Identification of "Structural Pin" Interactions and their Significance for the Conformational Control of Macrocyclic Scaffolds.

While peptide macrocycles with rigidified conformations have proven to be useful in the design of chemical probes of protein targets, conformational flexibility and rapid interconversion can be equally vital for biological activity and favorable physicochemical properties. This study introduces the concept of "structural pin", which describes a hydrogen bond that is largely responsible for stabilizing the entire macrocycle backbone conformation. Structural analysis of macrocycles using nuclear magnetic resonance (NMR), molecular modelling and X-ray diffraction indicates that disruption of the structural pin can drastically influence the conformation of the entire ring, resulting in novel states with increased flexibility. This finding provides a new tool to interrogate dynamic behaviour of macrocycles. Identification of structural pins offers a useful conceptual framework to understand positions that can either be modified to give flexible structures or retained to maintain the rigidity of the scaffold.

Two-Dimensional Barriers for Probing Conformational Shifts in Macrocycles.

We describe the development and use of composite two-dimensional barriers in macrocyclic backbones. These tunable constructs derive their mode of action from heterocyclic rearrangements. The Boulton-Katritzky reaction has been identified as a particularly versatile means to effect a composite barrier, allowing the examination of the influence of heterocycle translocation on conformation. Kinetic studies using 1H NMR have revealed that the in-plane atom movement is fast in 17, 18, 19-membered rings but slows down in 16-membered rings. The analysis by NMR and MD simulation experiments is consistent with the maintenance of rare cis-amide motifs during conformational interconversion. Taken together, our investigation demonstrates that heterocyclic rearrangement reactions can be used to control macrocyclic backbones and provides fundamental insights that may be applicable to the development of a wide range of other conformational control elements.

Conformational Control of Macrocycles by Remote Structural Modification.

The conformational analysis of macrocycles is a complex and challenging problem. There are many factors that contribute to this complexity. These include a large number of degrees of freedom, transannular interactions such as hydrogen bonds and hydrophobic interactions, and a range of steric interactions, along with ring strain effects. To a greater extent than within acyclic molecules, these interactions within macrocycles are coupled such that changing one dihedral angle can significantly affect other dihedral angles, further complicating the situation. However, this coupling of bond rotations and transannular interactions enables the transmission of three-dimensional information from one side of a macrocycle to the other. Making relatively small structural modifications to a macrocycle can result in local conformational changes that propagate along the ring to affect distal structural features. The factors that control how such changes can propagate are poorly understood, and it is difficult to predict which modifications will result in significant conformational reorganizations of remote regions of a macrocycle. This review discusses examples where small structural modifications to macrocyclic scaffolds change the conformational preferences of structurally remote regions of the ring. We will highlight evidence provided for conformational changes triggered by remote substituents and explanations of how these changes might occur in an effort to further understand the factors that control such phenomena.

Development of Endocyclic Control Elements for Peptide Macrocycles.

Synthetic methods that provide control over macrocycle conformation represent valuable tools for the discovery of bioactive molecules. Incorporation of heterocycles into cyclic peptides may offer a way to stabilize their solution conformations. Herein, we used N-(isocyanimino)triphenylphosphorane (Pinc) to install an oxadiazole ring and an endocyclic amine into peptide macrocycles. To elucidate the conformational effect of this constellation of functionalities, we performed synthesis, variable temperature NMR analysis, and NOE-based molecular dynamics simulation of a range of macrocycles in DMSO. As part of this study, we conducted experiments to compare macrocycle conformation in aqueous and DMSO solutions. The obtained solution structures suggest that the reduced amide bond/heterocycle (RAH) motif can stabilize macrocycle conformations in both water and DMSO, which addresses an enduring challenge in molecular design. The conformational effect of the RAH was used in an effort to mimic the biologically relevant secondary structure of MAdCAM-1. This resulted in the discovery of a novel α4ß7 integrin antagonist.

Heterocycles: Versatile control elements in bioactive macrocycles.

The potential of macrocyclic peptides as therapeutics has garnered much attention over the last several years. Unlike their linear counterparts, macrocycles have higher resistance to enzymatic degradation and often display improved bioavailability. However, macrocycles are typically not lipophilic enough for cellular membrane penetration, which prevents them from interacting with intracellular targets. Methods to increase cellular permeability have involved the incorporation of bicyclic scaffolds, d-amino acids and N-methylation of amides. These modifications exert their effect through conformational control of macrocycles and have been well studied in the literature. In contrast, the structural consequences of heterocycle incorporation into macrocyclic rings has not been as exhaustively investigated. In this mini-review we discuss key examples in which heterocycles influence the conformational stability and other properties of macrocycles.

Illuminating the dark conformational space of macrocycles using dominant rotors.

Three-dimensional conformation is the primary determinant of molecular properties. The thermal energy available at room temperature typically equilibrates the accessible conformational states. Here, we introduce a method for isolating unique and previously understudied conformations of macrocycles. The observation of unusual conformations of 16- to 22-membered rings has been made possible by controlling their interconversion using dominant rotors, which represent tunable atropisomeric constituents with relatively high rotational barriers. Density functional theory and in situ NMR measurements suggest that dominant rotor candidates for the amino-acid-based structures considered here should possess a rotational energy barrier of at least 25 kcal mol-1. Notable differences in the geometries of the macrocycle conformations were identified by NMR spectroscopy and X-ray crystallography. There is evidence that amino acid residues can be forced into rare turn motifs not observed in the corresponding linear counterparts and homodetic rings. These findings should unlock new avenues for studying the conformation-activity relationships of bioactive molecules.

Amidine Functionality As a Conformational Probe of Cyclic Peptides.

The amidine functionality switches between hydrogen bond donor and acceptor roles depending on pH. Herein, the amidine was incorporated to select amides in cyclo(d-Ala-Pro-d-Phe-Pro-Gly). The unprotonated amidine-containing macrocyclic conformation resembles its oxoamide counterpart. Upon protonation, minimal alterations in the macrocyclic conformation were observed despite changes to the hydrogen bond network. The amidine disrupts hydrogen bonding at minimal steric cost, making it a useful functionality to study the effect of hydrogen bonding on the macrocyclic conformation.

Oxadiazole-Containing Macrocyclic Peptides Potentiate Azole Activity against Pathogenic Candida Species.

Opportunistic pathogens of the genus Candida reign as the leading cause of mycotic disease and are associated with mortality rates greater than 40%, even with antifungal intervention. This is in part due to the limited arsenal of antifungals available to treat systemic fungal infections. Azoles have been the most widely deployed class of antifungal drug for decades and function by targeting the biosynthesis of ergosterol, a key component of the fungal cell membrane. However, their utility is compromised by their fungistatic nature, which favors the development of resistance. Combination therapy has the potential to confer enhanced efficacy as well as mitigate the evolution of resistance. Previously, we described the generation of structurally diverse macrocyclic peptides with a 1,3,4-oxadiazole and an endocyclic amine grafted within the peptide backbone. Importantly, this noncanonical backbone displayed high membrane permeability, an important attribute for compounds that need to permeate across the fungal cell wall and membrane in order to reach their intracellular target. Here, we explored the bioactivity of this novel chemical scaffold on its own and in combination with the azole fluconazole. Although few of the oxadiazole-containing macrocyclic peptides displayed activity against Candida albicans on their own, many increased the efficacy of fluconazole, resulting in a synergistic combination that was independent of efflux inhibition. Interestingly, these molecules also enhanced azole activity against several non-albicans Candida species, including the azole-resistant pathogens Candida glabrata and Candida auris This work characterizes a novel chemical scaffold that possesses azole-potentiating activity against clinically important Candida species.IMPORTANCE Fungal infections, such as those caused by pathogenic Candida species, pose a serious threat to human health. Treating these infections relies heavily on the use of azole antifungals; however, resistance to these drugs develops readily, demanding novel therapeutic strategies. This study characterized the antifungal activity of a series of molecules that possess unique chemical attributes and the ability to traverse cellular membranes. We observed that many of the compounds increased the activity of the azole fluconazole against Candida albicans, without blocking the action of drug efflux pumps. These molecules also increased the efficacy of azoles against other Candida species, including the emerging azole-resistant pathogen Candida auris Thus, we describe a novel chemical scaffold with broad-spectrum bioactivity against clinically important fungal pathogens.

Conformationally stable peptide macrocycles assembled using the Petasis borono-Mannich reaction.

Macrocyclization of linear peptide precursors using the Petasis borono-Mannich reaction affords a diverse range of macrocycles with an endocyclic amine. Analysis of the corresponding macrocyclic structures underscores that the hydrogen bond between an endocyclic amine and the adjacent amide NH is a powerful control element for conformationally homogenous peptide macrocycles.