Isolation of δ-missulenatoxin-Mb1a, the major vertebrate-active spider δ-toxin from the venom of Missulena bradleyi (Actinopodidae)

The present study describes the isolation and pharmacological characterisation of the neurotoxin δ-missulenatoxin-Mb1a (δ-MSTX-Mb1a) from the venom of the male Australian eastern mouse spider, Missulena bradleyi. This toxin was isolated using reverse-phase high-performance liquid chromatography and was subsequently shown to cause an increase in resting tension, muscle fasciculation and a decrease in indirect twitch tension in a chick biventer cervicis nerve-muscle bioassay. Interestingly, these effects were neutralised by antivenom raised against the venom of the Sydney funnel-web spider Atrax robustus. Subsequent whole-cell patch-clamp electrophysiology on rat dorsal root ganglion neurones revealed that δ-MSTX-Mb1a caused a reduction in peak tetrodotoxin (TTX)-sensitive sodium current, a slowing of sodium current inactivation and a hyperpolarising shift in the voltage at half-maximal activation. In addition, δ-MSTX-Mb1a failed to affect TTX-resistant sodium currents. Subsequent Edman degradation revealed a 42-residue peptide with unusual N- and C-terminal cysteines and a cysteine triplet (Cys14-16). This toxin was highly homologous to a family of δ-atracotoxins (δ-ACTX) from Australian funnel-web spiders including conservation of all eight cysteine residues. In addition to actions on sodium channel gating and kinetics to δ-ACTX, δ-MSTX-Mb1a caused significant insect toxicity at doses up to 2000 pmol/g. δ-MSTX-Mb1a therefore provides evidence of a highly conserved spider δ-toxin from a phylogenetically distinct spider family that has not undergone significant modification. © 2003 Published by Elsevier B.V. on behalf of the Federation of European Biochemical Societies

α-Elapitoxin-Aa2a, a long-chain snake α-neurotoxin with potent actions on muscle (α1)<inf>2</inf>βγδ nicotinic receptors, lacks the classical high affinity for neuronal α7 nicotinic receptors

In contrast to all classical long-chain α-neurotoxins possessing the critical fifth disulfide bond, α-elapitoxin-Aa2a (α-EPTX-Aa2a), a novel long-chain α-neurotoxin from the common death adder Acanthophis antarcticus, lacks affinity for neuronal α7-type nicotinic acetylcholine receptors (nAChRs) α-EPTX-Aa2a (8850 Da; 0.1-1 μM) caused a concentration-dependent inhibition of indirect twitches, and blocked contractures to cholinergic agonists in the isolated chick biventer cervicis nerve-muscle preparation, consistent with a postsynaptic curaremimetic mode of action. α-EPTX-Aa2a (1-10 nM) produced a potent pseudo-irreversible antagonism of chick muscle nAChRs, with an estimated pA2 value of 8.311 ± 0.031, which was not reversed by monovalent death adder antivenom. This is only 2.5-fold less potent than the prototypical long-chain α-neurotoxin, α-bungarotoxin. In contrast, α-EPTX-Aa2a produced complete, but weak, inhibition of 125I-α-bungarotoxin binding to rat hippocampal α7 nAChRs (pKI = 3.670), despite high sequence homology and similar mass to a wide range of long-chain α-neurotoxins. The mostly likely cause for the loss of α7 binding affinity is a leucine substitution, in loop II of α-EPTX-Aa2a, for the highly conserved Arg33 in long-chain α-neurotoxins. Arg 33 has been shown to be critical for both neuronal and muscle activity. Despite this substitution, α-EPTX-Aa2a retains high affinity for muscle (α1)2βγδ nAChRs. This is probably as a result of an Arg29 residue, previously shown to be critical for muscle (α1)2βγδ nAChR affinity, and highly conserved across all short-chain, but not long-chain, α-neurotoxins. α-EPTX-Aa2a therefore represents a novel atypical long-chain α-neurotoxin that includes a fifth disulfide but exhibits differential affinity for nAChR subtypes. Copyright © 2010 Published by Elsevier Inc. All rights reserved

Techniques for accurate protein identification in shotgun proteomic studies of human, mouse, bovine, and chicken lenses

Analysis of shotgun proteomics datasets requires techniques to distinguish correct peptide identifications from incorrect identifications, such as linear discriminant functions and target/decoy protein databases. We report an efficient, flexible proteomic analysis workflow pipeline that implements these techniques to control both peptide and protein false discovery rates. We demonstrate its performance by analyzing two-dimensional liquid chromatography separations of lens proteins from human, mouse, bovine, and chicken lenses. We compared the use of International Protein Index databases to UniProt databases and no-enzyme SEQUEST searches to tryptic searches. Sequences present in the International Protein Index databases allowed detection of several novel crystallins. An alternate start codon isoform of βA4 was found in human lens. The minor crystallin γN was detected for the first time in bovine and chicken lenses. Chicken γS was identified and is the first member of the γ-crystallin family observed in avian lenses

Sequencing and two-dimensional structure prediction of a phospholipase a<inf>2</inf> inhibitor from the serum of the common tiger snake (notechis scutatus)

A phospholipase A2 inhibitor has been identified in the serum of the common tiger snake (Notechis scutatus). The inhibitor is composed of two chains, an α-chain and a β-chain, that form a non-covalently associated complex capable of inhibiting the enzymatic activity of all phospholipase A2 enzymes it was tested against. The α and β-chains have been purified to homogeneity, digested and sequenced. From the peptide sequence generated, degenerate PCR primers were designed and used to elucidate the complete cDNA sequence of the chains using 5′ and 3′ RACE PCR. A total of three α-chain isoforms were identified, only one isoform of the β-chain was detected. The two-dimensional structure of the three α-chains and one β-chain were predicted using five prediction programs (discrimination of secondary structure class; nearest neighbour secondary structure, profile network from Heidelberg; self-optimised prediction method from multiple alignment, SSPAL). For each protein chain a consensus prediction was generated. Results are discussed in relation to the function of the protein, and how they may influence the three-dimensional structure of the inhibitor. Additionally, the sequences of several snake phospholipase A2 inhibitors were used as the input for a motif prediction algorithm (MEME). The results are discussed in relation to the activity of these proteins. © 2001 Academic Press

Characterization of monomeric and multimeric snake neurotoxins and other bioactive proteins from the venom of the lethal Australian common copperhead (Austrelaps superbus)

Envenomation by Australian copperheads results mainly in muscle paralysis largely attributed to the presence of postsynaptic α-neurotoxins. However, poorly reversible neurotoxic effects suggest that these venoms may contain snake presynaptic phospholipase A2 neurotoxins (SPANs) that irreversibly inhibit neurotransmitter release. Using size-exclusion liquid chromatography, the present study isolated the first multimeric SPAN complex from the venom of the Australian common copperhead, Austrelaps superbus. The multimeric SPAN P-elapitoxin-As1a (P-EPTX-As1a) along with two novel monomeric SPANs and a new postsynaptic α-neurotoxin were then pharmacologically characterized using the chick biventer cervicis nerve-muscle preparation. All SPANs inhibited nerve-evoked twitch contractions at the neuromuscular junction without inhibiting contractile responses to cholinergic agonists or KCl. These actions are consistent with a prejunctional action to inhibit neurotransmitter release, without direct myotoxicity. Furthermore, the multimeric P-EPTX-As1a caused tetanic 'fade' in muscle tension under high frequency nerve stimulation, and produced a triphasic alteration to neurotransmitter release. These actions have been previously noted with other multimeric SPAN complexes such as taipoxin. Moreover, the neurotoxic α-subunit of P-EPTX-As1a shows high homology to taipoxin α-chain. Several other coagulopathic and myotoxic high mass proteins including a class PIII snake venom metalloproteinase, C-type lectin, l-amino acid oxidase, acetylcholinesterase and phospholipase B were also identified that may contribute to the overall toxicity of A. superbus venom. In conclusion, clinicians should be aware that early antivenom intervention might be necessary to prevent the onset of irreversible presynaptic neurotoxicity caused by multimeric and monomeric SPANs and that A. superbus venom is potentially capable of producing coagulopathic and myotoxic effects. AbbreviationsAChacetylcholineAChEacetylcholinesteraseBCAbicinchoninic acid4-BPB4-bromophenacyl bromideCBCNMchick biventer cervicis nerve-muscleCChcarbacholD/Cdisintegrin-like/cysteine richEPPend-plate potentialESI-QTOF MSelectrospray ionization quadrupole time-of-flight mass spectrometryLAAOl-amino acid oxidaseMALDI-TOF MSmatrix-assisted laser desorption/ionization time-of-flight mass spectrometrynAChRnicotinic acetylcholine receptorNSWNew South WalesPDGFplatelet-derived growth factorPLA2phospholipase A2PLBphospholipase BEPTXelapitoxinRP-HPLCreversed-phase high-pressure liquid chromatographySAsinapinic acidSPANsnake presynaptic phospholipase A2 neurotoxinsPLA2secretory phospholipase A2SVMPsnake venom metalloproteinaset90time to 90% neuromuscular blockadeTHAP2,4,6- trihydroxyacetophenoneTFAtrifluoroacetic acidTSAVtiger snake antivenomVDGFvenom-derived growth factorVeelution volumeV ovoid volume.© 2013 Elsevier Inc. All rights reserved