PMAP-36

The growing problem of antibiotic resistance has attracted people's attention; thus, the search for new antibacterial agents is imminent. In this study, a series of antimicrobial peptides (AMPs) based on the porcine antibacterial peptide PMAP-36 were designed by amino acid substitution to develop peptide analogues as new classes of antimicrobial agents. By extending the α-helix and increasing the positive charge, two peptide analogues, PMAP-36PW and PMAP-36PK, were synthesized. The antibacterial activities of PMAP-36 and its peptide analogues were detected in vitro and in vivo. The results showed that PMAP-36PW and PMAP-36PK had a broadened antibacterial spectrum compared to that of PMAP-36. After the modification, PMAP-36PW and PMAP-36PK exhibited antibacterial activities on swine Escherichia coli K88, while PMAP-36 did not. PMAP-36, PMAP-36PW and PMAP-36PK did not have antibacterial activities against Enterococcus faecium B21. PMAP-36 PW had significant antibacterial activity against seven bacterial strains compared to PMAP-36, and PMAP-36PK had significant antibacterial activity against five bacterial strains compared to PMAP-36. Furthermore, PMAP-36PW exhibited enhanced pH stability. Moreover, in the in vivo efficacy assessment of mice infected with Salmonella choleraesuis C78-1 and Listeria monocytogenes CICC 21533, the peptide analogues exhibited an impressive therapeutic effect by reducing bacterial gene copies and decreasing inflammatory damage in mouse livers and lungs, resulting in a reduction in mouse mortality. This study provides reference data for the design of clinically effective antibacterial peptides.

Host defense peptides (HDPs), such as cathelicidins, are small, cationic, amphipathic peptides and represent an important part of the innate immune system. Most cathelicidins, including the porcine PMAP-36, are membrane active and disrupt the bacterial membrane. For example, a chicken cathelicidin, CATH-2, has been previously shown to disrupt both Escherichia coli membranes and to release, at sub-lethal concentrations, outer membrane vesicles (OMVs). Since OMVs are considered promising vaccine candidates, we sought to investigate the effect of sub-bactericidal concentrations of PMAP-36 on both OMV release by a porcine strain of Bordetella bronchiseptica and on the modulation of immune responses to OMVs. PMAP-36 treatment of bacteria resulted in a slight increase in OMV release. The characteristics of PMAP-36-induced OMVs were compared with those of spontaneously released OMVs and OMVs induced by heat treatment. The stability of both PMAP-36- and heat-induced OMVs was decreased compared to spontaneous OMVs, as shown by dynamic light scattering. Furthermore, treatment of bacteria with PMAP-36 or heat resulted in an increase in negatively charged phospholipids in the resulting OMVs. A large increase in lysophospholipid content was observed in heat-induced OMVs, which was at least partially due to the activity of the outer-membrane phospholipase A (OMPLA). Although PMAP-36 was detected in OMVs isolated from PMAP-36-treated bacteria, the immune response of porcine bone-marrow-derived macrophages to these OMVs was similar as those against spontaneous or heat-induced OMVs. Therefore, the effect of PMAP-36 addition after OMV isolation was investigated. This did decrease cytokine expression of OMV-stimulated macrophages. These results indicate that PMAP-36 is a promising molecule to attenuate undesirable immune responses, for instance in vaccines.

Host defense peptides (HDPs) play a pivotal role in innate immunity and have, in addition to antimicrobial activity, also important immunomodulatory functions. Bacteria are less likely to develop resistance against HDPs because these peptides target and kill bacteria in multiple ways, as well as modulate the immune system. Therefore, HDPs, and derivatives thereof, are promising alternatives to traditional antibiotics. Hardly anything is known about the immunomodulatory functions of porcine cathelicidin PMAP-36. In this study, we aimed to determine both antibacterial and immunomodulatory activities of PMAP-36 comparing the properties of PMAP-36 analogs with two well-studied peptides, human LL-37 and chicken CATH-2. Transmission electron microscopy revealed different killing mechanisms of E. coli for PMAP-36, CATH-2 and LL-37. LL-37 binds LPS very weakly in contrast to PMAP-36, but it inhibits LPS activation of macrophages the strongest. The first 11 amino acids of the N-terminal side of PMAP-36 are dispensable for E. coli killing, LPS-neutralization and binding. Deletion of four additional amino acids resulted in a strong decrease in activity. The activity of full length PMAP-36 was not affected by monomerization, whereas the shorter analogs require dimerization for proper immunomodulatory activity but not for their antibacterial activity.