Atomic force spectroscopy with magainin 1 functionalized tips and biomimetic supported lipid membranes.

Antimicrobial peptides are molecules synthesized by living organisms as the first line of defense against bacteria, fungi, parasites, or viruses. Since their biological activity is based on destabilization of the microbial membranes, a study of direct interaction forces between antimicrobial peptides and biomimetic membranes is very important for understanding the molecular mechanisms of their action. Herein, we use atomic force spectroscopy to probe the interaction between atomic force microscopy (AFM) tips functionalized with magainin 1 and supported lipid bilayers (SLBs) mimicking electrically uncharged membranes of normal eukaryotic cells and negatively charged membranes of bacterial cells. The investigations performed on negatively charged SLBs showed that the magainin 1 functionalized AFM tips are quickly adsorbed into the SLBs when they approach, while they adhere strongly to the lipid membrane when retracted. On contrary, same investigations performed on neutral SLBs showed mechanical resistance of the lipid membrane to the tip breakthrough and negligible adhesion force at detachment.

Nanoscale Probing of Informational Polymers with Nanopores. Applications to Amyloidogenic Fragments, Peptides, and DNA-PNA Hybrids.

The decades long advances in nanotechnology, biomolecular sciences, and protein engineering ushered the introduction of groundbreaking technologies devoted to understanding how matter behaves at single particle level. Arguably, one of the simplest in concept is the nanopore-based paradigm, with deep roots in what is originally known as the Coulter counter, resistive-pulse technique. Historically, a nanopore system comprising the oligomeric protein generated by Staphylococcus aureus toxin α-hemolysin (α-HL) was first applied to detecting polynucleotides, as revealed in 1996 by John J. Kasianowicz, Eric Brandin, Daniel Branton, and David W. Deamer, in the Proceedings of the National Academy of Sciences. Nowadays, a wide variety of other solid-state or protein-based nanopores have emerged as efficient tools for stochastic sensing of analytes as small as single metal ions, handling single molecules, or real-time, label-free probing of chemical reactions at single-molecule level. In this Account, we demonstrate the usefulness of the α-HL nanopore on probing metal-induced folding of peptides, and to investigating the reversible binding of various metals to physiologically relevant amyloid fragments. The widely recognized Achilles heel of the approach, is the relatively short dwell time of the analytes inside the nanopore. This hinders the collection of sufficient data required to infer statistically meaningful conclusions about the physical or chemical state of the studied analyte. To mitigate this, various approaches were successfully applied in particular experiments, including but not restricted to altering physical parameters of the aqueous solution, downsizing the nanopore geometry, the controlled tuning of the balance between the electrostatic and electro-osmotic forces, coating nanopores with a fluid lipid bilayer, employing a pressure-voltage biased pore. From our perspective, in this Account, we will present two strategies aimed at controlling the analyte passage across the α-HL. First, we will reveal how the electroosmotic flow can be harnessed to control residence time, direction, and the sequence of spatiotemporal dynamics of a single peptide along the nanopore. This also allows one to identify the mesoscopic trajectory of a peptide exiting the nanopore through either the vestibule or ß-barrel moiety. Second, we lay out the principles of an approach dubbed "nanopore tweezing", enabling simultaneous capture rate increase and escape rate decrease of a peptide from the α-HL, with the applied voltage. At its core, this method requires the creation of an electrical dipole on the peptide under study, via engineering positive and negative amino acid residues at the two ends of the peptide. Concise applications of this approach are being demonstrated, as in proof-of-concept experiments we probed the primary structure exploration of polypeptides, via discrimination between selected neutral amino acid residues. Another useful venue provided by the nanopores is represented by single-molecule force experiments on captured analytes inside the nanopore, which proved useful in exploring force-induced rupture of nucleic acids duplexes, hairpins, or various nucleic acids-ligand conjugates. We will show that when applied to oppositely charged, polypeptide-functionalized PNA-DNA duplexes, the nanopore tweezing introduces a new generation of force-spectroscopy nanopore-based platforms, facilitating unzipping of a captured duplex and enabling the duplex hybridization energy estimation.

The penetrating properties of the tumor homing peptide LyP-1 in model lipid membranes.

Cell-penetrating peptides (CPPs) have the property to cross the plasma membrane and enhance its permeability. CPPs were successfully used to deliver numerous cargoes such as drugs, proteins, nucleic acids, imaging and radiotherapeutic agents, gold and magnetic nanoparticles, or liposomes inside cells. Although CPPs were intensively investigated over the past 20 years, the exact molecular mechanisms of translocation across membranes are still controversial and vary from passive to active mechanisms. LyP-1 is a cyclic 9-amino-acids homing peptide that specifically binds to p32 receptors overexpressed in tumor cells. tLyP-1 peptide is the linear truncated form of LyP-1 and recognizes neuropilin (NRP) receptors expressed in glioma tumor tissue. Here, we investigate the interaction of the cyclic LyP-1 peptide and linear truncated tLyP-1 peptide with model plasma membrane in order to understand their passive, energy-independent mechanism of uptake. The experiments reveal that internalization of tLyP-1 peptides depends on membrane lipid composition. Inclusion of negatively charged phosphatidylserine (PS) or cone-shaped phosphatidylethanolamine (PE) lipids in the composition of giant unilamellar vesicles facilitates the membrane adsorption and direct penetration but without inducing pore formation in membranes. In contrast, cyclic LyP-1 peptide mostly accumulates on the membrane, with very low internalization, regardless of the lipid composition. Thus, the linear tLyP-1 peptide has enhanced penetrating properties compared with the cyclic LyP-1 peptide. Development of a mutant peptide containing higher number of arginine amino acids and preserving the homing properties of tLyP-1 may be a solution for new permeable peptides that facilitate the internalization in cells and further the endosomal escape as well.

Single-Molecule, Real-Time Dissecting of Peptide Nucleic Acid-DNA Duplexes with a Protein Nanopore Tweezer.

Peptide nucleic acids (PNAs) are artificial, oligonucleotides analogues, where the sugar-phosphate backbone has been substituted with a peptide-like N-(2-aminoethyl)glycine backbone. Because of their inherent benefits, such as increased stability and enhanced binding affinity toward DNA or RNA substrates, PNAs are intensively studied and considered beneficial for the fields of materials and nanotechnology science. Herein, we designed cationic polypeptide-functionalized, 10-mer PNAs, and demonstrated the feasible detection of hybridization with short, complementary DNA substrates, following analytes interaction with the vestibule entry of an α-hemolysin (α-HL) nanopore. The opposite charged state at the polypeptide-functionalized PNA-DNA duplex extremities, facilitated unzipping of a captured duplex at the lumen entry of a voltage-biased nanopore, followed by monomers threading. These processes were resolvable and identifiable in real-time, from the temporal profile of the ionic current through a nanopore accompanying conformational changes of a single PNA-DNA duplex inside the α-HL nanopore. By employing a kinetic description within the discrete Markov chains theory, we proposed a minimalist kinetic model to successfully describe the electric force-induced strand separation in the duplex. The distinct interactions of the duplex at either end of the nanopore present powerful opportunities for introducing new generations of force-spectroscopy nanopore-based platforms, enabling from the same experiment duplex detection and assessment of interstrand base pairing energy.

Nanoscale Investigation of Generation 1 PAMAM Dendrimers Interaction with a Protein Nanopore.

Herein, we describe at uni-molecular level the interactions between poly(amidoamine) (PAMAM) dendrimers of generation 1 and the α-hemolysin protein nanopore, at acidic and neutral pH, and ionic strengths of 0.5 M and 1 M KCl, via single-molecule electrical recordings. The results indicate that kinetics of dendrimer-α-hemolysin reversible interactions is faster at neutral as compared to acidic pH, and we propose as a putative explanation the fine interplay among conformational and rigidity changes on the dendrimer structure, and the ionization state of the dendrimer and the α-hemolysin. From the analysis of the dendrimer's residence time inside the nanopore, we posit that the pH- and salt-dependent, long-range electrostatic interactions experienced by the dendrimer inside the ion-selective α-hemolysin, induce a non-Stokesian diffusive behavior of the analyte inside the nanopore. We also show that the ability of dendrimer molecules to adapt their structure to nanoscopic spaces, and control the flow of matter through the α-hemolysin nanopore, depends non-trivially on the pH- and salt-induced conformational changes of the dendrimer.

A Protein Nanopore-Based Approach for Bacteria Sensing.

We present herein a first proof of concept demonstrating the potential of a protein nanopore-based technique for real-time detection of selected Gram-negative bacteria (Pseudomonas aeruginosa or Escherichia coli) at a concentration of 1.2 × 108 cfu/mL. The anionic charge on the bacterial outer membrane promotes the electrophoretically driven migration of bacteria towards a single α-hemolysin nanopore isolated in a lipid bilayer, clamped at a negative electric potential, and followed by capture at the nanopore's mouth, which we found to be described according to the classical Kramers' theory. By using a specific antimicrobial peptide as a putative molecular biorecognition element for the bacteria used herein, we suggest that the detection system can combine the natural sensitivity of the nanopore-based sensing techniques with selective biological recognition, in aqueous samples, and highlight the feasibility of the nanopore-based platform to provide portable, sensitive analysis and monitoring of bacterial pathogens.

Stochastic adhesion of hydroxylated atomic force microscopy tips to supported lipid bilayers.

This work reports results of an atomic force microscopy (AFM) study of adhesion force between hydroxylated AFM tips and supported lipid bilayers (SLBs) of phosphatidylcholine in phosphate buffer saline solution at neutral pH. Silicon nitride AFM probes were hydroxylated by treatment in water vapor plasma and used in force spectroscopy measurements of adhesion force on SLBs with control of contact loading force and residence time. The measurements showed a stochastic behavior of adhesion force that was attributed to stochastic formation of hydrogen bonds between the hydroxyl groups on the AFM tip and oxygen atoms from the phosphate groups of the phosphatidylcholine molecules. Analysis of a large number of force curves revealed a very low probability of hydrogen bond formation, a probability that increased with the increase of contact loading force and residence time. The variance and mean values of adhesion force showed a linear dependence on each other, which indicated that hydrogen bond formation obeyed the Poisson distribution of probability. This allowed for the quantitative determination of the rupture force per hydrogen bond of about 40 pN and showed the absence of other nonspecific interaction forces.

Bimodal effects of cinnamaldehyde and camphor on mouse TRPA1.

TRPA1 is a nonselective cation channel activated by a wide variety of noxious chemicals. Intriguingly, several TRPA1 modulators induce a bimodal effect, activating the channel at micromolar concentrations and inhibiting it at higher concentrations. Here we report the bimodal action of cinnamaldehyde (CA) and camphor, which are thus far reported as agonist and antagonist of TRPA1, respectively. Whole-cell patch-clamp experiments in TRPA1-expressing CHO cells revealed that, as previously reported, extracellular application of 100 µM CA strongly stimulates TRPA1 currents. However, subsequent application of 3 mM CA induced fast and reversible current inhibition. Application of 3 mM CA in basal conditions induced a rather small current increase, followed by current inhibition and a dramatic rebound of current amplitude upon washout. These observations are reminiscent of the effects of TRPA1 modulators having bimodal effects, e.g., menthol and nicotine. In line with previous reports, extracellular application of 1 mM camphor induced a decrease of basal TRPA1 currents. However, the current amplitude showed a significant overshoot upon washout. On the other hand, application of 100 µM camphor induced a 3-fold increase of the basal current amplitude measured at -75 mV. The bimodal effects of CA and camphor on TRPA1 were also observed in microfluorimetric measurements of intracellular Ca(2+) in intact TRPA1-expressing CHO cells and in primary cultures of mouse dorsal root ganglion neurons. These findings are essential for the understanding of the complex sensory properties of these compounds, as well as their utility when used to study the pathophysiological relevance of TRPA1.

The role of tryptophan spatial arrangement for antimicrobial-derived, membrane-active peptides adsorption and activity.

Herein we explored the role of topological distribution of aromatic amino acids in peptide-membrane interfacial interactions. The membrane activity of closely related peptides and their binding energy is sensitive to the positioning of minimum two tryptophans, and by the degree of flanking at the membrane interface mediated by aromatic amino acids.

Uni-molecular detection and quantification of selected ß-lactam antibiotics with a hybrid α-hemolysin protein pore.

Single-nanopores have recently been used to electrically detect a wide range of analytes. Similarly, using electrophysiology, we demonstrate how a system comprised of an ion channel formed by α-hemolysin (α-HL) and single-cyclic γ-cyclodextrin (γ-CD) molecule permits the detection of, and differentiation between three different antibiotics from the ß-lactam family. Specifically, histograms of the time between the successive binding events, and the residence time distributions of the antibiotic in the γ-CD molecular adapter vary with the antibiotic type. The results show that the association times of amoxicillin, azlocillin, and ampicillin are τ(on) = 2.1 ± 0.2, 2.2 ± 0.3, and 3.1 ± 0.4 ms, respectively. Interestingly, we found that the residence time of the bulkier and negatively charged azlocillin (τ(off) = 0.008 ± 0.0005 ms) is much less than that of ampicillin (τ(off) = 0.07 ± 0.005 ms) and amoxicillin (τ(off) = 0.1 ± 0.02 ms), even though the γ-CD-α-HL complex is anionic selective. The data were also used to estimate the standard free energy of binding between ampicillin to γ-CDs binding (-12 kJ mol(-1) [corrected]). The difference in association times might be due to γ-CDs-imposed steric hindrance or an energetically more expensive desolvation step for the antibiotics to gain access to the binding site in the CD. We suggest that this technique may be used to detect other analytes used in pharmaceutical applications.

The capsaicin receptor TRPV1 is a crucial mediator of the noxious effects of mustard oil.

Mustard oil (MO) is a plant-derived irritant that has been extensively used in experimental models to induce pain and inflammation. The noxious effects of MO are currently ascribed to specific activation of the cation channel TRPA1 in nociceptive neurons. In contrast to this view, we show here that the capsaicin receptor TRPV1 has a surprisingly large contribution to aversive and pain responses and visceral irritation induced by MO. Furthermore, we found that this can be explained by previously unknown properties of this compound. First, MO has a bimodal effect on TRPA1, producing current inhibition at millimolar concentrations. Second, it directly and stably activates mouse and human recombinant TRPV1, as well as TRPV1 channels in mouse sensory neurons. Finally, physiological temperatures enhance MO-induced TRPV1 stimulation. Our results refute the dogma that TRPA1 is the sole nocisensor for MO and motivate a revision of the putative roles of these channels in models of MO-induced pain and inflammation. We propose that TRPV1 has a generalized role in the detection of irritant botanical defensive traits and in the coevolution of multiple mammalian and plant species.

Investigation of single-molecule kinetics mediated by weak hydrogen bonds within a biological nanopore.

The study of factors essential for protein-peptide interactions and protein pore-mediated peptide transport are of particular relevance in biology. Wild-type α-hemolysin was adopted as a "nanoreactor" in which perturbations of the current through a protein containing a lumen-residing, aryl-capped antimicrobial peptide were seen for the first time and studied at the single-molecule level. Energy and steric considerations hint that Met-aryl interactions between aromatic residues placed at a peptide's extremities and any of the methionines lining the α-hemolysin constriction region may be the primary cause of peptide stabilization within the lumen and may be particularly important to the peptide-α-hemolysin interaction.

Unimolecular study of the interaction between the outer membrane protein OmpF from E. coli and an analogue of the HP(2-20) antimicrobial peptide.

Little is known on antimicrobial peptide permeation through outer membrane channels in gram-negative bacteria. Herein, we probed at a single-molecule level the interaction of two different peptides, magainin 2 and HPA3P with OmpF from E. coli. HPA3P is an analogue of the antimicrobial peptide HP(2-20) isolated from the N-terminal region of the Helicobacter pylori ribosomal protein. Our data show that the shorter and more charged HPA3P peptide is more accessible to the inner volume of the OmpF than magainin 2. We demonstrate the ability of HPA3P peptides to interact with OmpF in a voltage- and concentration-dependent manner, which does not rule out a novel mechanism by which such peptides could reach the periplasmic space of gram-negative bacteria. Unexpectedly, we found that increasing the applied voltage led to an increase of the residence time of HPA3P peptide inside the pore, possibly reflecting electric field-induced changes in pore and peptide geometry.

The RH 421 styryl dye induced, pore model-dependent modulation of antimicrobial peptides activity in reconstituted planar membranes.

BACKGROUND: Antimicrobial agents, with different pore-formation mechanisms, may be differently influenced by alteration of the dipolar electric field of a lipid membrane. METHODS: By using electrophysiological measurements on reconstituted lipid membranes, we used alamethicin, melittin and magainin to report on how controlled manipulation of the membrane dipole potential by the styrylpyridinium dye RH 421 affects the kinetic and transport features of peptides within membranes. RESULTS: Our data demonstrate that the increase of the membrane dipole potential caused by RH 421 decreases the activity and single-channel conductance of alamethicin. Surprisingly, we found that RH 421 increases the activity of melittin and magainin, suggesting that RH 421 may contribute via electrostatic repulsions, among others, to an increase in the monolayer spontaneous curvature of the membrane. We propose that RH 421-induced dipole potential and membrane elasticity changes alter the peptide-induced channel dynamics, and the prevalence of one mechanism over the other for particular classes of peptides is dictated by the electrical and mechanical interactions which rule the pore-formation mechanism of such peptides. GENERAL SIGNIFICANCE: These results point to a novel paradigm in which electrical and mechanical effects promoted by chemicals which preferentially alter the electrostatics of the membrane, may be employed to help distinguish among various pore-formation mechanisms of membrane-permeabilizing peptides.