Racemic and quasi-racemic x-ray structures of cyclic disulfide-rich peptide drug scaffolds

Cyclic disulfide-rich peptides have exceptional stability and are promising frameworks for drug design. We were interested in obtaining X-ray structures of these peptides to assist in drug design applications, but disulfide-rich peptides can be notoriously difficult to crystallize. To overcome this limitation, we chemically synthesized the L- and D-forms of three prototypic cyclic disulfide-rich peptides: SFTI-1 (14-mer with one disulfide bond), cVc1.1 (22-mer with two disulfide bonds), and kB1 (29-mer with three disulfide bonds) for racemic crystallization studies. Facile crystal formation occurred from a racemic mixture of each peptide, giving structures solved at resolutions from 1.25 Å to 1.9 Å. Additionally, we obtained the quasi-racemic structures of two mutants of kB1, [G6A]kB1, and [V25A]kB1, which were solved at a resolution of 1.25 Å and 2.3 Å, respectively. The racemic crystallography approach appears to have broad utility in the structural biology of cyclic peptides

Translational diffusion of cyclic peptides measured using pulsed-field gradient NMR

Cyclic peptides are increasingly being recognized as valuable templates for drug discovery or design. To facilitate efforts in the structural characterization of cyclic peptides, we explore the use of pulse-field gradient experiments as a convenient and noninvasive approach for characterizing their diffusion properties in solution. We present diffusion coefficient measurements of five cyclic peptides, including dichC, SFTI-1, cVc1.1, kB1, and kB2. These peptides range in size from six to 29 amino acids and have various therapeutically interesting activities. We explore the use of internal standards, such as dioxane and acetonitrile, to evaluate the hydrodynamic radius from the diffusion coefficient, and show that 2,2-dimethyl-2-silapentane-5-sulfonic acid, a commonly used chemical shift reference, can be used as an internal standard to avoid spectral overlap issues and simplify data analysis. The experimentally measured hydrodynamic radii correlate with increasing molecular weight and in silico predictions. We further applied diffusion measurements to characterize the self-association of kB2 and showed that it forms oligomers in a concentration-dependent manner, which may be relevant to its mechanism of action. Diffusion coefficient measurements appear to have broad utility in cyclic peptide structural biology, allowing for the rapid characterization of their molecular shape in solution

Effects of Cyclization on Peptide Backbone Dynamics

Despite the widespread use of cyclization as a structure optimization tool in peptide chemistry, little is known about the effect of cyclization on peptide internal dynamics. In this work, we used a combination of multifield NMR relaxation and molecular dynamics techniques to study both monocyclic and polycyclic peptides that have promising biopharmaceutical properties, namely, VH, SFTI-1, and cVc1.1, and their less constrained analogues to study the effects of backbone cyclization (which forms a macrocycle) and disulfide-bond cyclization (which forms internal cycles). We confirmed that backbone cyclization contributes to the rigidity of the monocyclic VH. Interestingly, however, backbone cyclization of the bicyclic SFTI-1 had a limited effect on rigidity, with changes in internal dynamics localized around the ligation site. This suggests that the disulfide bond, which creates an internal cycle, has an insulating effect, protecting the internal cycle from external motional effects. An insulating effect was also observed for the polycyclic cVc1.1: The rigidity of the core was not enhanced by macrocyclization. Additionally, we found that disulfide bonds provide a greater contribution to overall rigidity than macrocyclization. Overall, our results suggest that, although backbone cyclization can improve rigidity, there is a complex interplay between dynamics and cyclization, particularly for polycyclic systems

Native peptide folding dominates over stereoelectronic effects of prolyl hydroxylation in loop 5 of the macrocyclic peptide kalata B1

Kalata B1 (4) is a prototypical, 29-residue, Möbius cyclotide with a cis prolyl peptide bond in loop 5. Two analogs were synthesized in which Pro24 was substituted by trans-4-hydroxy-l-proline (peptide 5) and cis-4-hydroxy-l-proline (peptide 6). Linear peptides were assembled by solid phase peptide synthesis using Fmoc/tBu chemistry. Head-to-tail cyclization was performed using HATU, side-chain protecting groups removed and the cyclic peptides 2 and 3 isolated by RP-HPLC. Oxidation led to the formation of peptides 5 and 6, each incorporating three disulfide bonds. Analysis of TOCSY and NOESY spectra of the purified peptides enabled assignment of the backbone amide and Hα resonances. These showed a striking correlation with those of native kalata B1, indicating that folding had produced the same disulfide bridge topology. While somewhat surprising that stereoelectronic effects introduced by the hydroxyl substituents in this key region of the peptide had little impact, this reflects the strong thermodynamic driving force toward formation of the cyclic cystine knot scaffold

Inhibition of tau aggregation using a naturally-occurring cyclic peptide scaffold

Disulfide-rich macrocyclic peptides are emerging as versatile scaffolds for the development of stable biochemical tools. This potential is due to the combination of their structural stability and range of bioactivities. Here, we explored the activity of these peptides on fibril growth of the hexapeptide Ac-VQIVYK-NH2 (AcPHF6), which is a tau-derived peptide that has been widely used to understand the pathological mechanism of numerous tauopathies, including Alzheimer's disease. Of the cyclic peptides tested, SFTI-1 and kB1 showed an inherent ability to inhibit AcPHF6 fibril formation. Using an end-capping strategy and combining it with a molecular grafting approach, we demonstrated that SFTI-1 could be used as a starting point to design more potent fibril inhibitors. We further identified chemical and structural features of SFTI-1 and its analogues that underpin their inhibitory activity. The ability to inhibit fibril growth using the strategy employed herein supports the 'steric zipper' model of AcPHF6 fibril formation and shows that naturally-occurring cyclic peptides have potential as drug leads or molecular probes for understanding fibril formation

Disulfide-rich macrocyclic peptides as templates in drug design

Recently disulfide-rich head-to-tail cyclic peptides have attracted the interest of medicinal chemists owing to their exceptional thermal, chemical and enzymatic stability brought about by their constrained structures. Here we review current trends in the field of peptide-based pharmaceuticals and describe naturally occurring cyclic disulfide-rich peptide scaffolds, discussing their pharmaceutically attractive properties and benefits. We describe how we can utilise these stable frameworks to graft and/or engineer pharmaceutically interesting epitopes to increase their selectivity and bioactivity, opening up new possibilities for addressing ‘difficult’ pharmaceutical targets

Native turncoats and indirect facilitation of species invasions

At local scales, native species can resist invasion by feeding on and competing with would-be invasive species. However, this relationship tends to break down or reverse at larger scales. Here, we consider the role of native species as indirect facilitators of invasion and their potential role in this diversity-driven 'invasion paradox'. We coin the term 'native turncoats' to describe native facilitators of non-native species and identify eight ways they may indirectly facilitate species invasion. Some are commonly documented, while others, such as indirect interactions within competitive communities, are largely undocumented in an invasion context. Therefore, we use models to evaluate the likelihood that these competitive interactions influence invasions. We find that native turncoat effects increase with the number of resources and native species. Furthermore, our findings suggest the existence, abundance and effectiveness of native turncoats in a community could greatly influence invasion success at large scales

Rational design and synthesis of orally bioavailable peptides guided by NMR amide temperature coefficients

Enhancing the oral bioavailability of peptide drug leads is a major challenge in drug design. As such, methods to address this challenge are highly sought after by the pharmaceutical industry. Here, we propose a strategy to identify appropriate amides for N-methylation using temperature coefficients measured by NMR to identify exposed amides in cyclic peptides. N-methylation effectively caps these amides, modifying the overall solvation properties of the peptides and making them more membrane permeable. The approach for identifying sites for N-methylation is a rapid alternative to the elucidation of 3D structures of peptide drug leads, which has been a commonly used structure-guided approach in the past. Five leucine-rich peptide scaffolds are reported with selectively designed N-methylated derivatives. In vitro membrane permeability was assessed by parallel artificial membrane permeability assay and Caco-2 assay. The most promising N-methylated peptide was then tested in vivo. Here we report a novel peptide (15), which displayed an oral bioavailability of 33% in a rat model, thus validating the design approach. We show that this approach can also be used to explain the notable increase in oral bioavailability of a somatostatin analog