Design and synthesis of a DNA-encoded combinatorial library of bicyclic peptoids.

Here we describe the design and synthesis of a DNA-encoded library of bicyclic peptoids. We show that our solid-phase strategy is facile and DNA-compatible, yielding a structurally diverse combinatorial library of bicyclic peptoids of various ring sizes. We also demonstrate that affinity-based screening of a DNA-encoded library of bicyclic peptoids enables to efficiently identify high-affinity ligands for a target protein. Given their highly constraint structures, as well as increased cell permeability and proteolytic stability relative to native peptides, bicyclic peptoids could be an excellent source of protein capture agents. As such, our DNA-encoded library of bicyclic peptoids will serve as versatile tools that facilitate the generation of potent ligands against many challenging targets, such as intracellular protein-protein interactions.

Cell-penetrating, amphipathic cyclic peptoids as molecular transporters for cargo delivery.

Here we describe the design, synthesis, and biological evaluation of cell-penetrating, amphipathic cyclic peptoids as a novel class of molecular transporters. We demonstrated that macrocyclization, along with the introduction of hydrophobic residues, greatly enhanced cellular uptake of polyguanidine linear peptoids. The amphipathic cyclic peptoids showed an order of magnitude more efficient intracellular delivery ability, compared to a commonly used polyarginine cell-penetrating peptide, representing one of the best molecular transporters reported to date. Given the excellent cell-permeability, proteolytic stability, and ease of synthesis, the amphipathic cyclic peptoids would be broadly applicable to a wide range of clinical and biological applications.

Hydrophobic Tagging-Mediated Degradation of Transcription Coactivator SRC-1.

Steroid receptor coactivator-1 (SRC-1) is a transcription coactivator playing a pivotal role in mediating a wide range of signaling pathways by interacting with related transcription factors and nuclear receptors. Aberrantly elevated SRC-1 activity is associated with cancer metastasis and progression, and therefore, suppression of SRC-1 is emerging as a promising therapeutic strategy. In this study, we developed a novel SRC-1 degrader for targeted degradation of cellular SRC-1. This molecule consists of a selective ligand for SRC-1 and a bulky hydrophobic group. Since the hydrophobic moiety on the protein surface could mimic a partially denatured hydrophobic region of a protein, SRC-1 could be recognized as an unfolded protein and experience the chaperone-mediated degradation in the cells through the ubiquitin-proteasome system (UPS). Our results demonstrate that a hydrophobic-tagged chimeric molecule is shown to significantly reduce cellular levels of SRC-1 and suppress cancer cell migration and invasion. Together, these results highlight that our SRC-1 degrader represents a novel class of therapeutic candidates for targeting cancer metastasis. Moreover, we believe that the hydrophobic tagging strategy would be widely applicable to develop peptide-based protein degraders with enhanced cellular activity.

Targeted Degradation of Transcription Coactivator SRC-1 through the N-Degron Pathway.

Aberrantly elevated steroid receptor coactivator-1 (SRC-1) expression and activity are strongly correlated with cancer progression and metastasis. Here we report, for the first time, the development of a proteolysis targeting chimera (PROTAC) that is composed of a selective SRC-1 binder linked to a specific ligand for UBR box, a unique class of E3 ligases recognizing N-degrons. We showed that the bifunctional molecule efficiently and selectively induced the degradation of SRC-1 in cells through the N-degron pathway. Importantly, given the ubiquitous expression of the UBR protein in most cells, PROTACs targeting the UBR box could degrade a protein of interest regardless of cell types. We also showed that the SRC-1 degrader significantly suppressed cancer cell invasion and migration in vitro and in vivo. Together, these results demonstrate that the SRC-1 degrader can be an invaluable chemical tool in the studies of SRC-1 functions. Moreover, our findings suggest PROTACs based on the N-degron pathway as a widely useful strategy to degrade disease-relevant proteins.

DNA-Encoded Combinatorial Library of Macrocyclic Peptoids.

We report the design and synthesis of a DNA-encoded one-bead one-compound library of cyclic peptoids composed of more than 11 million molecules. We show that affinity-based screening of this large library can identify cyclic peptoid ligands for a target protein. In this work, we developed a simple method for amplifying the PCR product from DNA tags on a single bead, thereby enabling determination of the structures of hit cyclic peptoids with no need for high-throughput sequencing and complicated data analysis. We also developed a sublibrary screening strategy to minimize false positives caused by the interference of coding DNA tags before starting laborious and impractical hit confirmation. Given the simplicity and robustness of the synthesis and screening, along with the desirable features of macrocyclic peptoids including improved conformational rigidity, our method will be highly useful for discovering biologically active molecules modulating challenging targets such as protein-protein interactions that are not easily targeted by typical peptidomimetics and small-molecules.

Screening methods for identifying pharmacological chaperones.

Protein folding is crucial for most proteins to achieve their correct three-dimensional conformations and function properly. Defects in protein folding frequently caused by mutations lead to a range of protein misfolding diseases, including Alzheimer's disease, Parkinson's disease, cystic fibrosis, amyloidosis, Gaucher disease, etc. One approach to treat these devastating diseases would be to use pharmacological chaperones, which are small-molecules that bind to and stabilize misfolded proteins, thereby correcting their pathogenic misfolding and rescuing their functions. As such, pharmacological chaperone therapy holds great promise for the treatment of numerous protein misfolding diseases. In this review, we highlight recent strategies for identifying small-molecules that act as pharmacological chaperones and revert protein misfolding diseases, with a focus on reports within the last five years.

Supramolecular Enhancement of Protein Analysis via the Recognition of Phenylalanine with Cucurbit[7]uril.

Mass spectrometry (MS)-based analysis using enzymatic digestion is widely used for protein sequencing and characterization. The large number of peptides generated from proteolysis, however, suppresses the signal of peptides with low ionization efficiency, thus precluding their observation and analysis. This study describes a technique for improved analysis of peptic peptides by adding the synthetic receptor cucurbit[7]uril (CB[7]), which binds selectively to peptides with N-terminal aromatic residues. Capturing the N-terminal phenylalanine (Phe) of peptides using CB[7] enhances the peptide abundances both in electrospray ionization MS and in matrix-assisted laser desorption ionization MS. Moreover, collision-induced dissociation (CID) of the CB[7]·peptide complex ions generates b- and y-type fragment ions with higher sequence coverage than those generated with uncomplexed peptides. The signal enhancement mediated by CB[7] is attributed to an increase in the peptide proton affinities upon CB[7] complexation. The mechanistic details of the fragmentation process are discussed on the basis of the structures of the complex ions obtained from ion mobility (IM) measurements and molecular modeling. This study demonstrates a novel and powerful approach to the enhancement of protein and peptide analysis using a synthetic receptor, without the need for new instrumentation, chemical modifications, or specialized sample preparation. The simplicity and potential generality of this technique should provide a valuable asset in the toolbox of routine protein and peptide analysis.