Translocation T(4;14)(p16.3;q32) is a recurrent genetic lesion in primary amyloidosis.

Primary amyloidosis is a fatal disorder characterized by low numbers of clonal plasma cells in the bone marrow and the systemic deposition of light chain fragments in the form of amyloid. The molecular pathobiology of amyloidosis is primarily unknown. Recently, a novel karyotypically undetectable t(4;14)(p16.3;q32) translocation has been identified in approximately 20% of multiple myeloma patients. The translocation leads to the apparent deregulation of two genes located on 4p16.3, the fibroblast growth-factor receptor 3 (FGFR3), and the putative transcription factor multiple myeloma SET domain (MMSET), and to the generation of IGH/MMSET hybrid transcripts. In this study, we investigated the presence of the t(4;14) translocation in 42 AL patients using a reverse transcriptase-polymerase chain reaction assay for the detection of IGH/MMSET transcripts. Chimeric transcripts were found in six patients (14%) and were consistent with a 4p16.3 breakpoint involving intron 3 and juxtaposing IGH regions to exon 4. In three of these cases, hybrid transcripts juxtaposing IGH regions to exon 5 were also observed and were probably the result of an alternative splicing skipping exon 4. Because all of the fusion transcripts (six of six) excluded exon 3, the first translated MMSET exon, only putative 5' truncated MMSET proteins could be generated. In conclusion, our results demonstrate that the t(4;14)(p16.3;q32) translocation is a recurrent genetic lesion in primary amyloidosis.

Biological features of the clone involved in primary amyloidosis (AL).

Primary light chain-associated amyloidosis (AL) is a plasma cell dyscrasia that causes morbidity via systemic tissue deposition of monoclonal light chains in the form of fibrils (amyloid). It is the most common form of systemic amyloidosis in Western countries and is rapidly fatal. Knowledge of the pathobiology of the underlying B cell clone is of primary importance for the design and optimization of therapeutic strategies.

Detection of t(4;14)(p16.3;q32) chromosomal translocation in multiple myeloma by reverse transcription-polymerase chain reaction analysis of IGH-MMSET fusion transcripts.

We and others have recently identified a novel recurring t(4;14)(p16.3; q32) translocation in multiple myeloma (MM) that leads to an apparent deregulation of the FGFR3 and WHSC1/MMSET genes. Because the presence of IGH-MMSET hybrid transcripts has been found in MM cell lines with t(4;14), they may represent a specific tumor-associated marker in MM. In this study, we developed a reverse transcription-PCR (RTPCR) assay for detecting chimeric transcripts from all of the 4p16.3 breakpoints identified thus far, and we used it to investigate a representative panel of 53 MM patients and 16 patients with monoclonal gammopathy of uncertain significance; in addition, t(4;14) was investigated in all of the MM patients by means of two-color fluorescence in situ hybridization. IGH-MMSET transcripts were found in 11 of the 53 (20%) MM cases and 1 of 16 (6%) cases of monoclonal gammopathy of uncertain significance. There was complete concordance between the RT-PCR and fluorescence in situ hybridization analyses of the MM cases. The results of this study indicate that RT-PCR is a sensitive and reliable method of detecting t(4;14) and suggest that it may be useful for monitoring the disease in a significant proportion of patients.

Evidence that amyloidogenic light chains undergo antigen-driven selection.

AL amyloidosis is characterized by fibrillar tissue deposits (amyloid) composed of monoclonal light chains secreted by small numbers of indolent bone marrow plasma cells whose ontogenesis is unknown. To address this issue and to provide insights into the processes that accompanied pathogenic light chain formation, we isolated the complete variable (V) regions of 14 light (VL) and 3 heavy (VH) chains secreted by amyloid clones at diagnosis (10 Bence Jones and 4 with complete Igs, 9 lambda and 5 kappa) by using an inverse polymerase chain reaction-based approach free of primer-induced biases. Amyloid V regions were found to be highly mutated compared with the closest germline genes in the databases or those isolated from the patients' DNA, and mutations were not associated with intraclonal diversification. Apparently high usage of the lambdaIII family germline gene V lambdaIII.1 was observed (4 of 9 lambda light chains). Analysis of the nature and distribution of somatic mutations in amyloid V regions showed that there was statistical evidence of antigen selection in 8 of 14 clones (7 in VL and 1 in VH). These results indicate that a substantial proportion of the amyloid clones developed from B cells selected for improved antigen binding properties and that pathogenic light chains show evidence of this selection.

Membrane CD22 defines circulating myeloma-related cells as mature or later B cells.

Circulating clonally related earlier cells are present in multiple myeloma (MM) and may be involved in the dissemination of this disease, its recurrence, and chemoresistance. The nature, stage of differentiation, and size of this cell population remain uncertain. Unlike other B-cell markers, CD22 membrane expression is limited to the late differentiation stages comprised between mature B cells (CD22+) and plasma cells (PC; CD22-) and may thus be useful in delimiting the maturational state of circulating early myeloma cells. Peripheral blood clone-related cells were detected by anti-idiotypic (Id) monoclonal antibodies and found to express CD22 (92% to 95%), monotypic light and heavy chain (100%), and CD38 (45%), whereas bone marrow PC were CD22-negative. CD22 expression was also documented on functional myeloma PC precursors, defined as peripheral blood cells capable of in vitro cytokine-driven monotypic PC differentiation, because up to approximately 70% inhibition of this process was obtained in 10 myeloma patients through the use of biospecific antibodies (BsAb) that deliver the plant toxin saporin to CD22+ cells. As further evidence of CD22 on circulating abnormal cells, it was found that in the only patient analyzed for DNA content, a portion of the peripheral blood CD22+ cells killed were hyperdiploid. Collectively, these findings indicate that most peripheral blood myeloma PC precursors are mature or later B cells presenting membrane CD22. The pattern of CD22 expression suggests the existence in MM of a differentiation process analogous to the normal antigenic response, in which CD22+ B cells migrate to the bone marrow and lose CD22 with PC differentiation. In addition, the sensitivity of myeloma PC precursors to the cytotoxic effects of the anti-CD22 BsAb and the possibility of interfering with their differentiation have potential therapeutic relevance.

Diagnostic approach to and follow-up of difficult cases of AL amyloidosis.

BACKGROUND: Routine electrophoretic analysis fails to detect a monoclonal component (MC) in a considerable portion of AL amyloidosis patients. We investigated whether the combination of immunofixation (IF) on agarose gel electrophoresis and bone marrow plasma cell (BMPC) light chain kappa/lambda ratio analysis could contribute to diagnosis in these cases. The possible use of the BMPC kappa/lambda ratio in monitoring the clone was also investigated. METHODS: We performed BMPC kappa/lambda ratio analysis and IF of serum and urine in 16 selected patients with no detectable MC at routine analysis, despite clinical features suggestive of primary amyloidosis. An anti-idiotypic monoclonal antibody specific for the amyloidogenic immunoglobulin and the BMPC kappa/lambda ratio were used to monitor the clone in a patient who underwent autologous peripheral blood stem cell transplantation. RESULTS: Abnormal kappa/lambda ratios were found in 14 (sensitivity 87.5%), and a MC in 12 (sensitivity 75%). Combination of the two analyses confirmed diagnosis in all cases. In one patient changes in the size of the clone, monitored on serial bone marrow aspirates by an anti-idiotypic antibody, paralleled variations of the kappa/lambda ratio. CONCLUSIONS: This study demonstrates that the combined use of IF and the BMPC kappa/lambda ratio is extremely powerful in AL amyloidosis. In addition, the BMPC kappa/lambda ratio should be considered for monitoring the amyloidogenic clone when serum or urine MC is not quantifiable.