Synthesis of DNA‐encoded disulfide‐ and thioether‐cyclized peptides

DNA-encoded chemical library technologies enable the screening of large combinatorial libraries of chemically and structurally diverse molecules, including short cyclic peptides. A challenge in the combinatorial synthesis of cyclic peptides is the final step, the cyclization of linear peptides that typically suffers from incomplete reactions and large variability between substrates. Several efficient peptide cyclization strategies rely on the modification of thiol groups, such as the formation of disulfide or thioether bonds between cysteines. In this work, we established a strategy and reaction conditions for the efficient chemical synthesis of cyclic peptide-DNA conjugates based on linking the side chains of cysteines. We tested two different thiol-protecting groups and found that tert-butylthio (S-tBu) works best for incorporating a pair of cysteines, and we show that the DNA-linked peptides can be efficiently cyclized through disulfide and thioether bond formation. In combination with established procedures for DNA encoding, the strategy for incorporation of cysteines may be readily applied for the generation and screening of disulfide- and thioether-cyclized peptide libraries.

Methods for the generation of large combinatorial macrocycle libraries

Sevan Mleh Habeshian

Macrocycles are an attractive class of molecules due to their good binding properties and yet rather small size that allows, in many cases, crossing membranes to reach intracellular targets. In comparison to classical small molecule drugs, macrocycles are generally better at binding to challenging targets such as proteins having flat, featureless surfaces or protein-protein interactions. However, the development of macrocycle-based ligands has been challenging due to the lack of sufficiently large libraries of macrocyclic compounds for screening. The preparation of large numbers of macrocycles is limited due to the chromatographic purification that is typically required following low-yielding cyclization reactions. As a result, the full potential of macrocycles cannot be exploited in drug discovery efforts.The goal of my thesis was to develop new methods for the efficient generation of large macrocycle libraries. Towards this end, I envisioned to establish a new macrocycle library synthesis principle in which a large panel of m small cyclic peptides are combinatorially ligated in microwell plates with a large number of n chemical fragments, and the resulting m x n products screened without purification. For accessing large libraries, I planned to perform the reactions and screens at a nanomole scale and using contact-less liquid transfer.In a first project, I developed a method for obtaining readily pure macrocyclic peptides directly from solid phase. Peptide synthesis took place on a disulfide linker to solid phase, which allowed for side chain deprotection with acid without simultaneous peptide cleavage. When a thiol group was included at the N-terminus, treatment with base in DMSO resulted in an intramolecular disulfide exchange to release peptides cyclized by a disulfide bond. The method was tolerant of diverse peptide sequences, and released all tested compounds in high purity. With this method, I was able to synthesize cyclic peptides in 96-well plates, and thus hundreds of peptides in parallel with a moderate effort. I screened a test library and identified a weak inhibitor of thrombin (Ki = 13 ± 1 µM), which validated the method. In the second project, I intended to combinatorially diversify the above macrocyclic peptides with chemical fragments in nanoliter volumes, as described above. For chemical ligation, I chose to acylate amines built into the macrocyclic peptides with carboxylic acid building blocks. Following proof-of-concept experiments, I diversified a 384-member library with 10 carboxylic acids in nanoliter volumes to give 3,840 macrocyclic compounds, which I screened against thrombin. I identified a potent thrombin inhibitor (Ki = 44 ± 1 nM), and a co-crystal structure was obtained which confirmed binding to the active site of the protease. In a final application, I generated and screened a library of 19,968 macrocycles against MDM2, an important oncology target forming a protein-protein interaction with p53. The screen identified a high nanomolar binder (KD = 394 ± 41 nM) that I optimized in two rounds of iterative library synthesis and screening (KD = 31 ± 6 nM).The methods developed in the two projects are currently applied by our laboratory, and for the development of macrocycle-based ligands to diverse disease targets.

EPFL2021

Development of Stapling Methods by Selective Side Chain Modifications of Bioactive Peptides

Christopher Matthew Bandeli Kourra

Cyclic peptide therapeutics fill the gap between small molecules (5000 Da) as a separate class of drugs, combining the advantages of both in terms of high selectivity, bioavailability, synthetic accessibility and low toxicity. However, their conformational flexibility and proteolytic instability results in fast metabolism. Therefore, modification of their chemical and structural properties at the proteolytically vulnerable sites can circumvent these deficiencies. Several strategies exist to stabilise peptides through local or global constraints, side chain functionalisation or amide bond surrogates. This thesis describes the development and application of two chemical transformations to peptides with the aim of greatly enhancing their metabolic stability either via side chain to side chain cyclisation or disulfide modification. Following the functionalisation, a comparative evaluation of the pharmacological properties of the modified peptides was conducted with respect to the parent peptides. The first cyclisation strategy aimed to apply the redox-neutral chemistry developed in the burgeoning field of borrowing hydrogen technology to peptides, as a new class of tolerable substrates. These would contain the requisite amine and alcohol functional groups enabling their direct coupling to form the lactam or N-alkylated cycle. Numerous investigations into this transformation with a plethora of substrates and catalysts did not lead to the desired cyclisation. For the second approach, a simple one-pot procedure for the 'stapling' of disulfide bonds in native peptides was developed. Tris(2-carboxyethyl)phosphine mediated reduction of the disulfide bond was followed by concomitant insertion of a 'doubly electrophilic' carbon bridge to form a physiologically stable dithioacetal bond. The reaction was performed under mild, biocompatible reaction conditions, allowing for the facile conversion of native peptides into more stable analogues. The protocol was applicable to a range of bioactive peptides with a multitude of reactive functional groups demonstrating the high versatility of this approach. The importance and utility of the modified analogues were verified by testing their binding affinity and biological activity against the corresponding parent peptides. The impact of the disulfide modification on these properties for each peptide were analysed on a case-by-case basis. The SCS modified analogues of Oxytocin and Vasopressin maintained binding affinities in the same order of magnitude as their respective parent compounds across all corresponding receptors. Nevertheless, this was not the case for SCS-Octreotide and SCS-Somatostatin. Those peptides which maintained comparable binding affinities were then tested for their functional activity at the receptors of biological interest. SCS-Oxytocin retained its agonist potency displaying sub-nanomolar activity at the Oxytocin receptor, whilst SCS-Vasopressin exhibited sub micromolar functional response at the Vasopressin 1A receptor. Then the stability of the modified peptides in human serum was evaluated. In some cases, the enhancement in serum stability was vastly increased. In particular our modified SCS-Oxytocin analogue clearly demonstrated a significant improvement in serum half-life, as well as heat and pH stability over its native parent form. This disulfide stapling method could have wide-reaching application for the development of more stable therapeutic analogues.

EPFL2016

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