Probing human proteins for short encrypted antimicrobial peptides reveals Hs10, a peptide with selective activity for gram-negative bacteria

BackgroundSome cationic and amphiphilic α-helical segments of proteins adsorb to prokaryotic membranes when synthesized as individual polypeptide sequences, resulting in broad and potent antimicrobial activity. However, amphiphilicity, a determinant physicochemical property for peptide-membrane interactions, can also be observed in some β-sheets.MethodsThe software Kamal was used to scan the human reference proteome for short (7–11 amino acid residues) cationic and amphiphilic protein segments with the characteristic periodicity of β-sheets. Some of the uncovered peptides were chemically synthesized, and antimicrobial assays were conducted. Biophysical techniques were used to probe the molecular interaction of one peptide with phospholipid vesicles, lipopolysaccharides (LPS) and the bacterium Escherichia coli.ResultsThousands of compatible segments were found in human proteins, five were synthesized, and three presented antimicrobial activity in the micromolar range. Hs10, a nonapeptide fragment of the Complement C3 protein, could inhibit only the growth of tested Gram-negative microorganisms, presenting also little cytotoxicity to human fibroblasts. Hs10 interacted with LPS while transitioning from an unstructured segment to a β-sheet and increased the hydrodynamic radius of LPS particles. This peptide also promoted morphological alterations in E. coli cells. Conclusions: Data presented herein introduce yet another molecular template to probe proteins in search for encrypted membrane-active segments and demonstrates that, using this approach, short peptides with low cytotoxicity and high selectivity to prokaryotic cells might be obtained.General SignificanceThis work widens the biotechnological potential of the human proteome as a source of antimicrobial peptides with application in human health.     

Capability of ganglioside GM1 in modulating interactions,structure, location and dynamics of peptides/proteins: biophysical approaches

Gangliosides, are glycosphingolipids, present in all vertebrate plasma membranes with particular abundance in nerve cell membrane. Gangliosides can act as portals for antimicrobial peptides, hormones, viruses, lectins, toxins and pathogens. They are strategically positioned on the outer membrane and hence can participate in a large number of recognition processes. Their abundance in nerve cell membrane makes them “likely” receptor candidates for neuropeptides. In this review we outline our work in the area of GM1-peptide/protein interaction. We have explored the effect of GM1 containing micelles/bicelles on structures of peptides, proteins as well as on denatured proteins. It has been observed that the peptides that are disordered or having random coil structure in aqueous solution, attained an ordered three-dimensional structure when interact with GM1. It is also observed that denatured proteins undergo refolding in presence of ganglioside. Peptides/proteins show stronger interaction with membrane lipid bilayer in presence of ganglioside than that without ganglioside. This review mainly focuses on capability of ganglioside GM1 in modulating interaction, structural, location and dynamics of peptides/proteins using a number of biophysical techniques–solution NMR, DOSY, CD, fluorescence etc.     

The antimicrobial peptide Temporin L impairs E. coli cell division by interacting with FtsZ and the divisome complex

BackgroundThe comprehension of the mechanism of action of antimicrobial peptides is fundamental for the design of new antibiotics. Studies performed looking at the interaction of peptides with bacterial cells offer a faithful picture of what really happens in nature.MethodsIn this work we focused on the interaction of the peptide Temporin L with E. coli cells, using a variety of biochemical and biophysical techniques that include: functional proteomics, docking, optical microscopy, TEM, DLS, SANS, fluorescence.ResultsWe identified bacterial proteins specifically interacting with the peptides that belong to the divisome machinery; our data suggest that the GTPase FtsZ is the specific peptide target. Docking experiments supported the FtsZ-TL interaction; binding and enzymatic assays using recombinant FtsZ confirmed this hypothesis and revealed a competitive inhibition mechanism. Optical microscopy and TEM measurements demonstrated that, upon incubation with the peptide, bacterial cells are unable to divide forming long necklace-like cell filaments. Dynamic light scattering studies and Small Angle Neutron Scattering experiments performed on treated and untreated bacterial cells, indicated a change at the nanoscale level of the bacterial membrane.ConclusionsThe peptide temporin L acts by a non-membrane-lytic mechanism of action, inhibiting the divisome machinery.General significanceIdentification of targets of antimicrobial peptides is pivotal to the tailored design of new antimicrobials.     

Membrane interactions of the anuran antimicrobial peptide HSP1-NH2: Different aspects of the association to anionic and zwitterionic biomimetic systems

Studies have suggested that antimicrobial peptides act by different mechanisms, such as micellisation, self-assembly of nanostructures and pore formation on the membrane surface. This work presents an extensive investigation of the membrane interactions of the 14 amino-acid antimicrobial peptide hylaseptin P1-NH₂ (HSP1-NH₂), derived from the tree-frog Hyla punctata, which has stronger antifungal than antibacterial potential. Biophysical and structural analyses were performed and the correlated results were used to describe in detail the interactions of HSP1-NH₂ with zwitterionic and anionic detergent micelles and phospholipid vesicles. HSP1-NH₂ presents similar well-defined helical conformations in both zwitterionic and anionic micelles, although NMR spectroscopy revealed important structural differences in the peptide N-terminus. ²H exchange experiments of HSP1-NH₂ indicated the insertion of the most N-terminal residues (1–3) in the DPC-d₃₈ micelles. A higher enthalpic contribution was verified for the interaction of the peptide with anionic vesicles in comparison with zwitterionic vesicles. The pore formation ability of HSP1-NH₂ (examined by dye release assays) and its effect on the size and surface charge as well as on the lipid acyl chain ordering (evaluated by Fourier-transform infrared spectroscopy) of anionic phospholipid vesicles showed membrane disruption even at low peptide-to-phospholipid ratios, and the effect increases proportionately to the peptide concentration. On the other hand, these biophysical investigations showed that a critical peptide-to-phospholipid ratio around 0.6 is essential for promoting disruption of zwitterionic membranes. In conclusion, this study demonstrates that the binding process of the antimicrobial HSP1-NH₂ peptide depends on the membrane composition and peptide concentration.     

Autophagy and p62/sequestosome 1 generate neo-antimicrobial peptides (cryptides) from cytosolic proteins

In a manifestation of the immunological autophagy termed xenophagy, autophagic adapter proteins such as p62 and NDP52 directly capture microbes for delivery to autophagosomal organelles where they are eliminated. In a mirror image phenomenon, which is also an immunological variant of the process termed decryption, p62 and autophagy contribute to the elimination of Mycobacterium tuberculosis. During decryption, p62 sequesters cytosolic proteins into autophagosomes where they are proteolytically converted into peptides termed cryptides. A subset of cryptides possesses antimicrobial peptide properties exhibited upon their delivery to parasitophorous vacuoles where they kill intracellular microbes.Key words: autophagy, tuberculosis, ribosome, ubiquitin, antimicrobial peptidesAutophagy is an evolutionarily conserved cytoplasm-homeostatic process with a multitude of functions supporting, for the most part, cellular viability. During autophagy, cytoplasmic targets ranging from protein aggregates to whole organelles such as mitochondria and intracellular microbes are sequestered into a double-membrane bound organelle called the autophagosome. Autophagosomes mature into autolysosomes through fusion with lysosomes or their transport intermediates, bringing about acidification and acquisition of hydrolases leading to the digestion of the captured substrates. It is generally assumed that autophagy produces terminal degradative products such as free amino acids that are then used by the cell or the body as nutrients at times of starvation. Recently, we have discovered that autophagy generates, by proteolysis of captured cytosolic proteins, a mixture of peptides conferring potential cryptic biological functions, termed “cryptides.” Some of the cryptides with thus far assigned biological functions are the neo-antimicrobial peptides liberated from innocuous cytoplasmic proteins such as the ribosomal protein precursor FAU and ubiquitin.Our study was motivated by the search for factors or ingredients that make autophagic organelles particularly mycobactericidal, as Mycobacterium tuberculosis can survive the environment of the conventional phagolysosome. This was shown in the 1970s by the classical work of Armstrong and D''Arcy Hart at the same time when these authors established the more broadly appreciated and well-ingrained reputation of the tubercle bacillus as inhibiting the conventional phagosome-lysosome fusion. The approach to identifying such hypothetical ingredients was to first examine the steps of the autophagic pathway that are necessary for the mycobactericidal nature of macrophages induced for autophagy by, for example, starvation. We have found that not only are all stages of autophagy (initiation, elongation/closure and maturation) required for full mycobactericidal potency, but that p62, the first autophagic adapter characterized by the Johansen group, and also known as sequestosome 1, is absolutely required for autophagic elimination of M. tuberculosis. Sequestosome 1/p62 recognizes ubiquitinated protein aggregates and possibly ubiquitinated depolarized mitochondria and other targets, and delivers them to nascent autophagosomes; p62 also binds to the mammalian Atg8 paralog LC3 via its LC3-interaction region (LIR), thus conveniently bridging the targets with forming phagophores.At first blush, it may seem that mycobacteria follow the same fate demonstrated for several other bacteria, whereby p62 or another autophagic adapter, NDP52, capture cytosolic microbes and deliver them to autophagosomes. For example, the fraction of Salmonellae that are no longer retained within phagosomes and are free in the cytosol, or Shigella and Listeria that actively escape into the cytosol, are associated with ubiquitinated material or become otherwise recognized by p62 or NDP52, and end up being sequestered into autophagosomes. However, we found no evidence for p62 acting directly to transfer intraphagosomal mycobacteria into autophagic vacuoles. Instead, we observed p62-positive organelles as periodically fusing with mycobacterial phagosomes. At the same time, we found by imaging and biochemical means that proteins recruited by p62 from the cytosol into conventional autophagic organelles are subsequently transferred to model (latex bead phagosomes formed upon feeding 1 µm beads to macrophages) or mycobacterial phagosomes, as they gradually acquire autolysosomal characteristics. Next, we established that p62-captured cytosolic proteins (ribosomal protein rpS30 precursor FAU and ubiquitin) are proteolytically degraded into smaller peptides, and that specific peptides from these complex mixtures show antimycobacterial activity. Thus, the emerging model posits that autophagy captures cytosolic proteins and converts them into neo-antimycobacterial peptides that can then kill M. tuberculosis upon delivery to mycobacteria-containing phagosomes, which in turn gradually acquire autolysosomal properties (Fig. 1).Open in a separate windowFigure 1Elimination of M. tuberculosis by autophagy and p62. Mycobacteria are phagocytosed by macrophages and at least for some time reside within phagosomes. Upon induction of autophagy, p62, as a bifunctional agent interacting with autophagic substrates and with LC3, recruits into autophagosomes pre-antimicrobicidal cytosolic substrates. Autophagosome maturation including acquisition of lysosomal hydrolases leads to the proteolytic cleavage of p62 substrates and their conversion into peptides (cryptides) that can act as antimicrobial peptides.In contrast to the direct mechanism of capturing bacteria employed in some instances described above, in the case of M. tuberculosis, an organism that resides within the phagosomes, the adapter molecule p62 exerts its anti-microbial action through an indirect, but rather sophisticated mechanism. By sequestering into autophagosomes the initially harmless cytosolic components and by proteolytically processing them within maturing autophagosomes, p62 and autophagy liberate antimicrobial peptides from the otherwise innocuous substrates. This amounts to a resourceful utilization by the cell of otherwise spent or to-be-discarded cytoplasmic proteins and gives them an after-function upon completion of their “day jobs” that they performed as whole proteins.Our studies have uncovered a previously unappreciated function for autophagy in generating neo-antimicrobial peptides, and perhaps also opened the prospect for other biological functions potentially engendered by the products of autophagic proteolysis. Given that autophagy has the capacity to capture en masse and subject to digestion large sections of the cytoplasm, most cellular proteins are undergoing, or can undergo, processing into peptides or peptide intermediates within autophagic organelles. We postulate that the antimicrobial peptide production revealed in our studies thus far is only one manifestation of a spectrum of potential biological functions of cryptides generated by autophagy.     

A Peptide Derived from LFA-1 Protein that Modulates T-cell Adhesion Binds to Soluble ICAM-1 Protein

Abstract

Leukocyte function associated antigen 1 (LFA-1) and intercellular adhesion molecule 1 (ICAM-1) have been shown to be critical for adhesion process and immune response. Modulation or inhibition of the interaction between LFA-1/ICAM-1 interactions can result in therapeutic effects. Our group and others have shown that peptides derived from ICAM- 1 or LFA-1 inhibit adhesion in a homotypic T-cell adhesion assay. It is likely that the peptides derived from ICAM-1 bind to LFA-1 and peptides derived from LFA-1 bind to ICAM- 1 and inhibit the adhesion interaction. However, there are no concrete experimental evidence to show that peptides bind to either LFA-1 or ICAM-1 and inhibit the adhesion. Using NMR, CD and docking studies we have shown that an LFA-1 derived peptide binds to soluble ICAM-1. Docking studies using “autodock” resulted in LFA-1 peptide interacting with the ICAM-1 protein near Glu34. The proposed model based on our experimental data indicated that the LFA-1 peptide interacts with the protein via three intermolecular hydrogen bonds. Hydrophobic interactions also play a role in stabilizing the complex.     

Selective antibacterial activity of the cationic peptide PaDBS1R6 against Gram-negative bacteria

Infections caused by Gram-negative bacteria, Escherichia coli and Pseudomonas aeruginosa foremost among them, constitute a major worldwide health problem. Bioinformatics methodologies are being used to rationally design new antimicrobial peptides, a potential alternative for treating these infections. One of the algorithms used to develop antimicrobial peptides is the Joker, which was used to design the peptide PaDBS1R6. This study evaluates the antibacterial activities of PaDBS1R6 in vitro and in vivo, characterizes the peptide interaction to target membranes, and investigates the PaDBS1R6 structure in contact with mimetic vesicles. Moreover, we demonstrate that PaDBS1R6 exhibits selective antimicrobial activity against Gram-negative bacteria. In the presence of negatively charged and zwitterionic lipids the structural arrangement of PaDBS1R6 transits from random coil to α-helix, as characterized by circular dichroism. The tertiary structure of PaDBS1R6 was determined by NMR in zwitterionic dodecylphosphocholine (DPC) micelles. In conclusion, PaDBS1R6 is a candidate for the treatment of nosocomial infections caused by Gram-negative bacteria, as template for producing other antimicrobial agents.     

EcDBS1R6: A novel cationic antimicrobial peptide derived from a signal peptide sequence

BackgroundBacterial infections represent a major worldwide health problem the antimicrobial peptides (AMPs) have been considered as potential alternative agents for treating these infections. Here we demonstrated the antimicrobial activity of EcDBS1R6, a peptide derived from a signal peptide sequence of Escherichia coli that we previously turned into an AMP by making changes through the Joker algorithm.MethodsAntimicrobial activity was measured by broth microdilution method. Membrane integrity was measured using fluorescent probes and through scanning electron microscopy imaging. A sliding window of truncated peptides was used to determine the EcDBS1R6 active core. Molecular dynamics in TFE/water environment was used to assess the EcDBS1R6 structure.ResultsSignal peptides are known to naturally interact with membranes; however, the modifications introduced by Joker transformed this peptide into a membrane-active agent capable of killing bacteria. The C-terminus was unable to fold into an α-helix whereas its fragments showed poor or no antimicrobial activity, suggesting that the EcDBS1R6 antibacterial core was located at the helical N-terminus, corresponding to the signal peptide portion of the parent peptide.ConclusionThe strategy of transforming signal peptides into AMPs appears to be promising and could be used to produce novel antimicrobial agents.General significanceThe process of transforming an inactive signal peptide into an antimicrobial peptide could open a new venue for creating new AMPs derived from signal peptides.     

Structural interrogation of phosphoproteome identified by mass spectrometry reveals allowed and disallowed regions of phosphoconformation

Background

Many biologically active compounds bind to plasma transport proteins, and this binding can be either advantageous or disadvantageous from a drug design perspective. Human serum albumin (HSA) is one of the most important transport proteins in the cardiovascular system due to its great binding capacity and high physiological concentration. HSA has a preference for accommodating neutral lipophilic and acidic drug-like ligands, but is also surprisingly able to bind positively charged peptides. Understanding of how short cationic antimicrobial peptides interact with human serum albumin is of importance for developing such compounds into the clinics.

Results

The binding of a selection of short synthetic cationic antimicrobial peptides (CAPs) to human albumin with binding affinities in the μM range is described. Competitive isothermal titration calorimetry (ITC) and NMR WaterLOGSY experiments mapped the binding site of the CAPs to the well-known drug site II within subdomain IIIA of HSA. Thermodynamic and structural analysis revealed that the binding is exclusively driven by interactions with the hydrophobic moieties of the peptides, and is independent of the cationic residues that are vital for antimicrobial activity. Both of the hydrophobic moieties comprising the peptides were detected to interact with drug site II by NMR saturation transfer difference (STD) group epitope mapping (GEM) and INPHARMA experiments. Molecular models of the complexes between the peptides and albumin were constructed using docking experiments, and support the binding hypothesis and confirm the overall binding affinities of the CAPs.

Conclusions

The biophysical and structural characterizations of albumin-peptide complexes reported here provide detailed insight into how albumin can bind short cationic peptides. The hydrophobic elements of the peptides studied here are responsible for the main interaction with HSA. We suggest that albumin binding should be taken into careful consideration in antimicrobial peptide studies, as the systemic distribution can be significantly affected by HSA interactions.     

Advances in antimicrobial peptide immunobiology

Antimicrobial peptides are ancient components of the innate immune system and have been isolated from organisms spanning the phylogenetic spectrum. Over an evolutionary time span, these peptides have retained potency, in the face of highly mutable target microorganisms. This fact suggests important coevolutionary influences in the host-pathogen relationship. Despite their diverse origins, the majority of antimicrobial peptides have common biophysical parameters that are likely essential for activity, including small size, cationicity, and amphipathicity. Although more than 900 different antimicrobial peptides have been characterized, most can be grouped as belonging to one of three structural classes: (1) linear, often of alpha-helical propensity; (2) cysteine stabilized, most commonly conforming to beta-sheet structure; and (3) those with one or more predominant amino acid residues, but variable in structure. Interestingly, these biophysical and structural features are retained in ribosomally as well as nonribosomally synthesized peptides. Therefore, it appears that a relatively limited set of physicochemical features is required for antimicrobial peptide efficacy against a broad spectrum of microbial pathogens.During the past several years, a number of themes have emerged within the field of antimicrobial peptide immunobiology. One developing area expands upon known microbicidal mechanisms of antimicrobial peptides to include targets beyond the plasma membrane. Examples include antimicrobial peptide activity involving structures such as extracellular polysaccharide and cell wall components, as well as the identification of an increasing number of intracellular targets. Additional areas of interest include an expanding recognition of antimicrobial peptide multifunctionality, and the identification of large antimicrobial proteins, and antimicrobial peptide or protein fragments derived thereof. The following discussion highlights such recent developments in antimicrobial peptide immunobiology, with an emphasis on the biophysical aspects of host-defense polypeptide action and mechanisms of microbial resistance.     

TOAC spin-labeled peptides tailored for DNP-NMR studies in lipid membrane environments

The benefit of combining in-cell solid-state dynamic nuclear polarization (DNP) NMR and cryogenic temperatures is providing sufficient signal/noise and preservation of bacterial integrity via cryoprotection to enable in situ biophysical studies of antimicrobial peptides. The radical source required for DNP was delivered into cells by adding a nitroxide-tagged peptide based on the antimicrobial peptide maculatin 1.1 (Mac1). In this study, the structure, localization, and signal enhancement properties of a single (T-MacW) and double (T-T-MacW) TOAC (2,2,6,6-tetramethylpiperidine-N-oxyl-4-amino-4-carboxylic acid) spin-labeled Mac1 analogs were determined within micelles or lipid vesicles. The solution NMR and circular dichroism results showed that the spin-labeled peptides adopted helical structures in contact with micelles. The peptides behaved as an isolated radical source in the presence of multilamellar vesicles, and the electron paramagnetic resonance (EPR) electron-electron distance for the doubly spin-labeled peptide was ∼1 nm. The strongest paramagnetic relaxation enhancement (PRE) was observed for the lipid NMR signals near the glycerol-carbonyl backbone and was stronger for the doubly spin-labeled peptide. Molecular dynamics simulation of the T-T-MacW radical source in phospholipid bilayers supported the EPR and PRE observations while providing further structural insights. Overall, the T-T-MacW peptide achieved better ¹³C and ¹⁵N signal NMR enhancements and ¹H spin-lattice T₁ relaxation than T-MacW.     

LyeTx I,a potent antimicrobial peptide from the venom of the spider <Emphasis Type="Italic">Lycosa erythrognatha</Emphasis>

LyeTx I, an antimicrobial peptide isolated from the venom of Lycosa erythrognatha, known as wolf spider, has been synthesised and its structural profile studied by using the CD and NMR techniques. LyeTx I has shown to be active against bacteria (Escherichia coli and Staphylococcus aureus) and fungi (Candida krusei and Cryptococcus neoformans) and able to alter the permeabilisation of l-α-phosphatidylcholine-liposomes (POPC) in a dose-dependent manner. In POPC containing cholesterol or ergosterol, permeabilisation has either decreased about five times or remained unchanged, respectively. These results, along with the observed low haemolytic activity, indicated that antimicrobial membranes, rather than vertebrate membranes seem to be the preferential targets. However, the complexity of biological membranes compared to liposomes must be taken in account. Besides, other membrane components, such as proteins and even specific lipids, cannot be discarded to be important to the preferential action of the LyeTx I to the tested microorganisms. The secondary structure of LyeTx I shows a small random-coil region at the N-terminus followed by an α-helix that reached the amidated C-terminus, which might favour the peptide-membrane interaction. The high activity against bacteria together with the moderate activity against fungi and the low haemolytic activity have indicated LyeTx I as a good prototype for developing new antibiotic peptides.     

Autophagy and p62/sequestosome 1 generate neo-antimicrobial peptides (cryptides) from cytosolic proteins

In a manifestation of the immunological autophagy termed xenophagy, autophagic adapter proteins such as p62 and NDP52 directly capture microbes for delivery to autophagosomal organelles where they are eliminated. In a mirror image phenomenon, which is also an immunological variant of the process termed decryption, p62 and autophagy contribute to the elimination of Mycobacterium tuberculosis. During decryption, p62 sequesters cytosolic proteins into autophagosomes where they are proteolytically converted into peptides termed cryptides. A subset of cryptides possesses antimicrobial peptide properties exhibited upon their delivery to parasitophorous vacuoles where they kill intracellular microbes.     

The intriguing Cyclophilin A-HIV-1 Vpr interaction: prolyl cis/trans isomerisation catalysis and specific binding

Background

Cyclophilin A (CypA) represents a potential target for antiretroviral therapy since inhibition of CypA suppresses human immunodeficiency virus type 1 (HIV-1) replication, although the mechanism through which CypA modulates HIV-1 infectivity still remains unclear. The interaction of HIV-1 viral protein R (Vpr) with the human peptidyl prolyl isomerase CypA is known to occur in vitro and in vivo. However, the nature of the interaction of CypA with Pro-35 of N-terminal Vpr has remained undefined.

Results

Characterization of the interactions of human CypA with N-terminal peptides of HIV-1 Vpr has been achieved using a combination of nuclear magnetic resonace (NMR) exchange spectroscopy and surface plasmon resonance spectroscopy (SPR). NMR data at atomic resolution indicate prolyl cis/trans isomerisation of the highly conserved proline residues Pro-5, -10, -14 and -35 of Vpr are catalyzed by human CypA and require only very low concentrations of the isomerase relative to that of the peptide substrates. Of the N-terminal peptides of Vpr only those containing Pro-35 bind to CypA in a biosensor assay. SPR studies of specific N-terminal peptides with decreasing numbers of residues revealed that a seven-residue motif centred at Pro-35 consisting of RHFPRIW, which under membrane-like solution conditions comprises the loop region connecting helix 1 and 2 of Vpr and the two terminal residues of helix 1, is sufficient to maintain strong specific binding.

Conclusions

Only N-terminal peptides of Vpr containing Pro-35, which appears to be vital for manifold functions of Vpr, bind to CypA in a biosensor assay. This indicates that Pro-35 is essential for a specific CypA-Vpr binding interaction, in contrast to the general prolyl cis/trans isomerisation observed for all proline residues of Vpr, which only involve transient enzyme-substrate interactions. Previously suggested models depicting CypA as a chaperone that plays a role in HIV-1 virulence are now supported by our data. In detail the SPR data of this interaction were compatible with a two-state binding interaction model that involves a conformational change during binding. This is in accord with the structural changes observed by NMR suggesting CypA catalyzes the prolyl cis/trans interconversion during binding to the RHFP³⁵RIW motif of N-terminal Vpr.     

Membrane-disruptive properties of the bioinsecticide Jaburetox-2Ec: Implications to the mechanism of the action of insecticidal peptides derived from ureases

Jaburetox-2Ec, a recombinant peptide derived from an urease isoform (JBURE-II), displays high insecticidal activity against important pests such as Spodoptera frugiperda and Dysdercus peruvianus. Although the molecular mechanism of action of ureases-derived peptides remains unclear, previous ab initio data suggest the presence of structural motifs in Jaburetox-2Ec with characteristics similar to those found in a class of pore-forming peptides. Here, we investigated the molecular aspects of the interaction between Jaburetox-2Ec and large unilamellar vesicles. Jaburetox-2Ec displays membrane-disruptive ability on acidic lipid bilayers and this effect is greatly influenced by peptide aggregation. Corroborating with this finding, molecular modeling studies revealed that Jaburetox-2Ec might adopt a well-defined β-hairpin conformation similar to those found in antimicrobial peptides with membrane disruption properties. In addition, molecular dynamics simulations suggest that the protein is able to anchor at a polar/non-polar interface. In the light of these findings, for the first time it was possible to point out some evidence that the peptide Jaburetox-2Ec interacting with lipid vesicles promotes membrane permeabilization.     

Structure, dynamics and mapping of membrane-binding residues of micelle-bound antimicrobial peptides by natural abundance C NMR spectroscopy

Worldwide bacterial resistance to traditional antibiotics has drawn much research attention to naturally occurring antimicrobial peptides (AMPs) owing to their potential as alternative antimicrobials. Structural studies of AMPs are essential for an in-depth understanding of their activity, mechanism of action, and in guiding peptide design. Two-dimensional solution proton NMR spectroscopy has been the major tool. In this article, we describe the applications of natural abundance ¹³C NMR spectroscopy that provides complementary information to 2D ¹H NMR. The correlation of ¹³Cα secondary shifts with both 3D structure and heteronuclear ¹⁵N NOE values indicates that natural abundance carbon chemical shifts are useful probes for backbone structure and dynamics of membrane peptides. Using human LL-37-derived peptides (GF-17, KR-12, and RI-10), as well as amphibian antimicrobial and anticancer peptide aurein 1.2 and its analog LLAA, as models, we show that the cross peak intensity plots of 2D ¹H-¹³Cα HSQC spectra versus residue number present a wave-like pattern (HSQC wave) where key hydrophobic residues of micelle-bound peptides are located in the troughs with weaker intensities, probably due to fast exchange between the free and bound forms. In all the cases, the identification of aromatic phenylalanines as a key membrane-binding residue is consistent with previous intermolecular Phe-lipid NOE observations. Furthermore, mutation of one of the key hydrophobic residues of KR-12 to Ala significantly reduced the antibacterial activity of the peptide mutants. These results illustrate that natural abundance heteronuclear-correlated NMR spectroscopy can be utilized to probe backbone structure and dynamics, and perhaps to map key membrane-binding residues of peptides in complex with micelles. ¹H-¹³Cα HSQC wave, along with other NMR waves such as dipolar wave and chemical shift wave, offers novel insights into peptide-membrane interactions from different angles.     

The citrus plant pathogen Xanthomonas citri has a dual polyamine-binding protein

ATP-Binding Cassette transporters (ABC transporters) are protein complexes involved in the import and export of different molecules, including ions, sugars, peptides, drugs, and others. Due to the diversity of substrates, they have large relevance in physiological processes such as virulence, pathogenesis, and antimicrobial resistance. In Xanthomonas citri subsp. citri, the phytopathogen responsible for the citrus canker disease, 20% of ABC transporters components are expressed under infection conditions, including the putative putrescine/polyamine ABC transporter, PotFGHI. Polyamines are ubiquitous molecules that mediate cell growth and proliferation and play important role in bacterial infections. In this work, we characterized the X. citri periplasmic-binding protein PotF (XAC2476) using bioinformatics, biophysical and structural methods. PotF is highly conserved in Xanthomonas sp. genus, and we showed it is part of a set of proteins related to the import and assimilation of polyamines in X. citri. The interaction of PotF with putrescine and spermidine was direct and indirectly shown through fluorescence spectroscopy analyses, and experiments of circular dichroism (CD) and small-angle X-ray scattering (SAXS), respectively. The protein showed higher affinity for spermidine than putrescine, but both ligands induced structural changes that coincided with the closing of the domains and increasing of thermal stability.     

Production of a de-novo designed antimicrobial peptide in Nicotiana benthamiana

Antimicrobial peptides are important defense compounds of higher organisms that can be used as therapeutic agents against bacterial and/or viral infections. We designed several antimicrobial peptides containing hydrophobic and positively charged clusters that are active against plant and human pathogens. Especially peptide SP1-1 is highly active with a MIC value of 0.1 μg/ml against Xanthomonas vesicatoria, Pseudomonas corrugata and Pseudomonas syringae pv syringae. However, for commercial applications high amounts of peptide are necessary. The synthetic production of peptides is still quite expensive and, depending on the physico-chemical features, difficult. Therefore we developed a plant/tobacco mosaic virus-based production system following the ‘full virus vector strategy’ with the viral coat protein as fusion partner for the designed antimicrobial peptide. Infection of Nicotiana benthamiana plants with such recombinant virus resulted in production of huge amounts of virus particles presenting the peptides all over their surface. After extraction of recombinant virions, peptides were released from the coat protein by chemical cleavage. A protocol for purification of the antimicrobial peptides using high resolution chromatographic methods has been established. Finally, we yielded up to 0.025 mg of peptide per g of infected leaf biomass. Mass spectrometric and NMR analysis revealed that the in planta produced peptide differs from the synthetic version only in missing of N-terminal amidation. But its antimicrobial activity was in the range of the synthetic one. Taken together, we developed a protocol for plant-based production and purification of biologically active, hydrophobic and positively charged antimicrobial peptide.