Kozhinjampara R. Mahendran

How β-Lactam Antibiotics Enter Bacteria: A Dialogue with the Porins

Background Multi-drug resistant (MDR) infections have become a major concern in hospitals worldwide. This study investigates membrane translocation, which is the first step required for drug action on internal bacterial targets. β-lactams, a major antibiotic class, use porins to pass through the outer membrane barrier of Gram-negative bacteria. Clinical reports have linked the MDR phenotype to altered membrane permeability including porin modification and efflux pump expression. Methodology/Principal Findings Here influx of β-lactams through the major Enterobacter aerogenes porin Omp36 is characterized. Conductance measurements through a single Omp36 trimer reconstituted into a planar lipid bilayer allowed us to count the passage of single β-lactam molecules. Statistical analysis of each transport event yielded the kinetic parameters of antibiotic travel through Omp36 and distinguishable translocation properties of β-lactams were quantified for ertapenem and cefepime. Expression of Omp36 in an otherwise porin-null bacterial strain is shown to confer increases in the killing rate of these antibiotics and in the corresponding bacterial susceptibility. Conclusions/Significance We propose the idea of a molecular “passport” that allows rapid transport of substrates through porins. Deciphering antibiotic translocation provides new insights for the design of novel drugs that may be highly effective at passing through the porin constriction zone. Such data may hold the key for the next generation of antibiotics capable of rapid intracellular accumulation to circumvent the further development MDR infections.

Molecular basis of enrofloxacin translocation through OmpF, an outer membrane channel of Escherichia coli--when binding does not imply translocation.

The molecular pathway of enrofloxacin, a fluoroquinolone antibiotic, through the outer membrane channel OmpF of Escherichia coli is investigated. High-resolution ion current fluctuation analysis reveals a strong affinity for enrofloxacin to OmpF, the highest value ever recorded for an antibiotic-channel interaction. A single point mutation in the constriction zone of OmpF, replacing aspartic acid at the 113 position with asparagine (D113N), lowers the affinity to a level comparable to other antibiotics. All-atom molecular dynamics simulations allow rationalizing the translocation pathways: wild-type OmpF has two symmetric binding sites for enrofloxacin located at each channel entry separated by a large energy barrier in the center, which inhibits antibiotic translocation. In this particular case, our simulations suggest that the ion current blockages are caused by molecules occupying either one of these peripheral binding sites. Removal of the negative charge on position 113 removes the central barrier and shifts the two peripheral binding sites to a unique central site, which facilitates translocation. Fluorescence steady-state measurements agree with the different location of binding sites for wild-type OmpF and the mutant. Our results demonstrate how a single-point mutation of the porin, and the resulting intrachannel shift of the affinity site, may substantially modify translocation.

The role of lipids in mechanosensation

The ability of proteins to sense membrane tension is pervasive in biology. A higher-resolution structure of the Escherichia coli small-conductance mechanosensitive channel MscS identifies alkyl chains inside pockets formed by the transmembrane helices (TMs). Purified MscS contains E. coli lipids, and fluorescence quenching demonstrates that phospholipid acyl chains exchange between bilayer and TM pockets. Molecular dynamics and biophysical analyses show that the volume of the pockets and thus the number of lipid acyl chains within them decreases upon channel opening. Phospholipids with one acyl chain per head group (lysolipids) displace normal phospholipids (with two acyl chains) from MscS pockets and trigger channel opening. We propose that the extent of acyl-chain interdigitation in these pockets determines the conformation of MscS. When interdigitation is perturbed by increased membrane tension or by lysolipids, the closed state becomes unstable, and the channel gates.

Permeation of antibiotics through Escherichia coli OmpF and OmpC porins: screening for influx on a single-molecule level.

A chip-based automated patch-clamp technique provides an attractive biophysical tool to quantify solute permeation through membrane channels. Proteo–giant unilamellar vesicles (proteo-GUVs) were used to form a stable lipid bilayer across a micrometer-sized hole. Because of the small size and hence low capacitance of the bilayer, single-channel recordings were achieved with very low background noise. The latter allowed the characterization of the influx of 2 major classes of antibiotics—cephalosporins and fluoroquinolones—through the major Escherichia coli porins OmpF and OmpC. Analyzing the ion current fluctuations in the presence of antibiotics revealed transport properties that allowed the authors to determine the mode of permeation. The chip-based setup allows rapid solution exchange and efficient quantification of antibiotic permeation through bacterial porins on a single-molecule level.

Toward Screening for Antibiotics with Enhanced Permeation Properties through Bacterial Porins

Gram-negative bacteria are protected by an outer membrane barrier, and to reach their periplasmic target, penicillins have to diffuse through outer membrane porins such as OmpF. Here we propose a structure-dynamics-based strategy for improving such antibiotic uptake. Using a variety of experiments (high-resolution single channel recording, Minimum Inhibitory Concentration (MIC), liposome swelling assay) and accelerated molecular simulations, we decipher the subtle balance of interactions governing ampicillin diffusion through the porin OmpF. This suggests mutagenesis of a hot spot residue of OmpF for which additional simulations reveal drastic changes in the molecular and energetic pathway of ampicillins diffusion. Inverting the problem, we predict and describe how benzylpenicillin diffuses with a lower effective energy barrier by interacting differently with OmpF. The thorough comparison between the theoretical predictions and the three independent experiments, which were set up to measure the kinetics of transport and biological activity, gives insights on how to combine such different investigation techniques with the aim of providing complementary validation. Our study illustrates the importance of microscopic interactions at the constriction region of the biological channel to control the antibiotic flux through it. We conclude by providing a complete inventory of the channel and antibiotic hot spots and discuss the implications in terms of antibacterial screening and design.

Antibiotic Permeation across the OmpF Channel: Modulation of the Affinity Site in the Presence of Magnesium

We characterize the rate-limiting interaction of the antibiotic enrofloxacin with OmpF, a channel from the outer cell wall of Escherichia coli . Reconstitution of a single OmpF trimer into planar lipid membranes allows measurement of the ion current through the channel. Penetration of antibiotics causes ion current blockages, and their frequency allows a conclusion on the kinetics of channel entry and exit. In contrast to other antibiotics, enrofloxacin is able to block the OmpF channel for several milliseconds, reflecting high affinities comparable to substrate-specific channels such as the maltodextrin-specific maltoporin. Surprisingly, the presence of a divalent ion such as Mg(2+) leads to fast flickering with an increase in the rates of association and dissociation. All-atom computer modeling provides the most probable pathway able to identify the relevant rate-limiting interaction during antibiotic permeation. Mg(2+) has a high affinity for the aspartic acid at the 113 position (D113) in the center of the OmpF intracellular binding site. Therefore, the presence of Mg(2+) reverses the charge and enrofloxacin may cross the constriction region in its favorable orientation with the carboxylic group first.

Protein reconstitution into freestanding planar lipid membranes for electrophysiological characterization.

The reconstitution of channel-forming proteins into planar lipid bilayers enables their functional characterization at very low (sometimes below attomolar) concentrations. We describe the three main approaches used in our laboratories (the Mueller-Rudin technique, in which the bilayers contain an organic solvent, the Montal-Mueller or solvent-free technique, and a method for membrane reconstitution via liposome formation), and we discuss their respective advantages and limitations. Despite the differences in the reconstitution procedures, subsequent protein characterization is based on the same electrophysiological technique. A transmembrane electric field is applied, inducing an ion current and allowing conclusions to be drawn on apparent pore sizes, or suggesting functional properties such as channel opening and closing upon ligand binding, pH-induced conformational changes, ion selectivity or substrate specificity.

Implication of Porins in β-Lactam Resistance of Providencia stuartii

An integrative approach combining biophysical and microbiological methods was used to characterize the antibiotic translocation through the outer membrane of Providencia stuartii. Two novel members of the General Bacterial Porin family of Enterobacteriaceae, named OmpPst1 and OmpPst2, were identified in P. stuartii. In the presence of ertapenem (ERT), cefepime (FEP), and cefoxitin (FOX) in growth media, several resistant derivatives of P. stuartii ATCC 29914 showed OmpPst1-deficiency. These porin-deficient strains showed significant decrease of susceptibility to β-lactam antibiotics. OmpPst1 and OmpPst2 were purified to homogeneity and reconstituted into planar lipid bilayers to study their biophysical characteristics and their interactions with β-lactam molecules. Determination of β-lactam translocation through OmpPst1 and OmpPst2 indicated that the strength of interaction decreased in the order of ertapenem ≫ cefepime > cefoxitin. Moreover, the translocation of these antibiotics through OmpPst1 was more efficient than through OmpPst2. Heterologous expression of OmpPst1 in the porin-deficient E. coli strain BL21(DE3)omp8 was associated with a higher antibiotic susceptibility of the E. coli cells to β-lactams compared with expression of OmpPst2. All our data enlighten the involvement of porins in the resistance of P. stuartii to β-lactam antibiotics.

Pulling peptides across nanochannels: resolving peptide binding and translocation through the hetero-oligomeric channel from Nocardia farcinica.

We investigated translocation of cationic peptides through nanochannels derived from the Gram-positive bacterium Nocardia farcinica at the single-molecule level. The two subunits NfpA and NfpB form a hetero-oligomeric cation selective channel. On the basis of amino acid comparison we performed homology modeling and obtained a channel structurally related to MspA of Mycobacterium smegmatis. The quantitative single-molecule measurements provide an insight into transport processes of solutes through nanochannels. High-resolution ion conductance measurements in the presence of peptides of different charge and length revealed the kinetics of peptide binding. The observed asymmetry in peptide binding kinetics indicated a unidirectional channel insertion in the lipid bilayer. In the case of cationic peptides, the external voltage acts as a driving force that promotes the interaction of the peptide with the channel surface. At low voltage, the peptide just binds to the channel, whereas at higher voltage, the force is strong enough to pull the peptide across the channel. This allows distinguishing quantitatively between peptide binding and translocation through the channel.

Protein Translocation through Tom40: Kinetics of Peptide Release

Mitochondrial proteins are almost exclusively imported into mitochondria from the cytosol in an unfolded or partially folded conformation. Regardless of whether they are destined for the outer or inner membrane, the intermembrane space, or the matrix, proteins begin the importation process by crossing the mitochondrial outer membrane via a specialized protein import machinery whose main component is the Tom40 channel. High-resolution ion conductance measurements through the Tom40 channel in the presence of the mitochondrial presequence peptide pF(1)β revealed the kinetics of peptide binding. Here we show that the rates for association k(on) and dissociation k(off) strongly depend on the applied transmembrane voltage. Both kinetic constants increase with an increase in the applied voltage. The increase of k(off) with voltage provides strong evidence of peptide translocation. This allows us to distinguish quantitatively between substrate blocking and permeation.