Therapeutic affinity proteins offer a targeted mode of action due to their typically high affinity and specificity for disease-associated molecules. In cancer therapy, such target molecules are often overexpressed receptors on tumor cells. However, their presence in healthy tissues can lead to on-target, off-tumor toxicity, necessitating strategies to enhance tumor selectivity. Here, we present an affibody-based prodrug concept that exploits tumor-associated proteases for selective activation. As proof of concept, we designed, produced, and characterized HER2-specific prodrug candidates, each incorporating a distinct protease substrate for selective activation by tumor-associated proteases. Their activation by corresponding proteases and subsequent HER2 binding were assessed. The most promising prodrug candidate was conjugated to the cytotoxic agent DM1 and evaluated for cytotoxicity in HER2-positive cancer cells. The results demonstrated potent, HER2-dependent cell killing, with markedly reduced cytotoxicity in the absence of prodrug activation. These findings support the feasibility of affibody-based prodrugs as a strategy to enhance tumor selectivity and minimize off-tumor toxicity in targeted cancer therapy.

Overactive epidermal growth factor receptor (EGFR) signaling is often involved in driving different types of carcinomas. It is a well-studied target for targeted therapies, with both monoclonal antibodies and kinase inhibitors available for clinical use. Even though these drugs show a clinical benefit, most patients develop resistance over time. The development of new therapeutic modalities is therefore highly motivated. Herein, we describe a new type of drug candidate targeting EGFR, a so-called affibody-based drug conjugate. It consists of an EGFR-targeting affibody molecule, ZEGFR, expressed as a fusion to an albumin-binding domain for half-life extension, and coupled with the potent cytotoxic drug DM1 via a maleimidocaproyl linker. The resulting drug conjugate ZEGFR-ABD-mcDM1, showed strong binding to recombinant EGFR and EGFR-expressing cells. It was found to be highly potent in killing EGFR-expressing A431 cells with an IC50of 3.4 nM. In vivo, it showed moderate uptake in A431-derived xenografts with high EGFR expression. Collectively, the results from this study, demonstrate a potent and EGFR-specific drug candidate that holds promise for further development.

Proteases play a crucial role in biological functions such as tumor progression and tissue homeostasis. Recently, protease-activated prodrugs have gained attention for their potential to enhance selectivity in tumor-targeted therapies. In this study, we report the engineering of substrate sequences for matriptase, a protease overexpressed in tumors and previously explored for prodrug activation in vivo. A peptide library containing millions of potential substrates was displayed on Escherichia coli, and flow cytometric sorting was used to isolate improved substrates based on cleavage efficiency. Hits were ranked by flow cytometry, and the top substrates exhibited kcat /KM values over 40-fold higher than previously reported sequences. These substrates were further evaluated in an antibody-prodrug format, demonstrating exceptional activation. The matriptase substrates hold broad potential for applications such as cleavable linkers in next-generation antibody prodrugs. Furthermore, the developed bacterial display platform shows promise for discovering substrates of other proteases.

Safety and efficacy of cancer-targeting treatments can be improved by conditional activation enabled by the distinct milieu of the tumour microenvironment. Proteases are intricately involved in tumourigenesis and commonly dysregulated with elevated expression and activity. Design of prodrug molecules with protease -dependent activation has the potential to increase tumour-selective targeting while decreasing exposure to healthy tissues, thus improving the safety profile for patients. Higher selectivity could also allow for adminis-tration of higher doses or use of more aggressive treatment options, leading to higher therapeutic efficacy. We have previously developed an affibody-based prodrug with conditional targeting of EGFR conferred by an anti-idiotypic affibody masking domain (ZB05). We could show that binding to endogenous EGFR on cancer cells in vitro was restored following proteolytic removal of ZB05. In this study we evaluate a novel affibody-based pro -drug design, which incorporates a protease substrate sequence recognized by cancer-associated proteases and demonstrate the potential of this approach for selective tumour-targeting and shielded uptake in healthy tissues in vivo using tumour-bearing mice. This may widen the therapeutic index of cytotoxic EGFR-targeted thera-peutics by decreasing side effects, improving selectivity of drug delivery, and enabling the use of more potent cytotoxic drugs.

Within the field of combinatorial protein engineering there is a great demand for robust high-throughput selection platforms that allow for unbiased protein library display, affinity-based screening, and amplification of selected clones. We have previously described the development of a staphylococcal display system used for displaying both alternative-scaffolds and antibody-derived pro-teins. In this study, the objective was to generate an improved expression vector for displaying and screening a high-complexity naive affibody library, and to facilitate downstream validation of isolated clones. A high-affinity normalization tag, consisting of two ABD-moieties, was introduced to simplify off-rate screening procedures. In addition, the vector was furnished with a TEV protease substrate recog-nition sequence upstream of the protein library which enables proteolytic processing of the displayed construct for improved binding signal. In the library design, 13 of the 58 surface-exposed amino acid positions were selected for full randomization (except proline and cysteine) using trinucleotide tech-nology. The genetic library was successfully transformed to Staphylococcus carnosus cells, generating a protein library exceeding 109 members. De novo selections against three target proteins (CD14, MAPK9 and the affibody ZEGFR:2377) were successfully performed using magnetic bead-based capture followed by flow-cytometric sorting, yielding affibody molecules binding their respective target with nanomolar affinity. Taken together, the results demonstrate the feasibility of the staphylococcal display system and the proposed selection procedure to generate new affibody molecules with high affinity.

Due to their ability to catalytically cleave proteins and peptides, proteases present unique opportunities for the use in industrial, biotechnological, and therapeutic applications. Engineered proteases with redesigned substrate specificities have the potential to expand the scope of practical applications of this enzyme class. We here apply a combinatorial protease engineering-based screening method that links proteolytic activity to the solubility and correct folding of a fluorescent reporter protein to redesign the substrate specificity of tobacco etch virus (TEV) protease. The target substrate EKLVFQA differs at three out of seven positions from the TEV consensus substrate sequence. Flow cytometric sorting of a semi-rational TEV protease library, consisting of focused mutations of the substrate binding pockets as well as random mutations throughout the enzyme, led to the enrichment of a set of protease variants that recognize and cleave the novel target substrate.

Conditional activation of engineered affinity proteins by proteolytic processing is an interesting approach for a wide range of applications. We have generated an anti-idiotypic masking domain with specificity for the binding surface of an EGFR-targeting affibody molecule using an in-house developed staphylococcal display method. The masking domain could specifically abrogate EGFR-binding on cancer cells when fused to the EGFR-targeting affibody molecule via a linker comprising a protease cleavage site. EGFR-binding was restored by proteolytic cleavage of the linker region resulting in release of the masking domain. A saturation mutagenesis study provided detailed information on the interaction between the EGFR-targeting affibody molecule and the masking domain. Introducing an anti-idiotypic masking affibody domain is a viable approach for blocking EGFR-binding and al-lows for conditional activation by proteolytic processing. The results warrant further studies evaluating the therapeutic and diagnostic applicability both in vitro and in vivo.

Increasing evidence suggests that therapy targeting the human epidermal growth factor receptor 3 (HER3) could be a viable route for targeted cancer therapy. Here, we studied a novel drug conjugate, Z_HER3-ABD-mcDM1, consisting of a HER3-targeting affibody molecule, coupled to the cytotoxic tubulin polymerization inhibitor DM1, and an albumin-binding domain for in vivo half-life extension. Z_HER3-ABD-mcDM1 showed a strong affinity to the extracellular domain of HER3 (K-D 6 nM), and an even stronger affinity (K_D 0.2 nM) to the HER3-overexpressing pancreatic carcinoma cell line, BxPC-3. The drug conjugate showed a potent cytotoxic effect on BxPC-3 cells with an IC₅₀ value of 7 nM. Evaluation of a radiolabeled version, [^99mTc]Tc-Z_HER3-ABD-mcDM1, showed a relatively high rate of internalization, with a 27% internalized fraction after 8 h. Further in vivo evaluation showed that it could target BxPC-3 (pancreatic carcinoma) and DU145 (prostate carcinoma) xenografts in mice, with an uptake peaking at 6.3 +/- 0.4% IA/g at 6 h post-injection for the BxPC-3 xenografts. The general biodistribution showed uptake in the liver, lung, salivary gland, stomach, and small intestine, organs known to express murine ErbB3 naturally. The results from the study show that Z_HER3-ABD-mcDM1 is a highly potent and selective drug conjugate with the ability to specifically target HER3 overexpressing cells. Further pre-clinical and clinical development is discussed.

Safety and efficacy of cancer-targeting treatments can be improved by conditional activation conferred by the distinct milieu of the tumour microenvironment. Proteases are intricately involved in tumorigenesis and commonly dysregulated with elevated expression and activity. Design of prodrug molecules with protease-dependent activation has the potential to increase tumor-selective targeting, while decreasing the exposure to healthy tissues, thus improving safety, allowing for administration of higher doses or use of more aggressive treatment options, leading to higher therapeutic efficacy. We have previously performed in vitro characterizations of an affibody-based prodrug approach for protease-mediated targeting of EGFR. In this study we demonstrate the potential for selective tumor-targeting and shielded uptake in healthy tissues in vivo using tumor-bearing mice for an EGFR-targeting affibody prodrug.