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mAbs

ISSN: 1942-0862 (Print) 1942-0870 (Online) Journal homepage: www.tandfonline.com/journals/kmab20

Generation and characterization of monospecific
and bispecific hexavalent trimerbodies

Ana Blanco-Toribio, Noelia Sainz-Pastor, Ana Álvarez-Cienfuegos, Nekane
Merino, Ángel M. Cuesta, David Sánchez-Martín, Jaume Bonet, Patricia
Santos-Valle, Laura Sanz, Baldo Oliva, Francisco J. Blanco & Luis Álvarez-
Vallina

To cite this article: Ana Blanco-Toribio, Noelia Sainz-Pastor, Ana Álvarez-Cienfuegos,
Nekane Merino, Ángel M. Cuesta, David Sánchez-Martín, Jaume Bonet, Patricia Santos-Valle,
Laura Sanz, Baldo Oliva, Francisco J. Blanco & Luis Álvarez-Vallina (2013) Generation and
characterization of monospecific and bispecific hexavalent trimerbodies, mAbs, 5:1, 70-79,
DOI: 10.4161/mabs.22698

To link to this article:  https://doi.org/10.4161/mabs.22698

Copyright © 2013 Landes Bioscience

Published online: 05 Dec 2012.

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mAbs 5:1, 70–79; January/February 2013; © 2013 Landes Bioscience

 Report

70	 mAbs	 Volume 5 Issue 1

*Correspondence to: Luis Alvarez-Vallina; Email: lalvarezv.hpth@salud.madrid.org
Submitted: 10/02/12; Revised: 10/26/12; Accepted: 10/28/12
http://dx.doi.org/10.4161/mabs.22698

Introduction

Monoclonal antibodies (mAbs) are one of the fastest growing 
classes of therapeutic agents. Currently, more than 30 mAbs 
have been approved by regulatory agencies for clinical use,1 but 
conventional unmodified mAbs have limitations, such as low 
tumor-to-blood ratio, due to long serum half-life and limited tis-
sue penetration, and specificity for a single antigen epitope.2 The 
latter is a particularly important aspect because many diseases are 
multifactorial, involving multiple ligands, receptors and signaling 
cascades. Consequently, blockade of different pathological fac-
tors and pathways may result in improved therapeutic efficacy.3

To circumvent the limitations of current mAbs, substantial 
efforts have been devoted to the development of the next wave of 
antibody-based reagents for therapy, i.e., multivalent and multi-
specific molecules that block two or more relevant targets, with a 

Here, we describe a new class of multivalent and multispecific antibody-based reagents for therapy. The molecules, termed 
“trimerbodies,” use a modified version of the N-terminal trimerization region of human collagen XVIII noncollagenous 1 
domain flanked by two flexible linkers as trimerizing scaffold. By fusing single-chain variable fragments (scFv) with the 
same or different specificity to both N- and C-terminus of the trimerizing scaffold domain, we produced monospecific 
or bispecific hexavalent molecules that were efficiently secreted as soluble proteins by transfected mammalian cells. 
A bispecific anti-laminin x anti-CD3 N-/C-trimerbody was found to be trimeric in solution, very efficient at recognizing 
purified plastic-immobilized laminin and CD3 expressed at the surface of T cells, and remarkably stable in human 
serum. The bispecificity was further demonstrated in T cell activation studies. In the presence of laminin-rich substrate, 
the bispecific anti-laminin x anti-CD3 N-/C-trimerbody stimulated a high percentage of human T cells to express 
surface activation markers. These results suggest that the trimerbody platform offers promising opportunities for the 
development of the next-generation therapeutic antibodies, i.e., multivalent and bispecific molecules with a format 
optimized for the desired pharmacokinetics and adapted to the pathological context.

Generation and characterization of monospecific 
and bispecific hexavalent trimerbodies

Ana Blanco-Toribio,1,† Noelia Sainz-Pastor,2,† Ana Álvarez-Cienfuegos,1 Nekane Merino,3 Ángel M. Cuesta,2,6 David Sánchez-
Martín,2,7 Jaume Bonet,4 Patricia Santos-Valle,2 Laura Sanz,2 Baldo Oliva,4 Francisco J. Blanco3,5 and Luis Álvarez-Vallina2,*

1Leadartis S.L.; Madrid, Spain; 2Molecular Immunology Unit; Hospital Universitario Puerta de Hierro; Majadahonda, Madrid Spain; 3Structural Biology Unit, CIC bioGUNE, 
Parque Tecnológico de Bizkaia, Derio, Spain; 4Structural Bioinformatics Laboratory; Biomedical Informatics Research Unit; Parc de Recerca Biomèdica de Barcelona; Barcelona, 

Spain; 5IKERBASQUE; Basque Foundation for Science; Bilbao, Spain

6Current Address: Buchmann Institute of Molecular Life Science; Goethe University Frankfurt; Germany; 7Laboratory of Cellular Oncology; Center for Cancer Research; National 
Cancer Institute; National Institutes of Health; Bethesda, Maryland USA

†These authors contributed equally to this work.

Keywords: antibody engineering, multivalent antibodies, bispecific antibodies, collagen, trimerbody

Abbreviations: DNL, dock-and-lock method; EHS, Engelbreth-Holm-Swarm mouse tumor; Fab, fragment antigen binding; 
LM111, Laminin-111; mAb, monoclonal antibody; NC1, noncollagenous domain; scFv, single-chain Fv; SEC-MALLS, Size 

exclusion chromatography-multi-angle laser light scattering; TIE, Trimerization

format optimized for the desired pharmacokinetics and adapted 
to the pathological context.4 Conversion of monovalent antibody 
fragments (Fab, scFv, or single-domain antibody), into multiva-
lent formats increases functional affinity, decreases dissociation 
rates when bound to cell-surface receptors or polyvalent antigens, 
and enhances biodistribution.5

Monovalent antibody fragments have been engineered into 
multimeric conjugates using either chemical or genetic cross-
links. The most common strategy to create multimeric IgG-like 
formats has been the engineering of fusion proteins in which the 
antibody fragment makes a complex with homodimerization 
proteins (e.g., ZIP miniantibody,6 scFv-Fc antibody7 and mini-
body8). A different strategy to multimerize antibody fragments 
is based on the reduction of the interdomain linker length (0–5 
residues) to generate bivalent, trivalent or tetravalent antibod-
ies (referred to as diabody, triabody or tetrabody, respectively).9 
Strong protein-ligand interactions have been also used to make 



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 Report Report

antibody.15-17 Each TIE domain is composed of the N-terminal 
trimerization region of collagen XVIII NC1 (TIEXVIII) or col-
lagen XV NC1 (TIEXV) flanked by a flexible linker (Fig. 1). 
Purified N-terminal scFv-based trimerbodies (N-trimerbodyXVIII 
or N-trimerbodyXV) are trimeric in solution, and exhibit excellent 
antigen binding capacity.16,17

In this study, we created a new generation of scFv-based 
trimerbodies by fusion of the LM111-specific L36 scFv gene to the 
C-terminus of a TIEXVIII domain (C-trimerbodyXVIII), or to both 
N- and C-terminus of a TIEXVIII domain (N/C-trimerbodyXVIII) 
(Fig. 1). Recombinant L36 scFv-based N-trimerbodyXVIII (L36N), 
C-trimerbodyXVIII (CL36) and N/C-trimerbodyXVIII (L36N/CL36) 
molecules were efficiently secreted as soluble proteins by trans-
fected human HEK-293 cells, and were able to recognize their 
cognate antigen with high affinity and specificity (Fig. 2A). 
Western blot analysis demonstrated that under reducing condi-
tions L36 scFv-based trimerbodies are single chain type molecules 
with masses of 36.5 kDa (L36N), 36.7 kDa (CL36) and 63.9 kDa 
(L36N/CL36). Remarkably, the culture medium containing the 
N/C-trimerbodyXVIII displayed a higher ELISA signal than the 
one with N-trimerbodyXVIII in spite of the higher yield observed 
in the culture medium of cells secreting the N-trimerbodyXVIII 
(L36N: 21 μg/ml × 105 cells/72 h vs. L36N/CL36: 8 μg/ml × 105 
cells/72 h) (Fig. 2A and B).

To investigate whether TIE domains can drive the trimer-
ization of two different scFv, we generated a bispecific N/C-
trimerbodyXVIII by fusing the L36 scFv to the N-terminus and the 
scFv derived from the anti-CD3 OKT3 mAb to the C-terminus 
of a TIEXVIII domain (L36N/COKT3) (Fig. 1). As a control, we 
generated an OKT3 scFv C-trimerbodyXVIII (COKT3). Both 

other multimeric non-IgG-like formats. For example, the ribo-
nuclease barnase and its inhibitor barstar,10 TNFα11,12 streptav-
idin-biotin,13 and the dock-and-lock method (DNL) in which 
antibody fragments are fused to the regulatory subunit of the 
cAMP-dependent protein kinase A and the anchoring domain 
from A-kinase anchor protein.14

We recently described the in vitro and in vivo properties of 
a multivalent antibody made by fusing a trimerization (TIE) 
domain to the C-terminus of a scFv fragment. TIE domains are 
composed of the N-terminal trimerization region of collagen 
XVIII NC1 or collagen XV NC1 flanked by a flexible linker.15-17 
The new antibody format, termed “trimerbody” [(scFv-NC1)

3
; 

110 kDa] exhibited excellent antigen binding capacity and mul-
tivalency, which provided them with a significant increase in 
functional affinity and therefore enhanced binding capacity and 
slower dissociation rate.16,17

In this study, we used the trimerbody platform technology to 
create hexavalent molecules. By fusing scFv fragments to both N- 
and C-terminus of a TIEXVIII domain, monospecific or bispecific, 
hexavalent-binding trimerbodies were produced. Recombinant 
N/C-trimerbodies were efficiently secreted as soluble proteins by 
transfected human HEK-293 cells, and were able to recognize 
their cognate antigen with high affinity and specificity.

Results

Design, expression and functional characterization of scFv-
based N-terminal, C-terminal and N/C-terminal trimerbodies. 
We have previously shown that fusion of a TIE domain to the 
C-terminus of a scFv fragment confers a trimeric state to the fused 

Figure 1. Schematic diagram showing the genetic constructs used in the production of trimerbody molecules. (A) All constructs bear a TIE domain 
composed of the N-terminal trimerization region of collagen XVIII NC1 (red box) flanked by one or two flexible linkers (yellow box). The trimerbody 
gene constructs contain a heterologous signal peptide from the oncostatin M (gray box), the scFv gene (VH and VL domains joined by a flexible linker) 
and a TIEXVIII domain. Arrows indicate the direction of transcription. His6myc tag (purple box) appended was for immunodetection. (B) Schematic 
representation of the scFv-based N-, C- and N/C-terminal trimerbodies.



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72	 mAbs	 Volume 5 Issue 1

media from HEK-293 cells showed that the migration pattern 
of the secreted COKT3 and L36N/COKT3 was consistent with 
the molecular weight calculated from the polypeptide sequences 
(37.3 and 64.5 kDa, respectively). Functional analysis showed 

OKT3 scFv-based trimerbodies were secreted in functional active 
form by transfected human HEK-293 cells, but yielded signifi-
cantly lower levels than L36 scFv-based trimerbodies (Fig. 2C). 
Western blot analysis, under reducing conditions, of conditioned 

Figure 2. Characterization of recombinant trimerbodies. The presence of secreted scFv-based trimerbodies in the conditioned media from gene-
modified HEK-293 cells was demonstrated by western blot analysis (A and C). Migration distances of molecular mass markers are indicated (kDa). The 
blot was developed with anti-c-myc mAb. The functionality of secreted scFv-based trimerbodies was demonstrated by ELISA against plastic immo-
bilized LM-111 (B and D) and by FACS on CD3+ Jurkat cells and CD3- U937 cells (E). Anti-CD3 (OKT3) and anti-MHC class I (W6/32) mAbs were used as 
controls.



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www.landesbioscience.com	 mAbs	 73

of L36N/COKT3 produced a similar chro-
matogram with a larger proportion of 
aggregates eluting at the exclusion volume 
and a peak at 11.9 mL with a measured 
mass of 187 kDa at its center (Fig. 4B). 
This value is very close to the 196 kDa 
mass expected for the trimer. Both mea-
sured molar masses are, within the exper-
imental error, the same as the calculated 
values for trimeric molecules, indicating 
they are indeed trimers in solution.

The serum stability of both L36N and 
the L36N/COKT3 was studied by incu-
bating each of the purified antibodies 
in human serum at 37°C, for prolonged 
periods of time. As shown in Figure 5, the 
N-trimerbodyXVIII (L36N) and the bispe-
cific N/C-trimerbodyXVIII (L36N/COKT3) 
had similar stability, retaining more than 
50% of the initial laminin-binding activ-
ity after 96 h incubation.

Activation of human T cells. To dem-
onstrate the multivalent binding to cell 
surface receptors, we employed the mono-
specific anti-CD3 C-trimerbodyXVIII 
(COKT3) and the bispecific anti-LM111 
× anti-CD3 N/C-trimerbodyXVIII (L36N/

COKT3). The poor ability of monovalent 
(Fab and scFv) anti-CD3 antibodies to 
stimulate T cells compared with bivalent 
antibodies has long suggested ligand-

induced oligomerization as a necessary component of the activa-
tion mechanism.18-20 As shown in Figure 6A, Jurkat cells cultured 
with soluble anti-CD3 mAb OKT3 expressed the activation 
marker CD69, whereas Jurkat cells incubated in the presence of 
an isotype control mAb did not express CD69. Jurkat cells cul-
tured with conditioned media from HEK-293 cells transfected 
with expression vectors encoding different scFv-based trimer-
bodies (COKT3 or L36N/COKT3), or in the presence of puri-
fied L36N/COKT3 trimerbody, upregulated CD69, in a manner 
similar to the OKT3 mAb. By contrast, Jurkat cells cultured with 
conditioned media from HEK-293 cells transfected with expres-
sion vectors encoding scFv L36-based trimerbodies (L36N, CL36 
or L36N/CL36) did not express CD69 (Fig. 6A).

To further demonstrate the bispecificity and multivalency 
of the anti-LM111 × anti-CD3 N/C-trimerbodyXVIII, we per-
formed T cell activation studies in the presence of plastic immo-
bilized BSA (iBSA) or LM111 (iLM111). Purified L36N/COKT3 
was added to BSA- or LM111-coated wells and, after washing, 
the LM111-bound trimerbodies were able to activate Jurkat T 
cells more effectively than immobilized OKT3 mAb (Fig. 6B). 
Purified L36N trimerbody was shown to bind to laminin, but the 
bound trimerbody did not activate human T cells. Similar results 
were found with conditioned media from HEK-293 cells trans-
fected with expression vectors encoding other scFv-based trimer-
bodies (Fig. 6B).

that the bispecific L36N/COKT3 trimerbody bound specifically 
to both immobilized LM111 [as determined by ELISA (Fig. 
2D)], and native CD3 complex expressed on the T cell surface [as 
determined by flow cytometry (Fig. 2E)]. In contrast, the OKT3 
scFv-based C-trimerbodyXVIII bound to the surface of CD3+ cells, 
but did not interact with LM111 (Fig. 2D and E).

Structural characterization of bispecific scFv-based N/C-
terminal trimerbodies. The N-trimerbodyXVIII (L36N) and the 
bispecific N/C-trimerbodyXVIII (L36N/COKT3) were purified 
from conditioned medium by immobilized metal affinity chro-
matography, which yielded proteins that were > 95% pure by 
reducing SDS-PAGE (Fig. 3A). The functionality of the purified 
trimerbodies was demonstrated by ELISA and flow cytometry. 
Figure 3B shows that the dose-dependent binding curves of L36N 
and L36N/COKT3 to plastic immobilized LM111 were compa-
rable. Furthermore, bispecific L36N/COKT3 trimerbody recog-
nized cell surface CD3 as efficiently as the native mAb OKT3 
(mouse IgG

2a
) (Fig. 3C).

The trimeric nature of the molecules was confirmed by SEC-
MALLS measurements. The sample of L36N eluted from the size 
exclusion column as a major symmetric peak at 12.8 mL with a 
small portion of high molecular weight aggregates eluting at the 
exclusion volume of the column. The mass calculated from the 
dispersed light at the center of the peak is 103 kDa, close to the 
expected mass of 112 kDa for the trimer (Fig. 4A). The sample 

Figure 3. Functional characterization of purified trimerbodies. Reducing SDS-PAGE of purified N-
trimerbodyXVIII (L36N) and N/C-trimerbodyXVIII (L36N/COKT3) (A), antigen titration ELISA against plastic 
immobilized LM-111 (B) and FACS on CD3+ Jurkat cells (C).



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74	 mAbs	 Volume 5 Issue 1

Discussion

In this study, we used the trimerbody platform technology for the 
production of hexavalent scFv-based molecules. We fused scFv 
antibody fragments with the same or different specificity to both 
ends of a TIEXVIII domain to produce monospecific or bispecific 
hexavalent-binding trimerbodies. The monospecific anti-LM111 
N-/C-trimerbodyXVIII (L36N/CL36) was generated by fusing the 
scFv L36 to the N- and C-terminus of a TIEXVIII domain. The 
bispecific anti-LM111 × anti-CD3 N-/C-trimerbodyXVIII (L36N/

COKT3) was similarly generated by fusing the scFv OKT3 onto 
the C-terminus of a TIEXVIII domain. All the trimerbodies were 
expressed in functional active form from conditioned medium 
of transfected HEK293 cells. Variations in expression level were 
correlated with the scFv clone, rather than with the trimerbody 
format. Both L36N and L36N/COKT3 molecules were easily puri-
fied using standard chromatographic methods.

The purified trimerbodies were trimeric molecules in solution, 
as unambiguously shown by the light scattering measurements. 
The elution volumes from the gel filtration column, however, 
were smaller than those calculated for globular proteins of the 
same size, according to the calibration of the column with a set 
of molecular weight markers. This observation is diagnostic of a 
non-spherical shape of the trimerbodies, which causes them to 
advance through the column faster than globular molecules of 
the same size. This behavior is consistent with the design of the 
trimerbodies and the molecular modeling (Figs. 7 and 8). A sim-
ilar observation was recently reported for the elongated coiled-
coil domain of laminin.21

Monospecific and bispecific hexavalent trimerbodies were 
very efficient at recognizing antigen either immobilized in plas-
tic, or associated to the cell surface. The dose-dependent binding 
curves of the monospecific anti-LM111 N-trimerbodyXVIII and 
the bispecific anti-LM111 × anti-CD3 N-/C-trimerbodyXVIII to 
plastic immobilized LM111 were comparable. Furthermore, the 
bispecific L36N/COKT3 trimerbody recognized surface CD3 as 
efficiently as the native mAb OKT3. The bispecificity of L36N/

COKT3 trimerbody was further demonstrated on T cell activa-
tion assays. This molecule was very efficient and specific at induc-
ing CD69 expression by human T cells when pre-incubated on 
plastic-bound LM111, but not on plastic-bound BSA. In this 
work, we used an extracellular matrix protein (laminin) and a 
cell surface receptor (CD3) as model antigens to demonstrate 
the potential and versatility of trimerbody molecules. Although 
activation of T cells by antibody-mediated CD3 crosslinking pro-
vides us with relevant information regarding trimerbody multiv-
alency, it is obvious that multivalent anti-CD3 trimerbodies, at 
least in its current configuration, cannot be systemically admin-
istered due to the risk of unspecific T cell activation.

Although another group has also shown that collagen-derived 
sequences [in this case a short collagen-like peptide scaffold (Gly-
Pro-Pro)

10
] can promote trimerization of fused scFv antibody 

fragments,22 we demonstrated here, for the first time, the genera-
tion of functional bispecific and multivalent scFv-based antibod-
ies that contain modified versions of the trimerization region of 
human collagen XVIII.

Figure 4. Structural characterization of purified trimerbodies. Oligo-
meric analysis of the L36N (A) and L36N/COKT3 (B) trimerbodies. Size 
exclusion chromatogram profile, as measured by UV absorbance at 280 
nm (blue trace) and molar mass (red trace), as measured by MALLS (only 
the data at the central part of the peak is shown, and can be read at the 
right hand axis, in red color). The mass measured at the center of the 
peak is indicated.

Figure 5. Serum stability of purified of L36N and L36N/COKT3 trimerbod-
ies. ELISA against plastic immobilized LM-111 was performed after incu-
bation 37°C for different time periods in human serum, as explained in 
material and methods.



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www.landesbioscience.com	 mAbs	 75

poor stability or complex engineering.4 The trimerbody plat-
form has important advantages over conventional strategies, e.g., 
potentially no immunogenicity, strong association, high expres-
sion level and solubility. Furthermore, hexavalent monospecific 
or bispecific trimerbodies are easy to engineer due to the small 
size of TIE domains.

The trimerbody platform offers therefore promising opportu-
nities for the development of the next-generation of dual target-
ing agents. Bispecific antibodies are one of the most promising 
and exciting areas of protein engineering, and the range of their 
therapeutic uses have expanded beyond oncology to inflamma-
tory, autoimmune and infectious diseases.3 Bispecific antibodies 
suitable for therapeutic use can be produced by somatic hybrid-
ization, chemical conjugation and genetic engineering.23 Many 
recombinant bispecific antibodies are symmetric or asymmetric 
IgG-like molecules (bivalent, trivalent or tetravalent) produced 
by the dimeric assembly of two identical heavy chains.17 These 
antibody formats are full-length IgG in which constant domains 
represent more than 70% of the protein content. A different 
approach for the generation of recombinant bispecific antibod-
ies is the DNL method that allows the generation of trivalent 
or hexavalent molecules in which the constant domains also 

Since flexibility between antigen binding sites is an important 
aspect in the design of multivalent antibodies, all the generated 
trimerbodies have 21 residue flexible linkers allowing diverse 
binding geometries. Analysis of the trivalent scFv-based N- or 
C-trimerbody models suggests a tripod-shaped structure with the 
scFv domains outwardly oriented (Fig. 7). Hexavalent scFv-based 
trimerbodies are hourglass-shaped molecules (Fig. 8). The 21 res-
idues linker provides a maximum area of influence for each side 
of the hexavalent trimerbodies around 80 Å of radius. This area 
of access is slightly higher in the C-terminal side of the hexava-
lent trimerbodies due to the final orientation of the trimerization 
region of collagen XVIII NC1, whose last β-strand is oriented 
almost perpendicular to the plane of trimerization, contrary to 
the N-terminal side of the trimerization domain, whose final ori-
entation is practically parallel to the plane of trimerization. The 
trimerbody platform technology has a high degree of structural 
plasticity and would allow, by adjustment of the linker length, 
the design of more compact and rigid molecules to meet specific 
requirements.

Although numerous strategies have been used to generate 
multivalent antibodies, a number of them have drawbacks due 
to their immunogenicity, associated unwanted functional effects, 

Figure 6. Human T cell activation studies. (A) FACS analysis of CD69 expression by Jurkat cells stimulated either with soluble anti-CD3 (OKT3) or anti-
MHC class I (W6/32) mAb, with conditioned media from HEK-293 cells (293-CM) transfected with expression vectors encoding scFv-based trimerbodies 
(L36N, L36N/CL36, COKT3 or L36N/COKT3), or with purified trimerbodies (L36N or L36N/COKT3). (B) FACS analysis of CD69 expression by Jurkat cells stimu-
lated either with plastic immobilized mAb (imAb), BSA (iBSA) or LM-111 (iLM-111) in the presence of 293-CM from L36N, L36N/CL36, COKT3 or L36N/COKT3 
transfected cells or purified L36N or L36N/COKT3 trimerbodies.



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76	 mAbs	 Volume 5 Issue 1

anti-mouse IgG, Fc specific, (Sigma-Aldrich), and IRDye800 
conjugated donkey anti-mouse IgG (H&L) (Rockland 
Immunochemicals). Laminin-111 (LM111) extracted from 
the Engelbreth-Holm-Swarm (EHS) mouse tumor was from 
Invitrogen Life Technologies. Bovine serum albumin (BSA) was 
from Sigma-Aldrich.

Cells and culture conditions. HEK-293 (CRL-1573) cells 
were cultured in Dulbecco’s modified Eagle’s medium (DMEM) 
(Lonza) supplemented with 10% (vol/vol) heat inactivated Fetal 
Calf Serum (FCS) (Invitrogen Life Technologies), unless other-
wise stated. Jurkat clone E6–1 (TIB-152) cells were maintained 
in RPMI-1640 (Lonza) supplemented with heat-inactivated 10% 
FCS. All of these cell lines were obtained from the American 
Type Culture Collection.

Construction of expression vectors. To construct the 
pCR3.1-L36-hNC1

XVIII
 expression vector, the N-terminal 

trimerization region from human collagen XVIII NC1 domain 
(hNC1

XVIII
) was synthesized by GeneArt AG, and subcloned 

as NotI/XbaI into the vector pCR3.1-L36,24 containing the 
L36 (anti-LM111) single-chain Fv (scFv) gene.25 To generate a 
scFv-based C-terminal trimerbody molecule (C-trimerbody) a 

represent a large proportion of the protein content.14 In contrast, 
the trimerbody platform allows the generation of symmetric 
hexavalent bispecific molecules with less than 20% of the protein 
content serving a structural function.

Hexavalent trimerbodies may have applications as effective 
trapping agents, or for the simultaneous neutralization of differ-
ent angiogenic factors or disease-modulating cytokines. Other 
applications include the dual targeting of two receptors for cancer 
therapy and the development of improved agonistic reagents for 
immunotherapy. Further interests are the development of fusion 
proteins for the targeted delivery of a therapeutically active moi-
ety, e.g., angiogenic inhibitors, cytokines, toxins, enzymes.

Material and Methods

Reagents and antibodies. The mAbs used included 9E10 
(Abcam), anti-c-myc tag, Tetra-His (Qiagen, GmbH) specific for 
His-tagged proteins, OKT3 (Janssen-Cilag Pty Limited) anti-
human CD3ε and phycoerythrin (PE)-conjugated anti-human 
CD69 mAb (clone FN50, BD Biosciences). The polyclonal anti-
bodies included: horseradish peroxidase (HRP)-conjugated goat 

Figure 7. Modeling of scFv-based trivalent trimerbodies. (A) Superior (left) and lateral (right) views of the anti-LM111 N-terminal trimerbodyXVIII model. 
(B) Superior (left) and lateral (right) views of the anti-CD3 C-terminal trimerbodyXVIII model. The anti-LM111 scFv is colored in green while the anti-CD3 
scFv is colored in blue. In both cases, the N-terminal trimerization region from human collagen XVIII NC1 domain is colored in red. The image shows 
the different disposition of the linkers according to the terminal side of the trimerization domain. The starting point of the linkers in the N-terminal 
trimerbodyXVIII model appears completely over the trimerization domain, while in the C-terminal trimerbodyXVIII model, due to the disposition of the 
last β-strand, the linkers appears to be orientated perpendicular to the trimerization domain.



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Expression and purification of recombinant antibod-
ies. Stable cell lines were generated in HEK 293 cells, and the 
proteins purified from conditioned medium. HEK-293 cells 
were transfected with the appropriate expression vectors using 
calcium phosphate,27 and selected in DMEM with 0.5 mg/ml 
G-418 (Sigma-Aldrich). Supernatants from transiently and sta-
bly transfected cell populations were analyzed for protein expres-
sion by ELISA, SDS-PAGE and western blotting using anti-myc 
mAb and IRDye800 conjugated donkey anti-mouse IgG. Stably 
transfected cell lines were used to collect serum-free conditioned 
medium that was dialyzed against PBS (pH 7.4) and loaded onto 
a HisTrap HP 1 ml column using and ÄKTA Prime plus system 
(GE Healthcare). The purified proteins were dialyzed against 
PBS and stored at -80°C.

Size exclusion chromatography-multi-angle laser light scat-
tering (SEC-MALLS). Static light scattering experiments were 
performed at room temperature using a Superdex 200 Size 
Exclusion Chromatography column (GE HealthCare) attached 

DNA fragment–coding for the hNC1
XVIII

, a flexible linker and 
the V

H
 chain of the L36 scFv–was synthesized by GeneArt AG, 

and subcloned as ClaI/XhoI into the vector pCR3.1-L36,24 to 
obtain the pCR3.1-hNC1

XVIII
-L36 expression vector. To gener-

ate an anti-CD3 scFv-based C-trimerbody, a DNA fragment 
coding for a flexible linker and the OKT3 scFv26 was synthe-
sized by GeneArt AG, and subcloned as BamHI/XbaI into the 
vector pCR3.1-hNC1

XVIII
-L36, resulting in pCR3.1-hNC1

XVIII
-

OKT3. To generate a monospecific (anti-LM111) scFv-based 
N/C-terminal trimerbody the BamHI/XbaI fragment from 
plasmid pCR3.1-hNC1

XVIII
-L36 was ligated into the BamHI/

XbaI digested backbone of plasmid pCR3.1-L36-hNC1
XVIII

, to 
obtain the plasmid pCR3.1-L36-hNC1

XVIII
-L36. To generate a 

bispecific (anti-LM111 x anti-CD3ε) scFv-based N/C-terminal 
trimerbody the BamHI/XbaI fragment from plasmid pCR3.1-
hNC1 

XVIII
-OKT3 was ligated into the BamHI/XbaI digested 

backbone of plasmid pCR3.1-L36-hNC1
XVIII

, to obtain the plas-
mid pCR3.1-L36-hNC 

XVIII
-OKT3.

Figure 8. Modeling of monospecific (A) and bispecific (B) scFv-based hexavalent trimerbodies. (A) Superior (left) and lateral (right) views of a mono-
specific anti-LM111 N/C-terminal trimerbodyXVIII model. (B) Superior (left) and lateral (right) views of a bispecific anti-LM111 x anti-CD3 N/C-terminal 
trimerbodyXVIII model. The anti-LM111 scFv domain is colored green while the anti-CD3 scFv is colored in blue. In all cases, the trimerization region of 
human collagen XVIII NC1 is colored in red. The different configuration between both models shows the putative maximum and minimum aperture 
that the flexible linkers can achieve. In the monospecific model (A) the aperture of the linker is fixed so that no clashes appear between the initial part 
of the linker and the trimerization domain. The bispecific model (B) is closed up to the point in which no clashes appear between the scFv domains. In 
all cases, the linker stability is not affected by the change of orientation.



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78	 mAbs	 Volume 5 Issue 1

frozen immediately to represent a zero time point. Aliquots were 
then subjected to ELISA to test their capability to bind LM111.

Molecular modeling. Each monomer of the trivalent 
N-trimerbody contains one L36 scFv domain. The scFv domains 
were built by homology modeling29 using the structure of 
2GHW.B30 from the PDB database31 as template. The alignment 
between the template and the sequence of L36 using blast32 had 
an e-value of 2e-79 and 70% sequence identity. Each monomer 
of the trivalent C-trimerbody contains one OKT3 scFv domain. 
The OKT3 scFv domain was built using as template 1QOK.A,33 
with e-value of 3e-81 and 75% of sequence identity. Both mono-
mer types contain the N-terminal trimerization region from 
human collagen XVIII NC1 domain (hNC1

XVIII
). The structure 

of the trimer of hNC1
XVIII

 domains is stored in the PDB with 
code 3HSH.34 This structure was used to guide the trimerization 
of the modeled monomers by means of structural superimposi-
tion of the NC1 domains with STAMP,35 forming the hexavalent 
N/C-trimerbody. Each monomer of the hexavalent monospecific 
N/C-trimerbody contains two identical instances of the L36 
scFv antibody fragment, while the monomers of the hexavalent 
bispecific N/C-trimerbody contain one L36 scFv and one OKT3 
scFv.

Disclosure of Potential Conflicts of Interest

No potential conflicts of interest were disclosed.

Acknowledgments

This study was supported by grants from Ministerio de Ciencia 
e Innovación (BIO2008–03233), Ministerio de Economía y 
Competitividad (BIO2011–22738), and Comunidad de Madrid 
(S-BIO-0236–2006 and S2010/BMD-2312) to L.A-V.; from 
Fondo de Investigación Sanitaria/Instituto de Salud Carlos III 
(PI08/90856 and PS09/00227) to L.S.; Ministerio de Ciencia e 
Innovación (BIO2008–00205) to B.O., and CTQ2011–28680 
to F.J.B. A.B-T. and A.A-C. were supported by Programa Torres 
Quevedo from Ministerio de Economía y Competitividad, co-
founded by the European Social Fund (PTQ-09–01–01089 
and PTQ11–04604, respectively). P.S-V. was supported by a 
Fundación de Investigación Biomédica-Hospital Universitario 
Puerta de Hierro training grant. The authors declare no conflict 
of interest related to this work.

in-line to a DAWN-HELEOS light scattering detector (Wyatt 
Technology Corporation). This column had been previously 
calibrated with the Gel Filtration Molecular Weight Standards 
(Bio-Rad Laboratories Ltd.). The column was equilibrated with 
running buffer (PBS + 0.03% NaN

3
, 0.1 μm filtered) and the 

SEC-MALLS system was calibrated with a sample of BSA; at 
1 g/L. Then 100 μL samples of the different antibodies at 0.1 
mg/mL in PBS were injected into the column at a flow rate of 
0.5 mL/min. Data acquisition and analysis were performed using 
ASTRA software (v 5.3.4.19, Wyatt). Based on numerous mea-
surements on BSA samples at 1 g/L under the same or similar 
conditions we estimate that the experimental error in the molar 
mass is around 5%.

ELISA. The ability of N-, C- and N/C-trimerbodies to bind 
LM111 was studied by ELISA as described.16 Briefly, Maxisorp 
(NUNC Brand Products) plates were coated with LM111 (0.5 
μg/well) and after washing and blocking with 200 μl 5% BSA in 
PBS, 100 μl with indicated amount of purified protein or super-
natant from transiently or stably transfected HEK-293 cells were 
added for 1 h at room temperature. After three washes, 100 μl 
of anti-myc mAb (10 μg/ml) were added for 1 h at room tem-
perature. After three washes, 100 μl of HRP-conjugated goat 
anti-mouse IgG were added for 1 h at room temperature, after 
which the plate was washed and developed. Antigen titration was 
performed with serial dilutions of the purified trimerbodies.

Western blotting. Supernatant were separated by reducing 
SDS-PAGE in 12% Tris-Glycine gels (Bio-Rad Laboratories 
Ltd.) and transferred using iBlot system (Invitrogen Life 
Technologies). After blocking with LI-COR blocking solution 
(LI-COR), proteins were detected with anti-myc mAb and an 
IRDye800 conjugated donkey anti-mouse IgG. Images were 
taken using an Odyssey Infrared Imaging system (LI-COR).

Flow cytometry. The ability of N-, C- and N/C-trimerbodies 
to bind to cell surface antigens (CD3ε) was studied by FACS as 
described previously.16,28 Briefly, cells were incubated with super-
natants or purified trimerbody molecules (10 μg/ml) for 30 min. 
After washing, the cells were incubated with mAb Tetra-His in 
100 μl for 30 min. After washing, the cells were treated with 
appropriate dilutions of PE-conjugated goat anti-mouse IgG. 
The samples were analyzed with a Beckman-Coulter FC-500 
Analyzer (Beckman-Coulter).

T cell activation assays. To study the ability of N-, C- and 
N/C-trimerbodies to activate specifically human T cell in solu-
tion, Jurkat cells (105) were incubated overnight with superna-
tants or purified trimerbody molecules (2 μg/ml). For activation 
in solid phase, supernatants or purified trimerbody molecules (5 
μg/ml) were incubated with plastic immobilized LM111 (1 μg/
well) in round-bottom 96-well plates (BD Biosciences) for 30 
min at 4°C. After washing and blocking, 105 Jurkat cells were 
added and cultured overnight. After 16 h cells were collected and 
the surface expression of CD69 examined by flow cytometry.

Serum stability. One microgram of each purified trimerbody 
was incubated in 60% human serum at 37°C for up to 96 h. 
Samples were removed for analysis at 3 h, 24 h and 96 h following 
the start of incubation and frozen until the entire study was com-
pleted. As a control, a second set of serum-exposed samples was 



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