In Fig. 3A, we found that the fraction Fv6 presented a strong and single band of 65 kDa; fractions Fv7, Fv8 and Fv9 showed similar bands of 65 and 75 kDa and fractions Fv10 Fv11 presented the same two bands with lower intensity, ABT 263 a band of 48 kDa and an intense band of 12 kDa. In Fig. 3B, the fractions of the skin mucus presented more and complex protein bands. The fraction Fm8 presented an intense band of 62 kDa that was also present on the fraction Fm9 with other compounds up to 74 kDa and under

18 kDa. The fraction Fm10 can be considered the most complex presenting bands of approximately 40 kDa and at least 7 bands under 25 kDa. Fractions Fm11, Fm12 and Fm13 showed similar profiles, an intense band of 46 kDa and 12 kDa and a weak band of 23 kDa. Together, these results show that sting venom and skin mucus have distinct constituents that distinguished them like structural proteins, chaperones, ion transport, carbohydrate metabolism, oxidoreductase, cell cycle and protein binding present in sting venom

and like tropomyosin 3 isoform 2 and energy metabolim proteins in skin mucus. But in a group of common 13 proteins we identified and isolated a WAP65 protein. Next we evaluated the inflammatory effects of peptide Ruxolitinib chemical structure and protein fractions on microcirculation in mouse cremaster muscle by intravital microscopy. The topical application of 10 μL of the sting venom, skin mucus and

each fraction induced changes in the microcirculatory environment (i.e. rolling of leukocytes, changes in blood flow and vessel diameter). learn more Peptide fractions of sting venom (4 and 5) and of skin mucus (3, 4, 5, and 7) were able to increase the number of rolling leukocytes, but in contrast, fractions 1 to 3 of the sting venom and 1, 2 and 6 of the skin mucus were unable to elicit leukocyte mobilization (Fig. 4 and Fig. 5). The peptide sting venom fraction Fv4 induced the highest increase of rolling leukocytes compared to Fv5 and to sting venom or PBS. The number of rolling leukocytes induced by Fv5 after 10 min remained similar until 30 min after application. Until 20 min, all peptide skin mucus fractions induced elevated number of rolling leukocytes, but at 30 min after application of samples, the fraction Fm3 presented the higher capacity of increase the number of rolling leukocyte (Fig. 4). In Fig. 5A we observed that all protein sting venom fractions except for Fv6, exhibited the capacity to induce moderate increase of rolling leukocyte during 30 min of observation. Interestingly, Fv6 that showed as a unique band in SDP-PAGE induced the highest increase of rolling leukocyte until 20 min after topical application that diminished thereafter, remained similar to all protein sting venom fractions.