Topical gel containing phenolic-rich extract from Ipomoea pes-capre leaf (Convolvulaceae) has anti-inflammatory, wound healing, and antiophidic properties.

The growing use of phytotherapy in clinical practice arouses interest in studies using medicinal plants as active ingredients for new medicines. Ipomoea pes-caprae has a wide medicinal use in the treatment of inflammatory disorders, skin wounds, stings, and painful rheumatic processes. Assayed in this study are the physicochemical characterization of a gel developed with this extract and the evaluation of its anti-inflammatory and healing efficacy, in addition to its antiedematogenic action on Bothrops snake envenoming in mice. The qualitative and quantitative analyses of the hydroethanolic extract by mass spectrometry showed 18 phenolic compounds, highlighting a high content of chlorogenic acid (0.92 µg/g), neochlorogenic acid (6.07 µg/g), and isochlorogenic acid (0.80 µg/g) compounds. The formulation was stable in relation to the physical-chemical characteristics during the time of analysis and was considered safe for topical treatment in animals, causing no skin irritation. Although the results have shown an absence of activity in the model of ear edema induced by croton oil (acute inflammation), the herbal gel efficiently inhibited carrageenan paw edema and chronic ear edema induced by multiple applications of croton oil, which may indicate the possible performance under the kinin pathway such as bradykinin, histamine, and serotonin. Wound healing in the group treated with the I. pes-caprae gel was accelerated compared with the placebo group, also confirmed through histological data. Edema induced by Bothrops erythromelas snake venom was efficiently reduced in the treatment with I. pes-caprae gel associated with the antibothropic-crotalic serum, whereas the antivenom alone was not effective. This approach presents a promising formulation based on I. pes-caprae with potential therapeutic use for inflammatory disorders.

Structural insights into the catalytic mechanism of sphingomyelinases D and evolutionary relationship to glycerophosphodiester phosphodiesterases.

Spider venom sphingomyelinases D catalyze the hydrolysis of sphingomyelin via an Mg(2+) ion-dependent acid-base catalytic mechanism which involves two histidines. In the crystal structure of the sulfate free enzyme determined at 1.85A resolution, the metal ion is tetrahedrally coordinated instead of the trigonal-bipyramidal coordination observed in the sulfate bound form. The observed hyperpolarized state of His47 requires a revision of the previously suggested catalytic mechanism. Molecular modeling indicates that the fundamental structural features important for catalysis are fully conserved in both classes of SMases D and that the Class II SMases D contain an additional intra-chain disulphide bridge (Cys53-Cys201). Structural analysis suggests that the highly homologous enzyme from Loxosceles bonetti is unable to hydrolyze sphingomyelin due to the 95Gly-->Asn and 134Pro-->Glu mutations that modify the local charge and hydrophobicity of the interfacial face. Structural and sequence comparisons confirm the evolutionary relationship between sphingomyelinases D and the glicerophosphodiester phosphoesterases which utilize a similar catalytic mechanism.