https://orcid.org/0009-0002-8614-9457
Key Points
IL-18-secreting CAR T cells promote clearance of antigen-low myeloma with reprogramming of cells in the myeloma microenvironment.
Multiantigen targeting enhances T-cell-target avidity, increasing engineered IL-18 output and potentiating antimyeloma activity.
Abstract
Multiple myeloma is a plasma cell malignancy that is currently incurable with conventional therapies. Following the success of CD19-targeted chimeric antigen receptor (CAR) T cells in leukemia and lymphoma, CAR T cells targeting B-cell maturation antigen (BCMA) more recently demonstrated impressive activity in relapsed and refractory myeloma patients. However, BCMA-directed therapy can fail due to weak expression of BCMA on myeloma cells, suggesting that novel approaches to better address this antigen-low disease may improve patient outcomes. We hypothesized that engineered secretion of the proinflammatory cytokine interleukin-18 (IL-18) and multiantigen targeting could improve CAR T-cell activity against BCMA-low myeloma. In a syngeneic murine model of myeloma, CAR T cells targeting the myeloma-associated antigens BCMA and B-cell activating factor receptor (BAFF-R) failed to eliminate myeloma when these antigens were weakly expressed, whereas IL-18–secreting CAR T cells targeting these antigens promoted myeloma clearance. IL-18-secreting CAR T cells developed an effector-like T-cell phenotype, promoted interferon-gamma production, reprogrammed the myeloma bone marrow microenvironment through type-I/II interferon signaling, and activated macrophages to mediate antimyeloma activity. Simultaneous targeting of weakly-expressed BCMA and BAFF-R with dual-CAR T cells enhanced T-cell:target-cell avidity, increased overall CAR signal strength, and stimulated antimyeloma activity. Dual-antigen targeting augmented CAR T-cell secretion of engineered IL-18 and facilitated elimination of larger myeloma burdens in vivo. Our results demonstrate that combination of engineered IL-18 secretion and multiantigen targeting can eliminate myeloma with weak antigen expression through distinct mechanisms.
References
1.
Morgan
GJ
, Walker
BA
, Davies
FE
. The genetic architecture of multiple myeloma
. Nat Rev Cancer
. 2012
;12
(5
):335
-348
.2.
Cancer Stat Facts: Myeloma. National Cancer Institute
. Accessed 14 February 2024. https://seer.cancer.gov/statfacts/html/mulmy.html.3.
Moreau
P
, Attal
M
, Facon
T
. Frontline therapy of multiple myeloma
. Blood
. 2015
;125
(20
):3076
-3084
.4.
Mikkilineni
L
, Kochenderfer
JN
. CAR T cell therapies for patients with multiple myeloma
. Nat Rev Clin Oncol
. 2021
;18
(2
):71
-84
.5.
Van De Donk
NWCJ
, Richardson
PG
, Malavasi
F
. CD38 antibodies in multiple myeloma: back to the future
. Blood
. 2018
;131
(1
):13
-29
.6.
Mikkilineni
L
, Kochenderfer
JN
. Chimeric antigen receptor T-cell therapies for multiple myeloma
. Blood
. 2017
;130
(24
):2594
-2602
.7.
FDA approves idecabtagene vicleucel for multiple myeloma
. 2021. Accessed 14 February 2024. https://www.fda.gov/drugs/resources-information-approved-drugs/fda-approves-idecabtagene-vicleucel-multiple-myeloma.8.
FDA approves ciltacabtagene autoleucel for relapsed or refractory multiple myeloma
. 2022. Accessed 14 February 2024. https://www.fda.gov/drugs/resources-information-approved-drugs/fda-approves-ciltacabtagene-autoleucel-relapsed-or-refractory-multiple-myeloma.9.
Rodriguez-Otero
P
, Ailawadhi
S
, Arnulf
B
, et al. Ide-cel or standard regimens in relapsed and refractory multiple myeloma
. N Engl J Med
. 2023
;388
(11
):1002
-1014
.10.
San-Miguel
J
, Dhakal
B
, Yong
K
, et al. Cilta-cel or standard care in lenalidomide-refractory multiple myeloma
. N Engl J Med
. 2023
;389
(4
):335
-347
.11.
Brudno
JN
, Maric
I
, Hartman
SD
, et al. T cells genetically modified to express an anti-B-cell maturation antigen chimeric antigen receptor with a CD28 costimulatory moiety cause remissions of poor-prognosis relapsed multiple myeloma
. J Clin Oncol
. 2018
;36
(22
):2267
-2280
.12.
Cohen
AD
, Garfall
AL
, Stadtmauer
EA
, et al. B cell maturation antigen – specific CAR T cells are clinically active in multiple myeloma
. J Clin Invest
. 2019
;129
(6
):2210
-2221
.13.
Da Vià
MC
, Dietrich
O
, Truger
M
, et al. Homozygous BCMA gene deletion in response to anti-BCMA CAR T cells in a patient with multiple myeloma
. Nat Med
. 2021
;27
(4
):616
-619
.14.
Truger
MS
, Duell
J
, Zhou
X
, et al. Single- and double-hit events in genes encoding immune targets before and after T cell–engaging antibody therapy in MM
. Blood Adv
. 2021
;5
(19
):3794
-3798
.15.
Lee
L
, Lim
WC
, Galas-Filipowicz
D
, et al. Limited efficacy of APRIL CAR in patients with multiple myeloma indicate challenges in the use of natural ligands for CAR T-cell therapy
. J Immunother Cancer
. 2023
;11
(6
):e006699
.16.
Pegram
HJ
, Lee
JC
, Hayman
EG
, et al. Tumor-targeted T cells modified to secrete IL-12 eradicate systemic tumors without need for prior conditioning
. Blood
. 2012
;119
(18
):4133
-4141
.17.
Avanzi
MP
, Yeku
O
, Li
X
, et al. Engineered tumor-targeted T cells mediate enhanced anti-tumor efficacy both directly and through activation of the endogenous immune system
. Cell Rep
. 2018
;23
(7
):2130
-2141
.18.
Hu
B
, Ren
J
, Luo
Y
, et al. Augmentation of antitumor immunity by human and mouse CAR T cells secreting IL-18
. Cell Rep
. 2017
;20
(13
):3025
-3033
.19.
Ruella
M
, Barrett
DM
, Kenderian
SS
, et al. Dual CD19 and CD123 targeting prevents antigen-loss relapses after CD19-directed immunotherapies
. J Clin Invest
. 2016
;126
(10
):3814
-3826
.20.
Katsarou
A
, Sjöstrand
M
, Naik
J
, et al. Combining a CAR and a chimeric costimulatory receptor enhances T cell sensitivity to low antigen density and promotes persistence
. Sci Transl Med
. 2021
;13
(623
):eabh1962
.21.
Hirabayashi
K
, Du
H
, Xu
Y
, et al. Dual-targeting CAR-T cells with optimal co-stimulation and metabolic fitness enhance antitumor activity and prevent escape in solid tumors
. Nat Cancer
. 2021
;2
(9
):904
-918
.22.
Majzner
RG
, Rietberg
SP
, Sotillo
E
, et al. Tuning the antigen density requirement for CAR T-cell activity
. Cancer Discov
. 2020
;10
(5
):702
-723
.23.
Hamieh
M
, Dobrin
A
, Cabriolu
A
, et al. CAR T cell trogocytosis and cooperative killing regulate tumour antigen escape
. Nature
. 2019
;568
(7750
):112
-116
.24.
Mansilla-Soto
J
, Eyquem
J
, Haubner
S
, et al. HLA-independent T cell receptors for targeting tumors with low antigen density
. Nat Med
. 2022
;28
(2
):345
-352
.25.
Gogishvili
T
, Danhof
S
, Prommersberger
S
, et al. SLAMF7-CAR T cells eliminate myeloma and confer selective fratricide of SLAMF7+ normal lymphocytes
. Blood
. 2017
;130
(26
):2838
-2847
.26.
Smith
EL
, Harrington
K
, Staehr
M
, et al. Supplementary materials for: GPRC5D is a target for the immunotherapy of multiple myeloma with rationally designed CAR T cells
. Sci Transl Med
. 2019
;11
(485
):eaau7746
.27.
Mailankody
S
, Devlin
SM
, Landa
J
, et al. GPRC5D-targeted CAR T cells for myeloma
. N Engl J Med
. 2022
;387
(13
):1196
-1206
.28.
Radhakrishnan
S V
, Luetkens
T
, Scherer
SD
, et al. CD229 CAR T cells eliminate multiple myeloma and tumor propagating cells without fratricide
. Nat Commun
. 2020
;11
(1
):798
.29.
Sun
C
, Mahendravada
A
, Ballard
B
, et al. Safety and efficacy of targeting CD138 with a chimeric antigen receptor for the treatment of multiple myeloma
. Oncotarget
. 2019
;10
(24
):2369
-2383
.30.
Drent
E
, Groen
RWJ
, Noort
WA
, et al. Pre-clinical evaluation of CD38 chimeric antigen receptor engineered T cells for the treatment of multiple myeloma
. Haematologica
. 2016
;101
(5
):616
-625
.31.
Novak
AJ
, Darce
JR
, Arendt
BK
, et al. Expression of BCMA, TACI, and BAFF-R in multiple myeloma: a mechanism for growth and survival
. Blood
. 2004
;103
(2
):689
-694
.32.
Moreaux
J
, Legouffe
E
, Jourdan
E
, et al. BAFF and APRIL protect myeloma cells from apoptosis induced by interleukin 6 deprivation and dexamethasone
. Blood
. 2004
;103
(8
):3148
-3157
.33.
Garfall
AL
, Maus
MV
, Hwang
W-T
, et al. Chimeric antigen receptor T cells against CD19 for multiple myeloma
. N Engl J Med
. 2015
;373
(11
):1040
-1047
.34.
Shah
NN
, Johnson
BD
, Schneider
D
, et al. Bispecific anti-CD20, anti-CD19 CAR T cells for relapsed B cell malignancies: a phase 1 dose escalation and expansion trial
. Nat Med
. 2020
;26
(10
):1569
-1575
.35.
Larson
SM
, Walthers
CM
, Ji
B
, et al. CD19/CD20 bispecific chimeric antigen receptor (CAR) in naive/memory T cells for the treatment of relapsed or refractory non-Hodgkin lymphoma
. Cancer Discov
. 2023
;13
(3
):580
-597
.36.
Lee
L
, Draper
B
, Chaplin
N
, et al. An APRIL-based chimeric antigen receptor for dual targeting of BCMA and TACI in multiple myeloma
. Blood
. 2018
;131
(7
):746
-758
.37.
Wong
DP
, Roy
NK
, Zhang
K
, et al. A BAFF ligand-based CAR-T cell targeting three receptors and multiple B cell cancers
. Nat Commun
. 2022
;13
(1
):217
.38.
Fernández de Larrea
C
, Staehr
M
, Lopez
AV
, et al. Defining an optimal dual-targeted CAR T-cell therapy approach simultaneously targeting BCMA and GPRC5D to prevent BCMA escape–driven relapse in multiple myeloma
. Blood Cancer Discov
. 2020
;1
(2
):146
-154
.39.
Jaspers
JE
, Khan
JF
, Godfrey
WD
, et al. IL-18-secreting CAR T cells targeting DLL3 are highly effective in small cell lung cancer models
. J Clin Invest
. 2023
;133
(9
):e166028
.40.
Svoboda
J
, Landsburg
DL
, Chong
EA
, et al. Fourth generation HUCART19-IL18 produces durable responses in lymphoma patients previously relapsed/refractory to anti-CD19 CAR T-cell theraphy
. Hematol Oncol
. 2023
;41
(S2
):35
-37
.41.
Hofgaard
PO
, Jodal
HC
, Bommert
K
, et al. A novel mouse model for multiple myeloma (MOPC315.BM) that allows noninvasive spatiotemporal detection of osteolytic disease
. PLoS One
. 2012
;7
(12
):e51892
.42.
Schmidts
A
, Ormhøj
M
, Choi
BD
, et al. Rational design of a trimeric APRIL-based CAR-binding domain enables efficient targeting of multiple myeloma
. Blood Adv
. 2019
;3
(21
):3248
-3260
.43.
Carpenter
RO
, Evbuomwan
MO
, Pittaluga
S
, et al. B-cell maturation antigen is a promising target for adoptive T-cell therapy of multiple myeloma
. Clin Cancer Res
. 2013
;19
(8
):2048
-2060
.44.
Lam
N
, Trinklein
ND
, Buelow
B
, Patterson
GH
, Ojha
N
, Kochenderfer
JN
. Anti-BCMA chimeric antigen receptors with fully human heavy-chain-only antigen recognition domains
. Nat Commun
. 2020
;11
(1
):283
. 14.45.
Qin
H
, Dong
Z
, Wang
X
, et al. CAR T cells targeting BAFF-R can overcome CD19 antigen loss in B cell malignancies
. Sci Transl Med
. 2019
;11
(511
):eaaw9414
.46.
Tirier
SM
, Mallm
JP
, Steiger
S
, et al. Subclone-specific microenvironmental impact and drug response in refractory multiple myeloma revealed by single-cell transcriptomics
. Nat Commun
. 2021
;12
(1
):6960
.47.
Feucht
J
, Sun
J
, Eyquem
J
, et al. Calibration of CAR activation potential directs alternative T cell fates and therapeutic potency
. Nat Med
. 2019
;25
(1
):82
-88
.48.
Long
AH
, Haso
WM
, Shern
JF
, et al. 4-1BB costimulation ameliorates T cell exhaustion induced by tonic signaling of chimeric antigen receptors
. Nat Med
. 2015
;21
(6
):581
-590
.49.
Weber
EW
, Parker
KR
, Sotillo
E
, et al. Transient rest restores functionality in exhausted CAR-T cells through epigenetic remodeling
. Science
. 2021
;372
(6537
):eaba1786
.50.
Guedan
S
, Posey
AD
, Shaw
C
, et al. Enhancing CAR T cell persistence through ICOS and 4-1BB costimulation
. JCI Insight
. 2018
;3
(1
):e96976
.51.
Li
G
, Boucher
JC
, Kotani
H
, et al. 4-1BB enhancement of CAR T function requires NF-κB and TRAFs
. JCI Insight
. 2018
;3
(18
):e121322
-18
.52.
Maude
SL
, Frey
N
, Shaw
PA
, et al. Chimeric antigen receptor T cells for sustained remissions in leukemia
. N Engl J Med
. 2014
;371
(16
):1507
-1517
.53.
Lee
DW
, Kochenderfer
JN
, Stetler-Stevenson
M
, et al. T cells expressing CD19 chimeric antigen receptors for acute lymphoblastic leukaemia in children and young adults: a phase 1 dose-escalation trial
. Lancet
. 2015
;385
(9967
):517
-528
.54.
James
SE
, Chen
S
, Ng
BD
, et al. Leucine zipper-based sorting system enables generation of multi-functional CAR T cells
. bioRxiv
. 2023
.55.
Morris
EC
, Neelapu
SS
, Giavridis
T
, Sadelain
M
. Cytokine release syndrome and associated neurotoxicity in cancer immunotherapy
. Nat Rev Immunol
. 2022
;22
(2
):85
-96
.56.
Brudno
JN
, Kochenderfer
JN
. J.N. K. Toxicities of chimeric antigen receptor T cells: recognition and management
. Blood
. 2016
;127
(26
):3321
-3330
.57.
Shimabukuro-Vornhagen
A
, Gödel
P
, Subklewe
M
, et al. Cytokine release syndrome
. J Immunother Cancer
. 2018
;6
(1
):56
.58.
Legut
M
, Gajic
Z
, Guarino
M
, et al. A genome-scale screen for synthetic drivers of T cell proliferation
. Nature
. 2022
;603
(7902
):728
-735
.59.
Croft
M
. The role of TNF superfamily members in T-cell function and diseases
. Nat Rev Immunol
. 2009
;9
(4
):271
-285
.60.
Dinarello
CA
. IL-18: AtH1-inducing, proinflammatory cytokine and new member of the IL-1 family
. J Allergy Clin Immunol
. 1999
;103
(1 Pt 1
):11
-24
.61.
Torigoe
K
, Ushio
S
, Okura
T
, et al. Purification and characterization of the human interleukin-18 receptor
. J Biol Chem
. 1997
;272
(41
):25737
-25742
.62.
Weinstock
JV
, Blum
A
, Metwali
A
, Elliott
D
, Arsenescu
R
. IL-18 and IL-12 signal through the NF-kappa B pathway to induce NK-1R expression on T cells
. J Immunol
. 2003
;170
(10
):5003
-5007
.63.
Choi
BK
, Lee
DY
, Lee
DG
, et al. 4-1BB signaling activates glucose and fatty acid metabolism to enhance CD8 + T cell proliferation
. Cell Mol Immunol
. 2017
;14
(9
):748
-757
.64.
Boroughs
AC
, Larson
RC
, Marjanovic
ND
, et al. A distinct transcriptional program in human CAR T cells bearing the 4-1BB signaling domain revealed by scRNA-seq
. Mol Ther
. 2020
;28
(12
):2577
-2592
.65.
Pahl
HL
. Activators and target genes of Rel/NF-κB transcription factors
. Oncogene
. 1999
;18
(49
):6853
-6866
.66.
Boston University NF-kB Transcription Factors
. NF-kB Target Genes
. Accessed 14 February 2024. https://www.bu.edu/nf-kb/gene-resources/target-genes/.67.
Hinz
M
, Lemke
P
, Anagnostopoulos
I
, et al. Nuclear factor κB–dependent gene expression profiling of hodgkin’s disease tumor cells, pathogenetic significance, and link to constitutive signal transducer and activator of transcription 5a activity
. J Exp Med
. 2002
;196
(5
):605
-617
.68.
Catz
SD
, Johnson
JL
. Transcriptional regulation of bcl-2 by nuclear factor κB and its significance in prostate cancer
. Oncogene
. 2001
;20
(50
):7342
-7351
.69.
Okamura
H
, Tsutsui
H
, Komatsu
T
, et al. Cloning of a new cytokine that induces IFN-y production by T cells
. Nature
. 1995
;378
(6552
):88
-91
.70.
Göbel
TW
, Schneider
K
, Schaerer
B
, et al. IL-18 stimulates the proliferation and IFN-γ release of CD4+ T cells in the chicken: conservation of a Th1-like system in a nonmammalian species
. J Immunol
. 2003
;171
(4
):1809
-1815
.71.
Castro
F
, Cardoso
AP
, Gonçalves
RM
, Serre
K
, Oliveira
MJ
. Interferon-gamma at the crossroads of tumor immune surveillance or evasion
. Front Immunol
. 2018
;9
:847
.72.
Smeltz
RB
. Profound enhancement of the IL-12/IL-18 pathway of IFN-gamma secretion in human CD8+ memory T cell subsets via IL-15
. J Immunol
. 2007
;178
(8
):4786
-4792
.73.
Okamoto
I
, Kohno
K
, Tanimoto
T
, Ikegami
H
, Kurimoto
M
. Development of CD8+ effector T cells is differentially regulated by IL-18 and IL-12
. J Immunol
. 1999
;162
(6
):3202
-3211
.74.
Labanieh
L
, Mackall
CL
. CAR immune cells: design principles, resistance and the next generation
. Nature
. 2023
;614
(7949
):635
-648
.75.
Eyquem
J
, Mansilla-Soto
J
, Giavridis
T
, et al. Targeting a CAR to the TRAC locus with CRISPR/Cas9 enhances tumour rejection
. Nature
. 2017
;543
(7643
):113
-117
.76.
Gomes-Silva
D
, Mukherjee
M
, Srinivasan
M
, et al. Tonic 4-1BB costimulation in chimeric antigen receptors impedes T cell survival and is vector-dependent
. Cell Rep
. 2017
;21
(1
):17
-26
.77.
Haabeth
OAW
, Hennig
K
, Fauskanger
M
, Løset
GÅ
, Bogen
B
, Tveita
A
. CD4+T-cell killing of multiple myeloma cells is mediated by resident bone marrow macrophages
. Blood Adv
. 2020
;4
(12
):2595
-2605
.78.
Fauskanger
M
, Haabeth
OAW
, Skjeldal
FM
, Bogen
B
, Tveita
AA
. Tumor killing by CD4+ T cells is mediated via induction of inducible nitric oxide synthase-dependent macrophage cytotoxicity
. Front Immunol
. 2018
;9
:1684
.79.
Balasubramani
A
, Shibata
Y
, Crawford
GE
, Baldwin
AS
, Hatton
RD
, Weaver
CT
. Modular utilization of distal cis-regulatory elements controls Ifng gene expression in T cells activated by distinct stimuli
. Immunity
. 2010
;33
(1
):35
-47
.80.
Sica
A
, Dorman
L
, Viggiano
V
, et al. Interaction of NF-κB and NFAT with the interferon-γ promoter
. J Biol Chem
. 1997
;272
(48
):30412
-30420
.81.
Murray
PJ
. Macrophage polarization
. Annu Rev Physiol
. 2017
;79
:541
-566
.82.
Tugal
D
, Liao
X
, Jain
MK
. Transcriptional control of macrophage polarization
. Arterioscler Thromb Vasc Biol
. 2013
;33
(6
):1135
-1144
.83.
Orecchioni
M
, Ghosheh
Y
, Pramod
AB
, Ley
K
. Macrophage polarization: different gene signatures in M1(Lps+) vs. classically and M2(LPS-) vs. alternatively activated macrophages
. Front Immunol
. 2019
;10
:1084
.84.
Kuznetsova
T
, Prange
KHM
, Glass
CK
, de Winther
MPJ
. Transcriptional and epigenetic regulation of macrophages in atherosclerosis
. Nat Rev Cardiol
. 2020
;17
(4
):216
-228
.85.
Ming-Chin Lee
K
, Achuthan
AA
, De Souza
DP
, et al. Type I interferon antagonism of the JMJD3-IRF4 pathway modulates macrophage activation and polarization
. Cell Rep
. 2022
;39
(3
):110719
.86.
Den Haan
JMM
, Lehar
SM
, Bevan
MJ
. CD8+ but not CD8- dendritic cells cross-prime cytotoxic T cells in vivo
. J Exp Med
. 2000
;192
(12
):1685
-1696
.87.
Møller
SH
, Wang
L
, Ho
PC
. Metabolic programming in dendritic cells tailors immune responses and homeostasis
. Cell Mol Immunol
. 2022
;19
(3
):370
-383
.88.
Helft
J
, Böttcher
J
, Chakravarty
P
, et al. GM-CSF mouse bone marrow cultures comprise a heterogeneous population of CD11c+MHCII+ macrophages and dendritic cells
. Immunity
. 2015
;42
(6
):1197
-1211
.89.
Na
YR
, Jung
D
, Gu
GJ
, Seok
SH
. GM-CSF grown bone marrow derived cells are composed of phenotypically different dendritic cells and macrophages
. Mol Cells
. 2016
;39
(10
):734
-741
.90.
Leick
MB
, Silva
H
, Scarfò
I
, et al. Non-cleavable hinge enhances avidity and expansion of CAR-T cells for acute myeloid leukemia
. Cancer Cell
. 2022
;40
(5
):494
-508.e5
.91.
Cohen
AD
, Garfall
AL
, Stadtmauer
EA
, et al. B cell maturation antigen–specific CAR T cells are clinically active in multiple myeloma
. J Clin Invest
. 2019
;129
(6
):2210
-2221
.92.
Sun
Y
, Yang
X-N
, Yang
S-S
, et al. Antigen-induced chimeric antigen receptor multimerization amplifies on-tumor cytotoxicity
. Signal Transduct Target Ther
. 2023
;8
(1
):445
.93.
Alizadeh
D
, Wong
RA
, Gholamin
S
, et al. IFNγ is critical for CAR T cell–mediated myeloid activation and induction of endogenous immunity
. Cancer Discov
. 2021
;11
(9
):2248
-2265
.94.
Hu
X
, Ivashkiv
LB
. Cross-regulation of signaling pathways by interferon-γ: implications for immune responses and autoimmune diseases
. Immunity
. 2009
;31
(4
):539
-550
.95.
Lee
H
, Ahn
S
, Maity
R
, et al. Mechanisms of antigen escape from BCMA- or GPRC5D-targeted immunotherapies in multiple myeloma
. Nat Med
. 2023
;29
(9
):2295
-2306
.96.
Mantovani
A
, Allavena
P
, Marchesi
F
, Garlanda
C
. Macrophages as tools and targets in cancer therapy
. Nat Rev Drug Discov
. 2022
;21
(11
):799
-820
.2024
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