preliminary immunofluorescence experiments comparing binding of CLL mAb240 to the Ramos cell line cultured in the presence or absence of inhibitors of the synthesis of N-glycans (tunicamycin) or O-glycans (benzyl 2-acetamido-2-deoxy-α-D-galactopyranoside, BADGP) or glycolipids (D-1-phenyl-2-hexadecanoylamino-3-morpholino-1-propanol, PPMP) suggest that the target of the subset 4 CLL IG mAb240 is carried on N-glycans (data not shown). Detailed studies are under way to corroborate this possibility and establish the structure of the determinant.
Since subset 4 mAbs recurrently develop replacement mutations that create specific amino acids at defined sites/positions within the portion of the IG heavy (H) and light (L) variable domains coded by the IGHV4-34 and IGKV2-30 genes (14) (Figure 5), we investigated the roles of the individual somatically generated amino acids on binding to viable human B cells. For these studies, we used CLL subset 4 mAb240 as the starting template and selectively and specifically transformed its amino acid sequence back to that corresponding to the germline sequence of the IGHV4-34 and IGKV2-30 genes. Specifically, for IGHV4-34, we reverted four single amino acid mutations, N22T (rH-1), E28G (rH-2), A99T (rH-3) and I101V (rH-4), and a final revertant, rH-5, that had all four individual changes together. For IGKV2-30, we made one revertant, D66N (rL-1), since this gene differed from the corresponding germline sequence at only this residue.
Note that some of the positions reverted to the germline equivalent are frequently mutated in subset 4 mAbs; for example, amino acids at codon 28 in the VH CDR1 of IGHV4-34 and at codon 66 in the VK FR3 of IGKV2-30 (Figure 5 and ref. 14). The other mutations found in mAb240 are unique to this mAb and are not frequently seen in other members of subset 4.
After incubating the altered versions of mAb240 containing each of the IGHV4-34 H chain revertants with viable B cells from tonsil samples and analyzing them by flow cytometry, no substantial reproducible change in binding was observed from that using the original wild-type (wt) H chain (not shown). This was the case if we altered only single amino acids, including the “subset 4–biased” mutation at position 28 in VH CDR1, or all four mutations. Similar results were obtained when testing Ramos B cell line cells (not shown).
Therefore, we next analyzed the role of the L chain revertant at codon 66 in the VK FR3 on the binding of subset 4 mAb240 to healthy B cells from tonsil (Figure 6A). To do this, we paired the revertant L chain with the wt H chain (240Hwt + rL-1), and then analyzed binding of this and the unmanipulated mAb240 by flow cytometry. When the mAb containing the rL-1 revertant was used, binding of viable B cells decreased significantly (Figure 6A, orange line), compared with binding of mAb240 with the wt L chain (Figure 6A, blue line). Furthermore, the revertant now bound mainly the CD19+/CLL mAbbright cells (Figure 6A, contour plot) that have the phenotype of CD27–/IgD+ naïve B cells (Figure 2B). Similarly, we observed a marked decrease of B cell binding when staining Ramos cells with the L chain revertant-containing mAb240 (Figure 6B, left panel, orange line). Indeed, the extent of change in antigen binding observed with a single amino acid change in the L chain of mAb240 is equal to that seen when a completely different L chain (from non–subset 4 mAb141 that uses IGKV1-27) is paired with the H chain of the other subset 4 mAb183 (Figure 6B, right panel, orange line).
Hence, reactivity of subset 4 mAbs with viable human B cells and with memory B cells is a function of the somatically generated D residue at position 66 of the L chain that is characteristic of this stereotyped CLL subset. This structural alteration involves a change of an amino acid in the FR and not the CDR portion of the mAb. Of note, the amino acid change introduces a charged residue at this site.
In this study, we investigated antigen binding by recombinant mAbs from patients belonging to CLL stereotyped subset 4, the largest M-CLL subset and a prototype for indolent disease. The binding of these subset 4 mAbs was compared with other Abs using the IGHV4-34 gene in nonstereotyped configurations. Our findings are informative not only for the specific reactivities we identified, but also for those that were expected based on the literature (31–33) that we did not find. Specifically, we documented that, unlike most CLL mAbs (stereotyped or not), subset 4 IGHV4-34–expressing mAbs do not bind to the surface of apoptotic human B lymphocytes; rather, they bind selectively to viable cells. Furthermore, after conducting binding studies with normal B cell subsets, we discovered that subset 4 IGs bind both naïve and memory B lymphocytes, unlike IGHV4-34+ Abs in other disease settings that bind exclusively to naïve B cells (34). In addition, and unlike most reported IGHV4-34–expressing Abs, CLL subset 4 mAbs do not react with DNA, as IGHV-4-34+ Abs often do in systemic autoimmunity (31–33), nor with i-active NALs, as many IGHV4-34–expressing mAbs do in cold agglutinin disease (30). Thus, the uniqueness of the subset 4 IGHV4-34/IGHD5-18/IGHJ6 + IGKV2-30/IGKJ2 rearrangements overrides the ability of IGHV4-34 germline-encoded structures to bind DNA and i/I NALs and imparts reactivity with an antigen present on the surface of a defined functional subset of healthy human B cells. Moreover, to bind the B cell epitope, a residue (D66N) not encoded by the germline sequence is required in FR3; this lies at the junction of VK CDR2.
Although in principle it is possible that any germline IGHV could react with any antigen when associated with an appropriate IGHD and IGHJ as well as an IGK/LV-IGK/LJ rearrangement, IGHV4-34 appears to be unique among most germline genes in that it is inherently biased to react with autoantigens (41). This notion is strongly supported by the exclusion of normal human B lymphocytes bearing the stamp of IGHV4-34 rearrangements from entering germinal centers (42), where somatic hypermutation and class switch recombination can render innately autoreactive gene products even more dangerous by selecting variants having higher-avidity autoantigen-binding sites and/or more efficient IG effector isotypes. In this light, the lack of reactivity of CLL subset 4 mAbs to DNA and i antigen is remarkable. The inability to bind these two purified autoantigens was shown directly in solid-phase antigen binding assays using multiple subset 4 mAbs (Figures 3 and and4)4) that were selected for testing based solely upon available DNA sequences. Moreover, the amino acid residues known to be responsible for binding the i-type NAL antigen (W at position 7 and AVY at positions 24, 25 and 26; Figure 5) are not altered in the subset 4 IGs studied here and in most subset 4 mAbs in available databases (11,14).
It is possible that a protein prepared recombinantly does not fold like the native molecule made in a cell. Short of conducting a study of the crystal structure of the CLL mAbs used here, this possibility cannot be excluded. However, we do know that the H chain is associated with the provided L chain, as both are found on sodium dodecyl sulfate polyacrylamide gel electrophoresis run under reducing conditions. Also the H and L chain complex has an appropriate molecular weight based on mobility in size exclusion chromatography (data not shown). The lack of binding of these antibodies to I/i-type NALs requires further investigation with a wider range of carbohydrates.
A case for positive selection of a novel antigen-binding site is strengthened by our finding that subset 4 mAbs do not react with apoptotic human B cells, while they do bind to viable B lymphocytes (Figure 1). Furthermore, this disparity suggests that the target antigen on the B cell surface is present constitutively and therefore differs from target antigens brought to the cell surface from the inside on apoptotic cells. This selective binding to viable and not apoptotic cells also suggests that the antigenic epitope is modified, destroyed or removed by internalization or cleavage during the apoptotic process, consistent with structural antigenic changes due to oxidation (20,43), flipping of membrane components (44) or enzymatic cleavage (45,46).
The second distinguishing feature of subset 4 mAb binding to viable human B cells is reactivity with two phenotypically distinct B cell subsets with different functional properties. Specifically, subset 4 IGs bind memory and naïve human B cells. Although the antigenic epitope recognized could be shared by the two B cell subsets, two findings suggest that this is not the case. First, mAb141, which uses the IGHV4-34 gene but not the IGHD, IGHJ or IGKV genes of subset 4, binds to naïve B cells and not to memory B cells. We predict that this is due to reactivity with i-antigen, as indicated in Figure 3. Second, reversion of the subset 4 characteristic somatically generated charged residue (aspartic acid, D) to the germline-encoded residue (asparagine, N) at position 66 in the VK FR3 of the kappa L chain significantly reduces binding to memory B cells and enhances reactivity with naïve B cells (Figure 6A). Even though this obligate aspartic acid resides in the VK FR3, it is the first residue after VK CDR2, suggesting that it might influence the structure or accessibility of the VK CDR2 to antigen binding. The somatic nature of this residue highlights that the CLL precursor B cell was not excluded from undergoing a germinal center reaction, as is the case for most normal human B lymphocytes (42).
In CLL, the functional consequences of subset 4 binding to memory and naïve B cells have yet to be determined. In other instances, anti-lymphocyte Abs, some of which can be lymphocyte subset–specific (47,48), cause cytolysis (49). This has also been described for certain IGHV4-34+ mAbs (50). Therefore, the indolent clinical course of CLL subset 4 patients (51) could relate to an ongoing immunoregulatory interaction of these B cells and their Ig products. By extension, we could speculate that such an interaction might also induce and/or maintain the anergic status of subset 4 CLL cells (18), thus lying at the core of diminished responsiveness to external triggering that characterizes this prototypic favorable prognostic CLL subgroup.
This work was supported in part by an RO-1 grant from the National Cancer Institute/National Institutes of Health (CA081554) (to NC), and Bloodwise grant 14028 and Wellcome Trust grants WT093378MA and WT099197MA (to TF). Additional support in the form of philanthropic contributions was provided by the Karches Foundation, Marks Foundation, Nash Family Foundation, Jerome Levy Foundation, Leon Levy Foundation, Frank and Mildred Feinberg Foundation, Mona and Edward Albert Foundation and Jean Walton Fund for Leukemia, Lymphoma, and Myeloma Research.
Online address: http://www.molmed.org
The authors declare that they have no competing interests as defined by Molecular Medicine or other interests that might be perceived to influence the results and discussion reported in this paper.
Cite this article as: Catera R, et al. (2017) Binding of CLL subset 4 B cell receptor immunoglobulins to viable human memory B lymphocytes requires a distinctive IGKV somatic mutation. Mol. Med. 23:1–12.
Using recombinant IGs corresponding to CLL clones expressing IGHV4-34 in either stereotyped subset 4 or non-stereotyped configurations, we have shown that CLL subset 4 BCR IGs do not bind DNAs nor i or I carbohydrate antigens; these are common targets of IGHV4-34-utilizing antibodies in systemic lupus erythematosus and cold agglutinin disease, respectively. However, these IGs do react with viable memory B cells as well as naïve B lymphocytes, the latter being bound by other non-subset 4, IGHV4-34-utilizing antibodies. Notably, reactivity with viable B cells depends on the acquisition of a somatic mutation at position 66 of FR3 in the rearranged IGKV2-30 gene. This mutation changes a hydrophilic, uncharged amino acid (asparagine) to an acidic amino acid (aspartic acid) at that site. Our findings illustrate the importance of positive and negative selection for acquired structural changes in CLL subset 4 IGs in determining the unique antigen-reactivities of these CLL clones. These findings also suggest that the autoantigens driving normal B cells to become subset 4 CLL cells differ from those driving IGHV4-34-expressing B cells in other malignancies and in autoimmune diseases.