Antimicrobial activity of the recombinant designer host defence peptide P-novispirin G10 in infected full-thickness wounds of porcine skin.

OBJECTIVES: The growing number of patients with impaired wound healing and the development of multidrug-resistant bacteria demand the investigation of alternatives in wound care. The antimicrobial activity of naturally occurring host defence peptides and their derivatives could be one alternative to the existing therapy options for topical treatment of wound infection. Therefore, the aim of this study was to investigate the antimicrobial activity of proline-novispirin G10 (P-novispirin G10) in vitro and in the infected porcine titanium wound chamber model. METHODS: The new derived designer host defence peptide P-novispirin G10 was tested in vitro against Gram-positive and Gram-negative bacterial strains. Additionally, cytotoxicity and haemolytic activities of P-novispirin G10 and protegrin-1 were measured. For in vivo studies, six wound chambers were implanted on each flank of Göttinger minipigs (n = 2, female, 6 months old, 15-20 kg). Eleven wound chambers were inoculated 8 days post-operatively with 5 x 10(8) of Staphylococcus aureus; one wound chamber remained uninfected as a system control. After wound infection had been established (4 days after inoculation), each wound chamber was topically treated with P-novispirin G10, protegrin-1 or carrier control. Wound fluid was harvested every hour for a total follow up of 3 h. RESULTS: P-novispirin G10 demonstrated broad-spectrum antimicrobial activity with moderate haemolytic and cytotoxic activities compared with protegrin-1. In the infected wound chamber model P-novispirin G10 demonstrated a 4 log(10) reduction in bacterial counts. CONCLUSIONS: This implicates the potential of P-novispirin G10 as an alternative in future antimicrobial wound care. However, more studies are necessary to further define clinical applications and potential side effects in greater detail.

Improving on nature's defenses: optimization & high throughput screening of antimicrobial peptides.

Antimicrobial peptides (AMPs) are ubiquitous in nature where they play important roles in host defense and microbial control. Despite their natural origin, antimicrobial spectrum and potency, the lead peptide candidates that so far have entered pharmaceutical development have all been further optimized by rational or semi-rational approaches. In recent years, several high throughput screening (HTS) systems have been developed to specifically address optimization of AMPs. These include a range of computational in silico systems and cell-based in vivo systems. The in silico-based screening systems comprise several computational methods such as Quantitative Structure/Activity Relationships (QSAR) as well as simulation methods mimicking peptide/membrane interactions. The in vivo-based systems can be divided in cis-acting and trans-acting screening systems. The cis-acting pre-screens, where the AMP exerts its antimicrobial effect on the producing cell, allow screening of millions or even billions of lead candidates for their basic antimicrobial or membrane-perturbating activity. The trans-acting screens, where the AMP is secreted or actively liberated from the producing cell and interacts with cells different from the producing cell, allow for screening under more complex and application-relevant conditions. This review describes the application of HTS systems employed for AMPs and lists advantages as well as limitations of these systems.

Membrane proteins PmpG and PmpH are major constituents of Chlamydia trachomatis L2 outer membrane complex.

The outer membrane complex of Chlamydia is involved in the initial adherence and ingestion of Chlamydia by the host cell. In order to identify novel proteins in the outer membrane of Chlamydia trachomatis L2, proteins were separated by sodium dodecyl sulfate polyacrylamide gel electrophoresis. By silver staining of the protein profile, a major protein doublet of 100-110 kDa was detected. In-gel tryptic digestion and matrix-assisted laser desorption/ionization mass spectrometry identified these proteins as the putative outer membrane proteins PmpG and PmpH.