First vertebrate BRICHOS antimicrobial peptides: ß-hairpin host defense peptides in limbless amphibia lung resemble those of marine worms.

Innate immunity of invertebrates offers potent antimicrobial peptides (AMPs) against drug-resistant infections. To identify new worm ß-hairpin AMPs, we explored the sequence diversity of proteins with a BRICHOS domain, which comprises worm AMP precursors. Strikingly, we discovered new BRICHOS AMPs not in worms, but in caecilians, the least studied clade of vertebrates. Two precursor proteins from Microcaecilia unicolor and Rhinatrema bivittatum resemble SP-C lung surfactants and bear worm AMP-like peptides at C-termini. The analysis of M. unicolor tissue transcriptomes shows that the AMP precursor is highly expressed in the lung along with regular SP-C, suggesting a different, protective function. The peptides form right-twisted ß-hairpins, change conformation upon lipid binding, and rapidly disrupt bacterial membranes. Both peptides exhibit broad-spectrum activity against multidrug-resistant ESKAPE pathogens with 1-4 µM MICs and remarkably low toxicity, giving 40-70-fold selectivity towards bacteria. These BRICHOS AMPs, previously unseen in vertebrates, reveal a novel lung innate immunity mechanism and offer a promising antibiotics template.

Design of Functional Globular ß-Sheet Miniproteins.

The design of discrete ß-sheet peptides is far less advanced than e. g. the design of α-helical peptides. The reputation of ß-sheet peptides as being poorly soluble and aggregation-prone often hinders active design efforts. Here, we show that this reputation is unfounded. We demonstrate this by looking at the ß-hairpin and WW domain. Their structure and folding have been extensively studied and they have long served as model systems to investigate protein folding and folding kinetics. The resulting fundamental understanding has led to the development of hyperstable ß-sheet scaffolds that fold at temperatures of 100 °C or high concentrations of denaturants. These have been used to design functional miniproteins with protein or nucleic acid binding properties, in some cases with such success that medical applications are conceivable. The ß-sheet scaffolds are not always completely rigid, but can be specifically designed to respond to changes in pH, redox potential or presence of metal ions. Some engineered ß-sheet peptides also exhibit catalytic properties, although not comparable to those of natural proteins. Previous reviews have focused on the design of stably folded and non-aggregating ß-sheet sequences. In our review, we now also address design strategies to obtain functional miniproteins from ß-sheet folding motifs.

A turn for the worse: Aß ß-hairpins in Alzheimer's disease.

Amyloid-ß (Aß) oligomers are a cause of neurodegeneration in Alzheimer's disease (AD). These soluble aggregates of the Aß peptide have proven difficult to study due to their inherent metastability and heterogeneity. Strategies to isolate and stabilize homogenous Aß oligomer populations have emerged such as mutations, covalent cross-linking, and protein fusions. These strategies along with molecular dynamics simulations have provided a variety of proposed structures of Aß oligomers, many of which consist of molecules of Aß in ß-hairpin conformations. ß-Hairpins are intramolecular antiparallel ß-sheets composed of two ß-strands connected by a loop or turn. Three decades of research suggests that Aß peptides form several different ß-hairpin conformations, some of which are building blocks of toxic Aß oligomers. The insights from these studies are currently being used to design anti-Aß antibodies and vaccines to treat AD. Research suggests that antibody therapies designed to target oligomeric Aß may be more successful at treating AD than antibodies designed to target linear epitopes of Aß or fibrillar Aß. Aß ß-hairpins are good epitopes to use in antibody development to selectively target oligomeric Aß. This review summarizes the research on ß-hairpins in Aß peptides and discusses the relevance of this conformation in AD pathogenesis and drug development.

Mechanism of ß-hairpin formation in AzoChignolin and Chignolin.

AzoChignolin is a photoswitchable variant of the mini-protein Chignolin with an azobenzene (AMPP) replacing the central loop. AzoChignolin is unfolded with AMPP in the trans-isomer. Transition to the cis-isomer causes ß-hairpin folding similar to Chignolin. The AzoChignolin system is excellently suited for comprehensive analysis of folding nucleation kinetics. Utilizing multiple long-time MD simulations of AzoChignolin and Chignolin in MeOH and water, we estimated Markov models to examine folding kinetics of both peptides. We show that while AzoChignolin mimics Chignolin's structure well, the folding kinetics are quite different. Not only folding times but also intermediate states differ, particularly Chignolin is able to fold in MeOH into an α-helical intermediate which is impossible to form in AzoChignolin. The Markov models demonstrate that AzoChignolin's kinetics are generally faster, specifically when comparing the two main microfolding processes of hydrophobic collapse and turn formation. Photoswitchable loops are used frequently to understand the kinetics of elementary protein folding nucleation. However, our results indicate that intermediates and folding kinetics may differ between natural loops and photoswitchable variants.

Coupled folding-upon-binding of human tumor suppressor MIG6 to lung cancer EGFR kinase domain and molecular trimming/stapling of MIG6-derived ß-hairpins to target the coupling event.

Human epidermal growth factor receptor (EGFR) is involved in strong association with malignant proliferation, which has been shown to play a central role in the development and progression of non-small cell lung cancer and other solid tumors. The tumor-suppressor protein MIG6 is a negative regulator of EGFR kinase activity by binding at the activation interface of asymmetric dimer of EGFR kinase domain to disrupt EGFR dimerization and then inactivate the kinase. The protein adopts two discrete fragments 1 and 2 to directly interact with EGFR. It is revealed that the MIG6 fragment 2 is intrinsically disordered in free unbound state, but would fold into a well-structured ß-hairpin when binding to EGFR, thus characterized by a so-called coupled folding-upon-binding process, which can be regarded as a compromise between favorable direct readout and unfavorable indirect readout. Here, a 23-mer F2P peptide was derived from MIG6 fragment 2, trimmed into a 17-mer tF2P peptide that contains the binding hotspot region of the fragment 2, and then constrained with an ordered hairpin conformation in free unbound state by disulfide stapling, finally resulting in a rationally stapled/trimmed stF2P peptide that largely minimizes the unfavorable indirect readout effect upon its binding to EGFR kinase domain, with affinity improved considerably upon the trimming and stapling/trimming. These rationally designed ß-hairpin peptides may be further exploited as potent anti-lung cancer agents to target the activation event of EGFR dimerization.

Incorporating a ß-hairpin sequence motif to increase intracellular stability of a peptide-based PROTAC.

Proteolysis targeting chimeras (PROTACs) have emerged as a new class of therapeutics that utilize the ubiquitin-proteasome system (UPS) to facilitate proteasomal degradation of "undruggable" targets. Peptide-based PROTACs contain three essential components: a binding motif for the target protein, a short amino acid sequence recognized by an E3 ligase called a degron, and a cell penetrating peptide to facilitate uptake into intact cells. While peptide-based PROTACs have been shown to successfully degrade numerous targets, they have often been found to exhibit low cell permeability and high protease susceptibility. Prior work identified peptides containing a ß-hairpin sequence motif that function not only as protecting elements, but also as CPPs and degrons. The goal of this study was to investigate if a ß-hairpin sequence could replace commonly used unstructured peptides sequences as the degron and the CPP needed for PROTAC uptake and function. The degradation of the protein Tau was selected as a model system as several published works have identified a Tau binding element that could easily be conjugated to the ß-hairpin sequence. A series of time- and concentration-dependent studies confirmed that the ßhairpin sequence was an adequate alternative CPP and degron to facilitate the proteasomemediated degradation of Tau. Microscopy studies confirmed the time-dependent uptake of the PROTAC and a degradation assay confirmed that the ß-hairpin conjugated PROTAC had a greater lifetime in cells.

Unlocking the Potential of the Antimicrobial Peptide Gomesin: From Discovery and Structure-Activity Relationships to Therapeutic Applications.

Gomesin is a cationic antimicrobial peptide which is isolated from the haemocytes of the Brazilian tarantula Acanthoscurria gomesiana and can be produced chemically by Fmoc solid-phase peptide synthesis. Gomesin exhibits a range of biological activities, as demonstrated by its toxicity against therapeutically relevant pathogens such as Gram-positive or Gram-negative bacteria, fungi, cancer cells, and parasites. In recent years, a cyclic version of gomesin has been used for drug design and development as it is more stable than native gomesin in human serum and can penetrate and enter cancer cells. It can therefore interact with intracellular targets and has the potential to be developed as a drug lead for to treat cancer, infectious diseases, and other human diseases. This review provides a perspective on the discovery, structure-activity relationships, mechanism of action, biological activity, and potential clinical applications of gomesin.

Nucleation of α-Synuclein Amyloid Fibrils Induced by Cross-Interaction with ß-Hairpin Peptides Derived from Immunoglobulin Light Chains.

Heterologous interactions between different amyloid-forming proteins, also called cross-interactions, may have a critical impact on disease-related amyloid formation. ß-hairpin conformers of amyloid-forming proteins have been shown to affect homologous interactions in the amyloid self-assembly process. Here, we applied two ß-hairpin-forming peptides derived from immunoglobulin light chains as models to test how heterologous ß-hairpins modulate the fibril formation of Parkinson's disease-associated protein α-synuclein (αSyn). The peptides SMAhp and LENhp comprise ß-strands C and C' of the κ4 antibodies SMA and LEN, which are associated with light chain amyloidosis and multiple myeloma, respectively. SMAhp and LENhp bind with high affinity to the ß-hairpin-binding protein ß-wrapin AS10 according to isothermal titration calorimetry and NMR spectroscopy. The addition of SMAhp and LENhp affects the kinetics of αSyn aggregation monitored by Thioflavin T (ThT) fluorescence, with the effect depending on assay conditions, salt concentration, and the applied ß-hairpin peptide. In the absence of agitation, substoichiometric concentrations of the hairpin peptides strongly reduce the lag time of αSyn aggregation, suggesting that they support the nucleation of αSyn amyloid fibrils. The effect is also observed for the aggregation of αSyn fragments lacking the N-terminus or the C-terminus, indicating that the promotion of nucleation involves the interaction of hairpin peptides with the hydrophobic non-amyloid-ß component (NAC) region.

Diagonal Interactions between Glutamate and Arginine Analogs with Varying Side-Chain Lengths in a ß-Hairpin.

Cross-strand interactions are important for the stability of ß-sheet structures. Accordingly, cross-strand diagonal interactions between glutamate and arginine analogs with varying side-chain lengths were studied in a series of ß-hairpin peptides. The peptides were analyzed by homonuclear two-dimensional nuclear magnetic resonance methods. The fraction folded population and folding free energy of the peptides were derived from the chemical shift data. The fraction folded population trends could be rationalized using the strand propensity of the constituting residues, which was not the case for the peptides with lysine analogs, highlighting the difference between the arginine analogs and lysine analogs. Double-mutant cycle analysis was used to derive the diagonal ion-pairing interaction energetics. The most stabilizing diagonal cross-strand interaction was between the shortest residues (i.e., Asp2-Agp9), most likely due to the least side-chain conformational penalty for ion-pair formation. The diagonal interaction energetics in this study involving the arginine analogs appears to be consistent with and extend beyond our understanding of diagonal ion-pairing interactions involving lysine analogs. The results should be useful for designing ß-strand-containing molecules to affect biological processes such as amyloid formation and protein-protein interactions.

Exploiting the Innate Plasticity of the Programmed Cell Death-1 (PD1) Receptor to Design Pembrolizumab H3 Loop Mimics.

Checkpoint blockade of the immunoreceptor programmed cell death-1 (PD1) with its ligand-1 (PDL1) by monoclonal antibodies such as pembrolizumab provided compelling clinical results in various cancer types, yet the molecular mechanism by which this drug blocks the PD1/PDL1 interface remains unclear. To address this question, we examined the conformational motion of PD1 associated with the binding of pembrolizumab. Our results revealed that the innate plasticity of both C'D and FG loops is crucial to form a deep binding groove (371 Å3 ) across several distant epitopes of PD1. This analysis ultimately provided a rational-design to create pembrolizumab H3 loop mimics [RDYRFDMGFD] into ß-hairpin scaffolds. As a result, a 20-residue long ß-hairpin peptide 1 e was identified as a first-in-class potent PD1-inhibitor (EC50 of 0.29 µM; Ki of 41 nM).

In silico folding of hydrophobic peptides that form ß-hairpin structures in solution.

Peptides designed with residues that have a high propensity to occur in ß-turns form ß-hairpin structures in apolar as well as in polar organic solvents such as dimethyl sulfoxide (DMSO). Due to limited solubility, their conformations have not been investigated experimentally in water. We have examined the conformations of four of such designed peptides that fold into well-defined ß-hairpin structures facilitated by ß-turns, in the crystalline state and in solution, by molecular dynamics simulations (MDS). The peptides folded into ß-hairpin structures in water, starting from the fully extended conformation. However, in DMSO, neither folding nor unfolding was observed during MDS, when the starting structures were unfolded and folded, respectively. The lack of folding in DMSO was investigated by constructing folding free energy landscapes by umbrella sampling. The folding free energy landscape is smooth in water, whereas in DMSO, folded and unfolded structures are separated by high-energy barriers. The folding free energy is less in DMSO compared with water due to a more stable unfolded structure in DMSO compared with water, which in turn is due to stabilisation of the unfolded state by hydrophobic interactions in DMSO. This finding will be helpful to researchers to accurately model and/or design small peptide structures in water and organic solvents.

A Novel ß-Hairpin Peptide Z-d14CFR Enhances Multidrug-Resistant Bacterial Clearance in a Murine Model of Mastitis.

The widespread prevalence of antimicrobial resistance has spawned the development of novel antimicrobial agents. Antimicrobial peptides (AMPs) have gained comprehensive attention as one of the major alternatives to antibiotics. However, low antibacterial activity and high-cost production have limited the applications of natural AMPs. In this study, we successfully expressed recombinant Zophobas atratus (Z. atratus) defensin for the first time. In order to increase the antimicrobial activity of peptide, we designed 5 analogues derived from Z. atratus defensin, Z-d13, Z-d14C, Z-d14CF, Z-d14CR and Z-d14CFR. Our results showed that Z-d14CFR (RGCRCNSKSFCVCR-NH2) exhibited a broad-spectrum antimicrobial activity to both Gram-positive bacteria and Gram-negative bacteria, including multidrug-resistant bacteria. It possessed less than 5% hemolysis and 10% cytotoxicity, even at a high concentration of 1 mg/mL. Antimicrobial mechanism studies indicated that Z-d14CFR performed antimicrobial effect via inhibiting biofilm formation, disrupting bacterial membrane integrity and inducing cellular contents release. Furthermore, Z-d14CFR showed a great therapeutic effect on the treatment of multidrug-resistant Escherichia coli (E. coli) infection by enhancing bacterial clearance, decreasing neutrophils infiltration and the expression of tumor necrosis factor-alpha (TNF-α) and interleukin-1 beta (IL-1ß) in a murine model of mastitis. Our findings suggest that Z-d14CFR could be a promising candidate against multidrug-resistant bacteria.

The Effects of Charged Amino Acid Side-Chain Length on Diagonal Cross-Strand Interactions between Carboxylate- and Ammonium-Containing Residues in a ß-Hairpin.

The ß-sheet is one of the common protein secondary structures, and the aberrant aggregation of ß-sheets is implicated in various neurodegenerative diseases. Cross-strand interactions are an important determinant of ß-sheet stability. Accordingly, both diagonal and lateral cross-strand interactions have been studied. Surprisingly, diagonal cross-strand ion-pairing interactions have yet to be investigated. Herein, we present a systematic study on the effects of charged amino acid side-chain length on a diagonal ion-pairing interaction between carboxylate- and ammonium-containing residues in a ß-hairpin. To this end, 2D-NMR was used to investigate the conformation of the peptides. The fraction folded population and the folding free energy were derived from the chemical shift data. The fraction folded population for these peptides with potential diagonal ion pairs was mostly lower compared to the corresponding peptide with a potential lateral ion pair. The diagonal ion-pairing interaction energy was derived using double mutant cycle analysis. The Asp2-Dab9 (Asp: one methylene; Dab: two methylenes) interaction was the most stabilizing (-0.79 ± 0.14 kcal/mol), most likely representing an optimal balance between the entropic penalty to enable the ion-pairing interaction and the number of side-chain conformations that can accommodate the interaction. These results should be useful for designing ß-sheet containing molecular entities for various applications.

The ß-hairpin from the Thermus thermophilus HB27 laccase works as a pH-dependent switch to regulate laccase activity.

The multi-copper oxidase from the hyper-thermophilic bacteria Thermus thermophilus (Tth-MCO), has been previously characterized and described as an example of a laccase with low catalytic properties, especially when it is compared with the activity of fungal laccases, but it is active at high temperatures. Structurally, Tth-MCO has a unique feature: a ß-hairpin near the T1Cu site, which is not present in any other laccases deposited at the PDB. This ß-hairpin has an expected crystallographic behavior in solvent-exposed areas of a crystallized protein: lack of electron density, high B-values and several crystalline contacts with neighboring crystallographic copies; however, its dynamical behavior in solution and its biological implications have not been described. Here, we describe four new Tth-MCO crystallographic structures, and the ß-hairpin behavior has been analyzed by molecular dynamics simulations, considering the effect of pH and temperature. The ß-hairpin new crystallographic conformations described here, together with their dynamics, were used to understand the pH-restrained laccase activity of Tth-MCO against substrates as syringaldazine. Remarkably, there are insertions in laccases from Thermus and Meiothermus genus, sharing the same position and a methionine-rich composition of the Tth-MCO ß-hairpin. This unique high methionine content of the Tth-MCO ß-hairpin is responsible to coordinate, Ag+1 and Hg+1 in oxidative conditions, but Cu+1 and Cu+2 are not coordinated in crystallographic experiments, regardless of the redox conditions; however, Ag+1 addition does not affect Tth-MCO laccase activity against syringaldazine. Here, we propose that the pH-dependent ß-hairpin dynamical behavior could explain, at least in part, the inefficient laccase activity displayed by Tth-MCO in acidic pH values.

Cross-Strand Interaction, Central Bending, and Sequence Pattern Act as Biomodulators of Simplified ß-Hairpin Antimicrobial Amphiphiles.

Novel antimicrobial peptides (AMPs) have revolutionarily evolved into formidable candidates for antibiotic substitute materials against pathogenic infections. However, cost, lability, disorderly sequences, systemic toxicology, and biological profiles have plagued the perennial search. Here, a progressive ß-hairpin solution with the simplest formulation is implanted into an AMP-based therapeutic strategy to systematically reveal the complex balance between function and toxicity of structural moieties, including cationicity, hydrophobicity, cross-strand interactions, center bending, and sequence pattern. Comprehensive implementation of structural identification, ten microorganisms, eleven in vitro barriers, four mammalian cells, and a diversified membrane operation setup led to the emergence of ß-hairpin prototypes from a 24-member library. Lead amphiphiles, WKF-PG and WRF-NG, can tackle bacterial infection through direct antimicrobial efficacy and potential inflammation-limiting capabilities, such as an Escherichia coli challenge in a mouse peritonitis-sepsis model, without observed toxicity after systemic administration. Their optimal states with dissimilar modulators and the unavailable drug resistance related to membrane lytic mechanisms, also provide an usher for renewed innovation among ß-sheet peptide-based antimicrobial biomaterials.

Comparisons of ß-Hairpin Propensity Among Peptides with Homochiral or Heterochiral Strands.

Assemblies of racemic ß-sheet-forming peptides have attracted attention for biomedical applications because racemic forms of peptides can self-associate more avidly than do single enantiomers. In 1953, Pauling and Corey proposed "rippled ß-sheet" modes of H-bond-mediated interstrand assembly for alternating L- and D-peptide strands; this structural hypothesis was complementary to their proposal of "pleated ß-sheet" assembly for L-peptides. Although no high-resolution structure has been reported for a rippled ß-sheet, there is strong evidence for the occurrence of rippled ß-sheets in some racemic peptide assemblies. Here we compare propensities of peptide diastereomers in aqueous solution to form a minimum increment of ß-sheet in which two antiparallel strands associate. ß-Hairpin folding is observed for homochiral peptides with aligned nonpolar side chains, but no ß-hairpin population can be detected for diastereomers in which one strand contains L residues and the other contains D residues. These observations suggest that rippled ß-sheet assemblies are stabilized by interactions between ß-sheet layers rather than interactions within these layers.

Longer charged amino acids favor ß-strand formation in hairpin peptides.

Interactions between charged amino acids significantly influence the structure and function of proteins. The encoded charged amino acids Asp, Glu, Arg, and Lys have different number of hydrophobic methylenes linking the backbone to the charged functionality. It remains to be fully understood how does this difference in the number of methylenes affect protein structure stability. Protein secondary structures are the fundamental three-dimensional building blocks of protein structures. ß-Sheet structures are particularly interesting, because these structures have been associated with a number of protein misfolding diseases. Herein, we report the effect of charged amino acid side chain length at two ß-strand positions individually on the stability of a ß-hairpin. The charged amino acids include side chains with a carboxylate, an ammonium, or a guanidinium group. The experimental peptides, fully folded reference peptides, and fully unfolded reference peptides were synthesized by solid phase peptide synthesis and analyzed by 2D NMR methods including TOCSY, DQF-COSY, and ROESY. Sequence specific assignments were performed for all peptides. The chemical shift data were used to derive the fraction folded population and the folding free energy for the experimental peptides. Results showed that the fraction folded population increased with increasing charged amino acid side chain length. These results should be useful for developing functional peptides that adopt the ß-conformation.

A novel ß-hairpin peptide derived from the ARC repressor selectively interacts with the major groove of B-DNA.

Transcription factors (TFs) have a remarkable role in the homeostasis of the organisms and there is a growing interest in how they recognize and interact with specific DNA sequences. TFs recognize DNA using a variety of structural motifs. Among those, the ribbon-helix-helix (RHH) proteins, exemplified by the MetJ and ARC repressors, form dimers that insert antiparallel ß-sheets into the major groove of DNA. A great chemical challenge consists of using the principles of DNA recognition by TFs to design minimized peptides that maintain the DNA affinity and specificity characteristics of the natural counterparts. In this context, a peptide mimic of an antiparallel ß-sheet is very attractive since it can be obtained by a single peptide chain folding in a ß-hairpin structure and can be as short as 14 amino acids or less. Herein, we designed eight linear and two cyclic dodeca-peptides endowed with ß-hairpins. Their DNA binding properties have been investigated using fluorescence spectroscopy together with the conformational analysis through circular dichroism and solution NMR. We found that one of our peptides, peptide 6, is able to bind DNA, albeit without sequence selectivity. Notably, it shows a topological selectivity for the major groove of the DNA which is the interaction site of ARC and many other DNA-binding proteins. Moreover, we found that a type I' ß-hairpin folding pattern is a favorite peptide structure for interaction with the B-DNA major groove. Peptide 6 is a valuable lead compound for the development of novel analogs with sequence selectivity.

De novo design of a pH-triggered self-assembled ß-hairpin nanopeptide with the dual biological functions for antibacterial and entrapment.

BACKGROUND: Acid-tolerant enteric pathogens can evade small intestinal acid barriers, colonize and infect the intestinal tract. However, broad-spectrum antibiotics are not the best therapeutic strategy because of the disruption of intestinal flora caused by its indiscriminate antimicrobial activity against beneficial and harmful bacteria. So that is what inspired us to combine pH regulation with nanotechnology to develop a pH-triggered site-targeted antimicrobial peptide with entrapping function. RESULTS: A pH-triggered dual biological functional self-assembled peptide (SAP) was designed according to the features of amino-acid building blocks and the diagonal cation-π interaction principle. The results of characterization experiments showed that changes in pH conditions could trigger microstructural transformation of the nanopeptide from nanospheres to nanofibers. The subsequent antibacterial and toxicity experiments determined that SAP had great antimicrobial activity against Escherichia coli, Salmonella typhimurium, Listeria monocytogenes, and Bacillus cereus above 15.6 µg/mL under acidic conditions by disrupting bacterial membrane integrity, excellent biocompatibility in vitro even at 250 µg/mL and high tolerance in physical environment. Moreover, at peptide concentrations greater than 62.5 µg/mL, SAP showed the entrapment property, which played an important role in phagocytic clearance in infection forces. Meanwhile, the in vivo results revealed that SAP possessed excellent therapeutic effect and good biosafety. CONCLUSIONS: Our study revealed the antibacterial activity of a short ß-hairpin forming self-assembled peptide, and established an innovative design strategy for peptide-based nanomaterials and a new treatment strategy for gastrointestinal bacterial infections.

Swapping the Positions in a Cross-Strand Lateral Ion-Pairing Interaction between Ammonium- and Carboxylate-Containing Residues in a ß-Hairpin.

Cross-strand lateral ion-pairing interactions are important for antiparallel ß-sheet stability. Statistical studies suggested that swapping the position of cross-strand lateral residues should not significantly affect the interaction. Herein, we swapped the position of ammonium- and carboxylate-containing residues with different side-chain lengths in a cross-strand lateral ion-pairing interaction in a ß-hairpin. The peptides were analyzed by 2D-NMR. The fraction folded population and folding free energy were derived from the chemical shift data. The ion-pairing interaction energy was derived using double mutant cycle analysis. The general trends for the fraction folded population and interaction energetics remained similar upon swapping the position of the interacting charged residues. The most stabilizing cross-strand interactions were between short residues, similar to the unswapped study. However, the fraction folded populations for most of the swapped peptides were higher compared to the corresponding unswapped peptides. Furthermore, subtle differences in the ion-pairing interaction energy upon swapping were observed, most likely due to the "unleveled" relative positioning of the interacting residues created by the inherent right-handed twist of the structure. These results should be useful for developing functional peptides that rely on lateral ion-pairing interactions across antiparallel ß-strands.