Tripokin: A multi-specific immunocytokine for cancer immunotherapy.

Antibodies that target the tumor microenvironment can be used to deliver pro-inflammatory payloads, such as cytokines. Cytokines are small proteins able to modulate the activity of the immune system, and antibody-cytokine fusion proteins have been tested in preclinical and clinical settings. In this study, we describe Tripokin, a novel multi-specific fusion protein that combines interleukin-2 and a single amino acid mutant of tumor necrosis factor. The two pro-inflammatory payloads were fused to the L19 antibody, a clinical-grade antibody against the extradomain B of fibronectin. The human payloads were used for clinical applications, while the corresponding murine cytokines were used for preclinical studies. The resulting fusion proteins were produced in mammalian cells and purified to homogeneity. The murine Tripokin product was well tolerated in tumor-bearing mice at three doses of 30 µg in a 2-day interval and promoted rapid tumor eradication in murine models, more efficiently than single-agent immunocytokines. Tripokin induced rapid tumor necrosis and stimulated a robust immune response, impacting innate and adaptive immune pathways. In addition, the combination with immune checkpoint inhibitors further boosted the therapeutic efficacy of our molecule. Tripokin represents a promising clinical candidate for the simultaneous delivery of interleukin-2 and tumor necrosis factor to neoplastic sites.

A Comparative Analysis of Fibroblast Activation Protein-Targeted Small Molecule-Drug, Antibody-Drug, and Peptide-Drug Conjugates.

We present the first in vivo comparative evaluation of chemically defined antibody-drug conjugates (ADCs), small molecule-drug conjugates (SMDCs), and peptide-drug conjugates (PDCs) targeting and activated by fibroblast activation protein (FAP) in solid tumors. Both the SMDC (OncoFAP-Gly-Pro-MMAE) and the ADC (7NP2-Gly-Pro-MMAE) candidates delivered high amounts of active payload (i.e., MMAE) selectively at the tumor site, thus producing a potent antitumor activity in a preclinical cancer model.

Cross-reactivity to glutamate carboxypeptidase III causes undesired salivary gland and kidney uptake of PSMA-targeted small-molecule radionuclide therapeutics.

PURPOSE: Recently, Pluvicto™ ([177Lu]Lu-PSMA-617), a small-molecule prostate-specific membrane antigen (PSMA) radioligand therapeutic, has been approved by the FDA in metastatic castration-resistant prostate cancer. Pluvicto™ and other PSMA-targeting radioligand therapeutics (RLTs) have shown side effects due to accumulation in certain healthy tissues, such as salivary glands and kidney. Until now, the molecular mechanism underlying the undesired accumulation of PSMA-targeting RLTs had not been elucidated. METHODS: We compared the sequence of PSMA with the entire human proteome to identify proteins closely related to the target. We have identified glutamate carboxypeptidase III (GCPIII), N-acetylated alpha-linked acidic dipeptidase like 1 (NAALADL-1), and transferrin receptor 1 (TfR1) as extracellular targets with the highest similarity to PSMA. The affinity of compound 1 for PSMA, GCPIII, NAALADL-1, and TfR1 was measured by fluorescence polarization. The expression of the putative anti-target GCPIII was assessed by immunofluorescence on human salivary glands and kidney, using commercially available antibodies. RESULTS: A fluorescent derivative of Pluvicto™ (compound 1) bound tightly to PSMA and to GCPIII in fluorescence polarization experiments, while no interaction was observed with NAALADL-1 and TfR1. Immunofluorescence analysis revealed abundant expression of GCPIII both in healthy human kidney and salivary glands. CONCLUSION: We conclude that the membranous expression of GCPIII in kidney and salivary gland may be the underlying cause for unwanted accumulation of Pluvicto™ and other Glu-ureido PSMA radio pharmaceuticals in patients.

Tumor-Homing Antibody-Cytokine Fusions for Cancer Therapy.

Recombinant cytokine products have emerged as a promising avenue in cancer therapy due to their capacity to modulate and enhance the immune response against tumors. However, their clinical application is significantly hindered by systemic toxicities already at low doses, thus preventing escalation to therapeutically active regimens. One promising approach to overcoming these limitations is using antibody-cytokine fusion proteins (also called immunocytokines). These biopharmaceuticals leverage the targeting specificity of antibodies to deliver cytokines directly to the tumor microenvironment, thereby reducing systemic exposure and enhancing the therapeutic index. This review comprehensively examines the development and potential of antibody-cytokine fusion proteins in cancer therapy. It explores the molecular characteristics that influence the performance of these fusion proteins, and it highlights key findings from preclinical and clinical studies, illustrating the potential of immunocytokines to improve treatment outcomes in cancer patients. Recent advancements in the field, such as novel engineering strategies and combination strategies to enhance the efficacy and safety of immunocytokines, are also discussed. These innovations offer new opportunities to optimize this class of biotherapeutics, making them a more viable and effective option for cancer treatment. As the field continues to evolve, understanding the critical factors that influence the performance of immunocytokines will be essential for successfully translating these therapies into clinical practice.

Molecular Evolution of Multivalent OncoFAP Derivatives with Enhanced Tumor Uptake and Prolonged Tumor Retention.

Fibroblast activation protein (FAP) is a protein biomarker widely expressed in most solid human malignancies of epithelial origin. In recent years, a number of FAP-targeted small organic radioligands, including OncoFAP, have been utilized in the clinic for the detection and diagnosis of cancer. Despite their selective accumulation, conventional FAP ligands present a relatively short half-life in tumors, corresponding to a few hours after systemic administration. In order to maximize their efficacy, FAP-targeted radioligand therapeutics must possess prolonged tumor retention, thus irradiating tumor cells for days. In this work, we describe the development of compact OncoFAP multimers with improved FAP affinity (low picomolar IC50s), aimed at increasing tumor-residence time for therapeutic applications. An in silico analysis of the interaction of the multimers with FAP revealed a wide and deep pocket and six additional secondary binding sites. TriOncoFAP-DOTAGA emerged for its favorable in vitro profile and superior in vivo biodistribution performance in tumor-bearing mice.

An IL-7 fusion protein targeting EDA fibronectin upregulates TCF1 on CD8+ T-cells, preferentially accumulates to neoplastic lesions, and boosts PD-1 blockade.

BACKGROUND: Anti-PD-1 antibodies have revolutionized cancer immunotherapy due to their ability to induce long-lasting complete remissions in a proportion of patients. Current research efforts are attempting to identify biomarkers and suitable combination partners to predict or further improve the activity of immune checkpoint inhibitors. Antibody-cytokine fusions are a class of pharmaceuticals that showed the potential to boost the anticancer properties of other immunotherapies. Extradomain A-fibronectin (EDA-FN), which is expressed in most solid and hematological tumors but is virtually undetectable in healthy adult tissues, is an attractive target for the delivery of cytokine at the site of the disease. METHODS: In this work, we describe the generation and characterization of a novel interleukin-7-based fusion protein targeting EDA-FN termed F8(scDb)-IL7. The product consists of the F8 antibody specific to the alternatively spliced EDA of FN in the single-chain diabody (scDb) format fused to human IL-7. RESULTS: F8(scDb)-IL7 efficiently stimulates human peripheral blood mononuclear cells in vitro. Moreover, the product significantly increases the expression of T Cell Factor 1 (TCF-1) on CD8+T cells compared with an IL2-fusion protein. TCF-1 has emerged as a pivotal transcription factor that influences the durability and potency of immune responses against tumors. In preclinical cancer models, F8(scDb)-IL7 demonstrates potent single-agent activity and eradicates sarcoma lesions when combined with anti-PD-1. CONCLUSIONS: Our results provide the rationale to explore the combination of F8(scDb)-IL7 with anti-PD-1 antibodies for the treatment of patients with cancer.

An Antibody Targeting Fibroblast Activation Protein Simultaneously Fused to Interleukin-2 and Tumor Necrosis Factor Selectively Localizes to Neoplastic Lesions.

The delivery of specific cytokine payloads to a neoplastic environment employing antibodies able to selectively accumulate at the tumor site represents an attractive strategy to stimulate an immune response to cancer. Whilst conventional antibody-cytokine fusions based on a single payload have shown potent anticancer activity, the concomitant delivery of two cytokine payloads may further improve the therapeutic outcome as the immune system typically adopts multiple signals to reinforce an antitumor strategy. We here describe a potency-matched dual-cytokine antibody fusion protein containing a tumor-targeting antibody fragment specific to human fibroblast activation protein (FAP), simultaneously linked to both interleukin-2 (IL2) and a tumor necrosis factor (TNF) mutant. The resulting fusion protein, termed IL2-7NP2-TNFmut, formed stable non-covalent trimers driven by the interaction of the tumor necrosis factor subunits. Both cytokine payloads retained their biological activity within the fusion protein, as shown by in vitro cellular assays. The tumor-targeting properties and the anticancer activity of IL2-7NP2-TNFmut were investigated in vivo in immunocompromised mice bearing SKRC52 cells transduced with human FAP. The fusion protein preferentially localized to the cancer site and induced partial tumor retardation.

Generation and in vivo validation of an IL-12 fusion protein based on a novel anti-human FAP monoclonal antibody.

BACKGROUND: In this study, we describe the generation of a fully human monoclonal antibody (named '7NP2') targeting human fibroblast activation protein (FAP), an antigen expressed in the microenvironment of different types of solid neoplasms. METHODS: 7NP2 was isolated from a synthetic antibody phage display library and was improved by one round of mutagenesis-based affinity maturation. The tumor recognition properties of the antibody were validated by immunofluorescence procedures performed on cancer biopsies from human patients. A fusion protein consisting of the 7NP2 antibody linked to interleukin (IL)-12 was generated and the anticancer activity of the murine surrogate product (named mIL12-7NP2) was evaluated in mouse models. Furthermore, the safety of the fully human product (named IL12-7NP2) was evaluated in Cynomolgus monkeys. RESULTS: Biodistribution analysis in tumor-bearing mice confirmed the ability of the product to selectively localize to solid tumors while sparing healthy organs. Encouraged by these results, therapy studies were conducted in vivo, showing a potent antitumor activity in immunocompetent and immunodeficient mouse models of cancer, both as single agent and in combination with immune checkpoint inhibitors. The fully human product was tolerated when administered to non-human primates. CONCLUSIONS: The results obtained in this work provided a rationale for future clinical translation activities using IL12-7NP2.