Stability of the Salmonella Typhimurium rcsC11 mutant under different stress conditions.

The virulence genes of Salmonella are modulated during infection by several regulatory systems, and the RcsCDB system is one of the most important of these. The S. Typhimurium EG14873 (rcsC11) strain harbours the rcsC11 point mutation, displaying a constitutive activation of this system, which is characterized by mucoid colonies and attenuated virulence phenotypes. In this work, the stability of the rcsC11 mutation was analysed under stress conditions. Under acid and anaerobic stresses, we observed the appearance of small and non-mucoid colonies of the rcsC11 strain. The sequencing of the rcsC gene from these colonies showed that the mutation is conserved. Moreover, we found that small colonies were also generated when the wild-type strain grew in acid and anaerobic conditions. It is worth noting that the transition from normal to atypical colonies of both strains only took place after several days of incubation and was not observed during eukaryotic cell infection. Therefore, the appearance of these atypical colonies is a characteristic feature of S. Typhimurium strains under stressful situations and does not involve a reversion of the rcsC11 allele and nor does it imply any risk to mammalian cells. Therefore, we propose that the S. Typhimurium rcsC11 strain is a good candidate for the development of attenuated vaccines.

New insights into enterocin CRL35: mechanism of action and immunity revealed by heterologous expression in Escherichia coli.

The role of the class IIa bacteriocin membrane receptor protein remains unclear, and the following two different mechanisms have been proposed: the bacteriocin could interact with the receptor changing it to an open conformation or the receptor might act as an anchor allowing subsequent bacteriocin insertion and membrane disruption. Bacteriocin-producing cells synthesize an immunity protein that forms an inactive bacteriocin-receptor-immunity complex. To better understand the molecular mechanism of enterocin CRL35, the peptide was expressed as the suicidal probe EtpM-enterocin CRL35 in Escherichia coli, a naturally insensitive microorganism since it does not express the receptor. When the bacteriocin is anchored to the periplasmic face of the plasma membrane through the bitopic membrane protein, EtpM, E. coli cells depolarize and die. Moreover, co-expression of the immunity protein prevents the deleterious effect of EtpM-enterocin CRL35. The binding and anchoring of the bacteriocin to the membrane has demonstrated to be a sufficient condition for its membrane insertion. The final step of membrane disruption by EtpM-enterocin CRL35 is independent from the receptor, which means that the mannose PTS might not be involved in the pore structure. In addition, the immunity protein can protect even in the absence of the receptor.

Nisin Z produced by Lactococcus lactis from bullfrog hatchery is active against Citrobacter freundii, a red-leg syndrome related pathogen.

Lactococcus lactis subsp. lactis CRL 1584 isolated from a bullfrog hatchery produces a bacteriocin that inhibits both indigenous Citrobacter freundii (a Red-Leg Syndrome related pathogen) and Lactobacillus plantarum, and Listeria monocytogenes as well. Considering that probiotics requires high cell densities and/or bacteriocin concentrations, the effect of the temperature on L. lactis growth and bacteriocin production was evaluated to find the optimal conditions. Thus, the growth rate was maximal at 36 °C, whereas the highest biomass and bacteriocin activity was achieved between 20 and 30 °C and 20-25 °C, respectively. The bacteriocin synthesis was closely growth associated reaching the maximal values at the end of the exponential phase. Since bacteriocins co-production has been evidenced in bacterial genera, a purification of the bacteriocin/s from L. lactis culture supernatants was carried out. The active fraction was purified by cationic-exchange chromatography and then, a RP-HPLC was carried out. The purified sample was a peptide with a 3353.05 Da, a molecular mass that matches nisin Z, which turned out to be the only bacteriocin produced by L. lactis CRL 1584. Nisin Z showed bactericidal effect on C. freundii and L. monocytogenes, which increased in the presence L-lactic acid + H2O2. This is the first report on nisin Z production by L. lactis from a bullfrog hatchery that resulted active on a Gram-negative pathogen. This peptide has potential probiotic for raniculture and as food biopreservative for bullfrog meat.

Proton motive force dissipation precludes interaction of microcin J25 with RNA polymerase, but enhances reactive oxygen species overproduction.

BACKGROUND: Microcin J25 targets the RNA polymerase as well as bacterial membranes. Because there is scarce information on the relationship between the uptake and the activity, a fluorescent microcin J25-derivative was used to further characterize its mechanism of action. METHODS: MccJ25 I13K was labeled with FITC and its uptake by sensitive cells was assessed by fluorescence measurements from supernatants of MccJ25-Escherichia coli suspensions. The interaction of the peptide with bacterial membranes was investigated by fluorescence resonance energy transfer. Oxygen consumption was measured with Clark-type electrode. RNA synthesis was evaluated in vivo by incorporation of [3H]uridine. ROS production was assayed by measuring the fluorescence emission of the ROS-sensitive probe 5(and 6)-carboxy-2',7'-dichlorodihydrofluorescein diacetate. RESULTS: The protonophore 2,4-dinitrophenol decreased 80% of the MccJ25 uptake and prevented inhibition of transcriptional activity, the antibiotic intracellular target. On the other hand, peptide binding to bacterial membranes was not affected and antibacterial activity remained nearly unchanged. Proton gradient dissipation by protonophore accelerated cell oxygen consumption rates and enhanced MccJ25-related reactive oxygen species overproduction. GENERAL SIGNIFICANCE: The deleterious reactive oxygen species would be produced as a consequence of the minor fraction of MccJ25 that interacts with the bacterial plasma membrane from the periplasmic side. These results show the first evidence of the mechanism underlying ROS production in sensitive bacteria.

Bacteriocin enterocin CRL35 is a modular peptide that induces non-bilayer states in bacterial model membranes.

The mechanism of action of the anti-Listeria peptide enterocin CRL35 was studied with biophysical tools by using lipid mixtures that mimicked Gram-positive plasma membranes. Langmuir monolayers and infrared spectroscopy indicated that the peptide readily interacted with phospholipid assembled in monolayers and bilayers to produce a dual effect, depending on the acyl chains. Indeed, short chain mixtures were disordered by enterocin CRL35, but the gel-phases of membranes composed by longer acyl chains were clearly stabilized by the bacteriocin. Structural and functional studies indicated that non-bilayer states were formed when liposomes were co-incubated with enterocin CRL35, whereas significant permeabilization could be detected when bilayer and non-bilayer states co-existed. Results can be explained by a two-step model in which the N-terminal of the peptide firstly docks enterocin CRL35 on the lipid surface by means of electrostatic interactions; then, C-terminal triggers membrane perturbation by insertion of hydrophobic α-helix.

Membrane order and ionic strength modulation of the inhibition of the membrane-bound acetylcholinesterase by epigallocatechin­3­gallate.

In the present work, we analyzed how external factors can modulate the efficiency of epigallocatechin­3­O­gallate (EGCG) inhibition of a membrane-bound isoform of the acetylcholinesterase. Increasing the ionic strength but not the osmolarity of the bulk medium proved to be an important factor. In addition, we verified a clear correlation between the inhibitory activity with the order degree of the membranes by using cholesterol-partially depleted red blood cell ghosts. These two factors i.e. high salt concentration in the bulk medium and less viscous membranes, allow a deeper insertion of the EGCG into the lipid bilayer, thus leading to a greater inhibition of AChE. As a corollary, we propose that any treatment or process that leads to a slight decrease in cholesterol content in the membranes can efficiently enhance the inhibitory activity of EGCG, which can have important consequences in all the pathologies where the inhibition of AChE is recommended.

Differential inhibition of human erythrocyte acetylcholinesterase by polyphenols epigallocatechin-3-gallate and resveratrol. Relevance of the membrane-bound form.

The activity of acetylcholinesterase (AChE) from human erythrocytes was tested in the presence of the phenolic compounds resveratrol and epigallocatechin-3-gallate (EGCG). Even though the stilbene barely changed this enzymatic activity, EGCG did inhibit AChE. Importantly, it preferentially acted on the membrane-bound enzyme rather than on its soluble form. Actually, it was shown that this flavonoid may bind to the red blood cell membrane surface, which may improve the interaction between EGCG and AChE. Therefore, caution should be taken when screening AChE inhibitors. In fact, testing compounds with the soluble form of the enzyme may underestimate the activity of some of these potential inhibitors, hence it would be advisable not to use them as a sole model system for screening. Moreover, erythrocyte AChE is proposed as a good model for these enzymatic assays. © 2016 BioFactors, 43(1):73-81, 2017.

Membrane viscosity is a major modulating factor of the enterocin CRL35 activity.

Enterocin CRL35 activity is deeply influenced by the membrane viscosity as could be demonstrated performing determinations of the minimal inhibitory concentrations (MIC) at different temperatures and analyzing the membrane viscosity in these cells as well as in resistant bacteria. In all the cases, bacteriocin activity was linked to higher levels of viscosity. This finding was confirmed studying the interaction of enterocin CRL35 with liposomes composed of dimyristoyl phosphatidylcholine: dimyristoyl phosphatidylglycerol (9:1) in both gel and liquid-crystalline phases. It could be establish, from peptide insertion analysis following the tryptophan fluorescence and microviscosity experiments that this peptide is able to interact more efficiently with membranes having a more structured hydrophobic core.

The key role of membranes in amyloid formation from a biophysical perspective.

Even though our knowledge of how proteins misfold and aggregate is deeper nowadays, the mechanisms driving this process are still poorly understood. Among the factors involved, membranes should be taken into account. Indeed, convincing evidence suggests that membranes may influence protein folding, misfolding and aggregation. In fact, membrane lipid composition of different cellular types may attenuate or intensify the environmental pressure over protein folding equilibrium. In the present review the aim is to make an up-to-date analysis of the membrane influence on protein aggregation from a biophysical point of view in order to provide useful tools for researchers from other fields. In particular, we discuss how membranes can alter protein environment, e.g. increasing local protein concentration, lowering pH and dielectric constant, allowing accessibility to the hydrophobic milieu and promoting surface crowding, all of which will lead to protein aggregation. In addition, we review the role that specific lipids may exert on protein aggregation and finally we analyse the possible implication of membrane-related oxidative stress on amyloidogenesis.

Enhancement of antibiotic activity by sub-lethal concentrations of enterocin CRL35.

OBJECTIVE: The aim of this study was to evaluate the interaction of several conventional antibiotics with sub-lethal concentrations of enterocin CRL35, a cationic peptide, on Listeria innocua 7. METHODS: Susceptibility of L. innocua 7 cells to the combination of enterocin CRL35 and non-peptide antibiotics (cefalexin, ampicillin, ciprofloxacin, nalidixic acid, erythromycin, chloramphenicol, vancomycin and tetracycline) was assayed using the broth dilution method and killing curves. Fractional inhibitory concentration (FIC) index was calculated to assess synergy. The transmembrane electrical potential and pH gradient were determined by specific fluorescent probes. RESULTS: We found positive interactions between the cationic peptide and three conventional antibiotics (tetracycline, erythromycin and chloramphenicol) which are excluded from the cells by efflux pumps dependent on the membrane proton gradient. Furthermore, enterocin CRL35 even at sub-lethal concentrations induced the dissipation of both components of the proton motive force (Deltap), i.e. transmembrane electrical potential and pH gradient and hence the alteration of processes dependent on it. CONCLUSION: We hypothesize that enterocin CRL35 increases the effectiveness of these antibiotics by impairment of the bacterial active efflux systems and the consequent accumulation of these toxic compounds in the cytoplasm.

Antimitochondrial activity displayed by the antimicrobial peptide microcin J25.

In this report we studied the effect of the antimicrobial peptide, microcin J25, on the rat heart mitochondria. This peptide induced an important inhibition of the ATP synthesis with the concomitant enhancement of the ATP degradation. These effects were the result of two processes: on one hand, microcin J25 was able to insert into the membrane and hence alter its permeability with the consequent dissipation of the proton motive force. On the other, microcin J25 inhibited the enzymatic activity of the cytochrome c reductase (complex III) of the respiratory chain. The relevance of this study to the potential use of microcin J25 as an anti-tumoral agent is discussed.