Project description:As metalloproteins exemplify, the chemical and physical properties of metal centers depend not only on their first but also on their second coordination sphere. Installing arrays of functional groups around the first coordination sphere of synthetic metal complexes is thus highly desirable, but it remains a challenging objective. Here we introduce a novel approach to produce tailored second coordination spheres. We used bioinspired artificial architectures based on aromatic oligoamide foldamers to construct a rigid, modular and well-defined environment around a metal complex. Specifically, aza-aromatic monomers having a tethered [2Fe-2S] cluster have been synthesized and incorporated in conical helical foldamer sequences. Exploiting the modularity and predictability of aromatic oligoamide structures allowed for the straightforward design of a conical architecture able to sequester the metal complex in a confined environment. Even though no direct metal complex-foldamer interactions were purposely designed in this first generation model, crystallography, NMR and IR spectroscopy concurred to show that the aromatic oligoamide backbone alters the structure and fluxional processes of the metal cluster.

Project description:Bio-inspired synthetic backbones leading to foldamers can provide effective biopolymer mimics with new and improved properties in a physiological environment, and in turn could serve as useful tools to study biology and lead to practical applications in the areas of diagnostics or therapeutics. Remarkable progress has been accomplished over the past 20 years with the discovery of many potent bioactive foldamers originating from diverse backbones and targeting a whole spectrum of bio(macro)molecules such as membranes, protein surfaces, and nucleic acids. These current achievements, future opportunities, and key challenges that remain are discussed in this article.

Project description:Quinoline based aromatic amide foldamers are known to adopt stable folded conformations. We have developed a synthetic approach to produce similar oligomers where all amide bonds, or part of them, have been replaced by an isosteric vinylene group. The results of solution and solid state structural studies show that oligomers exclusively containing vinylene linkages are not well folded, and adopt predominantly flat conformations. In contrast, a vinylene segment flanked by helical oligoamides also folds in a helix, albeit with a slightly lower curvature. The presence of vinylene functions also result in an extension of π-conjugation across the oligomer that may change charge transport properties. Altogether, these results pave the way to foldamers in which both structural control and specific electronic properties may be engineered.

Project description:The functions performed by proteins and nucleic acids provide the foundation for life. Chemists have recently begun to ask whether it is possible to design synthetic oligomers that approach the structural and functional complexities of these biopolymers. The study of foldamers, non-natural oligomers displaying discrete folding propensities, has demonstrated that there are several synthetic backbones that exhibit biopolymer-like conformational behavior. Early work in this area focused on oligomers comprised of a single type of monomer subunit, but recent efforts have highlighted the potential of mixed or "heterogeneous" backbones to expand the structural and functional repertoire of foldamers. In this Account, we illustrate the promise of heterogeneous backbone foldamers by focusing on examples containing both alpha- and beta-amino acid residues. Some beta-residues bear protein-like side chains, while others have cyclic structures that confer conformational rigidity. The study of heterogeneous backbone foldamers has several advantages over that of their homogeneous backbone counterparts, including access to many new molecular shapes based on variations in the stoichiometries and patterns of the subunit combinations and improved prospects for side chain diversification. Recent efforts to develop alpha/beta-peptide foldamers can be divided into two conceptually distinct classes. The first includes entities prepared using a "block" strategy, in which alpha-peptide segments and beta-peptide segments are combined to form a hybrid oligomer. The second class encompasses designs in which alpha- and beta-amino acid monomers are interspersed in a regular pattern throughout an oligomer sequence. One alpha/beta-peptide helical secondary structure, containing C=O(i)...H-N(i+4) H-bonds analogous to those in the alpha-helix, has been shown via crystallography to form helix bundle quaternary structures. Desirable biological functions have been elicited from alpha/beta-peptide foldamers. Efforts to mimic naturally occurring host-defense alpha-peptides have yielded new antimicrobial agents and have led to a reexamination of the long-held views regarding structure-activity relationships among these alpha-peptides and their analogues. Foldamers offer new platforms for mimicry of the molecular surfaces involved in specific protein-protein recognition events; recent achievements in the preparation of alpha/beta-peptide inhibitors of the protein-protein interactions involved in apoptotic signaling (e.g., between Bcl-xL and pro-apoptotic partners) have revealed the benefits of employing heterogeneous backbones relative to homogeneous backbones for foldamer-based designs. These initial successes in the development of alpha/beta-peptides exhibiting specific biological activities highlight the potential of heterogeneous backbone foldamers for use in biomedical applications and provide guidelines for future studies into new target functions.

Project description:The intrinsic pathway of apoptosis is regulated by the Bcl-2 family of proteins. Inhibition of the anti-apoptotic members represents a strategy to induce apoptotic cell death in cancer cells. We have measured the membrane binding properties of a series of peptides, including modified α/β-peptides, designed to exhibit enhanced membrane permeability to allow cell entry and improved access for engagement of Bcl-2 family members. The peptide cargo is based on the pro-apoptotic protein Bim, which interacts with all anti-apoptotic proteins to initiate apoptosis. The α/β-peptides contained cyclic β-amino acid residues designed to increase their stability and membrane-permeability. Dual polarisation interferometry was used to study the binding of each peptide to two different model membrane systems designed to mimic either the plasma membrane or the outer mitochondrial membrane. The impact of each peptide on the model membrane structure was also investigated, and the results demonstrated that the modified peptides had increased affinity for the mitochondrial membrane and significantly altered the structure of the bilayer. The results also showed that the presence of an RRR motif significantly enhanced the ability of the peptides to bind to and insert into the mitochondrial membrane mimic, and provide insights into the role of selective membrane targeting of peptides.

Project description:Oligomers composed of β(3)-amino acid residues and a mixture of α- and β(3)-residues have emerged as proteolytically stable structural mimics of α-helices. An attractive feature of these oligomers is that they adopt defined conformations in short sequences. In this manuscript, we evaluate the impact of β(3)-residues as compared to their α-amino acid analogs in prenucleated helices. Our hydrogen-deuterium exchange results suggest that heterogeneous sequences composed of "αααβ" repeats are conformationally more rigid than the corresponding homogeneous α-peptide helices, with the macrocycle templating the helical conformation having a significant influence.

Project description:RiPP has the potential to binding metal. Investigating the type of metal this binds is key

Project description:RiPP has the potential to binding metal. Investigating the type of metal this binds is key

Project description:X-ray crystallography has played a major role in the advancement of foldamer research, however, obtaining well-formed single crystals of suitable quality for structure determination by X-ray diffraction methods is often rather challenging. Towards this end, we report here the ability of common surfactants to promote the crystallisation of a series of water-soluble oligourea foldamers which had previously proven highly resistant to crystallisation. Four high-resolution crystal structures are reported, suggesting certain surfactants could be potentially useful tools for the crystallisation of intractable water-soluble foldamers (or peptides).

Project description:Small arylamide foldamers designed to mimic the amphiphilic nature of antimicrobial peptides (AMPs) have shown potent bactericidal activity against both Gram-negative and Gram-positive strains without many of the drawbacks of natural AMPs. These foldamers were shown to cause large changes in the permeability of the outer membrane of Escherichia coli. They cause more limited permeabilization of the inner membrane which reaches critical levels corresponding with the time required to bring about bacterial cell death. Transcriptional profiling of E. coli treated with sublethal concentrations of the arylamides showed induction of genes related to membrane and oxidative stresses, with some overlap with the effects observed for polymyxin B. Protein secretion into the periplasm and the outer membrane is also compromised, possibly contributing to the lethality of the arylamide compounds. The induction of membrane stress response regulons such as rcs coupled with morphological changes at the membrane observed by electron microscopy suggests that the activity of the arylamides at the membrane represents a significant contribution to their mechanism of action.