An overview of DNA-encoded libraries: A versatile tool for drug discovery.

DNA-encoded libraries (DELs) are collections of small molecules covalently attached to amplifiable DNA tags carrying unique information about the structure of each library member. A combinatorial approach is used to construct the libraries with iterative DNA encoding steps, facilitating tracking of the synthetic history of the attached compounds by DNA sequencing. Various screening protocols have been developed which allow protein target binders to be selected out of pools containing up to billions of different small molecules. The versatile methodology has allowed identification of numerous biologically active compounds and is now increasingly being adopted as a tool for lead discovery campaigns and identification of chemical probes. A great focus in recent years has been on developing DNA compatible chemistries that expand the structural diversity of the small molecule library members in DELs. This chapter provides an overview of the challenges and accomplishments in DEL technology, reviewing the technological aspects of producing and screening DELs with a perspective on opportunities, limitations, and future directions.

PEARL-seq: A Photoaffinity Platform for the Analysis of Small Molecule-RNA Interactions.

RNA is emerging as a valuable target for the development of novel therapeutic agents. The rational design of RNA-targeting small molecules, however, has been hampered by the relative lack of methods for the analysis of small molecule-RNA interactions. Here, we present our efforts to develop such a platform using photoaffinity labeling. This technique, termed Photoaffinity Evaluation of RNA Ligation-Sequencing (PEARL-seq), enables the rapid identification of small molecule binding locations within their RNA targets and can provide information on ligand selectivity across multiple different RNAs. These data, when supplemented with small molecule SAR data and RNA probing data enable the construction of a computational model of the RNA-ligand structure, thereby enabling the rational design of novel RNA-targeted ligands.

A yoctoliter-scale DNA reactor for small-molecule evolution.

The center of DNA three-way junctions, constituting a yoctoliter (10(-24) L) volume, is applied as an efficient reactor to create DNA-encoded libraries of chemical products. Amino acids and short peptides are linked to oligonucleotides via cleavable and noncleavable linkers. The oligonucleotide sequences contain two universal assembling domains at the center and a distal codon sequence specific for the attached building block. Stepwise self-assembly and chemical reactions of these conjugates in a combinatorial fashion create a library of pentapeptides in DNA three-way junctions in a single reaction vessel. We demonstrate the formation of an evenly distributed library of 100 peptides. Each library member contains a short synthetic peptide attached to a unique genetic code creating the necessary "genotype-phenotype" linkage essential to the process of in vitro molecular evolution. Selective enrichment of the [Leu]-enkephalin peptide from an original frequency of 1 in 10 million in a model library to a final frequency of 1.7% in only two rounds of affinity selection is described and demonstrates successful molecular evolution for a non-natural system.

Fidelity by design: Yoctoreactor and binder trap enrichment for small-molecule DNA-encoded libraries and drug discovery.

DNA-encoded small-molecule library (DEL) technology allows vast drug-like small molecule libraries to be efficiently synthesized in a combinatorial fashion and screened in a single tube method for binding, with an assay readout empowered by advances in next generation sequencing technology. This approach has increasingly been applied as a viable technology for the identification of small-molecule modulators to protein targets and as precursors to drugs in the past decade. Several strategies for producing and for screening DELs have been devised by both academic and industrial institutions. This review highlights some of the most significant and recent strategies along with important results. A special focus on the production of high fidelity DEL technologies with the ability to eliminate screening noise and false positives is included: using a DNA junction called the Yoctoreactor, building blocks (BBs) are spatially confined at the center of the junction facilitating both the chemical reaction between BBs and encoding of the synthetic route. A screening method, known as binder trap enrichment, permits DELs to be screened robustly in a homogeneous manner delivering clean data sets and potent hits for even the most challenging targets.

Streamlining hit discovery and optimization with a yoctoliter scale DNA reactor.

BACKGROUND: The field of DNA-encoded technology offers a cutting edge approach to creating 10(9) - 10(12)-size small molecule libraries for the rapid identification of drug-like hits. The YoctoReactor(®) (yR) is the newest DNA-encoded technology and features an innovative and fundamentally different design. OBJECTIVE: This technology evaluation presents the basic principles of the yR drug discovery technology platform and discusses its potential as an alternative to current hit discovery methods where high quality and selective drug-like hits can be delivered together with instant structure activity relationships (SAR). CONCLUSION: The yR controls and encodes billions of different synthesis combinatorially through self-assembly of DNA into three-dimensional DNA junctions. The center of these junctions forms a yoctoliter (10(-24) L) volume reactor where single-molecule, DNA- encoded reactions can take place. yR technology circumvents the high throughput screening process (HTS). Instead, drug-like families of hits are rapidly identified by molecular evolution in a single tube approach making it highly parallelizable and scalable. DNA-encoded technologies such as the yR, therefore, represent a solution to many of the bottlenecks in current early phase discovery and in handling the vast emerging opportunities in functional genomics, systems biology and proteomics.