Over 30% of Patients with Splenic Marginal Zone Lymphoma Express Distinctive Antigen Receptors Utilizing a Single Immunoglogulin Variable Gene: Implications for the Origin and Selection of the Neoplastic Cells

Abstract 634

We systematically explored the immunoglobulin (IG) gene repertoire in 337 cases with splenic marginal-zone lymphoma (SMZL), by far the largest series yet. To resolve classification uncertainties, we included in the analysis only cases with a diagnosis of SMZL based on spleen histopathological findings or cases fulfilling the 2008 SBLG criteria (Matutes et al. Leukemia 2008). We here report that the IG heavy variable (IGHV) gene repertoire in SMZL is remarkably biased, with only three genes accounting for 45.8% of cases (IGHV1-2, 24.9%; IGHV4-34, 12.8%; IGHV3-23: 8.1%, respectively), significantly extending previous similar observations. Particularly for the IGHV1-2 gene, strong biases became evident at the level of utilization of different alleles, since 79/86 rearrangements (92%) utilized allele *04 vs. only 7/86 rearrangements (8%) that utilized allele *02. This is noteworthy, taking into consideration that these two alleles differ in a single nucleotide, leading to a single amino acid change in framework region (FR)-3. The repertoire biases became more pronounced when the analysis was focused on 171 rearrangements from 163 cases classified as SMZL based on splenic histopathology, according to the 2008 WHO criteria. Within this subgroup, 56/171 cases (32.7%) utilized IGHV1-2*04. Noticeably, only 1/17 cases with a diagnosis of splenic diffuse red pulp lymphoma utilized IGHV1-2*04 (p<0.02 for comparison to SMZL). The IGHV1-2*04 rearrangements carried significantly longer heavy complementarity-determining region-3 (VH CDR3) than all other cases (median, 22 vs. 17 amino acids, respectively; p<0.001). In addition, 52/79 IGHV1-2*04 cases (65.8%) employed one of the IGHD3-3, IGHD3-9 or IGHD3-10 genes. In 28/32 IGHV1-2*04/IGHD3 rearrangements, the IGHD gene was utilized in the same reading frame, leading to VH CDR3s with common “IGHD-derived” amino acid (AA) motifs. Using bioinformatics tools previously applied to CLL, biased associations of IGHV, IGHD and IGHJ genes with stereotyped VH CDR3s were identified in 25/345 sequences (7.2%). Noticeably, only 10/28 IGHV1-2*04/IGHD3-3 rearrangements with “IGHD-derived” VH CDR3 amino acid motifs could be assigned to “stereotyped” clusters. Despite exhibiting restricted usage of the IGHV1-2*04 and IGHD3-3 genes leading to great overall VH domain similarity, the remaining cases did not fulfill the established criteria for VH CDR3 “stereotypy”, as defined in other lymphoid malignancies, namely CLL. Based on somatic hypermutation (SHM) analysis, the sequences were divided into three groups: (i) truly unmutated (100% germline identity, GI): 46/345 sequences (13.3%); (ii) minimally/borderline mutated (97-99.9% GI): 130/345 sequences (37.7%); and (iii) significantly mutated (<97% identity): 169/345 sequences (49%). At the individual gene level, the distribution of rearrangements of IGHV genes according to SHM status varied significantly. In particular, 56/79 IGHV1-2*04 rearrangements (71%) were predominantly “borderline mutated”, whereas the majority (>67%) of rearrangements utilizing the IGHV3-23, IGHV3-30 and IGHV3-7 genes were “significantly mutated”; finally, IGHV4-34 gene rearrangements were evenly distributed to the three mutational subgroups. Shared (“stereotyped”) AA changes were identified for IGHV1-2*04 rearrangements, with certain FR2 and FR3 codons emerging as “hotspots” for recurrent, conservative AA changes. In conclusion, we demonstrate that more than 30% of cases with a histopathological diagnosis of SMZL on the spleen express IGHV1-2*04 receptors with unusually long VH CDR3s, biased usage of the IGHD3-3 gene, leading to shared “IGHD-derived” VH CDR3 motifs, and very precise molecular features of SHM. The biased expression of a distinctive germline-encoded VH specificity might be considered as evidence for heavy chain dominance in the clonogenic IG receptors in SMZL. These findings allude to selection by specific (super)antigenic element(s) in the pathogenesis of at least a major subset of SMZL. In addition, they raise the intriguing possibility that certain subtypes of SMZL could derive from progenitor cell populations adapted to particular antigenic challenges through cellular selection of VH domain specificities.