Characterization of the antinociceptive effect of peptides homologous to the C-terminus of murine S100A9 protein. Effects on sensory neurons, via type-N voltage-dependent calcium channels

Peptide identical to the C-terminus of S100A9 protein (mS100A9pH92-G110) inhibits inflammatory hyperalgesia induced by carrageenan and trypsin, a serine protease that activates protease-activated receptors 2 (PAR2). The aim of this work was to characterize the relationship between structure and function of mS100A9p in order to identify the shortest peptide sequence endowed with antinociceptive effect. Furthermore, the mechanisms involved on the antinociceptive effect of both mS100A9p and the shortest homologous sequence on PAR2-induced hyperalgesia were also evaluated. Different peptide sequences homologous to mS100A9p were synthesized and evaluated in rats submitted to the carrageenan-induced mechanical hyperalgesia model. Among all evaluated sequences, the peptide AcE97-G102 was found to be the shortest sequence that showed an antinociceptive effect similar to that induced by mS100A9p. In regard to PAR2 activation, data obtained herein demonstrated that both mS100A9p and AcE97-G102 inhibit PAR2-induced mechanical and thermal hyperalgesia, induced by the selective agonist peptide ? PAR2AP. Imunohistochemical evaluation demonstrated that PAR2 activation increased Egr-1 protein expression on sensory neurons and mS100A9p inhibited this effect. In addition, both mS100A9p and AcE97-G102 inhibited PAR2- and trypsin-induced calcium influx in dorsal root ganglia neurons (DRG). On the other hand, no effect on the calcium influx of the peptides were observed on HEK-293 cells or KNRK-PAR2 transfected cells, suggesting that the effects of mS100A9p and AcE97-G102 on PAR2 activation are specific for sensory neurons. Both mS100A9p and AcE97-G102 inhibited DRG calcium flux when cells were stimulated with bradykinin, capsaicin or KCl. Also, mS100A9p inhibited PAR2-induced substance P release in DRG. Treatment of DRG with either thapsigargin or calcium ionophore suggest a direct effect of mS100A9p on calcium channels. To evaluate this hypothesis the effects of mS100A9p and AcE97-G102 were evaluated on N-type or L-type voltage-dependent calcium channel transfected HEK-tsA cells. Both peptides inhibited calcium influx of N-type transfected cells. In conclusion, data presented herein demonstrate that the C-terminus of murine S100A9 protein inhibits experimental nociception through a block of N-type voltage-dependent calcium channels, directly on sensory neurons. Also, the domain involved in this effect is localized on the sequence E97-G102 of the C-terminus of murine S100A9 protein. (AU)