Table 1.
Controversial issues in genetics of MM
| Assumption | Controversy | Hypothesis/question/exploration |
|---|---|---|
| The t(4;14) largely involves the switch regions, suggesting errors during the CSR process. | Some of the IGH translocations may take place not in secondary lymphoid organs but within the bone marrow during the maturation IGH rearrangements | Occurrence of RAG-mediated molecular errors during a (re-)edition of the B-cell receptor. |
| The oncogenic transformation in MM is thought to occur within secondary lymphoid organs. | More than 4% of patients have 2 unrelated clones with different VDJ rearrangements. | Possibility of evolution of 2 independent clones at an earlier stage of plasma cells before VDJ rearrangement. |
| Hyperdiploidy is probably because of missegregation of chromosomes during mitosis. | The nature of the gained chromosomes in hyperdiploidy is totally different between ALL and MM. | Do chromosomes have a specific disposition on the mitotic plaque in MM as compared with ALL, leading to gains of different chromosomes? |
| Some of the 14q32 translocations are recurrent. | The selectivity in the nature of 14q32 translocation partners is not fully understood. | The vicinity of chromosomal domains of chromosomes 14, 11, and 4 at certain times of SMH or CSR. |
| Several subclones coexisting at the same time in a single patient are similarly distributed in all locations. | Several subclones coexisting at the same time in a single patient have differential locations. | Several aspirates/biopsies should be performed in a single patient, ideally MRI- or PET-CT-guided on focal lesions, with subsequent evaluation for clonal content and subclone distribution |
| The subclone selection is under therapeutic pressure. | The subclone selection occurs in the natural history of the disease, which includes growth potential of the subclones or their interaction with their microenvironment. | Data supporting both hypotheses. The only way to answer this question would be to systematically analyze the diagnostic and first relapse specimens in a homogeneously treated cohort of patients. |
| Rare recurrent mutations observed only in subclones include genes supposed to act as drivers, such as NRAS, KRAS, and BRAF. | Driver mutations are not always expressed at the RNA level. | Need for future analyses at the protein level and to define the role of some of the known DNA repair mechanisms in inducing clonal change. |
ALL, acute lymphoblastic leukemia; CT, computed tomography; MRI, magnetic resonance imaging; PET, positron emission tomography.