Genetic Origin of Myeloma.

Multiple myeloma (MM) is a tumor of isotype-switched plasma cells that accumulate in the bone marrow, replacing normal plasma cells and leading to bone destruction and marrow failure. It is often preceded by a stable monoclonal gammopathy (MG) with limited (<10%) bone marrow plasmacytosis that progresses stochastically to MM at a rate of between 1–2% per year. Primary genetic events thought to be associated with disease initiation are present at similar frequencies in both MG and MM. In approximately 40% of cases, there are recurrent chromosome translocations involving the immunoglobulin heavy chain gene that have the hallmarks of being mediated by errors in switch recombination (90%) or somatic hypermutation (10%). These involve recurrent loci that fall into three categories: Cyclin D (15% CCND1 at 11q13, <1% CCND2 at 12p13, 2% CCND3 at 6p21), MAF (5% c-maf at 16q23, 2% MAFB at 20q12, <1% MAFA at 8q24.3), and MMSET (usually with FGFR3 at 4p16, 15%). Approximately one-half of cases are hyperdiploid (48–75 chromosomes) with trisomies involving chromosomes 3, 5, 7, 9, 11, 15, 19 and 21. A unifying feature of MM is dysregulated expression of a cyclin D gene, either directly by Ig gene translocation, by transactivation by MAF (CCND2), or by unknown mechanisms (MMSET – CCND2, Hyperdiploid – CCND1). Interestingly, about 2% of patients express no cyclin D, and one-half of these patients have bi-allelic deletion of RB, highlighting the critical role of the CCND/RB axis in the pathogenesis of MM. Deletion of chromosome 13 is seen in one-half of MM but is much more common in the tumors that express CCND2 (>80%) than in those that express CCND1 (~30%). Although with largely redundant functions, CCND1 has additional ability to antagonize RB not shared by CCND2, suggesting that CCND2 tumors may be more critically dependent on the absolute level of RB protein. A variety of secondary genetic events associated with disease progression occur with a similar frequency in hyperdiploid and non-hyperdiploid tumors (17p loss or p53 mutations, RAS mutations, secondary Ig translocations, MYC translocations, and inactivation of p18INK4c or RB1). In contrast, a promiscuous array of mutations that activate the NFKB pathway are less common in hyperdiploid MM, which, nonetheless, has high levels of presumably ligand-dependent NFKB activity and appears particularly dependent on the bone marrow microenvironment. Both some of the primary (MAF, MMSET) and secondary (17p deletion) genetic events are associated with a poor prognosis with melphalan-based regimens and appear to benefit from the early introduction of bortezomib.