Citation: Carrasco-Padilla, C.;

Hernaiz-Esteban, A.; Álvarez-Vallina,

L.; Aguilar-Sopeña, O.;

Roda-Navarro, P. Bispecific Antibody

Format and the Organization of

Immunological Synapses in T

Cell-Redirecting Strategies for Cancer

Immunotherapy. Pharmaceutics 2023,

15, 132. https://doi.org/10.3390/

pharmaceutics15010132

Academic Editors: Maria João

Castro Gouveia and Dayun Yan

Received: 22 November 2022

Revised: 16 December 2022

Accepted: 24 December 2022

Published: 30 December 2022

Copyright: © 2022 by the authors.

Licensee MDPI, Basel, Switzerland.

This article is an open access article

distributed under the terms and

conditions of the Creative Commons

Attribution (CC BY) license (https://

creativecommons.org/licenses/by/

4.0/).

pharmaceutics

Review

Bispecific Antibody Format and the Organization of
Immunological Synapses in T Cell-Redirecting
Strategies for Cancer Immunotherapy
Carlos Carrasco-Padilla 1 , Alicia Hernaiz-Esteban 1, Luis Álvarez-Vallina 2,3,4 , Oscar Aguilar-Sopeña 1,*
and Pedro Roda-Navarro 1,*

1 Department of Immunology, Ophthalmology and ENT, School of Medicine, Universidad Complutense de
Madrid and 12 de Octubre Health Research Institute (imas12), 28040 Madrid, Spain

2 Cancer Immunotherapy Unit (UNICA), Department of Immunology, Hospital Universitario 12 de Octubre,
28009 Madrid, Spain

3 Immuno-Oncology and Immunotherapy Group, 12 de Octubre Health Research Institute (imas12),
28009 Madrid, Spain

4 H12O-CNIO Cancer Immunotherapy Clinical Research Unit, Spanish National Cancer Research
Centre (CNIO), 28029 Madrid, Spain

* Correspondence: oaguilar@ucm.es (O.A.-S.); proda@ucm.es (P.R.-N.)

Abstract: T cell-redirecting strategies have emerged as effective cancer immunotherapy approaches.
Bispecific antibodies (bsAbs) are designed to specifically recruit T cells to the tumor microenvironment
and induce the assembly of the immunological synapse (IS) between T cells and cancer cells or antigen-
presenting cells. The way that the quality of the IS might predict the effectiveness of T cell-redirecting
strategies, including those mediated by bsAbs or by chimeric antigen receptors (CAR)-T cells, is
currently under discussion. Here we review the organization of the canonical IS assembled during
natural antigenic stimulation through the T cell receptor (TCR) and to what extent different bsAbs
induce T cell activation, canonical IS organization, and effector function. Then, we discuss how the
biochemical parameters of different formats of bsAbs affect the effectivity of generating an antigen-
induced canonical IS. Finally, the quality of the IS assembled by bsAbs and monoclonal antibodies
or CAR-T cells are compared, and strategies to improve bsAb-mediated T cell-redirecting strategies
are discussed.

Keywords: IS; T cell; immunotherapy; bsAb; CAR; TCR

1. Introduction

Bispecific antibodies (bsAbs) are molecules with binding sites for two different anti-
gens or two different epitopes on the same antigen [1]. They represent valuable im-
munotherapy tools and can be designed to redirect T cells to cancer cells, although some of
them have been also used to treat other diseases, such as hemophilia A [2] or Alzheimer’s
disease [3]. The first application of bsAbs in cancer immunotherapy was for redirecting
T cells toward tumor cells. T cell-engaging bsAbs (TCEs) are specifically engineered to
simultaneously bind to a predefined tumor-associated antigen (TAA) on the surface of can-
cer cells and to one of the extracellular CD3 subunits (usually CD3ε) of the T cell receptor
(TCR) expressed on the surface of T cells, leading to the release of preformed cytotoxic
proteins, such as perforin and granzymes, as well as cytokines [4,5]. TCEs mediate a major
histocompatibility complex (MHC)-independent T cell activation and are applicable to
all patients regardless of their MHC haplotype. Other bsAbs are designed to target co-
stimulatory molecules [6] co-inhibitory checkpoints [7,8] enhance T cell activation, or target
TAAs to block dual signaling pathways necessary for tumor growth [9,10]. Regarding
the mechanism of action of TCEs, establishing an artificial link between the TCR and a

Pharmaceutics 2023, 15, 132. https://doi.org/10.3390/pharmaceutics15010132 https://www.mdpi.com/journal/pharmaceutics

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Pharmaceutics 2023, 15, 132 2 of 14

user-defined TAA facilitates both the recruitment of T cells to the tumor microenvironment
(TME) and the establishment of the immunological synapse (IS) [11].

In hematological tumors, the administration of bsAbs has been a major step forward
in clinical practice [12]. Blinatumomab, a CD19×CD3 TCE designed for the treatment of
relapsed or refractory B cell acute lymphoblastic leukemia (B-ALL), is the most remarkable
example [13–15]. Solid tumors present additional challenges to bsAb-based therapies,
given that the TME is strongly immunosuppressive [16], and the majority of known TAAs
are also expressed at low levels on normal tissues [17], leading to severe on-target off-
tumor toxicities [18]. A further shortcoming of Fc-free bsAb-based therapies is the need
for continuous infusion due to rapid clearance from the circulation [19]. Table 1 lists
the bsAbs approved by the Food and Drug Administration (FDA) and/or the European
Medicines Administration (EMA), or in clinical trials for the treatment of hematological or
solid tumors.

Table 1. BsAbs approved by EMA/FDA and some of the bsAbs in clinical trials for the treatment
of solid and hematological tumors. Formats, specificity of Target 1 and Target 2 binding (protein
and gene name included), mechanism of action, type of cancer, and clinical phase are indicated.
Abbreviations: EpCAM (epithelial cell adhesion molecule), GP100 (glycoprotein 100), EGFR (epider-
mal growth factor receptor), c-Met (tyrosine-protein kinase Met), HER3 (member 3 of EGFR family),
HER2 (member 2 of EGFR family), LAG3 (Lymphocyte-activation gene 3), BCMA (B cell maturation
antigen), DART (dual-affinity retargeting), ImmTACs (immune-mobilizing monoclonal TCRs against
cancer), KIH (Knobs into holes), CRIB (Charge Repulsion Induced Bispecific), BiTE (bispecific T cell
engager) and TriKe (tri-specific killer engagers). Data from the phase of clinical trials are derived from
ClinicalTrials.gov and biochempeg.com (accessed on 4 November 2022) and identifiers are shown at
the bottom of the table.

BsAbs Name Format Target Protein 1
(Gene; Cell)

Target Protein 2
(Gene; Cell)

Mechanism of
Action Type of Cancer Phase

(Identifier)

Catumaxomab Triomab

CD3 (CD3E;
T cell)

EpCAM
(EPCAM; cancer

cell)

Recruitment and
activation of T

cells [20]

Malignant
ascites

Solid tumors

Approved by
EMA *

Tebentafusp ImmTAC
PMEL peptide

280–288 (PMEL;
cancer cell)

Recruitment and
activation of T

cells [21,22]

Unresectable or
metastatic uveal

melanoma

Approved by
EMA and FDA

RO6958688 CrossMab/KIH
(IgG-like bsAbs)

CEA (CEACAM5;
cancer cell)

Recruitment and
activation of T

cells [23]

CEA-positive
tumors

Phase I
(NCT02324257)

Amivantamab Duobody
EGFR (EGFR;

cancer cell)

METcMet (MET;
cancer cell)

Blocking of dual
signal pathways

[9]

Non-small cell
lung cancer

(NSCLC)

Approved by
EMA and FDA

SI-B001 IgG-(scFv)2 HER3 (ERBB3;
cancer cell)

Blocking of dual
signal pathways

[10,24]
NSCLC Phase I

(NCT04603287)

GEN1402 Duobody
CD137

(TNFRSF9;
T cell)

CD40 (CD40;
APC)

Costimulating
molecule

engaging for
efficient T cell

activating
signals [6]

NSCLC,
Colorectal

Cancer and
Melanoma

Phase II
(NCT04083599)

Zanidatamab Asymmetric HER2 (ERBB2;
cancer cell)

HER2 (ERBB2;
cancer cell)

Blocking of dual
signal pathways

[25]

Gastro-
oesophagealadeno

carcinoma

Phase II
(NCT04513665)

Erfonrilimab CRIB CTLA-4 (CTLA4;
T cell)

PD-L1 (CD274;
cancer cell)

Blocking of
immune

checkpoints [7]

NSCLC and
pancreatic ductal
adenocarcinoma

Phase II
(NCT03838848)

Tebotelimab DART PD1 (CD80;
T cell)

LAG3 (LAG3;
cancer cell)

Blocking of
immune

checkpoints [8]
Gastric Cancer Phase III

(NCT04082364)

ClinicalTrials.gov
biochempeg.com


Pharmaceutics 2023, 15, 132 3 of 14

Table 1. Cont.

BsAbs Name Format Target Protein 1
(Gene; Cell)

Target Protein 2
(Gene; Cell)

Mechanism of
Action Type of Cancer Phase

(Identifier)

Blinatumomab BiTE

CD3 (CD3E;
T cell)

CD19 (CD19;
cancer cell)

Recruitment and
activation of
T cells [26]

Acute
lymphoblastic
leukaemia B

Haematological
tumors

Approved by
EMA and FDA

Mosunetuzumab KIH
(IgG1-like bsAb)

CD20 (CD20;
cancer cell)

Recruitment and
activation of
T cells [27]

Relapsed or
refractory
follicular

lymphoma

Approved by
EMA

Glofitamab CrossMab/KIH
(IgG-like bsAbs)

Recruitment and
activation of

T cells [1,28,29]

Diffuse large
B-cell lymphoma

Phase II/III
(NCT03075696,
NCT04408638)

Teclistamab Duobody
BCMA

(TNFRSF17;
cancer cell)

Recruitment and
activation of
T cells [30]

Multiple
myeloma

Approved by
EMA

Flotetuzumab DART CD123 (IL3RA;
cancer cell)

Recruitment and
activation of
T cells [31]

Acute myeloid
leukaemia

Phase II
(NCT03739606) *

* Withdrawn.

This review initially discusses the importance of the IS in achieving physiological
immune responses and then focuses on the ability of different bsAbs to trigger T cell
activation and induce IS assembly and effector functions. Secondly, it analyzes how the
biochemical characteristics of the different bsAb formats influence the organization of
the IS and T cell responses. Then, it compares the results obtained by bsAbs with those
generated by CAR-T cells or monoclonal antibodies (mAbs). Finally, different strategies
that are expected to benefit bsAb-mediated cancer immunotherapy are discussed.

2. Immune Synapse Formation and Pathology

The IS is a specialized adhesion formed between T cells and antigen-presenting cells
(APCs) that is essential to sustain T cell activation and effector function [32]. Seminal studies
showed that cognate interactions conducted to stable mature immune synapses composed
of concentric Supramolecular Activation Clusters (SMACs) (Figure 1A). A central (c)SMAC
was shown to contain the TCR and signaling molecules, such as PKCθ [33], while a periph-
eral (p)SMAC contained the integrin LFA-1 and components of the cytoskeleton important
for the stability of the adhesion [34,35]. More recent data show that the early TCR signaling
is triggered in peripheral microclusters (MCs), which move towards the cSMAC, where
signaling is terminated [36–38]. This centripetal movement is mediated by a retrograde
flow of filamentous actin (F-actin), organized at the so-called distal (d)SMAC and by the
contractility of actomyosin arcs organized at the pSMAC [39,40]. The contraction of acto-
myosin arcs also guides integrin clusters to their correct position at the pSMAC [39]. F-actin
retrograde flow is also critical for sustaining PLCγ1 activation during early TCR activation
signaling [41]. In order to maintain the TCR downstream signaling, the phosphatase CD45
is excluded from the TCR activation sites at MCs [37].

Currently, it is well known that the cSMAC contains a region for costimulation-
generated PKC signals [42] and a region where the TCR is endocytosed [36]. To accomplish
optimal sustained activating signaling, the delivery of the TCR from the endosomal com-
partment to replace endocytosed and degraded molecules during activation is required [43].
The cSMAC is also the site for the polarization of the microtubule organizing center (MTOC).
This mediates sustained signaling [44] and the polarization of the endosomal compartment
for the secretion of cytokines [45], lytic granules [46], and exosomes [47]. From the cSMAC,
ectosomes are also released, which bud from the plasma membrane of the T cell [48]. It has
been proposed that different kinds of extracellular vesicles and ectosomes released at the IS
might assist the APC function [47,49,50].



Pharmaceutics 2023, 15, 132 4 of 14Pharmaceutics 2023, 15, x FOR PEER REVIEW 4 of 14 
 

 

 
Figure 1. Immunological synapse assembled in response to antigen or bsAbs. (A) Schematic of 
the canonical IS assembled between a T cell and an APC presenting an antigenic peptide bound to 
the major histocompatibility complex (pMHC). pMHC I and II are indicated. However, for clarity, 
it is only represented the MHC class I. The main activating molecules, cytoskeleton components, 
and secretory granules or cytokines delivered at the contact interface are depicted in the upper 
panel. The principal components of the cSMAC, pSMAC, and dSMAC are indicated in the lower 
schematic. The signaling domain located in the cSMAC contains TCR microclusters (MCs), co-stim-
ulation molecules such as CD28 and PKCθ. The secretory domain of the cSMAC secretes perforin- 
and granzyme-containing granules in the IS assembled by cytotoxic T cells and different types of 
cytokines in the IS assembled by helper T cells. (B) Schematic of the topology of the IS assembly 
induced by bsAbs between a T cell and a tumor cell. BsAbs typically engage the T cell by the CD3ε 
chain of the TCR and the tumor cell through a TAA. This leads to the establishment of antigen-
stimulated canonical IS. Upper panel shows the main elements of the IS induced by bsAbs. The 
cSMAC, pSMAC, and dSMAC compositions are represented in the lower schematic. The signaling 
domain located in the cSMAC contains TCR MCs and signaling proteins such as PKCθ. Secretory 
domain of the cSMAC secretes lytic granules containing perforin and granzyme B. 

Figure 1. Immunological synapse assembled in response to antigen or bsAbs. (A) Schematic of
the canonical IS assembled between a T cell and an APC presenting an antigenic peptide bound to
the major histocompatibility complex (pMHC). pMHC I and II are indicated. However, for clarity, it
is only represented the MHC class I. The main activating molecules, cytoskeleton components, and
secretory granules or cytokines delivered at the contact interface are depicted in the upper panel. The
principal components of the cSMAC, pSMAC, and dSMAC are indicated in the lower schematic. The
signaling domain located in the cSMAC contains TCR microclusters (MCs), co-stimulation molecules
such as CD28 and PKCθ. The secretory domain of the cSMAC secretes perforin- and granzyme-
containing granules in the IS assembled by cytotoxic T cells and different types of cytokines in the
IS assembled by helper T cells. (B) Schematic of the topology of the IS assembly induced by bsAbs
between a T cell and a tumor cell. BsAbs typically engage the T cell by the CD3ε chain of the TCR
and the tumor cell through a TAA. This leads to the establishment of antigen-stimulated canonical
IS. Upper panel shows the main elements of the IS induced by bsAbs. The cSMAC, pSMAC, and
dSMAC compositions are represented in the lower schematic. The signaling domain located in the
cSMAC contains TCR MCs and signaling proteins such as PKCθ. Secretory domain of the cSMAC
secretes lytic granules containing perforin and granzyme B.



Pharmaceutics 2023, 15, 132 5 of 14

Several of the described events in in vitro studies, most remarkably the formation of
SMACs, have been robustly corroborated in vivo during immune responses against viruses
and cancer [51–53]. Thus, it is expected that the organization of SMACs found in vitro
might predict the role that this organization has during in vivo immune responses.

Due to the fact that the IS formation is responsible for T cell activation and effector
function, the molecular dynamics at the IS are expected to have a significant impact on the
quality of T cell responses. Consistent with this idea, patients diagnosed with multiple
sclerosis and type 1 diabetes have self-reactive CD4 T cells, which have been shown to
exhibit highly phosphorylated TCR MCs with reduced accumulation at the cSMAC of
TCR-pMHC (peptide bound to the MHC) complexes [54]. Therefore, it seems that proper
molecular dynamics at the IS are needed to achieve healthy T cell responses. It is then
plausible to think that canonical IS organized in response to T cell-redirecting strategies
would be essential to obtain effective and safe anti-tumor responses [55].

3. T Cell Is Organization and Effector Function Induced by bsAb

Seminal studies showed that a TCE effectively induced the assembly of an IS with a
similar topology to the IS generated by antigen-stimulated T cells [11] (Figure 1). Offner
and collaborators employed laser scanning confocal microscopy (LSCM) to assess the IS
organization induced with a TCE specific for CD3 and the epithelial cellular adhesion
molecule (EpCAM), which is overexpressed in epithelial cancer [56]. Analysis of the IS
established between cytotoxic T cells and EpCAM-expressing cells showed that they were
highly similar to those generated under antigen-specific stimulation. The formation of
SMACs and the organization of perforin, LCK, PKCθ, CD3, LFA-1, and CD45 were nearly
identical [11]. An EpCAMxCD3 TCE has shown therapeutic efficacy in malignant ascites in
ovarian cancer patients, using intraperitoneal administration regimens [57].

The IS has been also studied in T cells redirected by a TCE targeting carcinoembryonic
antigen (CEA), which is overexpressed in a variety of solid tumors [58]. In this case, the
MTOC polarization and perforin accumulation was observed at the IS, which coexisted with
tumor cell killing, secretion of cytokines and cytotoxic granules, and T cell proliferation in
mice [23].

Another study demonstrated that a TCE specific for FcRH5, a B cell lineage-specific
surface marker in multiple myeloma [59], induced the assembly of a canonical IS [60].
The analysis by LSCM of conjugates formed by FcRH5 expressing target cells and Jurkat
(JK) CD4 T cells revealed the polarization of the FcRH5 antigen and ZAP70 to the IS and
the efficient exclusion of CD45. Interestingly, the assembly of the IS correlated with an
efficient triggering of in vitro early TCR signaling and cytotoxic function [60]. We also have
previously shown efficient activating signaling in addition to the polarization of F-actin and
CD3ε to the IS induced by an anti-epidermal growth factor receptor (EGFR) and anti-CD19
TCE. The organized IS showed a similar topology to antigen-stimulated IS and correlated
with efficient T cell activation in vitro and in vivo [61–63]. Therefore, TCE-mediated T
cell redirection seems to induce the assembly of a canonical IS, as well as effective T cell
activating signaling and function similar to events induced during antigen stimulation of
T cells.

Although TCEs have been proven to be useful, the engagement of CD137 (also known
as tumor necrosis factor receptor superfamily member 9, TNFRSF9) on T cells (instead of
CD3) and CD40 on APCs (instead of a TAA) has emerged as a new efficient immunother-
apy [64,65]. Results obtained with the CD40xCD137 bsAb duobody have clearly shown this
end [6]. This duobody was shown to render efficient polarization of LFA-1 to primary T
cell/APC interactions, higher activation, and T cell activity in comparison with monovalent
controlxCD40 and controlxCD137 bsAbs. It is expected that in this strategy, the engagement
of CD137 would raise the activation of T cell clones specific for tumor antigens presented
by APCs.

Thus, the use of bsAbs, which target CD3, or co-stimulatory molecules results in useful
approaches to activate T cell responses against cancer. It should be noted that due to the



Pharmaceutics 2023, 15, 132 6 of 14

expression of CD3+ in CD4+ and CD8+ T cells, the action of TCEs in the tumor site would
not be restricted to CD8+ T cells, and the expected activation of CD4+ T cells might also
contribute to the outcome of the immune response against the tumor. The action of TCEs in
different CD3+ T cell subtypes should be investigated.

4. Format of bsAb and Immunological Synapse Organization

The clinical efficacy of bsAbs highly depends on the pharmacokinetics (PK), which is
influenced by multiple parameters such as molecular size and avidity [66]. Intermediate-
sized multivalent bsAbs aim to achieve a compromise between size and avidity in order
to reach optimal PK and tumor targeting [16]. In this context, the use of heavy-chain-
only immunoglobulins (VHHs) [67] is instrumental to increase the valence and functional
affinity while preserving an adequate size for good tumor penetration [16]. Due to the
nascent hypothesis that the success of T cell-redirecting strategies might depend on the
quality of the IS [55] the extent to which the format of bsAbs influences the organization of
the IS should be also taken into consideration. We discuss below how different biochemical
parameters influence the assembly of the IS and the efficiency of T cell activation.

4.1. TAA-Binding

In 2017, an Fc-free TCE called ATTACK (asymmetric tandem trimerbody for T cell
activation and cancer killing) was designed with trivalent and monovalent binding to
EGFR and CD3ε, respectively (3 + 1 stoichiometry). Jurkat cells and EGFR-expressing
cells were co-cultured and the IS assembly and T cell activation were compared with a
TCE with a 1 + 1 stoichiometry with monovalent binding to EGFR and CD3ε, termed
LiTE (light T-cell engager) [68]. LSCM showed a similar polarization of CD3ε, which was
surrounded by a peripheral network of F-actin at the IS established under stimulation
with both formats. Interestingly, however, the TAA avidity effect in the ATTACK format
improved the efficiency of the polarized activating signaling to the IS, T cell activation, and
T cell cytotoxic activity [62]. It is interesting to note that the optimal ATTACK size was
not compromised by the increment of binding sites thanks to the use VHHs for the EGFR
targeting. Therefore, the avidity of the bsAb might not only assist an adequate PK but also
improves IS assembly and T cell activation.

Knowing that the avidity effect enhances activation, another interesting question was
to determine whether binding to two different TAAs might assist T cell activation. The
assembly of the IS by a trispecific T cell engager (TriTE) against EGFR, EpCAM, and CD3ε
in comparison with two bispecific EGFRxCD3ε and EpCAMxCD3ε LiTEs has been also
evaluated under the microscope by co-culturing Jurkat cells with colorectal cancer cells
expressing EGFR and EpCAM. The number of cell interactions determined by F-actin
polarization was significantly higher with the TriTE format, which also showed a higher T
cell activation [69]. Therefore, interaction with two different TAAs also seems to assist T
cell activation and IS assembly, with dual TAA-targeting also being an important feature
preventing tumor escape by antigen loss caused by selective pressures from conventional
single TAA-targeting TCEs.

4.2. bsAbs Size and Spatial Requirements

It has been suggested that large molecules cannot access the IS cleft. Different studies
have shown that dextran particles and smaller antibodies enter the IS better than larger
molecules and that a full-length mAb directed against a molecule secreted inside the IS
cannot bind to its target [70,71]. Therefore, these studies suggest that the size of a bsAb
intended to target IS-distributed molecules would be important to ensure the accessibility
to the binding site. Thus, improving the PK of bsAbs while preserving their ability to
enter activation sites at the IS would be a major challenge in this field. However, large
bsAbs have been shown to properly trigger the IS. Cremasco et al. report the mecha-
nism of action of a TCE with bivalent binding to CD20 and monovalent binding to CD3ε
(2 + 1 stoichiometry), bearing an engineered Fc domain, which retains FcRn-driven half-



Pharmaceutics 2023, 15, 132 7 of 14

life extension while reducing adverse immune induction by removal of FcGR binding by
site-specific mutations [29,72]. This TCE (glofitamab) with a molecular weight of 194 kDa
is significantly larger than other bsAbs also designed for treating hematological cancers,
such as blinatumomab (55 kDa). Despite being a large molecule, in vitro confocal imaging
showed conjugate formation between CD8+ T cells and two CD20-expressing cell lines.
Interestingly, glofitamab promoted a proper LFA-1 distribution to the established activating
interactions [29]. These data highlight how large bsAbs with long half-lives are also able to
induce IS formation and efficient target cell killing. These data suggest that, in addition
to the size, other features of the bsAbs might also influence the ability to assemble the
IS. It is likely that those TAAs, which naturally enter the IS might offer better options to
accomplish this task.

Regarding the targeted TAA, a recent study has shown that the distance of the TAA epi-
tope to the cell membrane is critical to achieving proper T cell activation, IS assembly, and
cytotoxic activity against myeloma cells. The authors used several FcRH5-specific TCEs-
recognizing epitopes located at different distances from the plasma membrane, demon-
strating that stronger T cell activation and IS assembly resulted from proximal epitope
targeting [60]. Therefore, it seems that not only the avidity or the number of targeted
TAA should be taken into account but also the spatial location of the recognized epitope.
Furthermore, probably not all the TAAs are equally suitable for triggering the assembly of
a high-quality IS.

5. bsAbs versus mAbs

To achieve an effective and controlled T cell activation, the role of co-stimulatory
and co-inhibitory immune checkpoint molecules is necessary. Immunotherapies based on
checkpoint-blocking mAbs have achieved outstanding results in oncology [73,74]. Due to
the fact that bsAbs can potentially improve the PK of mAbs [5], the comparison of the IS
assembled by these two types of antibody molecules is important. The impact of combining
two specificities for a TAA and an immune checkpoint in a single molecule has been studied
by Gu and coworkers [75]. The authors showed that a PD-1xHER-2 bsAb can assemble the
T cell IS compared to monospecific anti-HER-2 and anti-PD-1 mAbs, which did not induce
any activating cell contact with tumor cells. The observed recruitment of PD-1 to the IS
indicates a potential role in these strategies. Therefore, bsAbs combining PD-1- and TAA
recognition could be the basis for new therapeutic agents.

6. bsAbs versus CARs

Chimeric antigen receptors (CARs) represent another T cell-redirecting strategy, in
which a TAA-specific single chain scFv fused to a transmembrane and CD247 domains is
transduced in T cells, making them effective killers for the TAA-expressing tumors [76]
that can migrate to the TME to exert their cytotoxic function [77]. Consecutive improved
generations of CAR-T cells with costimulatory and cytokine inducer domains have been
developed over the past few years [78]. Although treatment with CAR-T cells has produced
remarkable clinical responses in some hematological tumors, they are not absent of adverse
effects [79]. We expect that a more natural IS organization might assist in achieving the aim
of generating safer therapies. Thus, in order to achieve more effective and secure CAR-
T cell-based therapies, an important question to be investigated might be the molecular
dynamics mediating the CAR-T cell activation and how the IS is organized when interacting
with tumor cells. Different studies have shown that during the assembly of the IS by CAR-T
cells there is an efficient MTOC polarization and lytic granule delivery [80]. However, the
actin cytoskeleton is not properly cleared from the cSMAC and signaling microclusters as
well as LFA-1 displayed a disordered distribution. These properties correlate with more
transient early signaling and unstable interactions that have posed the hypothesis of CAR-T
cells being good serial killers [81].

When comparing CAR-T cell- and TCE-based therapies, the main advantages that
CAR-T cells offer are the active cell trafficking to tumor sites and the costimulation-induced



Pharmaceutics 2023, 15, 132 8 of 14

signaling, which are not feasible properties with current TCEs [82] (pros and cons of both
approaches are indicated in Table 2). However, in contrast to TCEs, which are expected to
engage any T cell at the TME, CAR-T cells cannot induce the TAA-specific activation of
bystander tumor-infiltrating lymphocytes [82,83]. This seems to be a clear advantage of
TCEs over CAR-based strategies and, given that the efficacy and safety of T cell-redirecting
strategies might depend on the quality of the T cell activation and IS organization, the
comparison of these bsAbs- and CAR-induced processes is an important question to be
considered in future studies.

Table 2. PROS (green) and CONS (red) of TCE- and CAR-T cell-based therapies.

TCEs CAR-T Cells

• Absence of costimulatory signal • Costimulatory domain can be added in
the CAR design

• Passive and inefficient trafficking to
tumor sites

• Active and efficient trafficking to tumor
sites

• Polyclonal activation of bystander
tumor-infiltrating lymphocytes (TILs)

• Exclusive activation of CAR-expressing T
cells, which cannot induce activation of
bystander TILs

• Short serum half-life and requirement of
continuous intravenous administration

• Long-term persistence

• Cytokine release-associated toxicities • Cytokine release-associated toxicities

• IS topology similar to canonical
antigen-induced synapse

• Non-canonical IS

To conduct this comparative study properly, it is essential to use the same anti-
body clone, rendering the TCE and CAR functionally equivalent with the same speci-
ficity. We have recently performed this comparison with CD19-specific molecules, a well-
characterized target for B cell neoplasias [84]. The 3D LSCM revealed that the IS organized
in response to the CD19-specific TCE was more similar to a TCR-induced canonical IS than
the IS assembled by the functional equivalent CD19-specific CAR-T. The TCE led to a simi-
lar CD3ε and F-actin organization at the IS compared to that observed in TCR-stimulated
Jukat cells while actin clearance and CD3ε distribution in CAR-T Jurkat cells were not
properly organized [63]. Importantly, similar results were also observed when primary
cells were used [61]. Therefore, this analysis indicates a higher quality of the IS assembled
by TCEs in comparison to CAR-T cells. However, further research will be needed to assess
how different formats of TCEs and CAR-T cells might affect the mechanisms and kinetics
of killing and the organization and functional contribution of other molecular components
(such as integrins) of antigenic T cell activation.

7. Improving Therapies Based on bsAbs
7.1. Direct Secretion of bsAbs to the Tumor Site

Due to the extraordinary potency of T cell-mediated responses and the absence of
tumor-specific antigens for the majority of cancers, there are significant risks associated
with T cell responses against non-malignant tissues and/or systemic cytokine release-
associated toxicities that are major barriers to the clinical application of bsAbs. To overcome
these shortcomings, a novel T-cell redirection strategy using engineered T cells secreting
T-cell redirection bsAb (STAb-T immunotherapy) has been devised. This approach might
solve the rapid renal clearance associated with small-sized Fc-free bsAbs, enable a specific
delivery of the bsAb to the TME, and produce better-tolerated antibodies due to the
glycosylation pattern [85].



Pharmaceutics 2023, 15, 132 9 of 14

We have recently defined the topology of the IS induced by CD19xCD3 secreting STAb-
T cells, compared to CD19-CAR T cells or the exogenous addition in the culture medium
of purified CD19xCD3 blinatumomab. The IS assembly and early signaling displayed
by the STAb Jurkat cells were similar to those assembled by TCR-stimulated Jurkat cells
or purified blinatumomab [63]. In contrast, CAR-T cell signaling kinetics was shown to
be more transient and the induced IS was disorganized as explained before, even when
primary cells were used [61]. Results both in primary T cells and in vivo assays showed
how canonical IS formation could be a predictor of treatment success, since the STAb-T cells
induced more potent cytotoxicity, prevented tumor escape in vitro, and avoided leukemia
relapse in vivo. The downmodulation of CD19 has been shown to be a mechanism of
tumor escape from anti-CD19 therapies [86,87]. Interestingly, STAb-T cells did not cause
the CD19 downmodulation found when CD19-CAR cells were used [61]. Then, STAb-T
therapy might improve the PK of bsAbs, mediate the organization of a high-quality IS,
trigger proper early signaling, and leave unaltered the expression of CD19 on tumor cells.
Therefore, it is expected that the STAb-T strategy may have potential among next-generation
cancer immunotherapy strategies.

7.2. Combining Different bsAbs

A combination of bsAbs is expected to improve immunotherapy by adding stimulatory
effects that individual molecules cannot achieve. This could be useful because most TAA-
specific TCEs lack domain binding to co-stimulatory molecules. Kantarjian H. and co-
workers reported that the treatment of B cell precursor acute lymphoblastic leukemia
(B-ALL) with blinatumomab induced a longer survival compared to chemotherapy [14],
but the lack of co-stimulation leads to poor persistence of T cell responses and low rates
of tumor-free patients after six months of treatment. Interestingly, the combination of a
TAA-specific TCE providing signal 1 with a bsAb that mimics signal 2 by binding to a TAA
on tumor cells and to a CD28 receptor on T cells, has been shown to achieve an enhanced IS
formation and anti-tumor activity compared to the single use of the TAA-specific TCE [88].
This example shows how combining different bsAbs may help to overcome the problem
associated with the lack of co-stimulation during bsAb-mediated cancer immunotherapy.

8. Conclusions and Final Remarks

Both hematological and solid tumors have been shown to be potentially treatable
with bsAbs (Table 1). It is becoming increasingly clear that high-quality IS formation is a
good predictor of successful cancer cell killing [23,60–63]. Therefore, a detailed analysis of
the molecular reactions organized at the artificial IS will help to predict the efficiency and
safety of therapies based on novel bsAb or CAR formats [89]. To achieve this goal with high
spatial and temporal definition, we should take advantage of high-resolution microscopy
techniques along with the use of bsAb-coupled fluorescent proteins, which will also aid in
the observation of the bsAb delivery to the IS and fate in live cells [90]. Therefore, bsAbs
should be designed with the appropriate format, assuring a compromise between size,
avidity, targeted TAA, and epitope location, to achieve optimal PK and a high-quality IS.

In addition to the format, the direct targeting of cell-secreted bsAbs to tumor sites, as
in the STAb-T approach, might solve problems associated with the short half-life of bsAb or
its systemic toxicity. The bsAbs secreted by STAb-T cells can not only induce the assembly
of the IS in the secreting cells but also in bystander T cells. Together, these features might
generate an optimal scenario for an efficient and secure therapy.

Finally, the combination of different TAA-specific bsAbs, targeting CD3 and a co-
stimulatory molecule, should certainly improve the efficacy of immunotherapies. Research
on multispecific molecules targeting a TAA, CD3, and co-stimulatory or co-inhibitory
checkpoint receptors is an active field of research, and it will be also necessary to understand
the molecular dynamics mediating T cell activation in those approaches. We anticipate that
preclinical in vitro studies focused on IS quality will assist the design of efficient and safe
next-generation T cell redirecting strategies.



Pharmaceutics 2023, 15, 132 10 of 14

Author Contributions: All authors contributed to manuscript writing, O.A.-S. and P.R.-N. con-
tributed the conception of the review. All authors have read and agreed to the published version of
the manuscript.

Funding: O.A.-S. is hired by a fellowship from the UCM, A.H.-E. by a ‘contrato investigo’ from
‘Comunidad de Madrid’ and C.C.-P. by the grant PID2020-115444GB-I00 that supports P.R.-N., L.A.-V.
was supported by grants from the Spanish Ministry of Science and Innovation (PID2020-117323RB-100
and PDC2021-121711-100), the Carlos III Health Institute (DTS20/00089), the CRIS Cancer Foundation
(FCRIS-2021-0090), the Spanish Association Against Cancer (PROYE19084ALVA), the Fundación “La
Caixa” (HR21-00761 project IL7R_LungCan) and the Fundación de Investigación Biomédica 12 de
Octubre Programa Investiga (2022-0082).

Institutional Review Board Statement: All donors provided written information and the study
was conducted according to the guidelines of the Declaration of Helsinki, and approved by the
Institutional Research Ethics Committee of Hospital Universitario 12 de Octubre (H12O 21/436–
27/07/2021).

Informed Consent Statement: Not applicable.

Data Availability Statement: Not applicable.

Acknowledgments: We thank Ana Isabel Martín Quiroga for administrative support.

Conflicts of Interest: The authors declare no conflict of interest.

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http://doi.org/10.3390/ijms232214255
http://doi.org/10.1016/j.ab.2011.12.042

	Introduction 
	Immune Synapse Formation and Pathology 
	T Cell Is Organization and Effector Function Induced by bsAb 
	Format of bsAb and Immunological Synapse Organization 
	TAA-Binding 
	bsAbs Size and Spatial Requirements 

	bsAbs versus mAbs 
	bsAbs versus CARs 
	Improving Therapies Based on bsAbs 
	Direct Secretion of bsAbs to the Tumor Site 
	Combining Different bsAbs 

	Conclusions and Final Remarks 
	References