As the field of traditional DNA-Encoded Library (DEL) chemistry reaches maturity, expectations for library quality have become increasingly exacting. Beyond conventional optimizations focused on purification protocols and reaction yields, a growing number of research groups have pioneered solid-phase synthesis strategies to enhance peptide library purity. Here, we present and discuss the key insights gleaned from three recent publications on solid-phase DEL derivatives.

Shiyu Chen et al. pioneered a solid-phase purification strategy for DNA-encoded peptide libraries (PDELs) by engineering a modified Fmoc (mFmoc) protecting group equipped with a terminal azido1. This design enables the specific immobilization of desired peptide intermediates onto alkyne-functionalized controlled pore glass (CPG) beads via copper-free click chemistry following each coupling step (Fig. 1). After rigorous washing to eliminate unreacted building blocks and truncated byproducts, the pure products are released through standard Fmoc deprotection. This "capture-and-release" cycle successfully facilitated the construction of the longest reported five-round PDEL with purity exceeding 95%, effectively breaking the conventional four-round synthesis barrier. (Solid DEL-1)

Fig. 1: Iterative cycles of generating a purified DNA-encoded peptide library with mFmoc-protected amino acids. The desired DNA-encoded peptide is isolated after immobilization and purification (Solid DEL-1).

The group of Jörg Scheuermann developed another dual-linker solid-phase synthesis strategy on magnetic beads to achieve "self-purifying" release of DELs (Fig. 2)2. This solid-phase platform not only facilitates the synthesis of high-purity five-cycle desired peptide compounds but also significantly expands the compatible reaction scope to include water-free conditions, enabling transformations previously inaccessible in traditional aqueous DEL synthesis, such as the SnAP cyclization reaction and acid-mediated Boc-deprotection. However, this synthetic strategy is quite tedious. (Solid DEL-2)

Fig. 2: Synthetic strategy used for "self-purifying" release of DEL (Solid DEL-2).

Brian M. Paegel has pioneered an alternative solid-phase DNA-encoded library (DEL) synthesis strategy that integrates the "one-bead-one-compound" (OBOC) approach3. In this method, library members are constructed on solid-phase microbeads and linked to DNA tags via a photocleavable linker. This design facilitates the physical isolation and light-triggered release of desired peptide compounds, thereby enabling a broader spectrum of screening modalities, including activity-based assays and cellular phenotypic screening. However, this approach is inherently limited to a library size of 104–106 members, as it relies on the individual screening of compounds on discrete physical beads (Fig. 3). (Solid DEL-3)

Fig. 3: Synthetic strategy used for one-bead-one-compound of DEL (Solid DEL-3).

Collectively, these three solid-phase DEL design paradigms offer new insights into the future of peptide DEL library construction. They suggest that we can strategically leverage emerging technologies to fundamentally enhance peptide DEL library quality. Aligning with this evolving paradigm, HitGen is also exploring the introduction of novel solid-phase methodologies to elevate the quality of our peptide libraries. We anticipate that, in the near future, these innovations will be successfully translated into practice, pointing a new direction for the next generation of DEL synthesis.

Reference:

1. He Q, Wang Y, Tang X, et al. Enhanced screening via a pure DNA-encoded peptide library enabled by an Fmoc modification. Proc Natl Acad Sci U S A. 2026;123(8):e2524999123. doi:10.1073/pnas.2524999123

2. Keller M, Petrov D, Gloger A, et al. Highly pure DNA-encoded chemical libraries by dual-linker solid-phase synthesis. Science. 2024;384(6701):1259-1265. doi:10.1126/science.adn3412

3. Dixit A, Paegel BM. Solid-phase DNA-encoded library synthesis: a master builder's instructions. Nat Protoc. 2026;21(2):542-581. doi:10.1038/s41596-025-01190-4

Maria Staikopoulou, Haitham Hassan

Drug Discovery Today

DOI: 10.1016/j.drudis.2026.104658

Highlight

• A comprehensive review of kinase inhibitors discovered via DNA-encoded libraries (DELs) from 2009 to 2025.
• Analysis of chemical diversity, binding interactions and optimisation strategies driving DEL-based kinase inhibitor discovery.
• Mapping of 22 kinase targets across 17 families, including CMGC, tyrosine kinase, TKL and STE superfamilies.
• Strategic design recommendations for DEL scaffolds, heterocycles and covalent warheads to enhance selectivity and druglike properties.
• Future directions integrating DELs with artificial intelligence/machine learning and hybrid screening approaches to accelerate the development of selective kinase inhibitors.

Abstract

In this review, we summarise and analyse the structures and key characteristics of kinase inhibitors identified through DNA-encoded libraries (DELs) from 2009 to 2025. We focus on their chemical diversity, binding interactions and optimisation strategies that have driven progress in DEL-based kinase inhibitor discovery. Representative case studies highlight innovative approaches and successes in addressing therapeutic challenges associated with kinases. We also examine the general physicochemical properties of the identified compounds and map the kinase families most frequently targeted by DELs. Overall, 47 initial hits and 17 leads were evaluated for 24 kinase targets across 19 families. Our aim is to inspire further advancements in DEL technology and promote its application in the selective and efficient discovery of kinase inhibitors to accelerate drug development.

Xuanjing Shen, Xudong Wang, Zijian Liu, Yueyue Xia, Xinyuan Wu, Hanqing Zhao, Caini He, Hongbin Xu, Zhiqiang Duan

Bioconjugate Chemistry

DOI: 10.1021/acs.bioconjchem.6c00057

Abstract

The development of DNA-encoded library (DEL) technology is contingent upon robust and DNA-compatible reactions to expand accessible chemical space. Tandem transformations, which combine functional group interconversion and scaffold construction in one step, are particularly attractive for streamlining on-DNA synthesis. Herein, we report a copper-mediated tandem reaction conducted under mild, aqueous conditions that enables the in situ reduction of nitro groups followed by reductive amination with aldehydes. This DNA-compatible protocol efficiently furnishes secondary amines directly from nitro substrates, circumventing the need for prereduction. Moreover, the methodology can be extended to o-nitroaniline derivatives, providing efficient one-pot access to benzimidazole scaffolds through tandem nitro reduction and cyclization with aldehydes. Compared to conventional stepwise sequences requiring isolated intermediates, this strategy provides a more streamlined and atom-economical route for constructing privileged pharmacophores directly on DNA.

Konstantin Egon Seifert,Julissa Reimann,Martin Rust,Martin Bögemann,Andres Jan Schrader,Michael Schäfers,Christof Bernemann,Philipp Backhaus

Seminars in Nuclear Medicine

DOI: 10.1053/j.semnuclmed.2026.03.004

Abstract

Prostate-specific membrane antigen (PSMA)-targeted theranostics have transformed the diagnostic and therapeutic landscape of prostate cancer; however, clinically relevant limitations persist, including heterogeneous or absent PSMA expression in a substantial subset of tumors and dose-limiting off-target uptake in salivary glands, lacrimal glands and kidneys. Prostatic acid phosphatase (ACP3), expressed in more than 95% of prostate cancers, has re-emerged as a promising complementary and potentially alternative theranostic target. ACP3 demonstrates favorable biological characteristics, including high and consistent tumor expression, persistence in castration-resistant disease, and minimal expression in critical but non-cancerous tissues. Recent advances in ligand discovery using DNA-encoded chemical libraries have enabled the development of high-affinity ACP3-targeting compounds, with successful first-in-human molecular imaging with [68Ga]Ga-OncoACP3-DOTA PET. Early clinical data demonstrate competitive diagnostic performance compared with PSMA-PET, markedly reduced salivary/lacrimal gland and renal uptake, and advantageous pharmacokinetics characterized by increasing tumor uptake and improving tumor-to-background ratios over time. Preclinical and translational evidence further supports the feasibility of ACP3-targeted radioligand therapy. This review summarizes the biological features of ACP3, its historical and current role as a biomarker, and emerging therapeutic applications, with a primary focus on ACP3-targeted molecular imaging and radioligand therapy. The available evidence positions ACP3 as a compelling next-generation theranostic target with the potential to overcome key limitations of PSMA-based approaches and expand precision treatment options for patients with prostate cancer.

Xudong Wang , Zijian Liu , Xuanjing Shen , Yueyue Xia, Sixiu Liu, Nidhal Selmi, Yinan Song, Xiaojie Lu

ChemRxiv

DOI: 10.26434/chemrxiv.15001270/v1

Abstract

DNA-encoded library (DEL) technology has become an essential approach for accelerating hit discovery in drug development, yet its success is closely tied to the availability of robust and DNA-compatible reactions. Here we report a diboron-mediated strategy that leverages in situ generated Cu(I) to enable the efficient on-DNA construction of dihydroquinazolinones, a privileged heterocyclic scaffold with broad pharmacological relevance. This transformation proceeds via selective nitro group reduction followed by intramolecular cyclization with aldehydes or ketones under mild, aqueous-compatible conditions. The method tolerates diverse building blocks, delivering high conversions across a panel of substrates. By providing a reliable and atom-economical route to dihydroquinazolinones directly on DNA, this study expands the accessible chemical space of DELs and enriches the toolbox of DNA-compatible heterocycle syntheses.

A recent review published in Bioconjugate Chemistry by Marinier et al. (2026) shows that DNA-encoded libraries (DELs), long established for therapeutic small-molecule discovery, represent an underutilized yet highly promising platform for the rapid, parallel development of next-generation molecular probes – particularly for live-cell imaging, targeted radioimaging, and personalized theranostics. DEL-derived targeting moieties can be efficiently and modularly converted into high-affinity, high-selectivity optical or radiolabeled probes – including dual-use agents that simultaneously enable precise diagnosis and effective therapy (Figure 1).A recent review published in Bioconjugate Chemistry by Marinier et al. (2026) shows that DNA-encoded libraries (DELs), long established for therapeutic small-molecule discovery, represent an underutilized yet highly promising platform for the rapid, parallel development of next-generation molecular probes – particularly for live-cell imaging, targeted radioimaging, and personalized theranostics. DEL-derived targeting moieties can be efficiently and modularly converted into high-affinity, high-selectivity optical or radiolabeled probes – including dual-use agents that simultaneously enable precise diagnosis and effective therapy (Figure 1).

Figure 1. DEL for new molecular probe discovery

1. Trends in molecular probe development

Conventional probes include several different types of structures. Non-targeted fluorescent dyes were developed and used in early years, but that resulted in high background and poor selectivity. Metabolic radiotracers like [¹⁸F]FDG lack target specificity. Bi-functional tracers with large targeting moiety (larger peptides, aptamers and antibodies) suffer from limited tissue penetration, instability, and complex manufacturing. Small molecules targeting moiety offer compelling advantages – as targeting ligands, they provide excellent cell permeability, metabolic stability, oral bioavailability potential, shelf life, and scalable synthesis – making them ideal scaffolds for bi-functional probes. An effective approach to discover suitable small molecules for probe development is in urgent need.

2. Development of DEL technology and its role in new probe discovery

DEL technology has undergone rapid development over the past few decades. Various DEL construction strategies (e.g., dsDEL, ssDEL, Dynamic DEL, OBOC-DEL), DNA-compatible chemistries (amide coupling, Suzuki cross-coupling, reductive amination), screening modalities (target-immobilized pulldown, live-cell selection, target-agnostic cell-based assays), and hit validation workflows (on-DNA/off-DNA resynthesis, FP, SPR, ELISA) have been reported. These advances enabled ultra-high-throughput screening of billions of compounds against diverse, challenging targets – including membrane proteins, intracellular targets, whole cells, pathogens, mRNA, and even patient-derived samples. The DNA tag acts as a robust, solvent-exposed conjugation handle – enabling rational, modular reporter attachment without compromising binding affinity. Highly selective molecules arise from DEL’s vast chemical diversity and compatibility with counter-screening (e.g., antitarget cells), while rapid screening (<1 week) makes fast probe development possible.

3. DEL-derived molecular probe development cases

The following figure shows some examples of DEL hit-based probe discovery (Figure 2). Some of them exhibit promising prospects:

• CAIX (Carbonic Anhydrase IX)-targeting optical probe: 3b (Kd = 7 nM) enabled ex vivo tumor imaging and successfully guided CAIX-expressing SK-RC-52 tumor lysis in the presence of fluorescein-specific UniCAR T-cells;
• PSMA (Prostate-Specific Membrane Antigen)-targeting probes: 7b/8b showed nanomolar affinity, high selectivity over antitarget GCP3 (glutamate carboxypeptidase III), and selective cellular internalization; 7c demonstrated reduced kidney uptake compared with Pluvicto® treatment to mitigate nephrotoxicity;
• CAIX-targeting radioactive probes: [¹⁷⁷Lu]-labeled 6d achieved near-exclusive tumor accumulation in xenografts; [⁶⁸Ga]-labeled 6e is currently in Phase I clinical trial for renal cancer.

Figure 2. Left: Structures of validated DEL hits against known cancer-associated antigens (R = DNA exit vector). Right: Structure of the optimized probes.

4. Future directions and summary

The successful cases shown above prove the potential of DEL-based new molecular probe development. Some challenges still need to be addressed, including cost and access barriers for DELs, as well as low retention and short circulation half-life. Commercial DEL products like HitGen OpenDEL™, as well as academic DEL platforms, will democratize the access to high-quality DELs. Predictive models can be built based on integration of AI/ML to extract structure-affinity relationships from DEL data. Broader adoption of covalent DEL binders (e.g., acrylamide warheads) will help enhance retention and theranostic efficacy. Incorporation of albumin-binding motifs is beneficial for extending circulation half-life. Ultimately, DEL is positioned as a foundational, data-rich, and highly adaptable technology uniquely suited to accelerate the development of personalized, next-generation molecular probes and theranostics.

Reference:

Julien Poupart, Sunit Kumar Jana, Sasmita Tripathy, and Anne Marinier. DNA-Encoded Libraries (DELs) for Discovering New Molecular Probes: Application to Live-Cell Bioimaging and Personalized Theranostics. Bioconjugate Chem. 2026, 37, 3, 511–525. https://pubs.acs.org/doi/10.1021/acs.bioconjchem.5c00661