Inflammatory peptides display different types of post-transcriptional modifications, such as C-terminal amidation, that alter their biological activity. Here we describe the structural and molecular dynamics features of the mast cell degranulating peptide, eumenine mastoparan-AF (EMP-AF-NH(2)), found in the venom of the solitary wasp, and of its carboxyl-free C-terminal form (EMP-AF-COO(-)) characterized by a reduced activity. Circular dichroism indicates that both peptides switch from a random coil conformation in water to a helical structure in TFE and SDS micelles. NMR data, in 30% TFE, reveal that the two peptides fold into an alpha-helix spanning most of their length, while they differ in terms of molecular rigidity. To understand the origins of the conformational flexibility observed in the case of EMP-AF-COO(-), a 5 ns MD simulation was carried out for each peptide, in an explicit water/TFE environment. The results show that the two peptides differ in an H-bond between Leu14 NH(2) and the backbone carbonyl of Ile11. The loss of that H-bond in EMP-AF-COO(-) leads to a significant modification of its structural dynamics. In fact, as evidenced by essential dynamics analysis, while EMP-AF-NH(2) exists mainly as a rigid structure, EMP-AF-COO(-) presents two helical stretches that fluctuate in some sort of independent fashion. We conclude that the diverse biological activity of the two peptides is not simply due to the reduction of the net positive charge, as generally suggested, but also to a structural perturbation of the amphipathic alpha-helix that affects their ability to perturb the cell membrane.
Hemoglobin is known to be a source of peptides involved in several functions. The peptide FLSFPTTKTYFPHFDLSHGSAQVKGHGAK (Hb33-61) is a proteolytic product of the bovine hemoglobin alpha-chain found in the gut content of the cattle tick, Boophilus microplus, and it possesses antimicrobial activity. Since in the past we showed that the amidated form of Hb33-61, Hb33-61a, is active against a few Gram-positive bacteria and fungi strains at micromolar concentration [Fogaca et al. (1999) J. Biol. Chem. 274, 25330-25334], we have been prompted to shed more light on its functional and structural features. Here we show that the peptide is able to disrupt the bacterial membrane ofMicrococcus luteus A270. As for its structure, it has a random conformation in water, and it does not interact with zwitterionic micelles. On the other hand, it binds to negatively charged micelles acquiring a finite structural organization. The 3D structure of Hb33-61a bound to SDS micelles exhibits a nonconventional conformation for an antimicrobial peptide. The backbone is characterized by the presence of a beta-turn in the N-terminus and by a beta-turn followed by a alpha-helical stretch in the C-terminus. A hinge, whose spatial organization is stabilized by side-chain-side-chain interactions, joins these two regions. Interestingly, it preserves structural features present in the corresponding segment of the bovine hemoglobin alpha-chain. Hb33-61a does not possess a well-defined amphipathic nature, and H/D exchange experiments show that while the C-terminal region is embedded in the SDS micelle, one face of the N-terminal half is partly exposed to the solvent.
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