Antibody-based immune therapies targeting the T-cell checkpoint molecules CTLA-4 and PD-1 have affected cancer therapy. However, this immune therapy requires complex manufacturing and frequent dosing, limiting the global use of this treatment. Here, we focused on the development of a DNA-encoded monoclonal antibody (DMAb) approach for delivery of anti–CTLA-4 monoclonal antibodies in vivo. With this technology, engineered and formulated DMAb plasmids encoding IgG inserts were directly injected into muscle and delivered intracellularly by electroporation, leading to in vivo expression and secretion of the encoded IgG. DMAb expression from a single dose can continue for several months without the need for repeated administration. Delivery of an optimized DMAb encoding anti-mouse CTLA-4 IgG resulted in high serum levels of the antibody as well as tumor regression in Sa1N and CT26 tumor models. DNA-delivery of the anti-human CTLA-4 antibodies ipilimumab and tremelimumab in mice achieved potent peak levels of approximately 85 and 58 μg/mL, respectively. These DMAb exhibited prolonged expression, with maintenance of serum levels at or above 15 μg/mL for over a year. Anti-human CTLA-4 DMAbs produced in vivo bound to human CTLA-4 protein expressed on stimulated human peripheral blood mononuclear cells and induced T-cell activation in a functional assay ex vivo. In summary, direct in vivo expression of DMAb encoding checkpoint inhibitors serves as a novel tool for immunotherapy that could significantly improve availability and provide broader access to such therapies.

Significance: DNA-encoded monoclonal antibodies represent a novel technology for delivery and expression of immune checkpoint blockade antibodies, thus expanding patient access to, and possible clinical applications of, these therapies. Cancer Res; 78(22); 6363–70. ©2018 AACR.

Immune modulatory monoclonal antibodies (mAb), in particular antibodies targeting the immune checkpoint molecules CTLA-4 and PD-1, have shown unprecedented impact in the clinic for patients with multiple types of solid tumors (1). Antibodies targeting CTLA-4, ipilimumab, and tremelimumab, were the first of this class to enter clinical studies in patients with solid tumors in 2000. Ipilimumab, was the first therapy to improve both progression-free survival and overall survival in patients with melanoma, and was FDA approved for treatment of unresectable or metastatic melanoma in 2011 (1). Additional clinical trials are ongoing for both ipilimumab and tremelimumab as well as next-generation CTLA-4–blocking antibodies alone or in combination therapies for a variety of different malignancies (1).

Despite the success of these therapies in the clinic, the price tag may limit the availability of these life-saving drugs for underserved populations (2). The high price is due in part to the complexity of manufacturing mAbs, and the high doses at which they are required in patients (3). Approaches that could allow for less frequent delivery and more simple formulations might be very valuable.

The use of gene delivery technologies has been proposed for delivery of prophylactic or therapeutic mAbs for infectious disease and cancer (4–7). The major delivery methods investigated have been viral vectors, DNA plasmids and in vitro transcribed RNA. Because of a host of likely limitations, to date none of these platforms have been used to encode antibodies targeting the immune checkpoint inhibitors PD-1 or CTLA-4.

Here, we report the design and development of DNA-encoded mAbs (DMAb) expressing antibodies targeting CTLA-4 directly in vivo. We show that synthetic sequence optimized DMAbs targeting mouse CTLA-4 protein can be robustly expressed in vivo, have a reasonable and unique half-life and can drive protective antitumor immune responses in vivo. We further show that optimized DMAbs encoding ipilimumab and tremelimumab are potently expressed in vivo, bind to human regulatory T cells and activate human effector T cells. This strategy potentially provides a novel approach to immune checkpoint therapy, allowing for more novel and widely useful options for this technology in the management and treatment of cancer.

Cell culture and transfection

HEK293T cells, CT26, and Sa1N tumor cells were obtained from the ATCC, which performs thorough testing and authentication of their cell lines using morphology, karyotyping, and PCR based approaches. They were maintained in DMEM supplemented with 10% FBS. They were both routinely tested for Mycoplasma contamination, and maintained at low passage (<20 passages) in cell culture. Only Sa1N or CT26 cells at lower than passage 5 were implanted into mice. HEK293T cells were transfected with GeneJammer transfection reagent according to the manufacturer's recommendations (Agilent). Cells and conditioned media were harvested 48 hours after transfection using RIPA lysis buffer (Cell Signaling Technology) containing EDTA-free protease inhibitor (Roche) for analysis by Western blot.

DNA plasmid construction

The amino acid sequences for 9D9, ipilimumab, and tremelimumab were obtained from published patents or available DrugBank sequences (US9868961B2 for 9D9). The nucleotide sequence for the mouse IgG2b (9D9) was codon optimized for mouse to enhance mammalian expression, and the nucleotide sequences for the human IgG1 (ipilimumab) and IgG2 (tremelimumab) were optimized for both mouse and human codon biases. All sequences were also RNA optimized and included a Kozak sequence. Plasmids were cloned into the modified pVax1 plasmid with a human cytomegalovirus promoter and bovine growth hormone polyA sequence (GenScript). Both heavy and light chains were encoded in the same plasmid, separated by a furin cleavage site (RGRKRRS) and a P2A peptide to ensure cleavage. Additional sequence modifications for 9D9 were made based on sequence alignment to the mouse germline IGHV1-19*01 sequence, and are indicated in Supplementary Fig. S1.

DMAb injection and mouse tumor studies

C57Bl/6, Balb/c and A/J mice were purchased from The Jackson laboratory. DNA plasmids were formulated with 12 U of hyaluronidase enzyme (Sigma-Aldrich) in 30 μL total injection volume. Formulated DNA plasmid was injected at one site (100 μg) in the tibialis anterior (TA) muscle, or at 4 sites (100 μg per site) in both TA muscles and quadriceps muscles. Following plasmid injection, the muscles were pulsed with two 0.1 Amp electric constant current square-wave pulses using the CELLECTRA-3P device (Inovio Pharmaceuticals). For tumor challenge studies, A/J or Balb/c mice were implanted subcutaneously with 10 million Sa1N tumor cells or 500,000 CT26 tumor cells, respectively, in PBS on the right flank. As human antibodies are immunogenic in immune competent mice, we studied their expression in Balb/c mice that were depleted of CD4+ and CD8+ T cells transiently at the time of DMAb injection (using a 200 μg injection of clone GK1.5 and clone YTS 169.4, BioXCell). For tumor studies, mice were euthanized when tumors reached 1.5 cm in diameter. All mice still alive at the end of study cleared their tumors completely. All animal studies were performed in accordance with guidelines from the National Institute of Health, and were approved by the Wistar Institutional Animal Care and Use Committee.

Human patient samples

Human blood was obtained from consenting adult healthy volunteers through the Wistar Phlebotomy core under Institutional Review Board–approved protocol #21801304. Written informed consent was obtained from all patients, and studies were conducted in accordance with recognized ethical guidelines (Delaration of Helsinki). Whole blood was collected in heparinized tubes and subsequently layered on top of an equal volume of histopaque 1083 (Sigma-Aldrich).

CTLA-4 blockade luciferase assay

T-cell activation after CTLA-4 blockade was assessed using the CTLA-4 Blockade Bioassay (Promega), according to the manufacturer's instructions. Ipilimumab and tremelimumab DMAb was purified from individual mice for this assay (n = 3 mice for each DMAb), using the Nab Protein A/G Spin Kit (ThermoFisher), and was concentrated using Amicon Ultra Centrifugal Filters (Millipore Sigma). Luciferase activity was measured using the Synergy2 plate reader (Biotek).

Statistical analysis

Statistical analysis was performed using GraphPad Prism software. Error bars represent the mean ± SEM or the mean ± SD, as indicated in the figure legend. Statistical significance was determined by a Student t test for experiments containing two experimental groups and by a one-way ANOVA, followed by Tukey post-hoc HSD test for experiments with more than two groups. For tumor growth over time, multiple t tests were performed for each time point. For mouse survival analysis, significance was determined using a Gehan–Brelow–Wilcoxon test. IC50 values were calculated using a non-linear regression of serum concentration versus OD450 value; *, P < 0.05; **, P < 0.01; ***, P < 0.001; ****, P < 0.0001.

Detailed methods related to Western blot, ELISA, immunofluorescence staining, and human peripheral blood mononuclear cell (PBMC) stimulation and staining are included in the Supplementary Methods.

Design, expression and binding of mouse anti-mouse CTLA-4 DMAbs

We used the mouse anti-mouse CTLA-4 9D9 clone to encode in our optimized DNA expression system, based on its previously described antitumor activity (8, 9). The design for this DMAb plasmid was built off prior DMAb work from our group in the infectious disease space, and is described in detail in the Materials and Methods (4, 5).

Transfected HEK293T cells were able to produce and secrete 9D9 DMAb antibody in vitro, detected by ELISA and Western blot (Fig. 1A and B). However, expression of this DMAb was low (∼660 ng/mL) compared with other previously examined DMAbs (4, 5). We therefore engineered several modifications into the DMAb to improve expression, including modification of the beginning and end of the heavy-chain sequence (Supplementary Fig. S1A and S1B). Although modification of the end sequence alone (mod #2) only slightly improved antibody production in vitro, modification of the beginning sequence or both sequences significantly improved antibody production, with nearly a 10-fold improvement in antibody secretion to the media for mod #4 (Fig. 1B). These framework modifications did not alter the binding to mouse CTLA-4 protein by ELISA, with similar IC50 values compared with recombinant 9D9 (range, 36.105–44.25 ng/mL; Fig. 1C).

We next tested expression of these DMAbs in C57Bl/6 mice through delivery by IM-EP (100 μg; Fig. 1D). Similar to the in vitro results, the original 9D9 DMAb produced antibody in the serum at relatively low levels (∼1.2 μg/mL of serum; Fig. 1D). All three modified DMAbs expressed at higher levels, with the mod #4 producing levels of approximately 7.9 μg/mL, over 6-fold higher than the original DMAb sequence (Fig. 1D). These important framework modifications, therefore, greatly improved both in vitro and in vivo expression of this DMAb without altering binding to mouse CTLA-4 protein.

Antitumor activity of anti-mouse CTLA-4 DMAb in multiple tumor models

We next studied the highest expressing 9D9 DMAb (9D9 DMAb mod #4) in mouse tumor challenge models. We first used the Sa1N fibrosarcoma model, which is one of the first models used to demonstrate antitumor immunity from CTLA-4 blockade (10). We compared antitumor activity of the 9D9 DMAb to that of the recombinant 9D9 antibody (Fig. 2A). Because DMAbs take a few days to be secreted from the muscle tissue, we started DMAb delivery 4 days earlier than recombinant 9D9. We compared one injection of DNA (400 μg) with three injections of recombinant 9D9 antibody, delivered 3 days apart (10 μg per injection), and observed similar kinetics of expression (Fig. 2A; Supplementary Fig. S2A and S2B), indicating prolonged duration of expression of the DMAb. Upon challenge with Sa1N tumor cells, both the 9D9 DMAb and the recombinant 9D9 were effective at inducing tumor clearance compared with control groups (Fig. 2B; Supplementary Fig. S2C). Tumors grew in all mice initially upon implantation; however, upon DMAb delivery, 8/10 mice cleared their tumors (Fig. 2B). Upon recombinant 9D9 delivery, 9/10 mice completely cleared their tumors (Supplementary Fig. S2D). Because of the immunogenic nature of this tumor, 3/10 mice in the mouse IgG control group also cleared their tumors spontaneously (Supplementary Fig. S2D). To test for immunologic memory after DMAb exposure, we re-challenged the mice that cleared their tumors 6 months after the initial treatment (Supplementary Fig. S3). 100% of the mice that were previously treated with either recombinant 9D9 antibody or 9D9 DMAb cleared the re-implanted tumors (Supplementary Fig. S4). We also demonstrated that earlier DMAb administration (7 days before tumor implantation) was also effective at inducing tumor clearance in 6/10 mice (Supplementary Fig. S4A–S4C). In summary, anti-CTLA4 DMAbs exhibit prolonged serum antibody levels exhibiting an injection sparing effect with similar antitumor activity compared with recombinant mAb.

We next tested the impact of 9D9 DMAb on the tumor microenvironment before tumor clearance at day 10 (Supplementary Fig. S5A). At this early time point, tumors from both groups were similar sizes. The 9D9 DMAb induced higher levels of global lymphocyte infiltration (CD3+ cells) as well as specifically CD8+ T-cell infiltration, compared with isotype control mice, indicating potent immune stimulatory capacity driven by the DMAb (Supplementary Fig. S5B and S5C). In addition, the CD8+ T cells infiltrating the 9D9 DMAb-treated tumors expressed higher levels of activation markers, including CD44, CD69, and PD1 (Supplementary Fig. S5D). Importantly, tumors treated with the 9D9 DMAb had a significantly lower proportion of regulatory T cells (CD4+/CD25+/FoxP3+; Supplementary Fig. S5E).

We next tested the efficacy of this DMAb in a therapeutic setting in the CT26 tumor model. For this model, we began DMAb administration 3 days after tumor implantation (Fig. 2C). The 9D9 DMAb exhibited high expression in this mouse strain (Fig. 2C), and was effective at controlling tumor growth in this therapeutic setting, inducing tumor clearance in 8/10 mice (Fig. 2D). These results support the versatility of this DMAb platform across multiple mouse strains and tumor models.

Expression and binding of human anti-human CTLA-4 DMAbs

We next studied both in vitro and in vivo production of clinically relevant ipilimumab and tremelimumab DMAbs (ipi-DMAb and treme-DMAb; Fig. 3). Both of these DMAbs were expressed and secreted at very high levels into the media of transfected cells in vitro (∼14.3 μg/mL for ipi-DMAb and ∼5.8 μg/mL for treme-DMAb, Fig. 3A). In addition, both heavy and light chains were clearly visible in both lysate and media by Western blot (Fig. 3B).

Dosing of 400 μg of formulated DNA in the tibialis anterior and quadriceps muscles of Balb/c mice demonstrated robust expression of both DMAbs, with potent peak expression levels of approximately 85 μg/mL for ipi-DMAb and approximately 58 μg/mL for treme-DMAb (Fig. 3C). These studies were done in mice depleted of CD4 and CD8 T cells to eliminate the anti-human immune response (Supplementary Fig. S6). Both DMAbs produced mAb for prolonged periods of over one year (Fig. 3C). Importantly, the DMAb harbored in the serum of the treated animals bound robustly to human CTLA-4 by ELISA (Fig. 3D).

Functionality of human anti-human CTLA-4 DMAbs

Functionality of the ipi-DMAb and treme-DMAbs was assessed using in vitro human T-cell assays (Fig. 4). PBMCs were isolated from three healthy donors, and stimulated with PMA/ionomycin to induce CTLA-4 surface expression on regulatory T cells (Fig. 4A; ref. 11). Because CD4 surface expression is downregulated upon stimulation with PMA/ionomycin, regulatory T cells (Treg) were classified as CD3+, CD8, and CD25+ PBMCs. Similar to the positive control anti-human CTLA-4 antibody, in vivo produced ipi-DMAb and treme-DMAb efficiently stained stimulated Tregs, but not unstimulated Tregs (Fig. 4A and B).

A functional T-cell activation assay was used to test the ability of the DMAbs to induce T-cell activation in vitro. For this assay, aAPC/Raji cells were coincubated with Jurkat cells that were transduced with a construct expressing luciferase off of the IL-2 promoter (Fig. 4C). Upon efficient blockade of the CTLA-4/CD80/CD86 interaction, these Jurkat cells can be efficiently activated and express luciferase (Fig. 4C). We found that ipi-DMAb, treme-DMAb and the positive control αCTLA-4 antibody induced luciferase expression in a dose-dependent manner (Fig. 4D). As expected, the negative control antibody (9D9) did not induce luciferase expression (Fig. 4D). Interestingly, the treme-DMAb induced luciferase expression at lower concentrations compared with the ipi-DMAb, potentially indicating more potent blocking function (Fig. 4D). Together, these results demonstrate that anti–CTLA-4 antibodies produced by DNA plasmids in vivo are functional.

Here, we have described and validated a novel platform for the administration of immune checkpoint blockade antibodies through the use of DNA plasmids encoding IgG. The CELLECTRA electroporation approach described here has been widely used in clinical DNA vaccine trials, has a favorable safety and tolerability profile, and would be more rapid and cost efficient for mAb delivery compared with intravenous injection, which may broaden the applications that can be used for checkpoint antibodies (12, 13). In these pre-clinical studies, engineered DMAbs were efficient at driving in vivo expression of anti–CTLA-4 mAbs, and exhibited properties of IgG encoded CTLA-4 mAb. The DMAbs were capable of inducing potent antitumor immunity and CD8 T-cell infiltration while decreasing Treg infiltration. These results suggest that this technology could be used for novel therapeutic approaches that are currently limited for biologic mAbs, such as maintenance therapies.

Both DNA plasmid and viral delivery approaches have been used in pre-clinical models to deliver therapeutic mAbs for cancer therapy (14–16). However, these approaches thus far have focused on antibodies targeting cancer surface antigens or angiogenic factors. Although viral vectors can drive high expression, their use is limited to seronegative individuals, they can genetically mark patients, and they are difficult to re-administer due to seroconversion (7). Here, we report that the DMAb approach for immune checkpoint delivery can result in significant and prolonged in vivo expression from as little as a single dose.

Immune checkpoint blockade combination therapies are showing synergy in the clinic for certain indications (1). Although combination therapy between ipilimumab and nivolumab is highly effective in patients with melanoma, it also results in even more toxicity compared with monotherapy (17). Unfortunately, the full scope of this toxicity was difficult to predict using pre-clinical mouse or non-human primate models (18, 19). Because of this toxicity concern, next-generation versions of ipilimumab that can be selectively activated within tumors are currently being developed and tested in clinical trials (9, 20). Additional designs are being developed to enhance the effector function induced by these antibodies, including Fc mutations that enhance binding to the human FcγRIIIa as well as non-fucosylated versions with enhanced antibody-dependent cell-mediated cytotoxicity activity (9, 21). These important antibody improvements may provide expanded uses for CTLA-4–targeted antibodies in the future.

Additional areas for further development of this technology could include exploration of different isotypes to control function or expression in vivo, as well as new approaches for in vivo regulation of DMAb expression such as gene switch platforms that use small-molecule regulation as well as allosteric ribozymes (22–24). These interesting approaches could allow for self-regulation of therapy.

Using the DMAb platform, we have successfully delivered complex bi-specific antibodies, in addition to multiple different antibodies simultaneously within the same animal in the infectious disease arena (4, 5). This technology could therefore be adapted to include combination therapy with anti-PD1 DMAbs or with vaccines to open up additional therapeutic avenues. Further study of this novel approach is likely to provide valuable additions to the cancer therapy toolbox.

M.C. Wise has ownership interest (including stock, patents, etc.) in Inovio Pharmaceuticals. T. Smith has ownership interest (including stock, patents, etc.) in and has provided expert testimony for Salary. K.E. Broderick has ownership interest (including stock, patents, etc.) in Inovio. E.L. Masteller is a senior director and has ownership interest (including stock, patents, etc.) in Inovio Pharmaceuticals. J.J. Kim is an employee and has ownership interest (including stock, patents, etc.) in Inovio. L. Humeau is SVP of R&D and has ownership interest (including stock, patents, etc.) in Inovio Pharmceuticals. K. Muthumani reports receiving a commercial research grant and is a consultant/advisory board member for Inovio Pharmaceutical. D.B. Weiner is in board service at Inovio and GeneOne, is a SAB, and reports receiving a commercial research grant from Inovio, GeneOne, Janssen, and Harbor, has ownership interest (including stock, patents, etc.) in Inovio, and is a consultant/advisory board member for Inovio, GeneOne, and Medimmune. No potential conflicts of interest were disclosed by the other authors.

Conception and design: E.K. Duperret, A. Patel, J.J. Kim, K. Muthumani, D.B. Weiner

Development of methodology: E.K. Duperret, A. Trautz, A. Patel, M.C. Wise, A. Perales-Puchalt, T. Smith, K.E. Broderick, K. Muthumani

Acquisition of data (provided animals, acquired and managed patients, provided facilities, etc.): E.K. Duperret, A. Trautz, M.C. Wise, K.E. Broderick

Analysis and interpretation of data (e.g., statistical analysis, biostatistics, computational analysis): E.K. Duperret, A. Trautz, A. Perales-Puchalt, K.E. Broderick, E. Masteller, J.J. Kim

Writing, review, and/or revision of the manuscript: E.K. Duperret, M.C. Wise, A. Perales-Puchalt, K.E. Broderick, E. Masteller, L. Humeau, D.B. Weiner

Administrative, technical, or material support (i.e., reporting or organizing data, constructing databases): R. Stoltz, L. Humeau, K. Muthumani

Study supervision: L. Humeau, D.B. Weiner

This work was supported by an NIH/NCI NRSA Individual Fellowship (F32 CA213795 to E.K. Duperret), a Penn/Wistar Institute NIH SPORE (P50CA174523 to D.B. Weiner), the Wistar National Cancer Institute Cancer Center (P30 CA010815), the W.W. Smith Family Trust (to D.B. Weiner), funding from the Basser Foundation (to D.B. Weiner), and a grant from Inovio Pharmaceuticals (to D.B. Weiner).

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