Antigenic relationships between Mojave toxin subunits, Mojave toxin and some crotalid venoms

Rattling the border wall: Pathophysiological implications of functional and proteomic venom variation between Mexican and US subspecies of the desert rattlesnake Crotalus scutulatus

While some US populations of the Mohave rattlesnake (Crotalus scutulatus scutulatus) are infamous for being potently neurotoxic, the Mexican subspecies C. s. salvini (Huamantlan rattlesnake) has been largely unstudied beyond crude lethality testing upon mice. In this study we show that at least some populations of this snake are as potently neurotoxic as its northern cousin. Testing of the Mexican antivenom Antivipmyn showed a complete lack of neutralisation for the neurotoxic effects of C. s. salvini venom, while the neurotoxic effects of the US subspecies C. s. scutulatus were time-delayed but ultimately not eliminated. These results document unrecognised potent neurological effects of a Mexican snake and highlight the medical importance of this subspecies, a finding augmented by the ineffectiveness of the Antivipmyn antivenom. These results also influence our understanding of the venom evolution of Crotalus scutulatus, suggesting that neurotoxicity is the ancestral feature of this species, with the US populations which lack neurotoxicity being derived states.

Biological and Proteolytic Variation in the Venom of Crotalus scutulatus scutulatus from Mexico

Rattlesnake venoms may be classified according to the presence/absence and relative abundance of the neurotoxic phospholipases A2s (PLA2s), such as Mojave toxin, and snake venom metalloproteinases (SVMPs). In Mexico, studies to determine venom variation in Mojave Rattlesnakes (Crotalus scutulatus scutulatus) are limited and little is known about the biological and proteolytic activities in this species. Tissue (34) and venom (29) samples were obtained from C. s. scutulatus from different locations within their distribution in Mexico. Mojave toxin detection was carried out at the genomic (by PCR) and protein (by ELISA) levels for all tissue and venom samples. Biological activity was tested on representative venoms by measuring LD50 and hemorrhagic activity. To determine the approximate amount of SVMPs, 15 venoms were separated by RP-HPLC and variation in protein profile and proteolytic activity was evaluated by SDS-PAGE (n = 28) and Hide Powder Azure proteolytic analysis (n = 27). Three types of venom were identified in Mexico which is comparable to the intraspecific venom diversity observed in the Sonoran Desert of Arizona, USA: Venom Type A (∼Type II), with Mojave toxin, highly toxic, lacking hemorrhagic activity, and with scarce proteolytic activity; Type B (∼Type I), without Mojave toxin, less toxic than Type A, highly hemorrhagic and proteolytic; and Type A + B, containing Mojave toxin, as toxic as venom Type A, variable in hemorrhagic activity and with intermediate proteolytic activity. We also detected a positive correlation between SVMP abundance and hemorrhagic and proteolytic activities. Although more sampling is necessary, our results suggest that venoms containing Mojave toxin and venom lacking this toxin are distributed in the northwest and southeast portions of the distribution in Mexico, respectively, while an intergradation in the middle of both zones is present.

Identification of linear B-cell epitopes on myotoxin II, a Lys49 phospholipase A₂ homologue from Bothrops asper snake venom

Knowledge on toxin immunogenicity at the molecular level can provide valuable information for the improvement of antivenoms, as well as for understanding toxin structure-function relationships. The aims of this study are two-fold: first, to identify the linear B-cell epitopes of myotoxin II from Bothrops asper snake venom, a Lys49 phospholipase A₂ homologue; and second, to use antibodies specifically directed against an epitope having functional relevance in its toxicity, to probe the dimeric assembly mode of this protein in solution. Linear B-cell epitopes were identified using a library of overlapping synthetic peptides spanning its complete sequence. Epitopes recognized by a rabbit antiserum to purified myotoxin II, and by three batches of a polyvalent (Crotalidae) therapeutic antivenom (prepared in horses immunized with a mixture of B. asper, Crotalus simus, and Lachesis stenophrys venoms) were mapped using an enzyme-immunoassay based on the capture of biotinylated peptides by immobilized streptavidin. Some of the epitopes identified were shared between the two species, whereas others were unique. Differences in epitope recognition were observed not only between the two species, but also within the three batches of equine antivenom. Epitope V, located at the C-terminal region of this protein, is known to be relevant for toxicity and neutralization. Affinity-purified rabbit antibodies specific for this site were able to immunoprecipitate myotoxin II, suggesting that the two copies of epitope V are simultaneously available to antibody binding, which would be compatible with the mode of dimerization known as "conventional" dimer.

Antibodies to a fragment of the Bothrops moojenil-amino acid oxidase cross-react with snake venom components unrelated to the parent protein

It is widely accepted that immunological cross-reactivity of snake venoms is mediated by antibodies that recognize venom components bearing either amino acid sequence homology or similar biological functions. However, here we demonstrate that polyspecific Bothrops antivenom is a source of cross-reactive antibodies that interact with venom proteins of distinctive primary structures and biological functions. The homoserine lactone derivative of the undecapeptide IQRWSLDKYAM (Ile1-Hse11), excised from the l-amino acid oxidase (LAAO) of the Bothrops moojeni venom, was the ligand of an affinity resin used to isolate specific anti-Ile1-Hse11 antibodies which were instrumental in revealing immunological cross-reactivity among unrelated venom proteins. We examined the extent of the cross-reactivity of these antibodies by probing electroblots of venoms from representative snakes of genera Bothrops, Lachesis, Crotalus and Micrurus, and by unambiguous structural characterization of the affinity-purified proteins of B. moojeni venom recovered from an agarose-anti-Ile1-Hse11 column. Our results indicate that all venoms tested had at least three reactive components toward anti-Ile1-Hse11 antibodies, among which we identified two serine proteases, one phospholipase A2 homologue, and LAAO. We hypothesize that the cross-reactivity of the anti-Ile1-Hse11 antibodies to unrelated venom proteins derives from their mechanism of antigen recognition, whereby complementarity is achieved through reciprocal conformational adaptation of the reacting molecules. Also, we believe these findings have implications both in the development of improved antivenoms and the preparation of immunochemical reagents for diagnostic and scientific investigation purposes in the field of snake venoms.

Mojave toxin in venom of Crotalus helleri (Southern Pacific Rattlesnake): molecular and geographic characterization

Mojave toxin (MT) was detected in five of 25 Crotalus helleri (Southern Pacific rattlesnake) sampled using anti-MT antibodies and nucleotide sequence analysis. All of the venoms that were positive for MT were collected from Mt San Jacinto in Riverside Co., California. Since this population is geographically isolated from C. scutulatus scutulatus (Mojave rattlesnake), it is unlikely that this finding is due to recent hybridization. MT concentration differences between C. helleri and C. s. scutulatus reflected the presence of 'isoforms' of the toxin in the venom. Whereas C. s. scutulatus generally has several isoforms of the toxin (detected by Western blotting), only one 'isoform' that focused at pI 5.1 was detected in C. helleri. Both acidic and basic subunits of MT sequences were obtained from C. helleri DNA with primers specific for MT, but only from snakes that had MT in their venom. The sequence identity of the C. helleri acidic subunit to the C. s. scutulatus subunit was 84.9%, whereas the sequence identity of the C. helleri basic subunit was 97% to the C. s. scutulatus basic subunit. Using casein, fibrin, and hide powder azure as substrates, assays for proteolytic activity suggested that C. helleri possesses several different types of metalloproteinases in their venom. However, proteolytic activity was not detected, or present in reduced amounts, in specimens having MT. Clinical neurotoxicity following envenomation by certain populations of C. helleri may be due to MT.

Snakes and snakebite in Central America

This review treats the general biology, taxonomy, distribution and venom apparatus of the venomous snakes of Central America. Consideration has been given to the chemistry, pharmacology and immunology of the venom, and particular attention is dispensed to the clinical problem, including the treatment, of envenomations by these reptiles.

Regional variation in the presence of canebrake toxin in Crotalus horridus venom

Reverse-phase HPLC was used to isolate the PLA complex neurotoxin "canebrake toxin" from the venom of Crotalus horridus from northern Florida. Individual venoms from 107 specimens of C. horridus throughout its range were investigated for the presence of the toxin. The distribution of canebrake toxin was limited to two separate regions, including a region of Louisiana, Arkansas and Oklahoma, and a separate region from southeastern South Carolina through eastern Georgia to northern Florida. Four distinct venom types were found and designated Venoms A (neurotoxic), B (hemorrhagic), A + B (neurotoxic and hemorrhagic) and C (lacking in both neurotoxic and hemorrhagic activities).

An investigation into the antigenic cross-reactivity of Ophiophagus hannah (king cobra) venom neurotoxin, phospholipase A2, hemorrhagin and L-amino acid oxidase using enzyme-linked immunosorbent assay

The antigenic cross-reactivity of four Ophiophagus hannah (king cobra) venom components, the neurotoxin (OH-NTX), phospholipase A2 (OH-PLA2), hemorrhagin (OH-HMG) and L-amino acid oxidase (OH-LAAO) were examined by indirect and double sandwich ELISAs. The indirect ELISAs for OH-NTX, OH-PLA2 and OH-HMG were very specific when assayed against the various heterologous snake venoms and O. hannah venom components, at 25 ng/ml antigen level. At higher antigen concentrations (100-400 ng/ml), there were moderate to strong indirect ELISA cross-reactions between anti-O. hannah neurotoxin and venoms from various species of cobra as well as two short neurotoxins. However, anti-O. hannah hemorrhagin did not cross-react with any of the venoms tested, even at these high antigen concentrations, indicating that O. hannah hemorrhagin is antigenically very different from other venom hemorrhagins. Examination of the indirect ELISA cross-reactions between anti-O. hannah PLA2 and several elapid PLA2 enzymes suggests that the elapid PLA2 antigenic class has more than two subgroups. The antibodies to O. hannah L-amino acid oxidase, however, yielded indirect ELISA cross-reactions with many venoms as well as with OH-NTX, OH-PLA2 and OH-HMG, indicating that OH-LAAO shares common epitopes even with unrelated proteins. The double sandwich ELISAs for the four anti-O. hannah venom components, on the other hand, generally exhibited a higher degree of selectivity than the indirect ELISA procedure.

Characterization and amino acid sequences of two lethal peptides isolated from venom of Wagler's pit viper, Trimeresurus wagleri

Two lethal toxins were isolated from Trimeresurus wagleri venom by fast protein liquid chromatography (molecular sieve) and high performance liquid chromatography (reverse phase). The toxins (termed peptide I and II) had mol. wt of 2504 and 2530, respectively, pIs of 9.6-9.9 and lacked phospholipase A, proteolytic, and hemolytic activity. Lethal peptide I had a murine i.p. LD50 of 0.369 mg/kg, while lethal II had a murine i.p. LD50 of 0.583 mg/kg. Peptide I retained full toxicity after autoclaving at 121 degrees C for 40 min. The lethal activity was found to represent less than 1% of the total venom protein, which was only 62-65% of crude venom. The amino acid sequence of peptide I revealed a proline-rich (over 30% of total sequence) sequence unique among snake venom toxins. Lethal peptide II showed the same sequence except for a second tyrosine in the position of histidine (residue No. 10) in peptide I. The toxin lacked antigenic identity with a number of representative neurotoxins and myotoxins. The crude venom shared at least one antigen with Crotalus scutulatus scutulatus venom. This antigen was not Mojave toxin. The toxin appears symptomatologically suggestive of a vasoactive peptide or neurotoxin.

Serum kinetics of crotoxin from Crotalus durissus terrificus venom in mice: evidence for a rapid clearance

We report on an ELISA for the detection of crotoxin with a detection limit of 1-3 pg/ml of sample. Cross-reactivity with other animal venoms occurred only at concentrations above 1 microgram/ml. Serum kinetics of crotoxin were investigated in BALB/c mice after a single 10 micrograms s.c. dose of venom obtained from Crotalus durissus terrificus. Crotoxin levels were 254 +/- 141 ng/ml serum (X +/- S.E.) 15 min after venom injection, 3.9 +/- 0.5 ng/ml serum at 30 min and undetectable thereafter. The rapid clearance of crotoxin from the serum suggests that the test may be unsuitable for the clinical management of envenomation victims.

The complete sequence of the acidic subunit from Mojave toxin determined by Edman degradation and mass spectrometry

Mojave toxin, a heterodimeric, neurotoxic phospholipase complex from Crotalus scutulatus scutulatus, is one of a group of closely related rattlesnake toxins for which much structural information is still lacking. The complete amino-acid sequence of the acidic subunit from Mojave toxin was determined. The three individual peptide chains, derived from the acidic subunit by reductive alkylation, were separated by high-performance liquid chromatography. Fragmentations of the A and B chains were done using specific proteinases and the resulting peptide mixtures were fractionated by reverse-phase high-performance liquid chromatography. Sequence analyses on the intact chains and the fragments from digests were done by automated Edman degradation, carboxypeptidase Y degradation and triple-quadrupole and tandem-quadrupole Fourier-transform mass spectrometry. The sequence for each acidic subunit chain is very similar to the corresponding chain from the related neurotoxin complex, crotoxin, and overall the sequence is similar to the sequences of group I and II phospholipases A2. The N-terminus of the B chain is blocked by pyroglutamic acid. The existence of two distinct and closely related C chains was established. It is unlikely that the small sequence difference can account for the isoforms that are present in purified Mojave toxin and in unfractionated venom.

Amino acid sequence of the basic subunit of Mojave toxin from the venom of the Mojave rattlesnake (Crotalus s. scutulatus)

The complete sequence of the basis subunit of Mojave toxin from the venom of the Mojave rattlesnake (Crotalus s. scutulatus) is presented. It is shown to have great similarity to the basic subunits of related toxins from the venoms of the South American and midget faded rattlesnakes.

Differences in distribution of myotoxic proteins in venoms from different Bothrops species

Antigens with high myotoxic activity were isolated from Bothrops jararacussu venom by Sephadex G-75 and SP-Sephadex C-25. These antigens were recognized using western blotting by B. jararacussu, B. moojeni, B. neuwiedi and B. pradoi antivenoms, and weakly by B. jararaca antivenom. B. alternatus, B. atrox, B. cotiara and B. erythromelas antivenoms failed to recognize these antigens. Antisera raised against these antigens recognized bands with mol. wt around 18,000 in the venoms of B. jararacussu, B. moojeni, B. neuwiedi and B. pradoi and reacted in ELISA with non-denaturated B. jararaca venom. However it failed to react in ELISA with nondenatured B. alternatus, B. atrox, B. cotiara and B. erythromelas venoms. The myotoxicity induced by these crude venoms confirmed that these antigens are possibly the only major myotoxin as the levels of creatine phosphokinase activity in mice serum released by intramuscular injection of B. jararacussu, B. moojeni, B. neuwiedi and B. pradoi venoms (myotoxin +) were five to eight-fold higher than those obtained with B. alternatus, B. atrox, B. cotiara, B. erythromelas and B. jararaca venoms. Using the double immunodiffusion technique the myotoxins of B. jararacussu, B. neuwiedi and B. pradoi showed total identity while B. moojeni myotoxin behaved as a partially identical antigen.

Venom characteristics as an indicator of hybridization between Crotalus viridis viridis and Crotalus scutulatus scutulatus in New Mexico

One hundred and thirteen venoms from 46 populations of Crotalus viridis viridis were screened by immunodiffusion for protein toxins antigenically similar to the phospholipase A2 (PLA) toxin 'Mojave toxin', using a polyclonal antibody to it's basic PLA subunit. Venom i.p. LD50 values in mice were recorded from 22 of the 46 populations. The venoms of three of 14 specimens from southwest (S.W.) New Mexico and one specimen from northern Arizona were immunologically positive by the immunodiffusion tests and produced low LD50 values (0.38-0.65 mg/kg) compared to all immunologically negative venoms (0.9-5.5 mg/kg). These four specimens were morphologically typical for C. v. viridis and their venoms were the only samples of 15 southern New Mexico specimens examined by reverse phase HPLC to exhibit peaks corresponding to the acidic and basic subunits of Mojave toxin. Alkaline polyacrylamide gel electrophoresis (PAGE) analysis of the recombined subunit peaks from the C.v. viridis venom from the S.W. New Mexico specimens showed more similarity to Mojave toxin from C.s. scutulatus venom than to similar toxins in C.v. concolor venom. The combined results of the immunodiffusion, lethal toxicity tests, HPLC profiles and PAGE analysis strongly suggest that the venoms of the three New Mexico specimens contain Mojave toxin(s), as a result of some previous hybridization with C.s. scutulatus. The northern Arizona specimen likely contains 'concolor toxin' through integration with C.v. concolor in its' genetic background.

Preliminary fractionation of tiger rattlesnake (Crotalus tigris) venom

Tiger rattlesnake (Crotalus tigris) venom was fractioned by using fast protein liquid chromatography (FPLC). The crude venom had low protease activity, lacked hemolytic activity and had an i.p. LD50 of 0.070 mg/kg for mice. Lethal fractions obtained by anion and cation exchange were examined for antigenic identity with crotoxin and Mojave toxin. Four toxins were obtained by anion exchange chromatography which showed immunoidentity with these toxins, and one fraction caused rear limb paresis in mice. A lethal toxin (about 10% of total venom protein) purified further with Superose-12 FPLC (molecular sieve) had an i.p. LD50 of 0.050 mg/kg for mice, reacted strongly with anti-crotoxin and anti-Mojave toxin antiserum in ELISA and immunoelectrophoresis. This toxin also showed complete immunoidentity with crotoxin and Mojave toxin in immunodiffusion assays with anti-crotoxin antiserum. The results indicated the presence of crotoxin and/or Mojave toxin isoforms in this venom. Although this species has a low venom yield (average 10 mg per snake), the venom is highly toxic and contains high concentrations of several neurotoxic isotoxins.

Comparative spectroscopic studies of four crotoxin homologs and their subunits

Structures of four related neurotoxins and their purified subunits from the venoms of Crotalus durissus terrificus, C. vegrandis, C. s. scutulatus and C. viridis concolor were examined by circular dichroism (CD), deconvolution Fourier-transform infrared (FTIR) and fluorescence spectroscopy. CD spectra suggest that in general, the isolated subunits were decreased slightly in alpha-helix, while they were increased in beta-sheet structure, relative to intact toxins. These results were consistent with FTIR results. Fluorescence quenching (50-80%) was also observed in three of the four intact toxins as compared to spectra predicted by summation of free acidic and basic subunit spectra. It was tempting to conclude from these results that major conformational changes occur in individual subunits upon formation of the dimeric toxins. Intact crotoxin, however, when exposed to urea, yields spectra (CD, FTIR and fluorescence) that are virtually identical to control intact crotoxin. These findings suggest that the enhanced fluorescence exhibited by the isolated subunits, as well as the secondary structural changes in alpha-helix and beta-sheet, are artifacts resulting from irreversible structural changes that occur during subunit isolation by urea ion-exchange chromatography. In spite of these structural changes, LD50 values of intact crotoxin reassembled from isolated subunits are unaltered from those of native crotoxin.

Immunological relationships of phospholipase A2 neurotoxins from snake venoms

Polyclonal rabbit antisera were raised against ten snake phospholipase A2 neurotoxins and one snake phospholipase A2 cytotoxin. Immunological cross-reactivities between these toxins, two other snake phospholipase A2 enzymes and pancreatic phospholipase A2 were studied using ELISA technology. All snake phospholipase A2 neurotoxins fell into two main antigenic classes. One antigenic class was composed of all the elapid toxins tested (textilotoxin, taipoxin, notexin, pseudexin and beta-bungarotoxin), the cytotoxic phospholipase A2 from Naja naja atra and pancreatic phospholipase A2. beta-Bungarotoxin seemed to be in an immunological subclass of its own compared to the rest of the elapid toxins. The second antigenic class was comprised of crotalid and viperid phospholipase A2 neurotoxins (crotoxin, concolor toxin, Mojave toxin, vegrandis toxin, ammodytoxin and caudoxin). Our data indicated that the viperid toxins, caudoxin and ammodytoxin, were an immunological subclass apart from the crotalid toxins.

Antigenic relationships of fractionated western diamondback rattlesnake (Crotalus atrox) hemorrhagic toxins and other rattlesnake venoms as indicated by monoclonal antibodies

Seven hemorrhagic factors have been isolated from Crotalus atrox venom, but their antigenic relationships have not been well studied. In this study, two different monoclonal antibodies, C. atrox peak 8 (CA-P-8) and C. atrox subclone 5 (CA-5+), were produced against two C. atrox venom hemorrhagic fractions and used in an ELISA (enzyme-linked immunosorbent assay) to determine if the hemorrhagic factors in C. atrox venom are antigenically related. The same ELISA test was used to determine cross-reactivity of seven other crude Crotalidae venoms. The two monoclonal antibodies were tested for their ability to neutralize each hemorrhagic HPLC fraction separated from C. atrox venom. C. atrox venom was fractionated into 22 fractions using HPLC analytical DEAE ion exchange. Fractions 4-17 were hemorrhagic. The CA-P-8 monoclonal antibody reacted strongly with hemorrhagic fraction 8; CA-5+ had a broader reactivity and reacted with several HPLC hemorrhagic and non-hemorrhagic fractions. Crude venoms of C. adamanteus, C. scutulatus scutulatus and C. viridis lutosus reacted with CA-P-8, while C. viridis lutosus, C. viridis oreganus, C. scutulatus scutulatus and C. horridus horridus reacted with CA-5+. C. molossus molossus and C. lepidus lepidus did not react with CA-P-8 and CA-5+. Hemorrhagic HPLC fractions 6, 7, 8, were completely neutralized by monoclonal antibody CA-P-8; fraction 9 was partially neutralized. The present study indicated that some C. atrox venom HPLC hemorrhagic fractions have both common and unique epitopes. Antigenic determinants were also found to be shared among different Crotalus species.(ABSTRACT TRUNCATED AT 250 WORDS)

Intergradation of two different venom populations of the Mojave rattlesnake (Crotalus scutulatus scutulatus) in Arizona

Two distinct venom populations of Crotalus scutulatus scutulatus exist in Arizona. The venom of one population (venom A) contains the toxin 'Mojave toxin' and is lacking in hemorrhagic and specific proteolytic activities. The other population (venom B) does not contain Mojave toxin but does produce hemorrhagic and proteolytic activities. The venoms of 15 Crotalus scutulatus scutulatus from regions between the venom A and venom B populations in Arizona were examined for the presence of Mojave toxin by immunochemical assay, lethality by mouse i.p. LD50, proteolytic activity and hemorrhagic activity in mice. Venom protein constituents were analyzed using reverse-phase HPLC. Seven venoms contained both the Mojave toxin of venom A and the proteolytic and hemorrhagic activities of venom B. The i.p. LD50 values of the A + B venoms were 0.4-2.6 mg/kg, compared to 0.2-0.5 mg/kg for venom A individuals and 2.1-5.3 mg/kg for the venom B individuals. HPLC illustrated that the A + B venoms exhibited a combined protein profile of venom A and venom B. These data indicate that an intergrade zone exists between the two venom types which arcs around the western and southern regions of the venom B population. Within these regions, three major venom types can occur in Crotalus s. scutulatus.

Preparation of a crotoxin neutralizing monoclonal antibody

Crotoxin is a heterodimeric protein composed of an acidic and basic subunit from the venom of Crotalus durissus terrificus and is representative of a number of presynaptically acting neurotoxins found in the venom of rattlesnakes. Four different monoclonal antibodies, typed as IgG1 subclass, were raised against the basic subunit of this toxin. One was a potent neutralizing antibody of intact crotoxin, which could neutralize approximately 1.6 moles of purified crotoxin per mole of antibody. The monoclonal antibody enhanced the neutralizing ability of commercial polyvalent crotalid antivenom against the lethality of crude C. d. terrificus venom four-fold. Paradoxically, this monoclonal antibody by itself was ineffective against the lethality of crude C. d. terrificus venom. Using an enzyme-linked immunosorbent assay, we tested various proteins for competitive inhibition of binding of biotinylated-crotoxin to plates coated with the four individual monoclonal antibodies. Concolor toxin, vegrandis toxin, intact crotoxin, Mojave toxin, and the basic subunit of crotoxin showed increasing effectiveness as displacers of crotoxin from the neutralizing monoclonal antibody. None of the monoclonal antibodies reacted with purified phospholipase A2 enzymes from Crotalus atrox or Crotalus adamanteus, nor any of the components present in the crude venoms from four different elapids known to contain presynaptically acting neurotoxins, which show some sequence identity to crotoxin.

Detection of myotoxin alpha-like proteins in various snake venoms

Ninety-five venom samples from eight snake genera (Agkistrodon, Bitis, Bothrops, Calloselasma, Crotalus, Sistrurus, Naja and Vipera) including venoms of Crotalus species of different geographical origin were assayed using immunodiffusion or an ELISA for the presence of the small basic protein, myotoxin alpha, known to cause muscle necrosis. Of the eight genera investigated, only Crotalus and Sistrurus venoms contained detectable amounts of myotoxin alpha-like proteins. The venoms of 13 out of 17 rattlesnake species investigated contained proteins immunologically similar to myotoxin alpha, including 12 Crotalus species and one Sistrurus species. The highest amounts were detected in venoms of C. exsul, C. viridis oreganus and C. v. viridis. Qualitative differences in the presence or absence of myotoxin alpha-like proteins were observed in the venoms of C. cerastes, C. horridus, C. lepidus, C. mitchelli, C. scutulatus, C. viridis and S. catenatus specimens of different geographic origin. The toxin was not detected in the venoms obtained from C. adamanteus, C. atrox, C. enyo or C. vegrandis specimens. The toxin appears to be widely distributed among rattlesnake species in the new world, but may vary qualitatively by geographical region in several species and subspecies.

Mojave toxin: rapid purification, heterogeneity and resistance to denaturation by urea

This report establishes that purified Mojave toxin prepared from the snake venom of Crotalus scutulatus scutulatus contains multiple heterogeneous dimers (isoforms) differing slightly in isoelectric points. This conclusion is based upon chromatographic, immunological, sodium dodecyl sulfate--polyacrylamide gel electrophoretic and polyacrylamide isoelectric focusing experiments. The Mojave toxin-related proteins were rapidly purified from venom via a single chromatography step. Generation of Mojave toxin-related proteins from isolated subunits and immunoblots of these proteins subsequent to electrophoretic separation demonstrate that each of the proteins consists of acidic and phospholipase basic subunits. The analysis of venom in narrow range polyacrylamide isoelectric focusing gels at varying concentrations of urea, in conjunction with immunoblots utilizing antibodies specific to the basic subunit, demonstrates that the isoforms of Mojave toxin are native and not artifacts from isolation procedures. Analyses of venoms from Crotalus scutulatus scutulatus individuals indicate that each snake produces multiple isoforms of the neurotoxin. Additionally, the same predominant isoform of Mojave toxin is present in both individual and commercial venoms. The heterogeneity of the Mojave toxin-related proteins is largely due to differences in the acidic subunits and some of the forms may reflect post-translational processing of the protein. The Mojave toxin-related proteins demonstrate a resistance to urea denaturation by characteristically entering and focusing in polyacrylamide isoelectric focusing gels containing 0-6 M urea, but dissociating to constituent subunits in 8 M urea. Experimental evidence suggest that salt bridges may be important in stabilization of the Mojave toxin complex.

Assignment of the aromatic 1H-NMR resonances of myotoxin a isolated from the venom of Crotalus viridis viridis

The 400 MHz 1H-NMR spectrum of myotoxin a from the venom of Crotalus viridis viridis is described. The identification of spin systems in the aromatic region corresponding to the six aromatic residues of myotoxin a was completed using both one- and two-dimensional NMR spectroscopy and the pH dependence of chemical shifts. Assignments of these spin systems to specific residues was possible for the singly occurring amino acids Tyr-1 and Phe-12. Resonances from Tyr-1, His-5 and His-10 were shifted significantly from their random coil values in a pH-dependent manner. These shift perturbations were deemed evidence of a helical arrangement of the amino terminal region which placed these residues in close proximity to each other.

A crotoxin homolog from the venom of the Uracoan rattlesnake (Crotalus vegrandis)

A major protein toxin from the venom of Crotalus vegrandis was examined by gel filtration, anion-exchange chromatography, and SDS polyacrylamide gel electrophoresis. The toxin was separated into several isoforms by ion-exchange chromatography and spontaneously dissociated into free acidic and basic subunits, mimicking the behavior of crotoxin. Rabbit antisera raised against crotoxin reacted strongly in enzyme-linked immunosorbent assays with the intact C. vegrandis toxin isoforms and their basic subunits, and formed precipitin lines of identity with intact crotoxin in double immunodiffusion gels. These results indicate that vegrandis toxin is strongly homologous with crotoxin from the venom of Crotalus durissus terrificus.

Cross-reactivity and neutralization by rabbit antisera raised against crotoxin, its subunits and two related toxins

Antisera were raised against intact crotoxin (Crotalus durissus terrificus), Mojave toxin (Crotalus scutulatus scutulatus) and concolor toxin (Crotalus viridis concolor), as well as the subunits of crotoxin. Double immunodiffusion and enzyme-linked immunosorbent assays (ELISA) demonstrated antigenic similarity between these three purified toxins and their subunits. Additionally, when crotoxin antisera were pre-incubated with each of the three toxins before injection, the lethal activity of all were neutralized equally well. Antiserum was considerably more effective in neutralizing crotoxin in vivo when the toxin was injected i.m. than when injected i.v. Antisera against both intact crotoxin and its basic subunit were an order of magnitude more effective than crotoxin acidic subunit antiserum in crotoxin neutralization. Purified phospholipase A2 from Crotalus adamanteus and Crotalus atrox showed weak cross-reactivity with antisera raised against intact crotoxin and its subunits in the ELISA. Our results suggest that crotalid neurotoxins can be detected and neutralized by polyclonal antibodies raised against any intact toxin or basic subunit in this group of homologous toxins.