Peptide macrocycle inhibitor of coagulation factor XII with subnanomolar affinity and high target selectivity

Factor XII (FXII) is a plasma protease that has emerged in recent years as a potential target to treat or prevent pathological thrombosis, to inhibit contact activation in extracorporeal circulation, and to treat the swelling disorder hereditary angioedema. While several protein based inhibitors with high affinity for activated FXII (FXIIa) were developed, the generation of small molecule inhibitors has been challenging. In this work, we have generated a potent and selective FXIIa inhibitor by optimizing a peptide macrocycle that was recently evolved by phage display (K-i = 0.84 +/- 0.03 nM). A fluorine atom introduced in the para-position of phenylalanine enhanced the binding affinity as much as 10-fold. Furthermore, we improved the proteolytic stability by substituting the N-terminal arginine by norarginine. The resulting inhibitor combines high inhibitory affinity and selectivity with a good stability in plasma (Ki = 1.63 +/- 0.18 nM, >27 000-fold selectivity, t(1/2)(plasma) =16 +/- 4 h). The inhibitor efficiently blocked activation of the intrinsic coagulation pathway in human blood ex vivo.

Development of cyclic peptide inhibitors of coagulation factor XII and matrix metalloproteinase 2

Jonas Alfred Karl Wilbs

Peptides represent a promising molecular class for drug development. They combine several strengths of small molecules (e.g. efficient tissue diffusion, low immunogenicity and access to chemical synthesis) and key properties of biologics such as monoclonal antibodies (e.g. high affinity and specificity). Most of the peptide drugs are natural products or derivatives thereof, as for example human peptide hormones or antibacterial peptides. In recent years, a range of methodologies were established to develop peptides binding to therapeutic targets de novo. Our laboratory is specialized on the in vitro evolution of bicyclic peptides by phage display. Bicyclic peptides have two macrocyclic rings that allow for binding protein targets with high affinity and selectivity. The aim of my thesis was to improve the potency, selectivity and stability of phage-selected bicyclic peptide inhibitors of coagulation factor XII (FXII) and matrix metalloproteinase 2 (MMP-2), and to test their therapeutic potential in vivo. Specifically, I planned at improving the bicyclic peptides by substituting natural amino acids with unnatural ones. As described in the following, the substitutions to unnatural amino acids had led to substantial improvements in the bicyclic peptides, and this had enabled me the evaluation of the inhibitors in disease models. In my first and second project, I aimed at improving the potency and stability of a bicyclic peptide FXII inhibitor that was previously developed in our lab by phage display, and to test the therapeutic potential of the resulting peptide in vivo. FXII has recently been identified as a promising target for safe anticoagulation therapy. In the first project, I investigated if the insertion of a single carbon atom into the macrocyclic backbone of a bicyclic peptide FXII inhibitor can improve its binding affinity. Positions within the macrocycle susceptible to atom insertion were first identified using a scanning methodology where glycine mutants were compared to ¿-alanine mutants. Upon insertion of atoms in the backbone using ¿-amino acids or homologated cysteine analogues, two peptides showed 4.7- and 2.5-fold improved Ki values. The better one blocked FXII with a Ki of 1.5 ± 0.1 nM and was more potent than the lead peptide in inhibiting the activation of the intrinsic coagulation pathway. The strategy of ring size variation by one or several atoms should be generally applicable for the affinity maturation of in-vitro-evolved cyclic peptides. In my second project, I aimed at improving further the potency of the bicyclic peptide FXII inhibitor described before, and to additionally improve its proteolytic stability. I achieved both these goals by replacing further natural amino acids to unnatural ones. Sub-nanomolar activity for human and mouse FXII (370 and 450 pM respectively) as well as a high stability (t1/2 > 128 ± 8 h in plasma) permitted preclinical evaluation of the peptide. The inhibitor efficiently blocked intrinsic coagulation in blood plasma from human, mouse and rabbit. I further demonstrated that the peptide reduced experimental thrombosis induced by ferric chloride in mice and suppressed blood coagulation in artificial lungs in rabbits, all without increasing the risk of bleeding. This shows that the optimized bicyclic peptide is a promising candidate for thromboprotection in various medical conditions. In a third project, I aimed at improving the potency and stability of a bicyclic peptide MMP-2 inhibi

EPFL2018

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

Peptide ligands stabilized by small molecules

Alessandro Angelini, Davide Bertoldo, Shiyu Chen, Christian Heinis, Florence Pojer

Bicyclic peptides generated through directed evolution by using phage display offer an attractive ligand format for the development of therapeutics. Being nearly 100-fold smaller than antibodies, they promise advantages such as access to chemical synthesis, efficient diffusion into tissues, and needle-free application. However, unlike antibodies, they do not have a folded structure in solution and thus bind less well. We developed bicyclic peptides with hydrophilic chemical structures at their center to promote noncovalent intramolecular interactions, thereby stabilizing the peptide conformation. The sequences of the peptides isolated by phage display from large combinatorial libraries were strongly influenced by the type of small molecule used in the screen, thus suggesting that the peptides fold around the small molecules. X-ray structure analysis revealed that the small molecules indeed formed hydrogen bonds with the peptides. These noncovalent interactions stabilize the peptide-protein complexes and contribute to the high binding affinity.