Drug resistance in multiple myeloma: novel therapeutic targets within the malignant clone

Myeloma is incurable because the malignant stem cell is not eradicated by treatment. Thus, identification of the malignant hierarchy of B lineage cells in myeloma is required to identify potentially generative components and to evaluate their drug resistance properties. BM plasma cells are usually depleted by chemotherapy, but clonotypic B cells survive melphalan/prednisone as well as combination chemotherapy. In vitro, circulating and bone marrow-localized myeloma plasma cells show defective drug export, despite their phenotypic expression of P-glycoprotein, the mdr1 gene product. In contrast to plasma cells, circulating myeloma clonotypic B cells exhibit very efficient drug export. This suggests that circulating clonotypic MM B cells comprise a reservoir of drug resistant disease in myeloma although their stem cell potential remains to be confirmed. The malignant clone in each myeloma patient is defined by a unique IgH VDJ gene rearrangement. Using methods that exclude the possibility that a frequent but non-malignant clone has inadvertently been identified, and after confirming that the sequence identified is expressed by nearly all bone marrow plasma cells, we show that the drug resistant set of myeloma B cells is clonally related to the malignant plasma cells in myeloma. Clonotypic MM B cells survive chemotherapy, persist during clinically defined "minimal residual disease" and remain after autologous transplantation. Thus their malignant status is an important consideration. If malignant, they must be considered in the design of therapy. If non-malignant, they would be expected to have minimal impact on the disease process. A variety of evidence provides strong support for the view that clonotypic drug resistant B cells are malignant and may include the generative compartment of myeloma. The P-gp+ set of clonotypic B cells is extensively DNA aneuploid, an attribute of malignancy. All clonotypic B cells overexpress RHAMM, a novel oncogene involved in malignant spread. Finally, the population of clonotypic B cells lacks intraclonal heterogeneity. Since intraclonal heterogeneity is driven by the response to antigens, its absence in these cells indicates that they are no longer antigen-responsive. Since antigen-independent clonal expansion is characteristic of lymphoid malignancies, these observations provide further proof that clonotypic B cells in myeloma are malignant. Thus, the drug resistance of these cells is highly relevant to understanding why myeloma remains incurable despite the initial chemosensitivity of most bone marrow plasma cells.     

Combination chemotherapy with cisplatin and nifedipine: synergistic antitumor effects against a cisplatin-resistant subline of the B16 amelanotic melanoma

Cisplatin has become one of the most commonly prescribed cytotoxic chemotherapeutic agents. Unfortunately, the cure rate is low due to the development or outgrowth of cisplatin-resistant cells which repopulate tumors, resulting in patient death. We reported previously that the calcium channel blocker nifedipine enhances the antitumour actions of cisplatin (cis-diamminedichloroplatinum (II)) against murine tumors which are inherently cisplatin-sensitive (B16a) or inherently cisplatin-resistant (ML). We have developed an induced cisplatin-resistant tumor variant (B16a-Pt) that is 30 times more resistant to cisplatin than its cisplatin-sensitive parent line. In short-term studies, we report that nifedipine significantly enhanced the cytotoxicity of cisplatin against primary B16a-Pt tumors and their spontaneous pulmonary metastases. In long term studies, we report that combination therapy with nifedipine and cisplatin results in significantly enhanced survival.     

Helper T cells are required for the polyclonal stimulation of cytotoxic T cells by concanavalin A

Concanavalin A stimulation of T-cell cytotoxicity has been shown to be absolutely dependent on helper T-cell collaboration. Thymocytes stimulated with ConA do not differentiate to yield cytotoxic effector cells. However, thymocytes cocultured with irradiated spleen cells as helpers and ConA yield high levels of cytotoxicity. The helper cell bears theta antigens on its surface, is not an adherent cell, and does not require any adherent cell functions in our culture conditions. The ConA-dependent helper cells appear to be polyclonal in specificity. Thus, polyclonal stimulation of cytotoxicity by ConA requires T helper-T precursor collaboration in analogy to antigen-specific T helper-T precursor interactions. Unlike the antigen-specific interacitons, the ConA-driven cytotoxicity does not appear to require linked associative recognition for induction of cytotoxicity.     

Severe deficiency of B lymphocytes in peripheral blood from multiple myeloma patients

A major problem in the assessment of circulating B lymphocytes in multiple myeloma is the extent to which cells with passively absorbed Ig contribute to the assay. We have analyzed peripheral blood B cell numbers in 51 patients in various treatment categories by using an assay that is not subject to artifacts involving cytophilic Ig. We have defined a B lymphocyte by three different criteria (a) expression of a high surface density of Ig (b) expression of a high density of HLA.DR and (c) expression of a marker exclusive to surface Ig+ B cells. By these criteria, normal individuals have an average of 6% B cells. In multiple myeloma patients, B cell levels in purified mononuclear cell preparations are severely reduced. Untreated patients and the majority of patients on intermittent chemotherapy have 20-600-fold fewer B cells than do normal donors (average = 0.3%). This decrease was even greater in whole blood of patients as compared with normal donors (100-1,000-fold fewer B cells). The number of B cells did not correlate with disease status or paraprotein concentration. We found no evidence to support the idea that B lymphocytes in patients include a substantial monoclonal subset.     

The selective Aurora B kinase inhibitor AZD1152 is a potential new treatment for multiple myeloma

Aurora kinases are potential targets for cancer therapy. Previous studies have validated Aurora kinase A as a therapeutic target in multiple myeloma (MM), and have demonstrated in vitro anti-myeloma effects of small molecule Aurora kinase inhibitors that inhibit both Aurora A and B. This study demonstrated that Aurora B kinase was strongly expressed in myeloma cell lines and primary plasma cells. The selective Aurora B inhibitor AZD1152-induced apoptotic death in myeloma cell lines at nanomolar concentrations, with a cell cycle phenotype consistent with that reported previously for Aurora B inhibition. In some cases, AZD1152 in combination with dexamethasone showed increased anti-myeloma activity compared with the use of either agent alone. AZD1152 was active against sorted CD138(+) BM plasma cells from myeloma patients but also, as expected, was toxic to CD138(-) marrow cells from the same patients. In a murine myeloma xenograft model, AZD1152-inhibited tumour growth at well-tolerated doses and induced cell death in established tumours, with associated mild, transient leucopenia. AZD1152 shows promise in these preclinical studies as a novel treatment for MM.     

Hyaluronan-dependent motility of B cells and leukemic plasma cells in blood, but not of bone marrow plasma cells, in multiple myeloma: alternate use of receptor for hyaluronan-mediated motility (RHAMM) and CD44

We investigated the ability of blood B cells, bone marrow (BM) plasma cells, and terminal leukemic plasma cells (T-PCL) from patients with multiple myeloma (MM) to migrate on extracellular matrix proteins. Hyaluronan (HA), but not collagen type I, collagen type IV, or laminin, promoted migration of MM blood B cells, as determined by time-lapse video microscopy. Between 13% and 20% of MM blood B cells migrated on HA with an average velocity of 19 micron/min, and greater than 75% of MM blood B cells exhibited vigorous cell movement and plasma membrane deformation, as did circulating T-PCL and extraskeletal plasma cells from patients with MM. In contrast, plasma cells obtained from BM of patients with MM lacked motility on all substrates tested and did not exhibit cell membrane protrusions or cellular deformation. MM blood B cells and MM plasma cells from all sources examined expressed the HA- binding receptors receptor for HA-mediated motility (RHAMM) and CD44. On circulating MM B cells, both RHAMM and CD44 participated in HA- binding, indicating their expression ex vivo in an activated conformation. In contrast, for the majority of BM plasma cells in the majority of patients with MM, expression of RHAMM or CD44 was not accompanied by HA binding. A minority of patients did have HA-binding BM plasma cells, involving both RHAMM and CD44, as evidenced by partial blocking with monoclonal antibodies (MoAbs) to RHAMM or to CD44. Despite HA binding by both RHAMM and CD44, migration of MM blood B cells on HA was inhibited by anti-RHAMM but not by anti-CD44 MoAbs, indicating that RHAMM but not CD44 mediates motility on HA. Thus, circulating B and plasma cells in MM exhibit RHAMM- and HA-dependent motile behavior indicative of migratory potential, while BM plasma cells are sessile. We speculate that a subset(s) of circulating B or plasma cells mediates malignant spread in myeloma.     

Abnormal clonogenic potential of T cells from multiple myeloma patients

Peripheral blood lymphocytes (PBLs) from multiple myeloma patients are defective in both proportion and absolute numbers of OKT4+ cells and have a normal proportion but reduced absolute number of OKT8+ cells. To assess the functional capabilities of the T cells in myeloma patients, we cloned the T cells in PBLs using limiting dilution conditions in which 100% of OKT4+ and OKT8+ T cells in normal PBLs are able to form a clone. In contrast, the OKT8+ cells from PBLs of five of seven multiple myeloma patients were severely compromised in their clonogenic potential; only 7% to 25% of OKT8+ T cells appeared to give rise to a clone. Clonogenic potential of the OKT4+ cells in patients was more nearly normal. Analysis of two multiple myeloma patients with abnormally low numbers of T cells in PBLs revealed the existence of abnormalities in the progenitors of T cell clones. In both patients, two to three times as many T cell clones were observed as would have been expected based on the number of PBLs cultured at limiting dilution, indicating that OKT4-8- cells in PBLs are capable of giving rise to OKT4+ and, at lower frequency, to OKT8+ clonal progeny in vitro. We conclude that purely quantitative assessment of T cell subsets should be interpreted with caution, since proportionately normal numbers of OKT8+ cells in patient PBLs are seriously compromised in their ability to give rise to clonal progeny in vitro, and since there appears to be a OKT4-8- population of T cells in PBLs that are committed to become OKT4+ or OKT8+ T cells, but are unable to do so in vivo.