Structurally Diverse Cyclisation Linkers Impose Different Backbone Conformations in Bicyclic Peptides

Combinatorial libraries of structurally diverse peptide macrocycles offer a rich source for the development of high-affinity ligands to targets of interest. In this work we have developed linkers for the generation of genetically encoded bicyclic peptides and tested whether the peptides cyclised by them have significant variations in their backbone conformations. Two new cyclisation reagents, each containing three thiol-reactive groups, efficiently and selectively cyclised linear peptides containing three cysteine moieties. When the mesitylene linker of the bicyclic peptide PK15, a potent inhibitor of plasma kallikrein (Ki=2 nM), was replaced by the new linkers, its inhibitory activity dropped by a factor of more than 1000, suggesting that the linkers impose different conformations on the peptide. Indeed, structural analysis by solution-state NMR revealed different NOE constraints in the three bicyclic peptides, indicating that these relatively small linkers at the centres of bicyclic peptide structures significantly influence the conformations of the peptides. These results demonstrate the prominent structural role of linkers in peptide macrocycles and suggest that application of different cyclisation linkers in a combinatorial fashion could be an attractive means to generate topologically diverse macrocycle libraries.

Development of New Bicyclic Peptide Formats and their Application in Directed Evolution

Shiyu Chen

Cyclic peptides have a range of properties that make them attractive as therapeutics such as high binding affinity, good target selectivity and low toxicity. While most peptides in the clinic are derived from nature, various powerful in vitro evolution techniques allow now the de novo development of cyclic peptide ligands to targets of interest. Our group is specialized in the development of bicyclic peptide ligands by phage display. A current limitation of phage-selected bicyclic peptides is their conformational flexibility limiting the binding affinity due to entropic effects or even preventing the generation of binders to challenging targets. The main goal of my thesis was the development of new bicyclic peptide formats that are conformationally more rigid or even have a stable fold in solution. The proposed bicyclic peptide formats are based on a rigid chemical structure containing multiple polar groups and peptides that are anchored to the structure and fold tightly around by forming non-covalent interactions. I also envisioned to cyclise peptide phage display libraries with several such chemical structures in parallel to generate and screen structurally highly diverse bicyclic peptide libraries. In a first project, I designed and synthesized three new compounds that have i) three thiol-reactive groups to react with peptides and ii) several polar groups. Two of these compounds efficiently and selectively cyclised linear peptides containing three cysteine residues. Functional and structural analysis of the bicyclic peptides showed that the relatively small compounds at the centre of bicyclic peptides significantly influence the activity and conformation of the peptides. These results demonstrated the prominent structural role of chemical linkers in peptide macrocycles. In a second project, I applied the compounds developed in the first project in phage selections. The sequences of isolted bicyclic peptide ligands were strongly influenced by the small chemical structures, suggesting that the peptides fold closely around them. X-ray structure analysis revealed that one of the chemical structures indeed nucleated peptides by forming H-bond interactions. This result showed that small rigid chemicals can serve as nucleating scaffolds and directs the way towards the generation of peptide ligands being folded in solution. A third project is based on an unexpected observation in the second project, namely that panning peptide phage libraries without prior alkylation with compounds yielded mostly peptides with four cysteines. The peptides bound with good affinity and characterization revealed that they contain two disulphide bridges and thus formed bicyclic peptide structures. An interesting feature of disulfide-based bicyclic peptide libraries was the high topological diversity: oxidation of peptide libraries of the form Xm CXn CXo CXp yielded 3 × (m+n+o+p) different bicyclic peptide topologies because the fourth cysteine could appear in any of the (m+n+o+p) randomized amino acid positions (X) and the four peptides in such peptides could pair in three different ways. X-ray structure analysis revealed an important structural role of the disulfide bridges. The new method offers an easy and robust way to generate bicyclic peptide ligands.

EPFL2013

New methods for developing (bi)cyclic peptides by phage display

Camille Villequey

Cyclic peptide ligands are a promising molecular format for the development of therapeutics. They combine some of the advantages of large protein therapeutics (high affinity and specificity) and of small molecule drugs (accessibility to chemical synthesis and low immunogenicity). With phage display, large combinatorial libraries of more than one billion mono- and polycyclic peptides can be developed and screened against virtually any target. During phage affinity selections, the physical link between phenotype (encoded peptide) and genotype (phage DNA) allows the identification of enriched peptide binders by sequencing of the phage vector DNA. Based on these concepts, our laboratory has established a robust chemistry in which phage displayed peptides containing two or three cysteines are cyclized or bi-cyclized with thiol-reactive linkers. This procedure has been generally applied for the isolation of potent and selective (bi)cyclic peptide ligands with therapeutic potential. The isolation of binders with optimal properties is highly dependent on the possibility to generate (bi)cyclic peptide libraries with high structural diversity and on the ability to thoroughly decode the phage selection output. In my PhD work, I developed new methods to generate large and structurally diverse libraries and to decode more efficiently phage selected peptides. In my first project, I explore the cyclization of peptides with two chemical bridges as a method to provide rapid access to phage-encoded libraries with high scaffold diversity. To this end, a range of twelve structurally diverse chemicals were tested for thiol-reactivity and phage compatibility. Subsequently, peptide libraries of the format XCXnCXnCX (X = random amino acid, C = cysteine, n = 3 or 4) were cyclized with six of these chemical linkers and panned against the protease plasma kallikrein. The selection yielded inhibitors with remarkable affinity (sub-nM KI), target selectivity (>1000-fold) and proteolytic stability (t1/2 in plasma > 3 days) despite a relatively small molecular mass (~ 1200 Da). In the second project, I developed phage-encoded libraries of small cyclic peptides in order to identify ligands that have the potential to be orally absorbed. A major challenge for the generation of such library is the usually low diversity of compounds due to the limited number of amino acids. In this work, we addressed this limitation by taking advantage of a recently discovered peptide cyclization reaction in which the thiol of a cysteine is ligated with the N-terminal amino group using a chemical reagent. We applied this strategies to two phage-encoded peptide libraries of four and five amino acids (XXXC and XXXXC) that were cyclized with eight chemical linkers yielding a collection of more than 1.3 million compounds. Panning the libraries against the two disease targets plasma kallikrein and coagulation factor XIa yielded ligands with single-digit micromolar affinity. In a third project, I developed a strategy to bypass the bacterial infection step in phage display. Bacterial infection is usually crucial for the propagation and identification of enriched clones by DNA sequencing. However, mutations or chemical modifications of the phage coat proteins, sometimes lead to decreased infection rates and therefore compromise the entire procedure. Consequently, there is an interest for developing methods in which this step could be completely omitted.

EPFL2017

Solid-phase peptide synthesis on disulfide-linker resin followed by reductive release affords pure thiol-functionalized peptides

Zsolt Bognár, Christian Heinis, Manuel Leonardo Merz, Ganesh Kumar Mothukuri, Alexander Lund Nielsen, Peter Matei Frisius Pânzar

Thiol groups are suitable handles for site-selectively modifying, immobilizing or cyclizing individual peptides or entire peptide libraries. A limiting step in producing the thiol-functionalized peptides is the chromatographic purification, which is particularly laborious and costly if many peptides or even large libraries are to be produced. Herein, we present a strategy in which thiol-functionalized peptides are obtained in >90% purity and free of reducing agent, without a single chromatographic purification step. In brief, peptides are synthesized on a solid support linked via a disulfide bridge, the side-chain protecting groups are eliminated and washed away while the peptides remain on resin, and rather pure peptides are released from the solid support by reductive cleavage of the disulfide linker. Application of a volatile reducing agent, 1,4-butanedithiol (BDT), enabled removal of the agent by evaporation. We demonstrate that the approach is suited for the parallel synthesis of many peptides and that peptides containing a second thiol group can directly be cyclized by bis-electrophilic alkylating reagents for producing libraries of cyclic peptides.