High-throughput evaluation of relative cell permeability between peptoids and peptides

Peptides are limited in their use as drugs due to low cell permeability and vulnerability to proteases. In contrast, peptoids are immune to enzymatic degradation and some peptoids have been shown to be relatively cell permeable. In order to facilitate future design of peptoid libraries for screening experiments, it would be useful to have a high-throughput method to estimate the cell permeability of peptoids containing different residues. In this paper, we report the strengths and limitations of a high-throughput cell-based permeability assay that registers the relative ability of steroid-conjugated peptides and peptoids to enter a cell. A comparative investigation of the physicochemical properties and side chain composition of peptoids and peptides is described to explain the observed higher cell permeability of peptoids over peptides. These data suggest that the conversion of the monomeric residues in peptides to an N-alkylglycine moiety in peptoids reduced the hydrogen-bonding potential of the molecules and is the main contributor to the observed permeability improvement.     

Macrocyclization enhances affinity of chemokine-binding peptoids

Peptoids that bind to protein targets can be selected from one-bead-one-compound libraries. Macrocyclization has been often used to increase conformational rigidity and binding affinity in both peptides and peptoids. Here we describe a combined strategy to label and cyclize hexameric peptoid sequences previously identified in a screen against the inflammatory chemokine interleukin-8/CXCL8 that is involved in a number of inflammatory diseases. Cyclization can be performed on-bead in the presence of side-chain protecting groups so that this strategy can be applied to a large variety of sequences. The affinity of the resulting tetramethylrhodamine-labeled macrocyclic peptomers to CXCL8 is increased by at least 1 order of magnitude compared to the original linear sequences.     

Conjugation of a novel Apaf-1 inhibitor to peptide-based cell-membrane transporters: effective methods to improve inhibition of mitochondria-mediated apoptosis

We have identified a family of peptoids that inhibits in vitro the activity of the apoptosome, a macromolecular complex that activates mitochondrial-dependent apoptosis pathways. The analysis of peptide-based cell compatible delivery systems of the most active peptoid is presented. The active peptoid was then fused to cell penetrating peptides (CPP) as penetratin (PEN-peptoid) and HIV-1 TAT (TAT-peptoid). PEN-peptoid showed greater cell viability and as a consequence better efficiency as an apoptosis inhibitor than the TAT-peptoid. The intracellular trafficking of both inhibitors was studied by flow cytometry and confocal fluorescence microscopy. Finally, the influence of the cargo (peptoid) molecules on the conformational behavior of the CPP in buffers and in membrane mimetic environments was analyzed using circular dichroism (CD) spectroscopy.     

Design and conformational analysis of peptoids containing N-hydroxy amides reveals a unique sheet-like secondary structure

N-hydroxy amides can be found in many naturally occurring and synthetic compounds and are known to act as both strong proton donors and chelators of metal cations. We have initiated studies of peptoids, or N-substituted glycines which contain N-hydroxy amide side chains to investigate the potential effects of these functional groups on peptoid backbone amide rotamer equilibria and local conformations. We reasoned that the propensity of these functional groups to participate in hydrogen bonding could be exploited to enforce intramolecular or intermolecular interactions that yield new peptoid structures. Here, we report the design, synthesis, and detailed conformational analysis of a series of model N-hydroxy peptoids. These peptoids were readily synthesized, and their structures were analyzed in solution by 1D and 2D NMR and in the solid-state by X-ray crystallography. The N-hydroxy amides were found to strongly favor trans conformations with respect to the peptoid backbone in chloroform. More notably, unique sheet-like structures held together via intermolecular hydrogen bonds were observed in the X-ray crystal structures of an N-hydroxy amide peptoid dimer, which to our knowledge represent the first structure of this type reported for peptoids. These results suggest that the N-hydroxy amide can be utilized to control both local backbone geometries and longer-range intermolecular interactions in peptoids, and represents a new functional group in the peptoid design toolbox.     

Hydrophobic interactions modulate antimicrobial peptoid selectivity towards anionic lipid membranes

Hydrophobic interactions govern specificity for natural antimicrobial peptides. No such relationship has been established for synthetic peptoids that mimic antimicrobial peptides. Peptoid macrocycles synthesized with five different aromatic groups are investigated by minimum inhibitory and hemolytic concentration assays, epifluorescence microscopy, atomic force microscopy, and X-ray reflectivity. Peptoid hydrophobicity is determined using high performance liquid chromatography. Disruption of bacterial but not eukaryotic lipid membranes is demonstrated on the solid supported lipid bilayers and Langmuir monolayers. X-ray reflectivity studies demonstrate that intercalation of peptoids with zwitterionic or negatively charged lipid membranes is found to be regulated by hydrophobicity. Critical levels of peptoid selectivity are demonstrated and found to be modulated by their hydrophobic groups. It is suggested that peptoids may follow different optimization schemes as compared to their natural analogues.     

Peptoids advance multidisciplinary research and undergraduate education in parallel: Sequence effects on conformation and lipid interactions

Peptoids are versatile peptidomimetic molecules with wide-ranging applications from drug discovery to materials science. An understanding of peptoid sequence features that contribute to both their three-dimensional structures and their interactions with lipids will expand functions of peptoids in varied fields. Furthermore, these topics capture the enthusiasm of undergraduate students who prepare and study diverse peptoids in laboratory coursework and/or in faculty led research. Here, we present the synthesis and study of 21 peptoids with varied functionality, including 19 tripeptoids and 2 longer oligomers. We observed differences in fluorescence spectral features for 10 of the tripeptoids that correlated with peptoid flexibility and relative positioning of chromophores. Interactions of representative peptoids with sonicated glycerophospholipid vesicles were also evaluated using fluorescence spectroscopy. We observed evidence of conformational changes effected by lipids for select peptoids. We also summarize our experiences engaging students in peptoid-based projects to advance both research and undergraduate educational objectives in parallel.     

Improved potency and reduced toxicity of the antifungal peptoid AEC5 through submonomer modification

As proteolytically stable peptidomimetics, peptoids could serve as antifungal agents to supplement a therapeutic field wrought with toxicity issues. We report the improvement of an antifungal peptoid, AEC5, through an iterative structure-activity relationship study. A sarcosine scan was used to first identify the most pharmacophorically important peptoid building blocks of AEC5, followed by sequential optimization of each building block. The optimized antifungal peptoid from this study, β-5, has improved potency towards Cryptococcus neoformans and decreased toxicity towards mammalian cells. For example, the selectivity ratio for C. neoformans over mammalian fibroblasts was improved from 8 for AEC5 to 37 for β-5.     

Peptoids at the 7th Summit: toward macromolecular systems engineering

Methods for facile synthesis of extraordinarily diverse peptide-like oligomers have placed peptoids at the center of a broad and vibrant area of foldamer science and technology. The 7th Peptoid Summit offered a perspective on the current state of peptoid science and technology and on prospects for engineering supramolecular assemblies that rival the complexity of biomolecular systems. Methods for engineering biomolecular systems based on DNA and protein are advancing rapidly, building a technology platform for engineering increasingly large and complex self-assembled nanosystems. A comparative review of the physical basis for DNA, protein, and peptoid engineering indicates that the characteristics of peptoids suit them for a strong role in developing self-assembled nanosystems. Physical parallels between peptoids and proteins indicate that peptoid engineering, like protein engineering, will require specialized software to support design. Access to novel side-chain functionality will enable peptoid designers to exploit novel binding interactions, including many that have been discovered and exploited in crystal engineering, a field that has extensively explored the self-assembly of small organic molecules to form well-ordered structures. Developments in DNA, protein, and inorganic nanotechnologies are converging to provide a technology platform for the design and fabrication of complex, functional, atomically precise nanosystems. Peptoid-based foldamer technologies, can contribute to this convergence, expanding the scope of the emerging field of atomically precise macromolecular nanosystems.     

A VEGFR2 Antagonist and Other Peptoids Evade Immune Recognition

We have recently reported a peptoid (N-alkyl-oligoglycine) molecule that binds to the Vascular Endothelial Growth Factor Receptor 2 (VEGFR2) with high affinity and specificity. Moreover, this peptoid is capable of inhibiting VEGFR2 function in vivo (Udugamasooriya et al. J Am Chem Soc 130:5744–5745, 2008) and thus is a lead compound for anti-angiogenic agents. Moreover, the assay developed to identify this VEGFR2 inhibitor is likely to be a general route to peptoid antagonists or agonists of integral membrane receptors. Therefore, it is important to determine whether the VEGFR2-targeted peptoid, and indeed peptoids in general, are inherently immunogenic since an anti-peptoid immune response would significantly complicate their development as therapeutic candidates. In this study, the VEGFR2-targeted peptoid as well as other peptoids of varying lengths were injected into mice along with an immunostimulatory agent. We demonstrate that no significant anti-peptoid immune response is induced. It is further shown that this is not a trivial result of the lack of immunogenicity of a particular peptoid sequence, since conjugation of the peptoids to carrier proteins such as KLH prior to injection induces a robust anti-peptoid immune response. We conclude that free peptoid molecules are not immunogenic, probably due to a lack of T cell epitopes and that peptoid-based therapeutics are therefore not likely to be hindered by anti-peptoid antibody production in most cases.     

Peptoid architectures: elaboration, actuation, and application

Peptoids are peptidomimetic oligomers composed of N-substituted glycine units. Their convenient synthesis enables strict control over the sequence of highly diverse monomers and is capable of generating extensive compound libraries. Recent studies are beginning to explore the relationship between peptoid sequence, structure and function. We describe new approaches to direct the conformation of the peptoid backbone, leading to secondary structures such as helices, loops, and turns. These advances are enabling the discovery of bioactive peptoids and will establish modules for the design and assembly of protein mimetics.     

Solid-phase submonomer synthesis of peptoid polymers and their self-assembly into highly-ordered nanosheets

Peptoids are a novel class of biomimetic, non-natural, sequence-specific heteropolymers that resist proteolysis, exhibit potent biological activity, and fold into higher order nanostructures. Structurally similar to peptides, peptoids are poly N-substituted glycines, where the side chains are attached to the nitrogen rather than the alpha-carbon. Their ease of synthesis and structural diversity allows testing of basic design principles to drive de novo design and engineering of new biologically-active and nanostructured materials. Here, a simple manual peptoid synthesis protocol is presented that allows the synthesis of long chain polypeptoids (up to 50mers) in excellent yields. Only basic equipment, simple techniques (e.g. liquid transfer, filtration), and commercially available reagents are required, making peptoids an accessible addition to many researchers' toolkits. The peptoid backbone is grown one monomer at a time via the submonomer method which consists of a two-step monomer addition cycle: acylation and displacement. First, bromoacetic acid activated in situ with N,N'-diisopropylcarbodiimide acylates a resin-bound secondary amine. Second, nucleophilic displacement of the bromide by a primary amine follows to introduce the side chain. The two-step cycle is iterated until the desired chain length is reached. The coupling efficiency of this two-step cycle routinely exceeds 98% and enables the synthesis of peptoids as long as 50 residues. Highly tunable, precise and chemically diverse sequences are achievable with the submonomer method as hundreds of readily available primary amines can be directly incorporated. Peptoids are emerging as a versatile biomimetic material for nanobioscience research because of their synthetic flexibility, robustness, and ordering at the atomic level. The folding of a single-chain, amphiphilic, information-rich polypeptoid into a highly-ordered nanosheet was recently demonstrated. This peptoid is a 36-mer that consists of only three different commercially available monomers: hydrophobic, cationic and anionic. The hydrophobic phenylethyl side chains are buried in the nanosheet core whereas the ionic amine and carboxyl side chains align on the hydrophilic faces. The peptoid nanosheets serve as a potential platform for membrane mimetics, protein mimetics, device fabrication, and sensors. Methods for peptoid synthesis, sheet formation, and microscopy imaging are described and provide a simple method to enable future peptoid nanosheet designs.     

Peptoid drug discovery and optimization via surface X-ray scattering

Synthetic polymers mimicking antimicrobial peptides have drawn considerable interest as potential therapeutics. N-substituted glycines, or peptoids, are recognized by their in vivo stability and ease of synthesis. Peptoids are thought to act primarily on the negatively charged lipids that are abundant in bacterial cell membranes. A mechanistic understanding of lipid–peptoid interaction at the molecular level will provide insights for rational design and optimization of peptoids. Here, we highlight recent studies that utilize synchrotron liquid surface X-ray scattering to characterize the underlying peptoid interactions with bacterial and eukaryotic membranes. Cellular membranes are highly complex, and difficult to characterize at the molecular level. Model systems including Langmuir monolayers, are used in these studies to reduce system complexity. The general workflow of these systems and the corresponding data analysis techniques are presented alongside recent findings. These studies investigate the role of peptoid physicochemical characteristics on membrane activity. Specifically, the roles of cationic charge, conformational constraint via macrocyclization, and hydrophobicity are shown to correlate their membrane interactions to biological activities in vitro. These structure–activity relationships have led to new insights into the mechanism of action by peptoid antimicrobials, and suggest optimization strategies for future therapeutics based on peptoids.     

Effects of including an N-terminal insertion region and arginine-mimetic side chains in helical peptoid analogues of lung surfactant protein B

Surfactant protein B (SP-B) is one of two helical, amphipathic proteins critical for the biophysical functioning of lung surfactant (LS) and hence is an important therapeutic protein. This small, complex 79mer has three internal disulfide bonds and homodimerizes via another disulfide bridge. A helical, amphipathic 25mer from the amino terminus (SP-B(1-25)) exhibits surface-active properties similar to those of full-length, synthetic SP-B. In previous work, we created helical, non-natural mimics of SP-B(1-25) based on sequence-specific peptoid 17mers and demonstrated their biomimetic surface activity. Like SP-B(1-25), the peptoids were designed to adopt helical structures with cationic and nonpolar faces. Here, we compare the surface activities of six different helical peptoid analogues of SP-B(1-25) to investigate the importance of mimicking its N-terminal insertion domain as well as its two arginine residues, both thought to be important for the peptide's proper function. Although the peptoid analogues of SP-B(1-25) studied here share many similar features and all functionally mimic SP-B(1-25) to some degree, it is notable that small differences in their sequences and side chain chemistries lead to substantial differences in their observed interactions with a lipid film. A peptoid comprising a hydrophobic, helical insertion region with aromatic side chains shows more biomimetic surface activity than simpler peptoids, and even better activity, by comparison to natural LS, than SP-B(1-25). However, the substitution of lysine-like side chains for arginine-like side chains in the peptoid has little effect on biomimetic surface activity, indicating that interactions of the guanidino groups with lipids may not be critical for the function of these SP-B mimics.     

Osmoprotective polymer additives attenuate the membrane pore‐forming activity of antimicrobial peptoids

Antimicrobial peptides (AMPs) are critical components of the innate immune system and exhibit bactericidal activity against a broad spectrum of bacteria. We investigated the use of N‐substituted glycine peptoid oligomers as AMP mimics with potent antimicrobial activity. The antimicrobial mechanism of action varies among different AMPs, but many of these peptides can penetrate bacterial cell membranes, causing cell lysis. We previously hypothesized that amphiphilic cyclic peptoids may act through a similar pore formation mechanism against methicillin‐resistant Staphylococcus aureus (MRSA). Peptoid‐induced membrane disruption is observed by scanning electron microscopy and results in a loss of membrane integrity. We demonstrate that the antimicrobial activity of the peptoids is attenuated with the addition of polyethylene glycol osmoprotectants, signifying protection from a loss of osmotic balance. This decrease in antimicrobial activity is more significant with larger osmoprotectants, indicating that peptoids form pores with initial diameters of ～2.0–3.8 nm. The initial membrane pores formed by cyclic peptoid hexamers are comparable in diameter to those formed by larger and structurally distinct AMPs. After 24 h, the membrane pores expand to >200 nm in diameter. Together, these results indicate that cyclic peptoids exhibit a mechanism of action that includes effects manifested at the cell membrane of MRSA. © 2014 Wiley Periodicals, Inc. Biopolymers 103: 227–236, 2015.     

Use of the environmentally sensitive fluorophore 4-N,N-dimethylamino-1,8-naphthalimide to study peptoid helix structures

Peptoids, oligomers of N-substituted glycine, have been valuable targets for study and diverse application as peptidomimetics and as nanomaterials. Their conformational heterogeneity has made the study of peptoid structures using high-resolution analyses challenging, limiting our understanding of the physiochemical features that mediate peptoid folding. Here, we introduce a new method for the study of peptoid structure that relies on the environmentally sensitive fluorescence properties of 4-N,N-dimethylamino-1,8-naphthalimide (4-DMN). We have prepared a 4-DMN-functionalized primary amine that is compatible with the traditional submonomer peptoid synthesis methods and incorporated it sequence-specifically into 11 of 13 new peptoids. When included as a peptoid side chain modification, the fluorescence emission intensity of 4-DMN correlates with predictions of the fluorophore's local polarity within a putative structure. 4-DMN fluorescence is maximized when the fluorophore is placed in the middle of the hydrophobic face of an amphiphilic helical peptoid. When the fluorophore is placed near the peptoid terminus or on a polar face of an amphiphilic sequence, 4-DMN fluorescence is diminished. Disruption of the peptoid secondary structure or amphiphilicity also modulates 4-DMN fluorescence. The peptoids' helical secondary structures are moderately disrupted by inclusion of a 4-DMN-modified side chain as evaluated by changes in the peptoids' CD spectral features. This new method for peptoid structure evaluation should be a valuable complement to existing peptoid structural analysis tools.     

Peptoid origins

Peptoid oligomers were initially developed as part of a larger basic research effort to accelerate the drug-discovery process in the biotech/biopharma industry. Their ease of synthesis, stability, and structural similarity to polypeptides made them ideal candidates for the combinatorial discovery of novel peptidomimetic drug candidates. Diverse libraries of short peptoid oligomers provided one of the first demonstrations in the mid-1990s that high-affinity ligands to pharmaceutically relevant receptors could be discovered from combinatorial libraries of synthetic compounds. The solid-phase submonomer method of peptoid synthesis was so efficient and general that it soon became possible to explore the properties of longer polypeptoid chains in a variety of areas beyond drug discovery (e.g., diagnostics, drug delivery, and materials science). Exploration into protein-mimetic materials soon followed, with the fundamental goal of folding a non-natural sequence-specific heteropolymer into defined secondary or tertiary structures. This effort first yielded the peptoid helix and much later the peptoid sheet, both of which are secondary-structure mimetics that are close relatives to their natural counterparts. These crucial discoveries have brought us closer to building proteinlike structure and function from a non-natural polymer and have provided great insight into the rules governing polymer and protein folding. The accessibility of peptoid synthesis to chemists and nonchemists alike, along with a lack of information-rich non-natural polymers available to study, has led to a rapid growth in the field of peptoid science by many new investigators. This work provides an overview of the initial discovery and early developments in the peptoid field.