Bin Gao

Structural and functional characterization of two genetically related meucin peptides highlights evolutionary divergence and convergence in antimicrobial peptides

Both vertebrates and invertebrates employ α‐helical antimicrobial peptides (AMPs) as an essential component of their innate immune system. However, evolutionary relation of these immune molecules remains unresolved. Venoms, as key weapons of venomous arthropods for prey and defense, receive increasing recognition as an emerging source of such peptides. From a cDNA library prepared from the venom gland of the scorpion Mesobuthus eupeus, clones encoding precursors of two new AMPs, named meucin‐13 (IFGAIAGLLKNIF‐NH2) and meucin‐18 (FFGHLFKLATKIIPSLFQ), have been isolated. The precursor of meucins consists of a signal peptide, a mature peptide, and an acidic propeptide, in which dibasic residues as the typical processing signal are located between the mature and propeptide. Meucin‐13 is an ortholog of several previously described AMPs from scorpion venom and has also detectable sequence similarity to temporins, a large family of AMPs from frog skin, whereas meucin‐18 displays some similarity to AMPs from diverse origin including arthropod venoms, fish mast cells, and frog skins. These two meucin peptides form α‐helical structure in the presence of 50% trifluoroethanol (TFE), a membrane‐mimicking environment, as identified by circular dichroism (CD) spectroscopy. This finding is further verified by their NMR structures that show a typical α‐helical amphipathic design, a structural prerequisite for cytolytic activity. Meucins exhibit extensive cytolytic effects on both prokaryotic and eukaryotic cells (gram+ and gram‐ bacteria, fungi, yeasts, rabbit erythrocytes, and rat dorsal root ganglion cells) at micromolar concentrations. It is remarkable that muecin‐18 was 2‐ to > 14‐fold more potent than meucin‐13 against nearly all the cells tested. Structural differences in hydrophilic/hydrophobic balance and cationic amino acid location between two meucins could account for their differential potency. Despite these differences, commonalities at precursor organization, three‐dimensional structure, and biological function suggests that meucins are two evolutionarily related AMPs and likely originated from a common ancestor by gene duplication. Our work presented here also provides new insights into an evolutionary link among AMPs from invertebrates and vertebrates and clues for evolutionary convergence between AMPs and virus fusion domains.—Gao, B., Sherman, P., Luo, L., Bowie, J., Zhu, S. Structural and functional characterization of two genetically related meucin peptides highlights evolutionary divergence and convergence in antimicrobial peptides. FASEB J. 23, 1230–1245 (2009)

Dermatophytic defensin with antiinfective potential

Fungi are a newly emerging source of peptide antibiotics with therapeutic potential. Here, we report 17 new fungal defensin-like peptide (fDLP) genes and the detailed characterization of a corresponding synthetic fDLP (micasin) from a dermatophyte in terms of its structure, activity and therapeutic potential. NMR analysis showed that synthetic micasin adopts a “hallmark” cysteine-stablized α-helical and β-sheet fold. It was active on both Gram-positive and Gram-negtive bacteria, and importantly it killed two clinical isolates of methicillin-resistant Staphylococcus aureus and the opportunistic pathogen Pseudomonas aeruginosa at low micromolar concentrations. Micasin killed approximately 100% of treated bacteria within 3 h through a membrane nondisruptive mechanism of action, and showed extremely low hemolysis and high serum stability. Consistent with these functional properties, micasin increases survival in mice infected by the pathogenic bacteria in a peritonitis model. Our work represents a valuable approach to explore novel peptide antibiotics from a large resource of fungal genomes.

Inducible antibacterial response of scorpion venom gland

Innate immunity is the first line defense of multicellular organisms that rapidly operates to limit aggression upon exposure to pathogen microorganisms. Although the existence of some antibacterial peptides in scorpion venoms suggests that venom gland could be protected by these effector molecules, antibacterial activity of venom itself has not been assessed. In this study, we reported the antibacterial activity of the venom of Chinese scorpion Buthus martensii. Protease K digestion test indicated that it is venom peptide/protein components, as key players, which are involved in such antibacterial response. As the first step toward studying molecular mechanism of scorpion venom gland immunity, we established an infection model which supports inducible antibacterial response of scorpion venom gland. A known B. martensii antibacterial peptide gene BmKb1 was up-regulated at the transcriptional level after venom gland was challenged, suggesting its key defense role. This is further strengthened by the presence of several immune response elements in the BmKb1 promoter region. Our work thus provides the first evidence supporting the role of venom antibacterial peptides (ABPs) in controlling scorpion venom gland infection and lays a basis for characterizing related components involved in regulation of scorpion venom gland ABP gene expression.

Mesomartoxin, a new Kv1.2-selective scorpion toxin interacting with the channel selectivity filter

Venom-derived neurotoxins are ideal probes for the investigation of structure-function relationship of ion channels and promising scaffolds for the design of ion channel-targeted drug leads as well. The discovery of highly selective toxins against a specific channel subtype facilitates the development of drugs with reduced side effects. Here, we describe the systemic characterization of a new scorpion short-chain K(+) channel blocker from Mesobuthus martensii, termed mesomartoxin (MMTX). MMTX is synthesized as a precursor comprising a signal peptide and a mature peptide of 29 residues. Nuclear magnetic resonance analysis confirmed that recombinant MMTX adopts a typical cysteine-stabilized α-helical and β-sheet fold. Electrophysiological experiments showed that MMTX exhibits high affinity for the Drosophila Shaker K(+) channel but differential selectivity on different members of the rat voltage-gated K(+) channel (Kv) family, with nanomolar affinity (IC50=15.6 nM) for rKv1.2, micromolar affinity for rKv1.3 (IC50=12.5 μM) and no activity on rKv1.1 at >50 μM. Site-directed mutagenesis of the channel pore identified a key site located on the selectivity filter of the pore, which is directly implicated in toxin binding and controls targets selectivity of the toxin. Given a key role of Kv1.2 in epilepsy, MMTX might serve as a potential drug lead for the disease.

An insect defensin-derived β-hairpin peptide with enhanced antibacterial activity.

Insect defensins are a class of small, cysteine-rich antimicrobial peptides primarily active on Gram-positive bacteria. Their roles in maggot therapy for treating chronic wound infection have been reported recently. However, a relatively narrow antibacterial spectrum together with the lack of a cost-effective means of commercial-scale production has limited their application. To further exploit the therapeutic potential of these molecules, we engineered the carboxyl-terminal β-sheet of navidefensin2-2, an insect defensin from Nasonia vitripennis, based on its structural similarity to naturally occurring microbicidal β-hairpin peptides. The designed peptide of 14 residues, referred to as NvBH, spans the β-sheet region of the defensin with two amino acids substituted for assembly of a disulfide-bonded amphipathic β-hairpin structure. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) combined with circular dichroism (CD) analysis shows that the oxidized NvBH (oNvBH), produced from the synthetic peptide by air oxidization in an alkaline environment, folds into a typical β-hairpin structure linked by two disulfide bridges (Cys1-Cys4; Cys2-Cys3). However, such a structure appears not to be functionally necessary as synthetic NvBH with a spontaneously oxidized disulfide bridge (Cys2-Cys3) (termed poNvBH) displayed similar antibacterial potency to oNvBH. In comparison with oNvBH, poNvBH exhibited higher serum stability and more resistance on tryptic digestion. These two forms of peptides are capable of killing an array of Gram-positive (including antibiotic-resistant strains of Staphylococcus) and Gram-negative bacterial pathogens at low micromolar concentrations through a membrane disruptive mode of action. Our work indicates that the β-sheet region of insect defensins is a promising subdomain of proteins in anti-infective drug discovery.

Nematode-derived drosomycin-type antifungal peptides provide evidence for plant-to-ecdysozoan horizontal transfer of a disease resistance gene

Drosomycin-type antifungal peptides (DTAFPs) are key innate immunity components of Drosophila and plants and confer resistance to fungal infection. Here we report the discovery of a multigene family of DTAFPs, comprising of 15 members (termed cremycin-1 to crymycin-15), in the fruit nematode Caenorhabditis remanei. Cremycins share highly similar amino-acid sequences and identical precursor organization to drosomycins. Of the 15 cremycin genes, 10 are found to be transcriptionally active and 6 are upregulated after fungal challenge. Synthetic cremycin-5 is active on filamentous fungi and a series of clinical isolates of human pathogenic yeasts and exhibits low haemolysis and high serum stability. The specific distribution of DTAFPs in a clade of moulting animals (Ecdysozoa), including Arthropoda, Nematoda and Tardigrada, together with the widespread presence in plants but the absence in fungi and protozoans, provides evidence for horizontal transfer of a disease resistance gene between plants and ecdysozoans.

Single-point mutation-mediated local amphipathic adjustment dramatically enhances antibacterial activity of a fungal defensin.

The emergence and rapid spread of multiresistant bacteria has lead to an urgent need for novel antimicrobials. Based on single‐point substitutions, we generated a series of mutants of micasin, a dermatophytic defensin, with enhanced activities against multiple clinical isolates of Staphylococcus species, including 4 antibiotic‐resistant strains. We first mapped the functional surface of micasin by alanine‐scanning mutational analysis of its highly exposed residues, through which we found that substitution of site 8 (acidic Glu) dramatically enhanced bacterial killing of this peptide. Structural analysis indicates that this single point mutation could result in a functional local amphipathic architecture. Four different types of side chains (hydrophobic, cationic polar, neutral polar, and acidic polar) were introduced at site 8 to clarify the role of this local architecture in micasin function. The results show that all mutants displayed increased antibacterial activity with the exception of the acidic replacement. These mutants with enhanced activity exhibited low hemolysis and cytotoxicity and showed high serum stability, indicating their therapeutic potential. Our work represents the first example of structural fine‐tuning to largely improve the antibacterial potency of a dermatophytic defensin.—Wu, J., Gao, B., Zhu, S. Single‐point mutation‐mediated local amphipathic adjustment dramatically enhances antibacterial activity of a fungal defensin. FASEB J. 30, 2602‐2614 (2016). www.fasebj.org

New fungal defensin-like peptides provide evidence for fold change of proteins in evolution

Defensins containing a consensus cystine framework, Cys[1]…Cys[2]X3Cys[3]…Cys[4]… Cys[5]X1Cys[6] (X, any amino acid except Cys; …, variable residue numbers), are extensively distributed in a variety of multicellular organisms (plants, fungi and invertebrates) and essentially involved in immunity as microbicidal agents. This framework is a prerequisite for forming the cysteine-stabilized α-helix and β-sheet (CSαβ) fold, in which the two invariant motifs, Cys[2]X3Cys[3]/Cys[5]X1Cys[6], are key determinants of fold formation. By using a computational genomics approach, we identified a large superfamily of fungal defensin-like peptides (fDLPs) in the phytopathogenic fungal genus – Zymoseptoria, which includes 132 structurally typical and 63 atypical members. These atypical fDLPs exhibit an altered cystine framework and accompanying fold change associated with their secondary structure elements and disulfide bridge patterns, as identified by protein structure modelling. Despite this, they definitely are homologous with the typical fDLPs in view of their precise gene structure conservation and identical precursor organization. Sequence and structural analyses combined with functional data suggest that most of Zymoseptoria fDLPs might have lost their antimicrobial activity. The present study provides a clear example of fold change in the evolution of proteins and is valuable in establishing remote homology among peptide superfamily members with different folds.

Mesobuthus Venom-Derived Antimicrobial Peptides Possess Intrinsic Multifunctionality and Differential Potential as Drugs

Animal venoms are a mixture of peptides and proteins that serve two basic biological functions: predation and defense against both predators and microbes. Antimicrobial peptides (AMPs) are a common component extensively present in various scorpion venoms (herein abbreviated as svAMPs). However, their roles in predation and defense against predators and potential as drugs are poorly understood. Here, we report five new venom peptides with antimicrobial activity from two Mesobuthus scorpion species. These α-helical linear peptides displayed highly bactericidal activity toward all the Gram-positive bacteria used here but differential activity against Gram-negative bacteria and fungi. In addition to the antibiotic activity, these AMPs displayed lethality to houseflies and hemotoxin-like toxicity on mice by causing hemolysis, tissue damage and inducing inflammatory pain. Unlike AMPs from other origins, these venom-derived AMPs seem to be unsuitable as anti-infective drugs due to their high hemolysis and low serum stability. However, MeuTXKβ1, a known two-domain Mesobuthus AMP, is an exception since it exhibits high activity toward antibiotic resistant Staphylococci clinical isolates with low hemolysis and high serum stability. The findings that the classical AMPs play predatory and defensive roles indicate that the multifunctionality of scorpion venom components is an intrinsic feature likely evolved by natural selection from microbes, prey and predators of scorpions. This definitely provides an excellent system in which one can study how a protein adaptively evolves novel functions in a new environment. Meantimes, new strategies are needed to remove the toxicity of svAMPs on eukaryotic cells when they are used as leads for anti-infective drugs.

Positive selection in cathelicidin host defense peptides: adaptation to exogenous pathogens or endogenous receptors?

The cause of adaptive protein evolution includes internal (for example, co-evolution of ligand-receptor pairs) and external (for example, adaptation to different ecological niches) mechanisms. Host defense peptides (HDPs) are a class of vertebrate-specific cationic antimicrobial peptides evolving under positive selection. Besides their antibiotic activity, HDPs also exert an effect on multiple host immune cells, thus providing an ideal model to study selective agents driving their evolution. On the basis of a combination of computational and experimental approaches, we studied the evolution of LL-37-type HDPs in mammals, the mature peptide of cathelicidin CAP18 (herein termed CAP18-MP) and investigated the driving force behind the evolution. Using codon-substitution maximum likelihood models, we analyzed CAP18-MPs in 40 species belonging to nine mammalian Orders and identified four positively selected sites (PSSs) that all are located on two terminal unordered regions of CAP18-MPs. Grafting the two positively selected regions of human or whale CAP18-MP to the α-helical scaffold of a rabbit homolog (substituting its corresponding parts) led to no alterations in antibacterial activity, spectrum and action mode. Likewise, further deletion of the two terminal regions did not alter its functional features. Evolutionary conservation analysis of mammalian FPR2, a receptor known to interact with the C-terminal positively selected region of LL-37, revealed high evolutionary variability in its ligand-binding extracellular loop domains, matching sequence diversity of the unordered regions in CAP18-MPs. This is the first report describing that the signature of positive selection of cathelicidins is not associated with their direct bactericidal activity, but rather with the evolutionary variability of their endogenous receptors.