Osteolytic disease in IL-6 and Myc dependent mouse model of human myeloma

IL6Myc mouse is an immunocompetent model for the development of aggressive multiple myeloma

Multiple Myeloma (MM) is a plasma cell neoplasm originating in the bone marrow and is the second most common blood cancer in the United States. One challenge in understanding the pathogenesis of MM and improving treatment is a lack of immunocompetent mouse models. We previously developed the IL6Myc mouse that generates plasmacytomas at 100% penetrance that phenotypically resemble aggressive MM. Using comprehensive genomic analysis, we found that the IL6Myc tumors resemble aggressive MM by RNA and protein expression. We also found that IL6Myc tumors accumulated fusions and missense mutations in genes that overlap significantly with human myeloma, indicating that the mouse is good model for studying disease etiology. Lastly, we derived cell lines from IL6Myc tumors that express cell surface markers typical of MM and readily engraft into mice, home to the bone marrow, and induce osteolytic disease. The cell lines may be useful in developing immunotherapies directed against BAFF-R and TACI, though not BCMA, and may also be a good model for studying dexamethasone resistance. These data indicate that the IL6Myc model is useful for studying development of aggressive MM and for developing new treatments against such forms of the disease.

Critical Role for Cap-Independent c-MYC Translation in Progression of Multiple Myeloma

Dysregulated c-myc is a determinant of multiple myeloma progression. Translation of c-myc can be achieved by an mTOR-mediated, cap-dependent mechanism or a cap-independent mechanism where a sequence in the 5'UTR of mRNA, termed the internal ribosome entry site (IRES), recruits the 40S ribosomal subunit. This mechanism requires the RNA-binding factor hnRNP A1 (A1) and becomes critical when cap-dependent translation is inhibited during endoplasmic reticulum (ER) stress. Thus, we studied the role of A1 and the myc IRES in myeloma biology. A1 expression correlated with enhanced c-myc expression in patient samples. Expression of A1 in multiple myeloma lines was mediated by c-myc itself, suggesting a positive feedback circuit where myc induces A1 and A1 enhances myc translation. We then deleted the A1 gene in a myc-driven murine myeloma model. A1-deleted multiple myeloma cells demonstrated downregulated myc expression and were inhibited in their growth in vivo. Decreased myc expression was due to reduced translational efficiency and depressed IRES activity. We also studied the J007 inhibitor, which prevents A1's interaction with the myc IRES. J007 inhibited myc translation and IRES activity and diminished myc expression in murine and human multiple myeloma lines as well as primary samples. J007 also inhibited tumor outgrowth in mice after subcutaneous or intravenous challenge and prevented osteolytic bone disease. When c-myc was ectopically reexpressed in A1-deleted multiple myeloma cells, tumor growth was reestablished. These results support the critical role of A1-dependent myc IRES translation in myeloma.

Laboratory Mice - A Driving Force in Immunopathology and Immunotherapy Studies of Human Multiple Myeloma

Mouse models of human cancer provide an important research tool for elucidating the natural history of neoplastic growth and developing new treatment and prevention approaches. This is particularly true for multiple myeloma (MM), a common and largely incurable neoplasm of post-germinal center, immunoglobulin-producing B lymphocytes, called plasma cells, that reside in the hematopoietic bone marrow (BM) and cause osteolytic lesions and kidney failure among other forms of end-organ damage. The most widely used mouse models used to aid drug and immunotherapy development rely on in vivo propagation of human myeloma cells in immunodeficient hosts (xenografting) or myeloma-like mouse plasma cells in immunocompetent hosts (autografting). Both strategies have made and continue to make valuable contributions to preclinical myeloma, including immune research, yet are ill-suited for studies on tumor development (oncogenesis). Genetically engineered mouse models (GEMMs), such as the widely known Vκ*MYC, may overcome this shortcoming because plasma cell tumors (PCTs) develop de novo (spontaneously) in a highly predictable fashion and accurately recapitulate many hallmarks of human myeloma. Moreover, PCTs arise in an intact organism able to mount a complete innate and adaptive immune response and tumor development reproduces the natural course of human myelomagenesis, beginning with monoclonal gammopathy of undetermined significance (MGUS), progressing to smoldering myeloma (SMM), and eventually transitioning to frank neoplasia. Here we review the utility of transplantation-based and transgenic mouse models of human MM for research on immunopathology and -therapy of plasma cell malignancies, discuss strengths and weaknesses of different experimental approaches, and outline opportunities for closing knowledge gaps, improving the outcome of patients with myeloma, and working towards a cure.

Generation of a lenalidomide-sensitive syngeneic murine in vivo multiple myeloma model by expression of CrbnI391V

The immunomodulatory drugs (IMiDs) thalidomide, lenalidomide, and pomalidomide are approved drugs for the treatment of multiple myeloma. IMiDs induce cereblon (CRBN) E3 ubiquitin ligase-mediated ubiquitination and degradation of Ikaros transcription factors Ikaros (IKZF1) and Aiolos (IKZF3), which are essential for multiple myeloma. However, because of a single amino acid substitution of valine to isoleucine in mouse CRBN at position 391, mice are not susceptible to IMiD-induced degradation of neosubstrates. Here, we report that expression of human CRBN or the Crbn^I391V mutant enables IMiD-induced degradation of IKZF1 and IKZF3 in murine MOPC.315.BM.Luc.eGFP and 5T33MM multiple myeloma cells. Accordingly, lenalidomide and pomalidomide decreased cell viability in a dose-dependent fashion in murine multiple myeloma cells expressing Crbn^I391V in vitro. The sensitivity of murine cells expressing Crbn^I391V to IMiDs highly correlated with their dependence on IKZF1. After transplantation, MOPC.315.BM.Luc.eGFP cells expressing murine Crbn^I391V induced multiple myeloma in mice, and treatment with lenalidomide and pomalidomide significantly delayed tumor growth. This straightforward model provides a proof-of-concept for studying the effects of IMiDs in multiple myeloma in mice, which allows for in vivo testing of IMiDs and other CRBN E3 ligase modulators.