Specificity of hemorrhagic proteinase from Crotalus atrox (western diamondback rattlesnake) venom

Hemorrhagic proteinase, HTb, isolated from Crotalus atrox (western diamondback rattlesnake) venom was studied for its specificity. HTb showed fibrinogenase activity, hydrolyzing the A alpha chain of fibrinogen first, followed by the cleavage of the B beta chain. HTb is different from thrombin and did not produce a fibrin clot. The degradation products of fibrinogen were found to be different, indicating that the cleavage sites in the A alpha and B beta chains are different from those of thrombin. N-Benzoyl-Phe-Val-Arg-p-nitroanilide was not hydrolyzed by HTb, although this substrate was hydrolyzed by thrombin and reptilase.     

Anticoagulant proteases from western diamondback rattlesnake (Crotalus atrox) venom

Crotalus atrox venom contains agents that render human fibrinogen and plasma incoagulable by thrombin. To elucidate the mechanism of alteration of fibrinogen clotting function by the venom, four immunochemically different proteases, I, II, III, and IV, were purified from the venom by anion-exchange chromatography and column gel filtration. All four proteases had anticoagulant activity rendering purified fibrinogen incoagulable. Proteases I and IV do not affect fibrinogen in plasma but in purified fibrinogen cleave the A alpha chain first and then the B beta and gamma chains. Both enzymes are metalloproteases containing a single polypeptide chain with 1 mol of zinc, are inhibited by (ethylenedinitrilo)tetraacetate and human alpha 2-macroglobulin, and have an optimal temperature of 37 degrees C and an optimal pH of 7. Protease I has a molecular weight (Mr) of 20 000 and is the most cationic. Protease IV has an Mr of 46 000 and is the most anionic glycoprotein with one free sulfhydryl group. Proteases II and III degrade both purified fibrinogen and fibrinogen in plasma, cleaving only the B beta chain and leaving the A alpha and gamma chains intact. Both enzymes are alkaline serine proteases, cleave chromogenic substrates at the COOH terminal of arginine or lysine, are inhibited by diisopropyl fluorophosphate and phenylmethanesulfonyl fluoride, and have an optimal temperature of 50-65 degrees C. Protease II is a single polypeptide chain glycoprotein with an Mr of 31 000. Protease III is a two polypeptide chain protein with an Mr of 24 000, each of the two chains having an Mr of 13 000; its activity is not affected by major protease inhibitors of human plasma. Proteases II and III are enzymes with unique and limited substrate specificity by cleaving only the B beta chain, releasing a peptide of Mr 5000 and generating a fibrinogen derivative of Mr 325 000, with intact A alpha and gamma chains and poor coagulability. Since the two enzymes are active in human plasma and serum, it is postulated that proteases II and III can mediate anticoagulant effects in vivo after envenomation.     

Proteolytic specificity of hemorrhagic toxin b from Crotalus atrox (western diamondback rattlesnake) venom

In our effort to identify the proteolytic specificity of various hemorrhagic toxins isolated from western diamondback rattlesnake venom, hemorrhagic toxin b was isolated in homogeneous form by previously published methods. Hemorrhagic toxin b hydrolyzed glucagon, producing six fragments. The proteolytic sites were identified as Thr(5)-Phe(6), Thr(10)-Ser(11), Asp(15)-Ser(16), Asp(21)-Phe(22) and Try(25)-Leu(26). When oxidized insulin B chain was used, proteolysis occurred at four sites: Asn(3)-Gln(4), His(10)-Leu(11), Tyr(16)-Leu(17) and Gly(23)-Phe(24). The proteolytic specificity of hemorrhagic toxin b is quite different from those of the nonvenom proteases such as thermomycolin, aspergillopeptidase c, alkaline protease from Aspergillus flavus, elastase, subtilisin and papain.     

Isolation and biochemical characterization of hemorrhagic toxin f from the venom of Crotalus atrox (western diamondback rattlesnake)

Hemorrhagic toxin f (HT-f) was isolated from Crotalus atrox (Western Diamondback Rattlesnake) venom by a five-step purification procedure. Homogeneity was established by the formation of a single band in acrylamide gel electrophoresis, isoelectric focusing, and sodium dodecyl sulfate (SDS)-electrophoresis. HT-f has a molecular weight of 64,000 and contains 572 amino acid residues. It contains 1 mol of zinc per mol of protein. Zinc is essential for both hemorrhagic and proteolytic activities. HT-f possesses proteolytic activity hydrolyzing the Val-Asn, Gln-His, Leu-Cys, His-Leu, Ala-Leu, and Tyr-Leu bonds of oxidized insulin B chain. HT-f did not coagulate fibrinogen to fibrin, yet it did hydrolyze the gamma chain of fibrinogen without affecting either the A alpha or B beta chains. This is the first time that a hemorrhagic toxin was shown to have fibrinogenase activity. HT-f was shown to differ immunologically from other hemorrhagic toxins such as HT-a and HT-c. HT-f also possesses lethal toxicity. When zinc was removed the apo-HT-f lost its lethal toxicity. HT-f produced not only local hemorrhage in the skin and muscle, but also produced systemic hemorrhage in internal organs such as the intestine, kidney, lung, heart, and liver.     

Characterization of two hemorrhagic zinc proteinases, toxin c and toxin d, from western diamondback rattlesnake (Crotalus atrox) venom

Two hemorrhagic proteinases from Crotalus atrox venom, hemorrhagic toxin c (Ht-c) and hemorrhagic toxin d (Ht-d), were characterized and compared to one another. The two toxins are zinc metalloproteinases which both have molecular weights of 24,000. Their isoelectric points are slightly acidic, Ht-c being the more basic of the two with an isoelectric point of 6.2, whereas Ht-d has an isoelectric point of 6.1. Only minor differences were found in the amino acid compositions of the two toxins. The toxins were both demonstrated to be hemorrhagic, using an in vivo assay, and also proteolytic. Prior treatment of the hemorrhagic proteinases with ethylenediaminetetraacetic acid and o-phenanthroline eliminated both the hemorrhagic and the proteolytic activities. Aprotinin and phenylmethylsulfonyl fluoride had no effect upon these activities. The pH optimum of the proteolysis by Ht-c and Ht-d on hide powder azure as the substrate was between pH 8 and pH 9. The circular dichroism spectra for Ht-c and Ht-d appear almost identical with respect to minima positions and elipticities, indicative of very similar solution structures for the two enzymes. Antiserum raised in mice against Ht-c was assayed on double-diffusion Ouchterlony plates for cross-reactivity with other hemorrhagic toxins from C. atrox venom. From this experiment it was concluded that the two hemorrhagic proteinases Ht-c and Ht-d share identical antigenic structures. This was corroborated by tryptic mapping of the two toxins. Only one major difference was observed from the maps. In the case of Ht-c, it was determined that an aspartate was substituted by an alanine when compared to Ht-d. From these characterization studies we conclude that Ht-c and Ht-d are isoenzymes with only very minor differences in their structures.     

Mechanisms controlling venom expulsion in the western diamondback rattlesnake, Crotalus atrox

Although many studies have documented variation in the amount of venom expended during bites of venomous snakes, the mechanistic source of this variation remains uncertain. This study used experimental techniques to examine how two different features of the venom delivery system, the muscle surrounding the venom gland (the Compressor Glandulae in the rattlesnake) and the fang sheath, could influence venom flow in the western diamondback rattlesnake, Crotalus atrox. Differential contraction of the Compressor Glandulae explained only approximately 30% of the variation in venom flow. Lifting (compression) of the fang sheath as occurs during a normal strike produced marked increases in venom flow; these changes were closely correlated and exceed in magnitude by almost 10 x those recorded from the Compressor Glandulae alone. These results suggest that variation in these two aspects of the venom delivery system--both in terms of magnitude and temporal patterning--explain most of the observed variation in venom injection. The lack of functional or mechanical links between the Compressor Glandulae and the fang sheath, and the lack of skeletal or smooth muscle within the fang sheath, make it unlikely that variation in venom flow is under direct neural control. Instead, differential venom injection results from differences in the pressurization by the Compressor Glandulae, the gate keeping effects of the fang sheath and enclosed soft-tissue chambers, and by differences in the pressure returned by peripheral resistance of the target tissue.     

Proteome analysis of the thermoreceptive pit membrane of the western diamondback rattlesnake Crotalus atrox

Rattlesnakes detect their prey's temperature by means of a cavern-like structure, the pit organ. The sensory component of this organ lies within a thin membrane called the pit membrane. Proteome analysis conducted on this neurosensory tissue revealed only a relatively small number of proteins, thereby depicting its high degree of specialization. In addition to containing blood serum and structural proteins, the proteome of this membrane appears to be strikingly similar to that of isolated rattlesnake brain mitochondria. Indeed, our results show that over 80% of the detected tissue proteins are of mitochondrial origin. Fluorescence microscopy studies of these organelles indicate their dense arrangement and accumulation in structures which have been previously reported to be the terminal ends of free nerve fibers of the innervating trigeminal branches. Thus, original ultrastructural observations are paralleled by our findings at the molecular level.     

Variation in oxygen consumption of the western diamondback rattlesnake (Crotalus atrox): implications for sexual size dimorphism

Variation in metabolism affects energy budgets of individuals and may serve as a mechanism that influences variation at whole organism or population levels. For example, sex differences in metabolic expenditure may contribute to bioenergetic sources of sexual size dimorphism. We measured oxygen consumption rates of 48 western diamondback rattlesnakes (Crotalus atrox) from a sexually dimorphic population and tested the effects of body mass, body temperature and time of day, in three groups of snakes: males, non-reproductive females, and vitellogenic females. Metabolic rates of male and non-reproductive female C. atrox were similar to rates reported for other rattlesnakes (mass exponents ranging from 0.645–0.670). Oxygen consumption was affected by body mass, body temperature and time of day, and was approximately 1.4 times greater in vitellogenic females than in non-reproductive females. No differences were found between males and non-reproductive females. Accordingly, differences in metabolic rate apparently do not contribute directly to sexual dimorphism in this population. Nevertheless, estimates of size-dependent maintenance expenditure lead us to hypothesize that adult female body size may represent a compromise between selection for increased litter size (accomplished by increasing body size), and selection for increased reproductive frequency (accomplished by decreasing body size, and, therefore inactive maintenance expenditure); this is a mechanistic scenario suggested previously for some endotherms. Accepted: 20 May 1998     

Isolation of a crotalase-like protease with alpha-fibrinogenase activity from the western diamondback rattlesnake, Crotalus atrox.

Venom toxins were isolated from rattlesnake (Crotalus atrox) venom by cation-exchange chromatography. Seven major fractions could be obtained by single-step ion-exchange chromatography with two fractions showing essentially apparent homogeneity by SDS-gel electrophoresis. All fractions showed various extents of specific proteolytic activity against alpha- or beta-chains of fibrinogen molecules. Further characterization of one of the purified fractions with alpha-fribrinogenase activity indicated that it is a single-chain thrombin-like protease with a molecular mass of about 30 kDa. It is relatively heat stable, inhibited by phenylmethanesulfonyl fluoride, N alpha-p-tosyl-L-phenylalanine chloromethyl ketone and N alpha-p-tosyl-L-lysine chloromethyl ketone but not by soybean trypsin inhibitor and beta-mercaptoethanol. Amino acid analysis showed that the enzyme possesses an amino acid composition very similar to thrombin and crotalase characterized before from the closely related snake venoms. N-Terminal sequence analysis of the enzyme corroborated the close similarity between this enzyme and those sequences of crotalase and kallikrein-like enzymes characterized from the same Crotalidae snake family. This study is in contrast to the previous reports which indicated a lack of thrombin- and crotalase-like enzyme in the venom of Western diamondback rattlesnake.     

Phylogeographic structure and historical demography of the western diamondback rattlesnake (Crotalus atrox): A perspective on North American desert biogeography

The western diamondback rattlesnake (Crotalus atrox) is a prominent member of North American desert and semi-arid ecosystems, and its importance extends from its impact on the region's ecology and imagery, to its medical relevance as a large deadly venomous snake. We used mtDNA sequences to identify population genetic structure and historical demographic patterns across the range of this species, and relate these to broader patterns of historical biogeography of desert and semi-arid regions of the southwestern USA and adjacent Mexico. We inferred a Late Pliocene divergence between peninsular and continental lineages of Crotalus, followed by an Early Mid Pleistocene divergence across the continental divide within C. atrox. Within desert regions (Sonoran and Chihuahuan Deserts, Southern Plains, and Tamaulipan Plain) we observed population structure indicating isolation of populations in multiple Pleistocene refugia on either side of the continental divide, which we attempt to identify. Evidence of post-glacial population growth and range expansion was inferred, particularly in populations east of the continental divide. We observed clear evidence of (probably recent) gene flow across the continental divide and secondary contact of haplotype lineages. This recent gene flow appears to be particularly strong in the West-to-East direction. Our results also suggest that Crotalus tortugensis (Tortuga Island rattlesnake) and a population of 'C. atrox' inhabiting Santa Cruz Island (in the Gulf of California) previously suggested to be an unnamed species, are in fact deeply phylogenetically nested within continental lineages of C. atrox. Accordingly, we suggest C. tortugensis and 'C. atrox' from Santa Cruz Island be placed in the synonymy of C. atrox.     

Prey envenomation does not improve digestive performance in western diamondback rattlesnakes (Crotalus atrox)

Although the toxic properties of snake venoms have been recognized throughout history, very little is known about the adaptive significance of these powerful mixtures. This study examined the popular hypothesis that prey envenomation enhances digestion by influencing the energetic costs of digestion and assimilation, gut passage time, and apparent assimilation efficiency (ASSIM) in western diamondback rattlesnakes (Crotalus atrox), a species whose venom is recognized for its comparatively high proteolytic activities. A complete randomized block design allowed repeated measures of specific dynamic action and gut passage time to be measured in eight snakes ingesting four feeding treatments (i.e., artificially envenomated live mice, artificially envenomated prekilled mice, saline injected live mice, and saline injected prekilled mice). A second experiment measured ASSIM in eight snakes ingesting a series of six artificially envenomated or six saline injected mice meals over an 8-week period. Contrary to expectations, the results of both these experiments revealed that envenomation had no significant influence on any of the measured digestive performance variables. Gut passage time averaged 6 days and ASSIM averaged 79.1%. Twenty-one hours following ingestion, postprandial metabolic rates exhibited factorial increases that averaged 3.9-fold greater than resting metabolic rate. Specific dynamic action lasted on average 88 hr and accounted for 26% of the total ingested energy. The results of this study reinforce the need to systematically examine the potential adaptive advantages that venoms confer on the snakes that produce them.     

Characterization of a protease with alpha- and beta-fibrinogenase activity from the Western diamondback rattlesnake, Crotalus atrox.

A metalloprotease from the rattlesnake Crotalus atrox venom was isolated and purified from multiple-step chromatographies including anion-exchange chromatography, gel permeation and reversed-phase HPLC. The fraction was shown to be homogeneous as judged by SDS-gel electrophoresis. It also showed a high proteolytic activity against alpha- and beta-chains of fibrinogen molecules. Further characterization of the purified fraction with fibrinogenase activity indicated that it is a single-chain protease with a molecular mass of about 24 kDa and an acidic isoelectric point. It is relatively heat stable up to about 65 degrees C, inhibited by EDTA, beta-mercaptoethanol, but not by phenylmethanesulfonyl fluoride, N alpha-p-tosyl-L-phenylalanine chloromethyl ketone and N alpha-p-tosyl-L-lysine chloromethyl ketone, soybean trypsin inhibitor and aprotinin. Amino acid analysis showed that the enzyme possesses an amino acid composition very similar to some metalloproteases characterized before from the closely related rattlesnake venoms. N-Terminal sequence analysis of the enzyme corroborated some similarity between this enzyme and the reported sequences of these enzymes characterized from the Crotalidae snake family. This study indicated the presence of a novel fibrinogenase (termed Catroxase) with N-terminal sequence different from the metalloprotease with hemorrhagic activity isolated from the same Western diamondback rattlesnake.     

Hemorrhagic toxins from Western diamondback rattlesnake (Crotalus atrox) venom: isolation and characterization of five toxins and the role of zinc in hemorrhagic toxin e.

Five previously unknown hemorrhagic proteins, designated hemorrhagic toxins a,b,c,d, and e, were isolated from the venom of the western diamondback rattlesnake (Crotalus atrox). Molecular weights of hemorrhagic toxins a-e were determined to be 68 000, 24 000, 24 000, 24 000, and 25 700, respectively, by sodium dodecyl sulfate-phosphate gel electrophoresis using various polyacrylamide gel concentrations. Amino acid composition showed a total of 636, 200, 213, 214, and 219 amino acids for hemorrhagic toxins a-e, respectively. All the hemorrhagic toxins were found to lose their hemorrhagic activities with the metal chelators ethylenediaminetetraacetic acid and 1, 10-phenanthroline. All the hemorrhagic toxins were found to contain approximately 1 mol of zinc/mol of toxin, and they were all demonstrated to be proteolytic when dimethylcasein and dimethylhemoglobin were used as substrates. When zinc was removed from hemorrhagic toxin e with 1,10-phenanthroline, both both the proteolytic and hemorrhagic activities were equally inhibited. When the apohemorrhagic toxin e thus produced was incubated with zinc, the hemorrhagic and proteolytic activities were regenerated to the same extent. CD, UV, and Raman spectroscopy were used to study the structure of native hemorrhagin toxin e as well as the structural changes caused by zinc removal. From CD spectroscopy the native toxin was estimated to consist of 23% alpha helix, 6% beta structure, and 71% random-coil conformation. When over 90% of the zinc was removed, the alpha-helix content dropped from 23 to 7%.     

Purification and characterization of a fibrinogenase from the venom of Western Diamondback rattlesnake (Crotalus atrox)

A fibrinogenolytic enzyme was isolated from the venom of Western Diamondback rattlesnake (Crotalus atrox) by a three-step procedure involving gel filtration and anion-exchange chromatography. The molecular weight was estimated as 22 900 by SDS-polyacrylamide gel electrophoresis. The isoelectric point was found to be pH 4.65. The enzyme rapidly destroyed the ability of bovine fibrinogen to form a clot on incubation with thrombin. Incubation of fibrinogen with the fibrinogenolytic enzyme for 5 min resulted in the disappearance of the beta-chain of fibrinogen and the appearance of lower molecular weight fragments. Thus the enzyme can be classified as a beta-fibrinogenase. However, on prolonged incubation of the fibrinogen there was also a partial digestion of the alpha-chain. The fibrinogenase showed no activity towards fibrin or casein or arginine esters. The fibrinogenolytic activity was inhibited by phenylmethanesulphonyl fluoride (PMSF) but was unaffected by EDTA.     

Scale variation in a laboratory colony of amelanistic diamondback rattlesnakes (Crotalus atrox)

Inbreeding for 6 generations has produced a strain of amelanistic western diamondback rattlesnakes (Crotalus atrox) with extremely variable scalation. Forty-four siblings varying from virtually no body scalation to normal scalation have been produced in the latest generation. Two of the 3 most extreme “scaleless” snakes were stillborn; the third was maintained for > 1 year. Two of 7 snakes with greatly reduced head and body scales have died; however, the remaining 5 are being maintained and appear to be growing and healthy at 5 or 6 years of age. All snakes with reduced body scales have abnormal ventral scutes. Fifteen snakes with predominantly normal body scales have anomalous head scales, head scale patterns, and ventral scutes. One snake has predominantly normal scalation except for aberrant ventrals. A total of 18 Generation VI snakes have been classified as “normal,” although all snakes were not closely examined before disposition. Nine of the more normally scaled generation VI snakes are also being maintained in the laboratory. It is difficult to separate the genetic and environmental components of these phenotypes with existing information; however, it seems apparent that more than a single locus is involved. © 1994 Wiley-Liss, Inc.     

Phenotypic integration in the feeding system of the eastern diamondback rattlesnake (Crotalus adamanteus)

Selection can vary geographically across environments and temporally over the lifetime of an individual. Unlike geographic contexts, where different selective regimes can act on different alleles, age‐specific selection is constrained to act on the same genome by altering age‐specific expression. Snake venoms are exceptional traits for studying ontogeny because toxin expression variation directly changes the phenotype; relative amounts of venom components determine, in part, venom efficacy. Phenotypic integration is the dependent relationship between different traits that collectively produce a complex phenotype and, in venomous snakes, may include traits as diverse as venom, head shape and fang length. We examined the feeding system of the eastern diamondback rattlesnake (Crotalus adamanteus) across environments and over the lifetime of individuals and used a genotype–phenotype map approach, protein expression data and morphological data to demonstrate that: (i) ontogenetic effects explained more of the variation in toxin expression variation than geographic effects, (ii) both juveniles and adults varied geographically, (iii) toxin expression variation was a result of directional selection and (iv) different venom phenotypes covaried with morphological traits also associated with feeding in temporal (ontogenetic) and geographic (functional) contexts. These data are the first to demonstrate, to our knowledge, phenotypic integration between multiple morphological characters and a biochemical phenotype across populations and age classes. We identified copy number variation as the mechanism driving the difference in the venom phenotype associated with these morphological differences, and the parallel mitochondrial, venom and morphological divergence between northern and southern clades suggests that each clade may warrant classification as a separate evolutionarily significant unit.