Mechanistic and phenotypic studies of bicarinalin, BP100 and colistin action on Acinetobacter baumannii.

Acinetobacter baumannii has been identified by the WHO as a high priority pathogen. It can be resistant to multiple antibiotics and colistin sulphate is often used as a last-resort treatment. However, the potentially severe side-effects of colistin are well documented and this study compared the bactericidal and anti-biofilm activity of two synthetic nature-inspired antimicrobial peptides, bicarinalin and BP100, with colistin. The minimum bactericidal concentration (MBC) against planktonic A. baumannii was approximately 0.5 µg/ml for colistin sulphate and ∼4 µg/ml for bicarinalin and BP100. A. baumannii commonly occurs as a biofilm and biofilm removal assay results highlighted that both bicarinalin and BP100 had significantly greater potential than colistin. Atomic force microscopy (AFM) showed dramatic changes in A. baumannii cell size and surface conformity when treated with peptide concentrations at and above the MBC. Scanning electron microscopy (SEM) visualised the reduction of biofilm coverage and cell surface changes as peptide concentration increased. Liposome assays revealed that these peptides most likely act as pore-forming agents in the membrane. Bicarinalin and BP100 may be effective therapeutic alternatives to colistin against A. baumannii infections but further research is required to assess if they elicit cytotoxicity issues in patients.

Chitosan nanoparticle antigen uptake in epithelial monolayers can predict mucosal but not systemic in vivo immune response by oral delivery.

This study compared in vitro and in vivo antigen delivery effects of ultrapure chitosan (CS) chloride. CS nanoparticles were formulated to incorporate ovalbumin (OVA) as a model antigen and characterised for size, charge, OVA complexation and release. The effect of CS:OVA nanoparticles on cell viability, epithelial tight junctions and transepithelial permeation of OVA was tested on Caco-2 monolayer in vitro intestinal model. The system's ability to elicit immune responses was subsequently tested in vivo. The work confirmed that CS complexes with OVA into nano-size entities. Nanocomplexes displayed favourable delivery properties, namely OVA release and no notable cytotoxicity. CS:OVA markedly enhanced antigen delivery across Caco-2 monolayers. However, the system did not elicit notable in vivo immune responses (some mucosal response was apparent) following oral delivery. The study highlights that a clear effect on antigen permeability across epithelial monolayers in vitro may predict the in vivo mucosal but not systemic immune response following oral delivery.

Consequences of inducing intrinsic disorder in a high-affinity protein-protein interaction.

The kinetic and thermodynamic consequences of intrinsic disorder in protein-protein recognition are controversial. We address this by inducing one partner of the high-affinity colicin E3 rRNase domain-Im3 complex (K(d) ≈ 10(-12) M) to become an intrinsically disordered protein (IDP). Through a variety of biophysical measurements, we show that a single alanine mutation at Tyr507 within the hydrophobic core of the isolated colicin E3 rRNase domain causes the enzyme to become an IDP (E3 rRNase(IDP)). E3 rRNase(IDP) binds stoichiometrically to Im3 and forms a structure that is essentially identical to the wild-type complex. However, binding of E3 rRNase(IDP) to Im3 is 4 orders of magnitude weaker than that of the folded rRNase, with thermodynamic parameters reflecting the disorder-to-order transition on forming the complex. Critically, pre-steady-state kinetic analysis of the E3 rRNase(IDP)-Im3 complex demonstrates that the decrease in affinity is mostly accounted for by a drop in the electrostatically steered association rate. Our study shows that, notwithstanding the advantages intrinsic disorder brings to biological systems, this can come at severe kinetic and thermodynamic cost.

Immunogenicity and physico-chemical characterisation of a candidate conjugate vaccine against group B streptococcus serotypes Ia, Ib and III.

The immunogenicity and physico-chemical characteristics of a candidate conjugate vaccine against group B streptococcus serotypes Ia, Ib and III, were evaluated. The level and functional activity of serotype-specific antibody responses induced by monovalent and combined formulations were investigated using a mouse model and in vitro opsonophagocytosis assay. Molecular sizing of the conjugates and integrity of the intermediate components were evaluated by optical spectroscopy and size exclusion chromatography. All three serotypes induced substantial antibody responses which were functionally active. Combining the three serotypes did not seem to affect the antibody responses to individual serotypes, except when given at high dose, where the IgG response to serotype III but not the opsonophagocytic activity was slightly reduced compared to monovalent administration.

An assessment of thermal stability of Clostridium difficile toxoid formulations.

Strains of Clostridium difficile produce toxins A and B that can cause diarrhoea and pseudomembranous colitis. Currently, there is no preventative therapy for this infection but antibodies to the toxins provide protection, therefore a toxoid-based vaccine is needed. To evaluate thermal stability, a lyophilized and liquid formulation of toxoids A and B were stored at a range of temperatures for 5 weeks. Changes in toxoid structures and immune responses in an animal model before and after the incubation period were assessed. The structural integrity and the immune responses to liquid formulations were affected when stored at 56°C but the lyophilized formulation was thermally stable and same treatment did not result in significant loss of immunological responses when immunized in an animal model.

Colicin E3 cleavage of 16S rRNA impairs decoding and accelerates tRNA translocation on Escherichia coli ribosomes.

The cytotoxin colicin E3 targets the 30S subunit of bacterial ribosomes and specifically cleaves 16S rRNA at the decoding centre, thereby inhibiting translation. Although the cleavage site is well known, it is not clear which step of translation is inhibited. We studied the effects of colicin E3 cleavage on ribosome functions by analysing individual steps of protein synthesis. We find that the cleavage affects predominantly the elongation step. The inhibitory effect of colicin E3 cleavage originates from the accumulation of sequential impaired decoding events, each of which results in low occupancy of the A site and, consequently, decreasing yield of elongating peptide. The accumulation leads to an almost complete halt of translation after reading of a few codons. The cleavage of 16S rRNA does not impair monitoring of codon-anticodon complexes or GTPase activation during elongation-factor Tu-dependent binding of aminoacyl-tRNA, but decreases the stability of the codon-recognition complex and slows down aminoacyl-tRNA accommodation in the A site. The tRNA-mRNA translocation is faster on colicin E3-cleaved than on intact ribosomes and is less sensitive to inhibition by the antibiotic viomycin.

Colicins and their potential in cancer treatment.

Colicins are a family of antibacterial cytotoxins produced by Escherichia coli and released into the environment to reduce competition from other bacterial strains. Colicins kill the target cell by a variety of effects that include depolarisation of the cytoplasmic membrane, a non-specific DNase activity, a highly specific RNase activity or by inhibition of murein synthesis. This review summarises some important findings that implicate colicins as potential anti-tumor agents. Colicins appear to inhibit proliferation of tumor cell lines in a colicin-type--and cell line-dependent fashion and are more toxic to tumor cells than to normal cells within the body. This opens a potential for using bacterial colicins in combating cancer and raises a number of questions concerning the mechanism of action of colicins in targeting tumor cells, their specificity and applicability as anti-tumor therapeutics.

Identification of the catalytic motif of the microbial ribosome inactivating cytotoxin colicin E3.

Colicin E3 is a cytotoxic ribonuclease that specifically cleaves 16S rRNA at the ribosomal A-site to abolish protein synthesis in sensitive Escherichia coli cells. We have performed extensive mutagenesis of the 96-residue colicin E3 cytotoxic domain (E3 rRNase), assayed mutant colicins for in vivo cytotoxicity, and tested the corresponding E3 rRNase domains for their ability to inactivate ribosome function in vitro. From 21 alanine mutants, we identified five positions where mutation resulted in a colicin with no measurable cytotoxicity (Y52, D55, H58, E62, and Y64) and four positions (R40, R42, E60, and R90) where mutation caused a significant reduction in cytotoxicity. Mutations that were found to have large in vivo and in vitro effects were tested for structural integrity through circular dichroism and fluorescence spectroscopy using purified rRNase domains. Our data indicate that H58 and E62 likely act as the acid-base pair during catalysis with other residues likely involved in transition state stabilization. Both the Y52 and Y64 mutants were found to be highly destabilized and this is the likely origin of the loss of their cytotoxicity. The identification of important active site residues and sequence alignments of known rRNase homologs has allowed us to identify other proteins containing the putative rRNase active site motif. Proteins that contained this active site motif included three hemagglutinin-type adhesins and we speculate that these have evolved to deliver a cytotoxic rRNase into eukaryotic cells during pathogenesis.