Calsequestrin is a major binding protein of myotoxin alpha and an endogenous Ca2+ releaser in sarcoplasmic reticulum

Synthetic polypeptide crotamine: characterization as a myotoxin and as a target of combinatorial peptides

Crotamine is a rattlesnake-derived toxin that causes fast-twitch muscle paralysis. As a cell-penetrating polypeptide, crotamine has been investigated as an experimental anti-cancer and immunotherapeutic agent. We hypothesized that molecules targeting crotamine could be designed to study its function and intervene in its adverse activities. Here, we characterize synthetic crotamine and show that, like the venom-purified toxin, it induces hindlimb muscle paralysis by affecting muscle contraction and inhibits KCNA3 (Kv1.3) channels. Synthetic crotamine, labeled with a fluorophore, displayed cell penetration, subcellular myofiber distribution, ability to induce myonecrosis, and bind to DNA and heparin. Here, we used this functionally validated synthetic polypeptide to screen a combinatorial phage display library for crotamine-binding cyclic peptides. Selection for tryptophan-rich peptides was observed, binding of which to crotamine was confirmed by ELISA and gel shift assays. One of the peptides (CVWSFWGMYC), synthesized chemically, was shown to bind both synthetic and natural crotamine and to block crotamine-DNA binding. In summary, our study establishes a functional synthetic substitute to the venom-derived toxin and identifies peptides that could further be developed as probes to target crotamine. KEY MESSAGES: Synthetic crotamine was characterized as a functional substitute for venom-derived crotamine based on myotoxic effects. A combinatorial peptide library was screened for crotamine-binding peptides. Tryptophan-rich peptides were shown to bind to crotamine and interfere with its DNA binding. Crotamine myofiber distribution and affinity for tryptophan-rich peptides provide insights on its mechanism of action.

Co-Localization of Crotamine with Internal Membranes and Accentuated Accumulation in Tumor Cells

Crotamine is a highly cationic; cysteine rich, cross-linked, low molecular mass cell penetrating peptide (CPP) from the venom of the South American rattlesnake. Potential application of crotamine in biomedicine may require its large-scale purification. To overcome difficulties related with the purification of natural crotamine (nCrot) we aimed in the present study to synthesize and characterize a crotamine analog (sCrot) as well investigate its CPP activity. Mass spectrometry analysis demonstrates that sCrot and nCrot have equal molecular mass and biological function—the capacity to induce spastic paralysis in the hind limbs in mice. sCrot CPP activity was evaluated in a wide range of tumor and non-tumor cell tests performed at different time points. We demonstrate that sCrot-Cy3 showed distinct co-localization patterns with intracellular membranes inside the tumor and non-tumor cells. Time-lapse microscopy and quantification of sCrot-Cy3 fluorescence signalss in living tumor versus non-tumor cells revealed a significant statistical difference in the fluorescence intensity observed in tumor cells. These data suggest a possible use of sCrot as a molecular probe for tumor cells, as well as, for the selective delivery of anticancer molecules into these tumors.

Toxin bioportides: exploring toxin biological activity and multifunctionality

Toxins have been shown to have many biological functions and to constitute a rich source of drugs and biotechnological tools. We focus on toxins that not only have a specific activity, but also contain residues responsible for transmembrane penetration, which can be considered bioportides-a class of cell-penetrating peptides that are also intrinsically bioactive. Bioportides are potential tools in pharmacology and biotechnology as they help deliver substances and nanoparticles to intracellular targets. Bioportides characterized so far are peptides derived from human proteins, such as cytochrome c (CYCS), calcitonin receptor (camptide), and endothelial nitric oxide synthase (nosangiotide). However, toxins are usually disregarded as potential bioportides. In this review, we discuss the inclusion of some toxins and molecules derived thereof as a new class of bioportides based on structure activity relationship, minimization, and biological activity studies. The comparative analysis of the amino acid residue composition of toxin-derived bioportides and their short molecular variants is an innovative analytical strategy which allows us to understand natural toxin multifunctionality in vivo and plan novel pharmacological and biotechnological products. Furthermore, we discuss how many bioportide toxins have a rigid structure with amphiphilic properties important for both cell penetration and bioactivity.

Ophidian envenomation strategies and the role of purines

Snake envenomation employs three well integrated strategies: prey immobilization via hypotension, prey immobilization via paralysis, and prey digestion. Purines (adenosine, guanosine and inosine) evidently play a central role in the envenomation strategies of most advanced snakes. Purines constitute the perfect multifunctional toxins, participating simultaneously in all three envenomation strategies. Because they are endogenous regulatory compounds in all vertebrates, it is impossible for any prey organism to develop resistance to them. Purine generation from endogenous precursors in the prey explains the presence of many hitherto unexplained enzyme activities in snake venoms: 5'-nucleotidase, endonucleases (including ribonuclease), phosphodiesterase, ATPase, ADPase, phosphomonoesterase, and NADase. Phospholipases A(2), cytotoxins, myotoxins, and heparinase also participate in purine liberation, in addition to their better known functions. Adenosine contributes to prey immobilization by activation of neuronal adenosine A(1) receptors, suppressing acetylcholine release from motor neurons and excitatory neurotransmitters from central sites. It also exacerbates venom-induced hypotension by activating A(2) receptors in the vasculature. Adenosine and inosine both activate mast cell A(3) receptors, liberating vasoactive substances and increasing vascular permeability. Guanosine probably contributes to hypotension, by augmenting vascular endothelial cGMP levels via an unknown mechanism. Novel functions are suggested for toxins that act upon blood coagulation factors, including nitric oxide production, using the prey's carboxypeptidases. Leucine aminopeptidase may link venom hemorrhagic metalloproteases and endogenous chymotrypsin-like proteases with venom L-amino acid oxidase (LAO), accelerating the latter. The primary function of LAO is probably to promote prey hypotension by activating soluble guanylate cyclase in the presence of superoxide dismutase. LAO's apoptotic activity, too slow to be relevant to prey capture, is undoubtedly secondary and probably serves principally a digestive function. It is concluded that the principal function of L-type Ca(2+) channel antagonists and muscarinic toxins, in Dendroaspis venoms, and acetylcholinesterase in other elapid venoms, is to promote hypotension. Venom dipeptidyl peptidase IV-like enzymes probably also contribute to hypotension by destroying vasoconstrictive peptides such as Peptide YY, neuropeptide Y and substance P. Purines apparently bind to other toxins which then serve as molecular chaperones to deposit the bound purines at specific subsets of purine receptors. The assignment of pharmacological activities such as transient neurotransmitter suppression, histamine release and antinociception, to a variety of proteinaceous toxins, is probably erroneous. Such effects are probably due instead to purines bound to these toxins, and/or to free venom purines.

Identification of 30 kDa protein for Ca(2+) releasing action of myotoxin a with a mechanism common to DIDS in skeletal muscle sarcoplasmic reticulum

The molecular mechanism of Ca(2+) release by myotoxin a (MTYX), a polypeptide toxin isolated from the venom of prairie rattlesnakes (Crotalus viridis viridis), was investigated in the heavy fraction of sarcoplasmic reticulum (HSR) of rabbit skeletal muscles. [(125)I]MYTX bound to four HSR proteins (106, 74, 53 and 30 kDa) on polyvinylidene difluoride (PVDF) membrane. DIDS, 4, 4'-diisothiocyanatostilbene-2,2'-disulfonic acid, bound predominantly to 30 kDa protein on the PVDF membrane, the molecular weight of which was similar to one of the MYTX binding proteins. The maximum (45)Ca(2+) release induced by caffeine (30 mM) was further increased in the presence of MYTX (10 microM) or DIDS (30 microM), whereas that induced by DIDS (30 microM) was not affected by MYTX (10 microM). MYTX inhibited [(3)H]DIDS binding to HSR in a concentration-dependent manner. Furthermore, [(125)I]MYTX binding to 30 kDa protein was inhibited by DIDS in a concentration-dependent manner. These results suggest that MYTX and DIDS release Ca(2+) from HSR in a common mechanism. The 30 kDa protein may be a target protein for the Ca(2+) releasing action of MYTX and DIDS.

Nucleotide sequence of crotamine isoform precursors from a single South American rattlesnake (Crotalus durissus terrificus)

A cDNA phage library was constructed from venom glands of a single adult specimen of crotamine-plus Crotalus durissus terrificus (South American rattlesnake) captured in a known region. Fifteen crotamine positive clones were isolated using a PCR-based screening protocol and sequenced. These complete cDNAs clones were grouped for maximal alignment into six distinct nucleotide sequences. The crotamine cDNAs, with 340-360 bases, encompass open reading frame of 198 nucleotides with 5' and 3' untranslated regions of variable size, signal peptide sequence, one crotamine isoform message, and putative poly(A+) signal. Of these six different crotamine cDNA precursors, two predict the identical amino acid sequence previously described by Laure (1975), and the other four a crotamine isoform precursor where the Leucine residue at position 19 is replaced by isoleucine by a single base change. On the other hand, nucleotide variation was observed in the 5' and 3' untranslated regions, with one interesting variant containing an 18 base pair deletion at the 5' untranslated region which results in the usual ATG initiator being replaced by the rarely used GUG start codon. Comparison by Northern blot analysis of poly(A+) RNA from venom glands of a crotamine-plus specimen to total and poly(A+) RNA from a crotamine-minus snake indicated that crotamine transcripts were not expressed in the crotamine-minus specimen.

Characterization of the two myotoxin a isomers from the prairie rattlesnake (Crotalus viridis viridis) by capillary zone electrophoresis and fluorescence quenching studies

The two myotoxin a isomers from the venom of the prairie rattlesnake Crotalus viridis viridis have different isoelectric points, as determined by capillary zone electrophoresis. The pI values are 10.50 and 10.57, respectively, and both are higher than the previously reported pI value for myotoxin a. The difference in the isoelectric points between the two isomers is attributed to altered surface charge as a result of the conformational change in myotoxin a. Both isomers exist in crude venom, discounting the possibility that they are artifacts formed during the purification process. Fluorescence quenching of myotoxin a reveals heterogeneity of the tryptophans, possibly due to different environments. The fraction of the total tryptophan fluorescence quenched by iodide is 81% and is attributed to solvent-accessible tryptophan residues at the protein surface. The 19% non-quenchable tryptophans probably represent residues that are shielded from the solvent exposure. The ratio of buried to exposed tryptophans is similar to the ratio of isomers seen by capillary zone electrophoresis and reverse-phase high-performance liquid chromatography (c. 1 : 4).

Evidence for isomerization in myotoxin a from the prairie rattlesnake (Crotalus viridis viridis)

Myotoxin a, from the venom of the prairie rattlesnake, Crotalus viridis viridis, exists as a temperature-dependent equilibrium of two interconverting forms. Reverse-phase high-performance liquid chromatography (RP-HPLC) shows that the two forms interconvert slowly enough at 25 degrees C to be seen as two separate peaks with a molar ratio of c. 1:4. Each peak can be isolated and individually injected to give the same two peaks in the same ratio of areas. The two peaks merge during chromatography at elevated temperatures, indicating an increase in the rate of interconversion. At low temperature, c. 5 degrees C, the individual peaks can be isolated and maintained for several days without reaching equilibrium. Mass analysis by matrix-assisted laser desorption ionization (MALDI) time-of-flight mass spectrometry shows that myotoxin a is present in both RP-HPLC peaks, suggesting that the two resolved forms are conformational isomers. Capillary zone electrophoresis (CZE) also shows two resolved, but interconvertible peaks over a range of pH values. Furthermore, RP-HPLC chromatograms of myotoxin a at concentrations from 0.013 mM to 0.41 mM maintain a consistent ratio of peak areas, without evidence of dimerization. Two-dimensional 1H-NMR nuclear Overhauser enhancement spectroscopy indicates the presence of a cis-proline peptide bond, consistent with an equilibrium mixture of cis-trans isomers; however, addition of peptidyl-prolyl cis-trans isomerase (PPI) does not enhance the rate of equilibration of the RP-HPLC peaks isolated at c. 5 degrees C.

Calsequestrin is essential for the Ca2+ release induced by myotoxin alpha in skeletal muscle sarcoplasmic reticulum

Myotoxin alpha (MYTX), a polypeptide toxin purified from the venom of prairie rattlesnakes (Crotalus viridis viridis), induced Ca2+ release from the heavy fraction of skeletal sarcoplasmic reticulum (HSR), using a Ca2+ electrode. The effect of MYTX was nearly abolished by pretreatment with ryanodine, an alkaloid-based Ca2+ channel blocker. In the stopped-flow experiments, MYTX increased the choline+ permeability of HSR in the presence of calsequestrin (CS). Single channel recording experiments showed that in the presence of CS, the channel currents were markedly enhanced by MYTX applied to the cis side, but not to the trans side. However, in the absence of CS, MYTX failed to cause the excitatory effect in both the experiments. These results suggest that CS is essential for MYTX-induced Ca2+ release through the Ca2+ release channels in skeletal HSR.