Ion-Pairing Mechanism for the Valinomycin-Mediated Transport of Potassium Ions across Phospholipid Bilayers

Ligand Conformational and Metal Coordination Isomers in Complexes of Metal Ions and Cyclic Depsipeptides

A critical challenge in the structural characterization of metal complexes in apolar environments is distinguishing transient structural isomers within an ensemble of lower- and higher-order assemblies. These structural variations arise from subtle changes in ligand architecture and metal coordination chemistry, which are often difficult to deconvolute. Here, we utilize ion activation in both drift-tube and cyclic ion mobility spectrometry-mass spectrometry (IMS-MS) to resolve ligand conformational isomerism and metal coordination isomerism in metal sandwich complexes of cyclic depsipeptide ligands known for selective metal ion transport. Our approach reveals that isomerism driven by ligand structural rearrangements exhibits low energy barriers, allowing their interconversion to be captured on the IMS-MS time scale. In contrast, isomers involving distinct metal coordination states are characterized by higher energy barriers, precluding rapid interconversion. These findings establish a direct correlation between isomer distributions and selective metal binding and transport, providing mechanistic insights into the biological functions of cyclic depsipeptides. This work underscores the utility of IMS-MS for disentangling complex structural dynamics in biologically relevant metal-peptide ligand systems.

Chemically diverse antimicrobial peptides induce hyperpolarization of the E. coli membrane

The negative membrane potential within bacterial cells is crucial in various essential cellular processes. Sustaining a hyperpolarised membrane could offer a novel strategy to combat antimicrobial resistance. However, it remains uncertain which molecules are responsible for inducing hyperpolarization and what the underlying molecular mechanisms are. Here, we demonstrate that chemically diverse antimicrobial peptides (AMPs) trigger hyperpolarization of the bacterial cytosolic membrane when applied at subinhibitory concentrations. Specifically, these AMPs adopt a membrane-induced amphipathic structure and, thereby, generate hyperpolarization in Escherichia coli without damaging the cell membrane. These AMPs act as selective ionophores for K+ (over Na+) or Cl- (over H2PO4- and NO3-) ions, generating diffusion potential across the membrane. At lower dosages of AMPs, a quasi-steady-state membrane polarisation value is achieved. Our findings highlight the potential of AMPs as a valuable tool for chemically hyperpolarising bacteria, with implications for antimicrobial research and bacterial electrophysiology.

Electrocatalysis of CO2 Reduction by Immobilized Formate Dehydrogenase without a Metal Redox Center

Nicotinamide adenine dinucleotide-dependent formate dehydrogenase from Candida boidinii was immobilized in a 1,2-dimyristoyl-sn-glycero-3-phosphocholine/cholesterol floating lipid bilayer on the gold surface as a biocatalyst for electrochemical CO2 reduction. We report that, in contrast to common belief, the enzyme can catalyze the electrochemical reduction of CO2 to formate without the cofactor protonated nicotinamide adenine dinucleotide. The electrochemical data indicate that the enzyme-catalyzed reduction of CO2 is diffusion-controlled and is a reversible reaction. The orientation and conformation of the enzyme were investigated by surface-enhanced infrared reflection absorption spectroscopy. The α-helix of the enzyme adopts an orientation nearly parallel to the surface, bringing its active center close to the gold surface. This orientation allows direct electron transfer between CO2 and the gold electrode. The results in this paper provide a new method for the development of enzymatic electrocatalysts for CO2 reduction.

Cation Dependence of Enniatin B/Membrane-Interactions Assessed Using Surface-Enhanced Infrared Absorption (SEIRA) Spectroscopy

Enniatins are mycotoxins with well-known antibacterial, antifungal, antihelmintic and antiviral activity, which have recently come to attention as potential mitochondriotoxic anticancer agents. The cytotoxicity of enniatins is traced back to ionophoric properties, in which the cyclodepsipeptidic structure results in enniatin:cation-complexes of various stoichiometries proposed as membrane-active species. In this work, we employed a combination of surface-enhanced infrared absorption (SEIRA) spectroscopy, tethered bilayer lipid membranes (tBLMs) and density functional theory (DFT)-based computational spectroscopy to monitor the cation-dependence (Mz+=Na+, K+, Cs+, Li+, Mg2+, Ca2+) on the mechanism of enniatin B (EB) incorporation into membranes and identify the functionally relevant EBn : Mz+ complexes formed. We find that Na+ promotes a cooperative incorporation, modelled via an autocatalytic mechanism and mediated by a distorted 2 : 1-EB2 : Na+ complex. K+ (and Cs+) leads to a direct but less efficient insertion into membranes due to the adoption of "ideal" EB2 : K+ sandwich complexes. In contrast, the presence of Li+, Mg2+, and Ca2+ causes a (partial) extraction of EB from the membrane via the formation of "belted" 1 : 1-EB : Mz+ complexes, which screen the cationic charge less efficiently. Our results point to a relevance of the cation dependence for the transport into the malignant cells where the mitochondriotoxic anticancer activity is exerted.

Comparative analysis of a bulk optode based on a valinomycin ionophore and a nano-optode in micelles with pluronic F-127 for the quantification of potassium in aqueous solutions

In this work, two types of optical sensors were prepared for the quantification of potassium: the bulk optode (BO) and nano-optode (NO). The BO was prepared using three main components: the ionophore valinomycin, the ion exchanger tetrakis(4-chlorophenyl) potassium borate (K-TCPB), and the chromoionophore ETH 5294 (CHI). The optimal composition was found to be in a ratio of [1 : 1 : 1]. The NO was prepared by miniaturizing the BO through sonication in surfactant Pluronic F-127. The working range for the linear calibration model of BO was from 10-6 to 1.0 M K+ with a LODBO = 0.31 μM, meanwhile for NO was from 10-4 to 1.0 M K+ with a LODNO = 30.3 μM. Both optodes were tested for selectivity towards K+ in the presence of alkaline and alkaline earth ions, with a selectivity coefficient > 1.0. Furthermore, precision and stability studies of BO and NO were performed for three levels of K+ concentrations, 10-6, 10-3, 1.0 M for BO and 10-4, 10-2, 1.0 M for NO, showing a good homogeneity of the NO in the whole concentration range. However, an excessive variability was obtained for BO at 1.0 M K+. Therefore, the NO represents a potential tool for quantification of K+.

Electrochemical and Infrared Studies of a Model Bilayer of the Outer Membrane of Gram-Negative Bacteria and its Interaction with polymyxin─the Last-Resort Antibiotic

A model bilayer of the outer membrane (OM) of Gram-negative bacteria, composed of lipid A and 1,2-dimyristoyl-sn-glycero-3-phosphoethanolamine (DMPE), was assembled on the β-Tg modified gold (111) single crystal surface using a combination of Langmuir-Blodgett and Langmuir-Schaefer transfer. Electrochemical and spectroscopic methods were employed to study the properties of the model bilayer and its interaction with polymyxin. The model bilayer is stable on the gold surface in the transmembrane potential region between 0.0 and -0.7 V. The presence of Mg2+ coordinates with the phosphate and carboxylate groups in the leaflet of lipid A and stabilizes the structure of the model bilayer. Polymyxin causes the model bilayer leakage and damage in the transmembrane potential region between 0.2 and -0.4 V. At transmembrane potentials lower than -0.5 V, polymyxin does not affect the membrane integrity. Polymyxin binds to the phosphate and carboxylate groups in lipid A molecules and causes the increase of the tilt angle of acyl chains and the decrease of the tilt of the C═O bond. The results in this paper indicate that the antimicrobial activity of polymyxin depends on the transmembrane potential at the model bilayer and provides useful information for the development of new antibiotics.

Theoretical investigation of hydroxylated analogues of valinomycin as potassium transporter

Valinomycin is a potent ionophore known for its ability to transport potassium ions across biological membranes. The study focuses on the hydroxylated analogues of valinomycin (HyVLMs) and compares their energy profiles and capabilities for transporting potassium ions across phospholipid membranes. Using metadynamics, we investigated the energy profiles of wildtype valinomycin (VLM_1) and its three hydroxylated analogues (VLM_2, VLM_3, and VLM_4). We observed that all analogues exhibited energy maxima in the centre of the membrane and preferred positions below the phospholipid heads. Furthermore, the entry barriers for membrane penetration were similar among the analogues, suggesting that the hydroxyl group did not significantly affect their passage through the membrane. Transition state calculations provided insights into the ability of valinomycin analogues to capture potassium ions, with VLM_4 showing the lowest activation energy and VLM_2 displaying the highest. Our findings contribute to understanding the mechanisms of potassium transport by valinomycin analogues and highlight their potential as ionophores. The presence of the hydroxyl group is of particular importance because it paves the way for subsequent chemical modifications and the synthesis of new antiviral agents with reduced intrinsic toxicity.

Electrochemical studies of the mitochondrial ROMK2 potassium channel activity reconstituted into the free-standing and tethered bilayer lipid membranes

The renal-outer-medullary‑potassium (ROMK2) channel modulates potassium transport in the kidney. It has been postulated that the ROMK2 is the pore-forming subunit of the mitochondrial ATP-sensitive potassium channel as a mediator of cardioprotection. In this study, cell-free synthesis of the ROMK2 was performed in presence of membrane scaffold protein (MSP1D1) nanodiscs. Activity measurements were achieved after channel reconstitution into the planar lipid bilayer and tethered bilayer lipid membranes. Both methods allowed for monitoring of channel function, verified with channel blocking and activation/re-activation experiments. The primary function of the mitochondrial potassium channels is to regulate the potential of the mitochondrial membrane, which allows them to play an important role in cytoprotection. This work focuses on obtaining the ROMK2 using a cell-free expression system, followed by the incorporation of the channel protein into the lipid bilayer and studying the influence of voltage changes and molecular modulators on channel activity. Channel activity was measured after its reconstitution into two models of lipid bilayers - BLM (Bilayer Lipid Membrane) and tBLM (Tethered Bilayer Lipid Membrane) deposited on a solid gold electrode. These two model membranes and electrochemical measurements made it possible to measure the flux of K⁺ ions in the presence of channel modulators.

Na+/K+ carrier ionophore antibiotics valinomycin and monensin enhance the antibacterial activity of fluoride

Fluoride is routinely used as a highly effective antibacterial agent that interferes with bacterial metabolism through fundamentally different mechanisms. One of the major bacterial evasion mechanisms against fluoride is the impermeability of cell envelope to the anion that limits its cellular uptake. Therefore, translating such compounds to clinical settings requires novel mechanisms to facilitate the uptake of membrane-impermeant molecules. Published data have indicated antibiotic synergy between fluoride and membrane destabilizing agents that induce strong fluoride toxicity in bacteria via enhancing the permeability of bacterial membranes to fluoride. Here, we report a similar mechanism of antibiotic synergy between fluoride and potassium ion carriers, valinomycin and monensin against Gram-positive bacteria, B. subtilis and S. aureus. Molecular dynamics simulations were performed to understand the effect of potassium on the binding affinity of fluoride to monensin and valinomycin. The trajectory results strongly indicated that the monensin molecules transport fluoride ions across the cell membrane via formation of ion-pair between the monensin-K⁺ complex and a fluoride. This study provides new insights to design novel compounds to enhance the uptake of small toxic anions via synergistic interactions and thus exert strong antibacterial activity against a wide variety of pathogens.