Molecular genetics of human multiple myeloma

Molecular methods of defining gene rearrangements and DNA alterations that effect gene expression offer additional insights into malignant transformation of lymphoid cells. The highly clonal nature of myeloma is revealed by characterization of the unique Ig and TcR rearrangements. Whereas detection by DNA blot hybridization requires 2–5% clonality, more recent methods of DNA analysis, such as the polymerase chain reaction (PCR), can now increase the sensitivity of detection by several orders of magnitude. With improvement in therapies to treat myeloma, the issue of detection of minimal residual disease may be an important consideration in clinical management of the disease. The unique combinations of immunoglobulin gene segments and additional nucleotide alterations at junctional regions can be determined, and DNA probes can be synthesized that are clone-specific (Figure 1). By combining PCR amplification with detection methods employing clone-specific probes, significant improvements in disease detection are possible. As we begin to understand the functional consequences of genetic alterations associated with growth promoting genes such as the oncogenes myc and ras, and their role in myeloma, more promising therapies may be devised.     

Specific targeting to murine myeloma cells of Cyt1Aa toxin from Bacillus thuringiensis subspecies israelensis

Multiple myeloma is currently an incurable cancer of plasma B cells often characterized by overproduction of abnormally high quantities of a patient-specific, clonotypic immunoglobulin "M-protein." The M-protein is expressed on the cell membrane and secreted into the blood. We previously showed that ligand-toxin conjugates (LTC) incorporating the ribosome-inactivating Ricin-A toxin were very effective in specific cytolysis of the anti-ligand antibody-bearing target cells used as models for multiple myeloma. Here, we report on the incorporation of the membrane-disruptive Cyt1Aa toxin from Bacillus thuringiensis subsp. israelensis into LTCs targeted to murine myeloma cells. Proteolytically activated Cyt1Aa was conjugated chemically or genetically through either its amino or carboxyl termini to the major peptidic epitope VHFFKNIVTPRTP (p87-99) of the myelin basic protein. The recombinant fusion-encoding genes were cloned and expressed in acrystalliferous B. thuringiensis subsp. israelensis through the shuttle vector pHT315. Both chemically conjugated and genetically fused LTCs were toxic to anti-myelin basic protein-expressing murine hybridoma cells, but the recombinant conjugates were more active. LTCs comprising the Cyt1Aa toxin might be useful anticancer agents. As a membrane-acting toxin, Cyt1Aa is not likely to induce development of resistant cell lines.     

The biology and cytogenetics of multiple myeloma

Despite the advances in our knowledge of myeloma cell biology, our understanding of myeloma pathogenesis is still incomplete. In this review, we present a summary of the cellular and molecular aspects of B-cell development and immunoglobulin (lg) gene rearrangement which have been important in defining the characteristics of the myeloma plasma cell (MPC). The PMC has undergone variable gene recombination, somatic hypermutation and isotype switching, and is therefore at a postgerminal center stage of development. The finding of preswitch clonal cells and isotype variants have raised interesting questions about the cell of origin of myeloma, for which no conclusive data is as yet available. However much information has been obtained about the chromosomal and genetic aberrations in myeloma, including monosomy 13, Ig heavy chain (IgH) switch region translocations, numerical abnormalities and a multitude of heterogeneous changes. A variety of techniques have been developed to overcome the insensitivity of conventional karyotyping, utilizing molecular cytogenetic strategies ranging from the delineation of precise loci by fluorescent in situ hybridization, a more "global" assessment of the genome by multicolor spectral karyotyping, to the quantitation of chromosomal material of specific origin by comparative genomic hybridization. Whether the abnormalities detected represent oncogenic insults, are involved in disease progression or are simply "by-products" of genetic instability is still unclear. For IgH translocations, the role of candidate genes such as Cyclin D1 and FGFR3 has been studied extensively by quantitating their expression and assessment of their oncogenicity (e.g. for FGFR3) in animal models. The significance of other aberrations such as c-myc, ras and p53 has also been investigated. With the advent of oligonucleotide microarrays, the expression of thousands of genes can be efficiently examined. So far, this approach seems promising in defining subgroups of different disease behavior, and may highlight specific genes and molecular mechanisms which are important in myeloma pathogenesis.     

Role of osteoblast suppression in multiple myeloma

Multiple myeloma is the most common form of plasma cell dyscrasia and virtually all cases of myeloma exhibit osteolytic lesions, which result in bone pain, pathological fractures, spinal cord compression, and hypercalcaemia. Malignant plasma cells disrupt the delicate balance between bone formation and bone resorption, which ultimately leads to the debilitating osteolytic lesions. This review focuses principally on mechanisms of osteoblast inhibition by malignant plasma cells with emphasis placed on our experimental findings, which support a model for abnormal Wnt signaling in osteoblast suppression. We describe how excessive amounts of soluble Wnt inhibitors secreted by malignant plasma cells in multiple myeloma could promote osteolytic lesions, tumor growth, suppress hematopoiesis, prevent proper engraftment, and expansion of transplanted stem cells. Finally, we detail current therapies shown to disrupt the interaction between the myeloma cell and the microenvironment, leading to activation of osteoblasts.     

Mesenchymal stromal cells revert multiple myeloma cells to less differentiated phenotype by the combined activities of adhesive interactions and interleukin-6

Multiple myeloma is characterized by the malignant growth of immunoglobulin producing plasma cells, predominantly in the bone marrow. The effects of primary human mesenchymal stromal cells on the differentiation phenotype of multiple myeloma cells were studied by co-culture experiments. The incubation of multiple myeloma cells with bone marrow-derived mesenchymal stromal cells resulted in significant reduction of the expression of the predominant plasma cell differentiation markers CD38 and CD138, and cell surface immunoglobulin light chain. While the down-regulation of CD138 by stromal cells was completely dependent on their adhesive interactions with the multiple myeloma cells, interleukin-6 induced specific down-regulation of CD38. Mesenchymal stromal cells or their conditioned media inhibited the growth of multiple myeloma cell line, thereby reducing the overall amounts of secreted light chains. Analysis of primary multiple myeloma bone marrow samples reveled that the expression of CD38 on multiple myeloma cells was not affected by adhesive interactions. The ex vivo propagation of primary multiple myeloma cells resulted in significant increase in their differentiation markers. Overall, the data indicate that the bone marrow-derived mesenchymal stromal cells revert multiple myeloma cells to less differentiated phenotype by the combined activities of adhesive interactions and interleukin-6.     

The role of interleukin-6 and interleukin-6/interleukin-6 receptor-alpha complex in the pathogenesis of multiple myeloma

Multiple myeloma (MM) is a plasma-cell disorder in which malignant plasma cells accumulate in the bone marrow and usually produce a monoclonal immunoglobulin. Usual presenting features of overt MM include recurrent osteolytic lesions, bacterial infections, anemia and renal insufficiency. MM is responsible for about 1 percent of all cancer-related deaths in Western countries. Its epidemiologic pattern remains obscure, and its cause unknown [1]. The presence of somatic mutations within the immunoglobulin genes of myeloma cells indicate that the putative myeloma-cell precursors have been stimulated by antigens within germinal centers and are either memory B cells or migrating plasmablasts. Myeloma cells proliferate slowly in the bone marrow and display a weak apoptotic index in vivo [2]. This suggest that some defects in the apoptotic process could be involved in this neoplasia. Interleukin-6 (IL-6) is known to be an essential survival factor of myeloma cells and to protect them from apoptosis induced by different stimuli (e.g. dexamethasone, CD95, serum starvation, gamma-irradiation). More recently, important works have been devoted to the biology of the soluble form of the IL-6R alpha i.e., sIL-6R alpha. These works give IL-6/sIL-6R alpha complex an important role in the biology of IL-6. The purpose of the current review is to emphasize the role of this complex in the pathogenesis of MM.     

Mitogen induced cellular cytotoxicity (MICC) in multiple myeloma.

Mitogen induced cellular cytotoxicity (MICC) was noted to be markedly increased in patients with multiple myeloma as compared to normal controls and to patients with chronic lymphocytic leukemia (CLL). Enhanced MICC was present at various effector-to-target cell ratios and at several mitogen concentrations. Removal of adherent, phagocytic cells by carbonyl iron, glass wool, or rayon columns abolished the MICC response from the peripheral blood of both multiple myeloma patients and normal controls. Thus, the effector cell mediating MICC may be monocytic in origin and closely resembles the suppressor cell for immunoglobulin synthesis described in patients with multiple myeloma. Our data suggest that the MICC assay with chicken red blood cells as targets may provide a convenient method for identifying pathologic conditions where this cytotoxic effector cell population plays an active role.     

Growth inhibition of myeloma cells by anti-idiotype antibodies in the absence of membrane-bound immunoglobulin

Immunoglobulins are expressed as membrane-bound or secreted forms. Plasma cells produce little or no membrane immunoglobulin but secrete immunoglobulin molecules in large amounts. Immunoglobulin idiotypes of malignant B cells are tumor-specific antigens that may be targeted for immunotherapy. Thus, idiotype vaccination is being evaluated in clinical trials to control residual disease in multiple myeloma and non-Hodgkin's lymphoma. It is traditionally considered that anti-idiotype antibodies are not effective against plasma cell tumors, because the large amounts of immunoglobulin molecules secreted by the tumors block anti-idiotype antibodies, and because the absence of membrane immunoglobulin on the surface of these tumor cells renders them resistant to the effect of anti-idiotype antibodies. While the obstacle of abundant circulating idiotype may be obviated by reducing tumor burden to minimal residual disease, the absence of membrane immunoglobulin has been considered as a limiting factor that prevents tumor eradication by anti-idiotype antibodies. We demonstrate here that murine plasmacytoma cells can produce small amounts of membrane immunoglobulin M (IgM) heavy chains. However, the latter are precursor molecules that do not reach the cell surface. Although membrane-bound IgM is absent, the cells stain positively for surface IgM, reflecting molecules of the secreted form in the process of secretion. In spite of the relatively low levels of secreted immunoglobulin on the cell surface, anti-idiotype antibodies are effective in retardation of tumor growth in vivo. Thus, while there is no doubt that idiotype-specific cell-mediated responses are very important, myeloma patients in complete remission may additionally benefit from idiotype-specific humoral responses.     

Immunotherapy in multiple myeloma: Id-specific strategies suggested by studies in animal models

Multiple myeloma (MM) cells produce monoclonal immunoglobulin (Ig) which serves as a truly tumor-specific antigen. The tumor-specific antigenic determinants are localized in the variable (V)-regions of the monoclonal Ig and are called idiotopes (Id). We review here the evidence obtained in a T-cell receptor (TCR) transgenic mouse model that Id-specific, MHC class II–restricted CD4⁺ T cells play a pivotal role in immunosurveillance and eradication of MHC class II-negative MM cells. In brief, monoclonal Ig secreted by MM cells is endocytosed and processed by antigen-presenting cells (APCs) in the tumor. Such tumor-resident dendritic cell APCs in turn present Id peptide on their class II molecules to Id-specific CD4⁺ T cells which become activated and indirectly kill the MHC class II-negative myeloma cells. However, if the Id-specific CD4⁺ cells fail to eliminate the MM cells during their initial encounter, the increasing number of tumor cells secretes so much monoclonal Ig that T-cell tolerance to Id is induced. Extending these findings to MM patients, Id-specific immunotherapy should be applied at a time of minimal residual disease and when new Id-specific T cells have been educated in the thymus, like after high-dose chemotherapy and autologous stem cell transplantation.Abbreviations APC antigen-presenting cell - ASCT autologous stem cell transplantation - CDR complementarity-determining region - CFA complete Freunds adjuvant - DC dendritic cell - GM-CSF granulocyte-macrophage colony-stimulating factor - H heavy - Id idiotope or idiotype - Ig immunoglobulin - IL interleukin - L light - M-component monoclonal component - MGUS monoclonal gammopathy of undetermined significance - MHC major histocompatibility complex - MM multiple myeloma - MOPC mineral oil–induced plasmacytoma - TCR T-cell antigen receptor - V variableA. Corthay and B. Bogen are joint corresponding authors for this article.     

DNA repair pathways in human multiple myeloma

Every day, cells are faced with thousands of DNA lesions, which have to be repaired to preserve cell survival and function. DNA repair is more or less accurate and could result in genomic instability and cancer. We review here the current knowledge of the links between molecular features, treatment, and DNA repair in multiple myeloma (MM), a disease characterized by the accumulation of malignant plasma cells producing a monoclonal immunoglobulin. Genetic instability and abnormalities are two hallmarks of MM cells and aberrant DNA repair pathways are involved in disease onset, primary translocations in MM cells, and MM progression. Two major drugs currently used to treat MM, the alkylating agent Melphalan and the proteasome inhibitor Bortezomib act directly on DNA repair pathways, which are involved in response to treatment and resistance. A better knowledge of DNA repair pathways in MM could help to target them, thus improving disease treatment.     

Distinguishing primary and secondary translocations in multiple myeloma

Multiple myeloma (MM) is a malignant post-germinal center tumor of somatically-mutated, isotype-switched plasma cells that accumulate in the bone marrow. It often is preceded by a stable pre-malignant tumor called monoclonal gammopathy of undetermined significance (MGUS), which can sporadically progress to MM. Five recurrent primary translocations involving the immunoglobulin heavy chain (IgH) locus on chromosome 14q32 have been identified in MGUS and MM tumors. The five partner loci include 11q13, 6p21, 4p16, 16q23, and 20q12, with corresponding dysregulation of CYCLIN D1, CYCLIN D3, FGFR3/MMSET, c-MAF, and MAFB, respectively, by strong enhancers in the IgH locus. The five recurrent translocations, which are present in 40% of MM tumors, typically are simple reciprocal translocations, mostly having breakpoints within or near IgH switch regions but sometimes within or near VDJ or JH sequences. It is thought that these translocations are caused by aberrant IgH switch recombination, and possibly by aberrant somatic hypermutation in germinal center B cells, thus providing an early and perhaps initiating event in transformation. A MYC gene is dysregulated by complex translocations and insertions as a very late event during the progression of MM tumors. Since the IgH switch recombination and somatic hypermutation mechanism are turned off in plasma cells and plasma cell tumors, the MYC rearrangements are thought to be mediated by unknown mechanisms that contribute to structural genomic instability in all kinds of tumors. These rearrangements, which often but not always juxtapose MYC near one of the strong immunoglobulin enhancers, provide a paradigm for secondary translocations. It is hypothesized that secondary translocations not involving a MYC gene can occur at any stage of tumorigenesis, including in pre-malignant MGUS tumor cells.     

Serum protein N-glycosylation changes in multiple myeloma

BackgroundMultiple myeloma is characterized by clonal proliferation of malignant plasma cells in the bone marrow that produce monoclonal immunoglobulins. N-glycosylation changes of these monoclonal immunoglobulins have been reported in multiple myeloma, but previous studies only detected limited serum N-glycan features.MethodsHere, a more detailed study of the human serum N-glycome of 91 multiple myeloma patients and 51 controls was performed. We additionally analyzed sequential samples from patients (n = 7) which were obtained at different time points during disease development as well as 16 paired blood serum and bone marrow plasma samples. N-glycans were enzymatically released and measured by mass spectrometry after linkage specific derivatization of sialic acids.ResultsA decrease in both α2,3- and α2,6-sialylation, galactosylation and an increase in fucosylation within complex-type N-glycans were found in multiple myeloma patients compared to controls, as well as a decrease in difucosylation of diantennary glycans. The observed glycosylation changes were present in all ISS stages, including the “low-risk” ISS I. In individual patients, difucosylation of diantennary glycans decreased with development of the disease. Protein N-glycosylation features from blood and bone marrow showed strong correlation. Moreover, associations of monoclonal immunoglobulin (M-protein) and albumin levels with glycan traits were discovered in multiple myeloma patients.Conclusions & general significanceIn conclusion, serum protein N-glycosylation analysis could successfully distinguish multiple myeloma from healthy controls. Further studies are needed to assess the potential roles of glycan trait changes and the associations of glycans with clinical parameters in multiple myeloma early detection and prognosis.     

Antigen-specificity of oligoclonal abnormal protein bands in multiple myeloma after allogeneic stem cell transplantation

Myeloma patients may develop oligoclonal immunoglobulins, so-called abnormal protein bands (APB), after stem cell transplantation. APB do not correspond to the patient's paraprotein and confer a good prognosis. We set out to investigate whether such APB represent a humoral anti-myeloma immune response by screening immunoglobulins of 15 myeloma patients after allogeneic stem cell transplantation and a control group of healthy donors for reactivity with myeloma protein extracts. While the immunoglobulins of healthy donors did not react with myeloma protein extracts, patient-derived immunoglobulins showed variable levels of interaction, depending on the presence of APB on immunofixation. Most commonly, we detected interactions with heat-shock proteins, followed by neutral alpha-glucosidase, alpha-enolase and vimentin, as well as proliferating cell nuclear antigen and MAGEA4. More than 80% of targets were upregulated in myeloma. Heat-shock protein 60 (HSP60) was subsequently evaluated as an exemplary antigen. We found that HSP60 was aberrantly displayed on the surface of primary myeloma cells. Indeed, patient-derived APB-containing immunoglobulins recognized surface HSP60 suggesting that this antigen becomes accessible to the immune system after aberrant membrane exposition. We conclude that immunoglobulin fractions with APB recognize recurrent myeloma antigens and that this humoral response may contribute to the more favorable prognosis in patients with APB.     

Role of INTERLEUKIN-6 in the pathogenesis of multiple myeloma

Multiple myeloma (MM) is a currently incurable disease caused by the proliferation of malignant plasma cells. Although the pathogenesis of the disease still remains unclear, recent research in the biology of MM has produced new insights into the factors that control the growth and survival of myeloma cells. Among the growth factors, interleukin-6 (IL-6) has an essential role. Evidence suggests that IL-6 is not only a growth factor, but also a survival factor in MM, inhibiting apoptosis in myeloma cells. IL-6 interacts with several factors which are involved in the pathogenesis of MM, such as adhesion molecules, tumour suppressor genes and oncogenes. Considering the essential role of IL-6, it could serve as a target for new therapeutic interventions. Neutralizing the effect of IL-6 may result in a regression of tumour progression.     

Identify multiple myeloma stem cells: Utopia?

Multiple myeloma (MM) is a hematologic malignancy of monoclonal plasma cells which remains incurable despite recent advances in therapies. The presence of cancer stem cells (CSCs) has been demonstrated in many solid and hematologic tumors, so the idea of CSCs has been proposed for MM, even if MM CSCs have not been define yet. The existence of myeloma CSCs with clonotypic B and clonotypic non B cells was postulated by many groups. This review aims to focus on these distinct clonotypic subpopulations and on their ability to develop and sustain MM. The bone marrow microenvironment provides to MM CSCs self-renewal, survival and drug resistance thanks to the presence of normal and cancer stem cell niches. The niches and CSCs interact each other through adhesion molecules and the interplay between ligands and receptors activates stemness signaling (Hedgehog, Wnt and Notch pathways). MM CSCs are also supposed to be responsible for drug resistance that happens in three steps from the initial cancer cell homing microenvironment-mediated to development of microenvironment-independent drug resistance. In this review, we will underline all these aspects of MM CSCs.     

Expression profile of telomere‐associated genes in multiple myeloma

To further contribute to the understanding of multiple myeloma, we have focused our research interests on the mechanisms by which tumour plasma cells have a higher survival rate than normal plasma cells. In this article, we study the expression profile of genes involved in the regulation and protection of telomere length, telomerase activity and apoptosis in samples from patients with monoclonal gammopathy of undetermined significance, smouldering multiple myeloma, multiple myeloma (MM) and plasma cell leukaemia (PCL), as well as several human myeloma cell lines (HMCLs). Using conventional cytogenetic and fluorescence in situ hybridization studies, we identified a high number of telomeric associations (TAs). Moreover, telomere length measurements by terminal restriction fragment (TRF) assay showed a shorter mean TRF peak value, with a consistent correlation with the number of TAs. Using gene expression arrays and quantitative PCR we identified the hTERT gene together with 16 other genes directly involved in telomere length maintenance: HSPA9, KRAS, RB1, members of the Small nucleolar ribonucleoproteins family, A/B subfamily of ubiquitously expressed heterogeneous nuclear ribonucleoproteins, and 14‐3‐3 family. The expression levels of these genes were even higher than those in human embryonic stem cells (hESCs) and induced pluripotent stem cells (iPSCs), which have unlimited proliferation capacity. In conclusion, the gene signature suggests that MM tumour cells are able to maintain stable short telomere lengths without exceeding the short critical length, allowing cell divisions to continue. We propose that this could be a mechanism contributing to MM tumour cells expansion in the bone marrow (BM).     

Light chain myeloma plasma cells induce a strong cell-mediated immune response mainly directed against the monoclonal light chain determinants in a murine experimental model

An important goal for the treatment of human B cell malignancies lies in the induction of an active immune response directed against the tumoral clone, and more particularly against antigenic determinants of the monoclonal immunoglobulin (Ig). The presence of idiotype-reactive T-cells in patients with multiple myeloma has been previously reported, and strategies to increase their responsiveness towards the malignant plasma cells are being actively explored. Light chain (LC) myeloma is often an aggressive form of the disease, regarding which antitumoral immunity has not yet been studied. Here, we investigated in an experimental murine model a secreted monoclonal LC that may behave as a strong tumor antigen after immunization of animals with mitomycin C-treated malignant plasma cells producing monoclonal Ig. Non-dividing plasma cells were utilized as a cell suspension to immunize the mice intraperitoneally (i.p.). The immunized mice produced anti-Ig LC antibodies, mounted a cell-mediated response mainly directed against the monoclonal LC determinants, and survived tumor challenge with significant frequency. These results suggest that plasma cells are capable of presenting antigenic determinants derived from a secreted monoclonal LC in an MHC class I context, and of predominantly inducing a monoclonal Ig-specific T-cell response which can contribute to tumor rejection.