The Leading Role of the Immune Microenvironment in Multiple Myeloma: A New Target with a Great Prognostic and Clinical Value

Multiple myeloma (MM) is a plasma cell (PC) malignancy whose development flourishes in the bone marrow microenvironment (BMME). The BMME components’ immunoediting may foster MM progression by favoring initial immunotolerance and subsequent tumor cell escape from immune surveillance. In this dynamic process, immune effector cells are silenced and become progressively anergic, thus contributing to explaining the mechanisms of drug resistance in unresponsive and relapsed MM patients. Besides traditional treatments, several new strategies seek to re-establish the immunological balance in the BMME, especially in already-treated MM patients, by targeting key components of the immunoediting process. Immune checkpoints, such as CXCR4, T cell immunoreceptor with immunoglobulin and ITIM domains (TIGIT), PD-1, and CTLA-4, have been identified as common immunotolerance steps for immunotherapy. B-cell maturation antigen (BCMA), expressed on MMPCs, is a target for CAR-T cell therapy, antibody-(Ab) drug conjugates (ADCs), and bispecific mAbs. Approved anti-CD38 (daratumumab, isatuximab), anti-VLA4 (natalizumab), and anti-SLAMF7 (elotuzumab) mAbs interfere with immunoediting pathways. New experimental drugs currently being evaluated (CD137 blockers, MSC-derived microvesicle blockers, CSF-1/CSF-1R system blockers, and Th17/IL-17/IL-17R blockers) or already approved (denosumab and bisphosphonates) may help slow down immune escape and disease progression. Thus, the identification of deregulated mechanisms may identify novel immunotherapeutic approaches to improve MM patients’ outcomes.

[1]  Y. Tai,et al.  Promising Antigens for the New Frontier of Targeted Immunotherapy in Multiple Myeloma , 2021, Cancers.

[2]  D. Dingli,et al.  “Real-life” data of the efficacy and safety of belantamab mafodotin in relapsed multiple myeloma—the Mayo Clinic experience , 2021, Blood Cancer Journal.

[3]  A. Neri,et al.  Mechanisms of Immune Evasion in Multiple Myeloma: Open Questions and Therapeutic Opportunities , 2021, Cancers.

[4]  P. Campbell,et al.  Whole-genome sequencing reveals progressive versus stable myeloma precursor conditions as two distinct entities , 2021, Nature Communications.

[5]  H. Goldschmidt,et al.  Idecabtagene Vicleucel in Relapsed and Refractory Multiple Myeloma. , 2021, The New England journal of medicine.

[6]  D. Joshua,et al.  Treg and Oligoclonal Expansion of Terminal Effector CD8+ T Cell as Key Players in Multiple Myeloma , 2021, Frontiers in Immunology.

[7]  J. Caetano,et al.  The Immune Microenvironment in Multiple Myeloma: Friend or Foe? , 2021, Cancers.

[8]  F. Zhan,et al.  The molecular make up of smoldering myeloma highlights the evolutionary pathways leading to multiple myeloma , 2021, Nature Communications.

[9]  C. Gisselbrecht,et al.  The EMA Review of Belantamab Mafodotin (Blenrep) for the Treatment of Adult Patients with Relapsed/Refractory Multiple Myeloma. , 2020, The oncologist.

[10]  A. Vacca,et al.  Actors on the Scene: Immune Cells in the Myeloma Niche , 2020, Frontiers in Oncology.

[11]  Delong Liu,et al.  BCMA-targeted immunotherapy for multiple myeloma , 2020, Journal of Hematology & Oncology.

[12]  Zhaowu Ma,et al.  Dendritic cell biology and its role in tumor immunotherapy , 2020, Journal of Hematology & Oncology.

[13]  M. Smyth,et al.  Cancer immunoediting and immune dysregulation in multiple myeloma. , 2020, Blood.

[14]  K. Hilligan,et al.  Antigen presentation by dendritic cells and their instruction of CD4+ T helper cell responses , 2020, Cellular & Molecular Immunology.

[15]  H. Einsele,et al.  Carfilzomib Based Treatment Strategies in the Management of Relapsed/Refractory Multiple Myeloma with Extramedullary Disease , 2020, Cancers.

[16]  S. Quezada,et al.  Marrow-Infiltrating Regulatory T Cells Correlate with the Presence of Dysfunctional CD4+PD-1+ Cells and Inferior Survival in Patients with Newly Diagnosed Multiple Myeloma , 2020, Clinical Cancer Research.

[17]  M. Lishner,et al.  Multiple myeloma BM-MSCs increase the tumorigenicity of MM cells via transfer of VLA4 enriched microvesicles. , 2020, Carcinogenesis.

[18]  W. Han,et al.  TGFβ inhibition via CRISPR promotes the long-term efficacy of CAR-T cells against solid tumors. , 2020, JCI insight.

[19]  J. Dudley,et al.  Mutation-derived Neoantigen-specific T-cell Responses in Multiple Myeloma , 2019, Clinical Cancer Research.

[20]  S. Lonial,et al.  Belantamab mafodotin for relapsed or refractory multiple myeloma (DREAMM-2): a two-arm, randomised, open-label, phase 2 study. , 2019, The Lancet. Oncology.

[21]  N. Raje,et al.  Anti-BCMA CAR T-cell therapy in multiple myeloma: can we do better? , 2019, Leukemia.

[22]  B. Wood,et al.  γ-secretase inhibition increases efficacy of BCMA-specific chimeric antigen receptor T cells in multiple myeloma. , 2019, Blood.

[23]  Yan Song,et al.  Targeting tryptophan catabolic kynurenine pathway enhances antitumor immunity and cytotoxicity in multiple myeloma , 2019, Leukemia.

[24]  H. Goldschmidt,et al.  Chimeric antigen receptor T-cell therapy for multiple myeloma: a consensus statement from The European Myeloma Network , 2019, Haematologica.

[25]  H. Einsele,et al.  The use of bispecific antibodies to optimize the outcome of patients with acute leukemia, lymphoma and multiple myeloma after SCT , 2019, Bone Marrow Transplantation.

[26]  A. Jakubowiak,et al.  Daratumumab Plus Carfilzomib and Dexamethasone in Patients With Relapsed or Refractory Multiple Myeloma. , 2019, Blood.

[27]  P. Sonneveld,et al.  Bortezomib, thalidomide, and dexamethasone with or without daratumumab before and after autologous stem-cell transplantation for newly diagnosed multiple myeloma (CASSIOPEIA): a randomised, open-label, phase 3 study , 2019, The Lancet.

[28]  Melissa L. Kemp,et al.  Early alterations in stem-like/resident T cells, innate and myeloid cells in the bone marrow in preneoplastic gammopathy. , 2019, JCI insight.

[29]  S. Jagannath,et al.  Anti‐BCMA CAR T‐Cell Therapy bb2121 in Relapsed or Refractory Multiple Myeloma , 2019, The New England journal of medicine.

[30]  Weiss,et al.  B cell maturation antigen-specific CAR T cells are clinically active in multiple myeloma. , 2019, The Journal of clinical investigation.

[31]  R. Demichelis-Gómez,et al.  Bispecific Antibodies in Hematologic Malignancies: When, to Whom, and How Should Be Best Used? , 2019, Current Oncology Reports.

[32]  Scott N. Mueller,et al.  Tissue-resident memory CD8+ T cells promote melanoma–immune equilibrium in skin , 2018, Nature.

[33]  B. Lei,et al.  A phase 1, open-label study of LCAR-B38M, a chimeric antigen receptor T cell therapy directed against B cell maturation antigen, in patients with relapsed or refractory multiple myeloma , 2018, Journal of Hematology & Oncology.

[34]  S. Mccarroll,et al.  Abstract 139: Single-cell RNA sequencing reveals compromised immune microenvironment in precursor stages of multiple myeloma , 2019, Tumor Biology.

[35]  Michael D. Robbins,et al.  Elotuzumab plus Pomalidomide and Dexamethasone for Multiple Myeloma , 2018, The New England journal of medicine.

[36]  W. Dougall,et al.  TIGIT immune checkpoint blockade restores CD8+ T-cell immunity against multiple myeloma. , 2018, Blood.

[37]  Thomas S. Watkins,et al.  Bone marrow transplantation generates T cell–dependent control of myeloma in mice , 2018, The Journal of clinical investigation.

[38]  T. Luetkens,et al.  Biomarkers for checkpoint inhibition in hematologic malignancies. , 2018, Seminars in cancer biology.

[39]  Camille Guillerey,et al.  Myeloma escape after stem cell transplantation is a consequence of T-cell exhaustion and is prevented by TIGIT blockade. , 2018, Blood.

[40]  G. Morgan,et al.  Subclonal evolution in disease progression from MGUS/SMM to multiple myeloma is characterised by clonal stability , 2018, Leukemia.

[41]  Michael L. Wang,et al.  T Cells Genetically Modified to Express an Anti-B-Cell Maturation Antigen Chimeric Antigen Receptor Cause Remissions of Poor-Prognosis Relapsed Multiple Myeloma. , 2018, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[42]  Angela E. Leek,et al.  Fc Effector Function Contributes to the Activity of Human Anti-CTLA-4 Antibodies , 2018, Cancer cell.

[43]  P. L. Bergsagel,et al.  Dysregulated IL-18 Is a Key Driver of Immunosuppression and a Possible Therapeutic Target in the Multiple Myeloma Microenvironment. , 2018, Cancer cell.

[44]  Christopher A. Lazarski,et al.  A reappraisal of CTLA-4 checkpoint blockade in cancer immunotherapy , 2018, Cell Research.

[45]  K. Vanderkerken,et al.  Mesenchymal stem cells in multiple myeloma: a therapeutical tool or target? , 2018, Leukemia.

[46]  H. Tamura Immunopathogenesis and immunotherapy of multiple myeloma , 2018, International Journal of Hematology.

[47]  Y. Asmann,et al.  High somatic mutation and neoantigen burden are correlated with decreased progression-free survival in multiple myeloma , 2017, Blood Cancer Journal.

[48]  S. Hervás-Stubbs,et al.  Expansion of Tumor-Infiltrating CD8+ T cells Expressing PD-1 Improves the Efficacy of Adoptive T-cell Therapy. , 2017, Cancer research.

[49]  Xiao-dong Zhu,et al.  Colony-Stimulating Factor 1 Receptor Blockade Inhibits Tumor Growth by Altering the Polarization of Tumor-Associated Macrophages in Hepatocellular Carcinoma , 2017, Molecular Cancer Therapeutics.

[50]  A. Lesokhin,et al.  Immune checkpoint blockade for hematologic malignancies: a review. , 2017, Stem cell investigation.

[51]  C. Benoist,et al.  T Regulatory Cells Support Plasma Cell Populations in the Bone Marrow. , 2017, Cell reports.

[52]  J. Dudley,et al.  Integrative network analysis identifies novel drivers of pathogenesis and progression in newly diagnosed multiple myeloma , 2018, Leukemia.

[53]  S. Mattarollo,et al.  Therapeutic Efficacy of 4-1BB Costimulation Is Abrogated by PD-1 Blockade in a Model of Spontaneous B-cell Lymphoma , 2017, Cancer Immunology Research.

[54]  R. Greil,et al.  T cells in multiple myeloma display features of exhaustion and senescence at the tumor site , 2016, Journal of Hematology & Oncology.

[55]  J. Soria,et al.  Concurrent irradiation with the anti-programmed cell death ligand-1 immune checkpoint blocker durvalumab: Single centre subset analysis from a phase 1/2 trial. , 2016, European journal of cancer.

[56]  Syed Abbas Ali,et al.  T cells expressing an anti-B-cell maturation antigen chimeric antigen receptor cause remissions of multiple myeloma. , 2016, Blood.

[57]  M. Millenson,et al.  Nivolumab in Patients With Relapsed or Refractory Hematologic Malignancy: Preliminary Results of a Phase Ib Study. , 2016, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[58]  K. Anderson,et al.  Osteoclasts promote immune suppressive microenvironment in multiple myeloma: therapeutic implication. , 2016, Blood.

[59]  N. Callander,et al.  Immunoregulatory roles of versican proteolysis in the myeloma microenvironment. , 2016, Blood.

[60]  N. Nassif,et al.  Multiple myeloma causes clonal T-cell immunosenescence: identification of potential novel targets for promoting tumour immunity and implications for checkpoint blockade , 2016, Leukemia.

[61]  B. Nico,et al.  Microenvironment drug resistance in multiple myeloma: emerging new players , 2016, Oncotarget.

[62]  Bie M. P. Verbist,et al.  Daratumumab depletes CD38+ immune regulatory cells, promotes T-cell expansion, and skews T-cell repertoire in multiple myeloma. , 2016, Blood.

[63]  Hao Liu,et al.  Clinical responses with T lymphocytes targeting malignancy-associated κ light chains. , 2016, The Journal of clinical investigation.

[64]  W. Han,et al.  CD138-directed adoptive immunotherapy of chimeric antigen receptor (CAR)-modified T cells for multiple myeloma , 2016 .

[65]  Camille Guillerey,et al.  Immune responses in multiple myeloma: role of the natural immune surveillance and potential of immunotherapies , 2016, Cellular and Molecular Life Sciences.

[66]  A. Zannettino,et al.  Osteoclasts control reactivation of dormant myeloma cells by remodelling the endosteal niche , 2015, Nature Communications.

[67]  J. Crowley,et al.  Prospective analysis of antigen-specific immunity, stem-cell antigens, and immune checkpoints in monoclonal gammopathy. , 2015, Blood.

[68]  Z. Xia,et al.  Serum levels of soluble programmed death ligand 1 predict treatment response and progression free survival in multiple myeloma , 2015, Oncotarget.

[69]  S. Devlin,et al.  T-cell Exhaustion in Multiple Myeloma Relapse after Autotransplant: Optimal Timing of Immunotherapy , 2015, Cancer Immunology Research.

[70]  F. Dammacco,et al.  Dendritic cells accumulate in the bone marrow of myeloma patients where they protect tumor plasma cells from CD8+ T-cell killing. , 2015, Blood.

[71]  D. Maloney,et al.  Chimeric antigen receptor-modified T cells derived from defined CD8+ and CD4+ subsets confer superior antitumor reactivity in vivo , 2015, Leukemia.

[72]  H. Goldschmidt,et al.  Revised International Staging System for Multiple Myeloma: A Report From International Myeloma Working Group. , 2015, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[73]  A. Bagg,et al.  Chimeric Antigen Receptor T Cells against CD19 for Multiple Myeloma. , 2015, The New England journal of medicine.

[74]  Jessica Katz,et al.  Elotuzumab Therapy for Relapsed or Refractory Multiple Myeloma. , 2015, The New England journal of medicine.

[75]  M. Chiarini,et al.  CXCR4 Regulates Extra-Medullary Myeloma through Epithelial-Mesenchymal-Transition-like Transcriptional Activation. , 2015, Cell reports.

[76]  Xiaodi Wu,et al.  Klf4 expression in conventional dendritic cells is required for T helper 2 cell responses. , 2015, Immunity.

[77]  H. Kohrt,et al.  Boosting Cancer Immunotherapy with Anti-CD137 Antibody Therapy , 2015, Clinical Cancer Research.

[78]  J. Miguel,et al.  PD-L1/PD-1 presence in the tumor microenvironment and activity of PD-1 blockade in multiple myeloma , 2015, Leukemia.

[79]  T. Luetkens,et al.  Immunomodulatory molecule PD-L1 is expressed on malignant plasma cells and myeloma-propagating pre-plasma cells in the bone marrow of multiple myeloma patients , 2015, Blood Cancer Journal.

[80]  O. Pradier,et al.  Immune impairments in multiple myeloma bone marrow mesenchymal stromal cells , 2015, Cancer Immunology, Immunotherapy.

[81]  J. Gershan,et al.  Combined immune checkpoint protein blockade and low dose whole body irradiation as immunotherapy for myeloma , 2015, Journal of Immunotherapy for Cancer.

[82]  Pamela A Shaw,et al.  Chimeric antigen receptor T cells for sustained remissions in leukemia. , 2014, The New England journal of medicine.

[83]  Giuseppe Rossi,et al.  SDF-1 inhibition targets the bone marrow niche for cancer therapy. , 2014, Cell reports.

[84]  D. Atanackovic,et al.  FOXP3 and CTLA4 overexpression in multiple myeloma bone marrow as a sign of accumulation of CD4+ T regulatory cells , 2014, Cancer Immunology, Immunotherapy.

[85]  J. Blay,et al.  Targeting tumor-associated macrophages with anti-CSF-1R antibody reveals a strategy for cancer therapy. , 2014, Cancer cell.

[86]  P. L. Bergsagel,et al.  CD28-mediated pro-survival signaling induces chemotherapeutic resistance in multiple myeloma. , 2014, Blood.

[87]  D. Joshua,et al.  Myeloma skews regulatory T and pro-inflammatory T helper 17 cell balance in favor of a suppressive state , 2014, Leukemia & lymphoma.

[88]  Deepak Mittal,et al.  New insights into cancer immunoediting and its three component phases--elimination, equilibrium and escape. , 2014, Current opinion in immunology.

[89]  C. Hofmeister,et al.  Genetic Modification of T Cells Redirected toward CS1 Enhances Eradication of Myeloma Cells , 2014, Clinical Cancer Research.

[90]  Christopher J. Ott,et al.  The Myeloma Drug Lenalidomide Promotes the Cereblon-Dependent Destruction of Ikaros Proteins , 2014, Science.

[91]  S. Carr,et al.  Lenalidomide Causes Selective Degradation of IKZF1 and IKZF3 in Multiple Myeloma Cells , 2014, Science.

[92]  P. Agostinis,et al.  Immature, Semi-Mature, and Fully Mature Dendritic Cells: Toward a DC-Cancer Cells Interface That Augments Anticancer Immunity , 2013, Front. Immunol..

[93]  L. Naldini,et al.  CD44v6-targeted T cells mediate potent antitumor effects against acute myeloid leukemia and multiple myeloma. , 2013, Blood.

[94]  W. Blackstock,et al.  Plasma Membrane Proteomics Identifies Biomarkers Associated with MMSET Overexpression in T(4;14) Multiple Myeloma , 2013, Oncotarget.

[95]  D. Joshua,et al.  Trogocytosis generates acquired regulatory T cells adding further complexity to the dysfunctional immune response in multiple myeloma , 2012, Oncoimmunology.

[96]  A. Roccaro,et al.  Bone Marrow Microenvironment in Multiple Myeloma Progression , 2012, Journal of biomedicine & biotechnology.

[97]  A. Cortelezzi,et al.  Lenalidomide in the Treatment of Chronic Lymphocytic Leukemia , 2012, Advances in hematology.

[98]  S. Rutella,et al.  Targeting Multiple-Myeloma-Induced Immune Dysfunction to Improve Immunotherapy Outcomes , 2012, Clinical & developmental immunology.

[99]  P. Ricciardi-Castagnoli,et al.  Interleukin-2 Production by Dendritic Cells and its Immuno-Regulatory Functions , 2012, Front. Immun..

[100]  Y-X Liu,et al.  Increased numbers of T helper 17 cells and the correlation with clinicopathological characteristics in multiple myeloma. , 2012, The Journal of international medical research.

[101]  N. Halama,et al.  The selective adhesion molecule inhibitor Natalizumab decreases multiple myeloma cell growth in the bone marrow microenvironment: therapeutic implications , 2011, British journal of haematology.

[102]  R. Schreiber,et al.  Cancer Immunoediting: Integrating Immunity’s Roles in Cancer Suppression and Promotion , 2011, Science.

[103]  M. Caligiuri,et al.  The PD-1/PD-L1 axis modulates the natural killer cell versus multiple myeloma effect: a therapeutic target for CT-011, a novel monoclonal anti-PD-1 antibody. , 2010, Blood.

[104]  J. Kutok,et al.  Elevated IL-17 produced by TH17 cells promotes myeloma cell growth and inhibits immune function in multiple myeloma. , 2010, Blood.

[105]  D. Joshua,et al.  Prognostically significant cytotoxic T cell clones are stimulated after thalidomide therapy in patients with multiple myeloma , 2009, Leukemia & lymphoma.

[106]  T. Nomura,et al.  Functional delineation and differentiation dynamics of human CD4+ T cells expressing the FoxP3 transcription factor. , 2009, Immunity.

[107]  R. Hayes,et al.  Monoclonal gammopathy of undetermined significance (MGUS) consistently precedes multiple myeloma: a prospective study. , 2009, Blood.

[108]  D. Neuberg,et al.  MHC class I chain-related protein A antibodies and shedding are associated with the progression of multiple myeloma , 2008, Proceedings of the National Academy of Sciences.

[109]  Lloyd J. Old,et al.  Adaptive immunity maintains occult cancer in an equilibrium state , 2007, Nature.

[110]  G. Morgan,et al.  The requirement for DNAM-1, NKG2D, and NKp46 in the natural killer cell-mediated killing of myeloma cells. , 2007, Cancer research.

[111]  P. Moss,et al.  Immunodeficiency and immunotherapy in multiple myeloma , 2007, British journal of haematology.

[112]  B. Quesnel,et al.  Plasma cells from multiple myeloma patients express B7-H1 (PD-L1) and increase expression after stimulation with IFN-{gamma} and TLR ligands via a MyD88-, TRAF6-, and MEK-dependent pathway. , 2007, Blood.

[113]  Charles P. Lin,et al.  Mechanisms of regulation of CXCR4/SDF-1 (CXCL12)-dependent migration and homing in multiple myeloma. , 2007, Blood.

[114]  T. Rème,et al.  Bone marrow mesenchymal stem cells are abnormal in multiple myeloma , 2007, Leukemia.

[115]  H. Johnsen,et al.  Impaired circulating myeloid DCs from myeloma patients. , 2004, Cytotherapy.

[116]  Virginia Pascual,et al.  Plasmacytoid dendritic cells induce plasma cell differentiation through type I interferon and interleukin 6. , 2003, Immunity.

[117]  Kenneth C. Anderson,et al.  Criteria for the classification of monoclonal gammopathies, multiple myeloma and related disorders: a report of the International Myeloma Working Group , 2003, British journal of haematology.

[118]  C. Yee,et al.  Tumour-derived soluble MIC ligands impair expression of NKG2D and T-cell activation , 2002, Nature.

[119]  Haidong Dong,et al.  Tumor-associated B7-H1 promotes T-cell apoptosis: A potential mechanism of immune evasion , 2002, Nature Medicine.

[120]  E. Chiang,et al.  TIGIT: A Key Inhibitor of the Cancer Immunity Cycle. , 2017, Trends in immunology.

[121]  W. Han,et al.  CD 138-directed adoptive immunotherapy of chimeric antigen receptor ( CAR )-modified T cells for multiple myeloma , 2016 .

[122]  P. L. Bergsagel,et al.  Immunosurveillance and therapy of multiple myeloma are CD226 dependent. , 2015, The Journal of clinical investigation.

[123]  L. Naldini,et al.  CD 44 v 6-targeted T cells mediate potent antitumor effects against acute myeloid leukemia and multiple myeloma , 2013 .

[124]  D. Kufe,et al.  Lenalidomide enhances anti-myeloma cellular immunity , 2012, Cancer Immunology, Immunotherapy.

[125]  Patrizia Agostinis,et al.  Immunogenic cell death, DAMPs and anticancer therapeutics: an emerging amalgamation. , 2010, Biochimica et biophysica acta.

[126]  S. Indraccolo,et al.  The involvement of stromal derived factor 1alpha in homing and progression of multiple myeloma in the 5TMM model. , 2006, Haematologica.

[127]  P. Tassone,et al.  HLA class I, NKG2D, and natural cytotoxicity receptors regulate multiple myeloma cell recognition by natural killer cells. , 2005, Blood.

[128]  Laurence Zitvogel,et al.  Antigen presentation and T cell stimulation by dendritic cells. , 2002, Annual review of immunology.

[129]  G. Zhu,et al.  Tumor-associated B7-H1 promotes T-cell apoptosis: A potential mechanism of immune evasion , 2002, Nature Medicine.

[130]  E. Vitetta,et al.  Immunotherapy of multiple myeloma , 1995, Stem cells.