Oral treatment with a rattlesnake native polypeptide crotamine efficiently inhibits the tumor growth with no potential toxicity for the host animal and with suggestive positive effects on animal metabolic profile.

The efficacy of crotamine as antitumoral was first demonstrated by daily intraperitoneal (IP) injections of low doses of this toxin in an animal model bearing melanoma tumors. Significant inhibition of tumor growth and increased lifespan of mice bearing tumor was also noticed after 21 consecutive days of this daily IP administration of crotamine. However, due to the limited acceptance of treatments by IP route in clinical conditions, herein, we evaluated the antitumor effect of this native polypeptide employing the oral route. The efficacy of crotamine in inhibiting the melanoma growth in vivo, even after passing through the gastrointestinal tract of the animal, was confirmed here. In addition, biochemical biomarkers and also histopathological analysis showed both the absence of any potential toxic effects in tissues or organs of the animal in which the highest accumulation of crotamine is expected. Interestingly, a reduction of weight gain was observed mainly in animals with tumor treated with crotamine by IP route, but not by oral administration. Albeit, oral administered crotamine was able to significantly decrease the body weight gain of healthy animals without tumor. Taking advantage of this same experimental animal models receiving crotamine by oral route, it was possible to show metabolic changes as the increased capacity of glucose clearance, which was accompanied by a reduction of the total cholesterol, and by increased high-density lipoprotein levels, both observed mainly in the absence of tumor. Triglycerides and low-density lipoprotein were also significantly decreased, but only in the absence of tumor. Taken together, these data suggest a clear trend for metabolic positive effects and mischaracterize unhealthy condition of animals, with or without tumors, treated with crotamine for 21 days. In addition, this study confirmed the efficacy of crotamine administered by oral route as antitumor agent, which besides the additional advantage of administration convenience and decreased risk of toxic effects, allowed the serendipitous observation of several positive metabolic effects on treated animals.

Crotamine induces browning of adipose tissue and increases energy expenditure in mice.

Crotamine, originally isolated from rattlesnake venom, has been extensively studied due to its pleiotropic biological properties, and special attention has been paid to its antitumor activity. However, long-term treatment with crotamine was accompanied by a reduction in animal body weight gain and by increases in glucose tolerance. As cancer is commonly associated with cachexia, to preclude the possible cancer cachexia-like effect of crotamine, herein this polypeptide was administered in healthy wild-type C57/BL6 mice by the oral route daily, for 21 days. Reduced body weight gain, in addition to decreased white adipose tissue (WAT) and increased brown adipose tissue (BAT) mass were observed in healthy animals in the absence of tumor. In addition, we observed improved glucose tolerance and increased insulin sensitivity, accompanied by a reduction of plasma lipid levels and decreased levels of biomarkers of liver damage and kidney disfunctions. Importantly, long-term treatment with crotamine increased the basal metabolic rate in vivo, which was consistent with the increased expression of thermogenic markers in BAT and WAT. Interestingly, cultured brown adipocyte cells induced to differentiation in the presence of crotamine also showed increases in some of these markers and in lipid droplets number and size, indicating increased brown adipocyte maturation.

Enzyme specificity and effects of gyroxin, a serine protease from the venom of the South American rattlesnake Crotalus durissus terrificus, on protease-activated receptors.

Gyroxin is a serine protease displaying a thrombin-like activity found in the venom of the South American rattlesnake Crotalus durissus terrificus. Typically, intravenous injection of purified gyroxin induces a barrel rotation syndrome in mice. The serine protease thrombin activates platelets aggregation by cleaving and releasing a tethered N-terminus peptide from the G-protein-coupled receptors, known as protease-activated receptors (PARs). Gyroxin also presents pro-coagulant activity suggested to be dependent of PARs activation. In the present work, the effects of these serine proteases, namely gyroxin and thrombin, on PARs were comparatively studied by characterizing the hydrolytic specificity and kinetics using PARs-mimetic FRET peptides. We show for the first time that the short (sh) and long (lg) peptides mimetizing the PAR-1, -2, -3, and -4 activation sites are all hydrolyzed by gyroxin exclusively after the Arg residues. Thrombin also hydrolyzes PAR-1 and -4 after the Arg residue, but hydrolyzes sh and lg PAR-3 after the Lys residue. The kcat/KM values determined for gyroxin using sh and lg PAR-4 mimetic peptides were at least 2150 and 400 times smaller than those determined for thrombin, respectively. For the sh and lg PAR-2 mimetic peptides the kcat/KM values determined for gyroxin were at least 6500 and 2919 times smaller than those determined for trypsin, respectively. The kcat/KM values for gyroxin using the PAR-1 and -3 mimetic peptides could not be determined due to the extreme low hydrolysis velocity. Moreover, the functional studies of the effects of gyroxin on PARs were conducted in living cells using cultured astrocytes, which express all PARs. Despite the ability to cleavage the PAR-1, -2, -3, and -4 peptides, gyroxin was unable to activate the PARs expressed in astrocytes as determined by evaluating the cytosolic calcium mobilization. On the other hand, we also showed that gyroxin is able to interfere with the activation of PAR-1 by thrombin or by synthetic PAR-1 agonist in cultured astrocytes. Taken together, the data presented here allow us showing that gyroxin cleaves PARs-mimetic peptides slowly and it does not induce activation of PARs in astrocytes. Although gyroxin does not mobilize calcium it was shown to interfere with PARs activation by thrombin and PAR-1 agonist. The determination of gyroxin enzymatic specificity and kinetics on PAR-1, -2, -3, and -4 will potentially help to fill the gap in the knowledge in this field, as the PARs are still believed to have a key role for the gyroxin biological effects.