Correlated proton dynamics in hydrogen bonding networks: the benchmark case of 3-hydroxyglutaric acid.

Proton and hydrogen-bonded networks sustain a broad range of structural and charge transfer processes in supramolecular materials. The modelling of proton dynamics is however challenging and demands insights from prototypical benchmark systems. The intramolecular H-bonding networks induced by either protonation or deprotonation of 3-hydroxyglutaric acid provide intriguing case studies of correlated proton dynamics. The vibrational signatures associated with the fluxional proton bonding and its coupling with the hydroxyglutaric backbone are investigated here with infrared action ion spectroscopy experiments and Born-Oppenheimer molecular dynamics (BOMD) computations. Despite the formally similar symmetry of protonated and deprotonated hydroxyglutaric acid, the relative proton affinities of the oxygen centers of the carboxylic and carboxylate groups with respect to that of the central hydroxyl group lead to distinct proton dynamics. In the protonated acid, a tautomeric arrangement of the type HOCO·[HOH]+·OCOH is preferred with the proton binding tighter to the central hydroxyl moiety and the electronic density being shared between the two nearly symmetric H-bonds with the carboxylic end groups. In the deprotonated acid, the asymmetric [OCO]-·HO·HOCO configuration is more stable, with a stronger H-bonding on the bare carboxylate end. Both systems display active backbone dynamics and concerted Grothuss-like proton motions, leading to diffuse band structures in their vibrational spectra. These features are accurately reproduced by the BOMD computations.

Insights into the binding of arginine to adenosine phosphate from mimetic complexes.

The amino acid arginine plays a key role in the interaction of proteins with adenosine phosphates, as its protonated guanidinium side group is capable of building multipodal H-bonding interactions with the oxygen atoms of the phosphate, phosphoester and ribose moieties and with the nitrogen atoms of adenine. Protein interactions often take place in competition with other ionic species, typically metal cations, which are prone to build concerted coordination arrangements with the same centers of negative charge as guanidinium. We report on a vibrational spectroscopy and computational investigation of a positively charged ternary complex formed by adenosine monophosphate (AMP) with methyl guanidinium and Na+. Following a bottom-up approach, an analogous complex with ribose phosphate is characterized as well, which serves to assess the individual role of the phosphate, sugar and adenine moieties in the binding process and to compare, within a single complex, the interactions associated with diffuse versus localized charge distributions of guanidinium and the alkali cation, respectively. The results indicate that Na+ is preferentially hosted in a semi-rigid pocket formed by the phosphoester-adenosine backbone of AMP and displaces guanidinium to a peripheral binding to the phosphate anionic end group. This suggests that the control of the salt concentration may constitute an effective route to modulate protein-AMP complexation.

Inclusion complexes of the macrocycle nonactin with benchmark protonated amines: aniline and serine.

The biological activity of the macrocycle nonactin is intimately related to its ionophore properties and ability to act as a selective cation carrier. While the focus of most investigations on nonactin has been on the binding of metal cations and small molecular ions, this study pursues the characterization of its inclusion complexes with primary amines with bulky structured side groups of different polarity. To this end, the complexes of nonactin with aniline and with the amino acid L-serine, both in protonated form, are considered as case studies and their relevant coordination arrangements are assessed by means of infrared action spectroscopy, quantum chemical density functional theory and Born-Oppenheimer molecular dynamics. The study suggests that the oxygen atoms from the oxolane (tetrahydrofuran) groups of nonactin constitute the preferential docking sites of the ammonium moiety of the guest cation, although conformational constraints promote interactions with the ester carbonyl backbone groups. In the aniline complex, the benzyl side ring is oriented outwards from the cavity, whereas in the case of L-serine, the side carboxylic acid and alcohol groups participate actively in the coordination process. Interestingly, the accommodation of L-serine is favoured when nonactin adopts an enantiomeric-selective folding, that promotes the tripodal coordination of the protonated amine group with oxolane rings from three nonactinic acid blocks with enantiomeric sequence (+)-(-)-(+), which allows for a facile coordination of the serine side groups. This is recognized as a general feature associated with the alternation of chiral domains in globally achiral natural nonactin, yielding mirror-symmetric complexes with the enantiomers of chiral amines.

Tailoring the phase diagram of discotic mesogens.

The computational modelling of discotic molecules is a central topic in colloid science that is key for the smart design of a broad range of modern functional materials. This work lays out a versatile interaction model capable of exposing the rich mesogenic behaviour of discotics. A single coarse-grained spheroplatelet core framework is employed to generate a variety of pair interaction anisotropy classes, favouring specific relative orientations of the particles (stacked, side-side, crossed, T-shaped). This paves the way for the systematic tailoring of the discotic liquid phase diagram. Monte Carlo simulations are performed for an ensemble of case studies to illustrate the correlation between the topology of the interaction and the formation of stable nematic, smectic and columnar phases, as well as of less common cubatic, uniaxial and biaxial columnar domains.

Proton in the ring: spectroscopy and dynamics of proton bonding in macrocycle cavities.

The proton bond is a paradigmatic quantum molecular interaction and a major driving force of supramolecular chemistry. The ring cavities of crown ethers provide an intriguing environment, promoting competitive proton sharing with multiple coordination anchors. This study shows that protons confined in crown ether cavities form dynamic bonds that migrate to varying pairs of coordinating atoms when allowed by the flexibility of the macrocycle backbone. Prototypic native crown ethers (12-crown-4, 15-crown-5 and 18-crown-6) and aza-crown ethers (cyclen, 1-aza-18-crown-6 and hexacyclen) are investigated. For each system, Infrared action spectroscopy experiments and ab initio Molecular Dynamics computations are employed to elucidate the structural effects associated with proton diffusion and its entanglement with the conformational and vibrational dynamics of the protonated host.

Multipodal coordination and mobility of molecular cations inside the macrocycle valinomycin.

The macrocycle valinomycin displays an outstanding ability in cation binding and carriage across hydrophobic environments (e.g., cell membranes) and constitutes a central landmark for the design of novel ionophores for the regulation of biochemical processes. Most previous investigations have focused on the capture of metal cations (primarily K+). Here, we address the versatility of valinomycin in the encapsulation of molecular ions of small and moderate size, with NH4+ and H4PO4+ as case studies. A combination of infrared action vibrational spectroscopy and quantum chemical computations of molecular structure and dynamics is employed with the two-fold aim of assessing the dominant H-bonding coordination networks in the complexes and of characterizing the positional and rotational freedom of the guest cations inside the cavity of the macrocycle. Valinomycin binds NH4+ with only moderate distortion of the C3 configuration adopted in the complexes with the metal cations. The ammonium cation occupies the center of the cavity and displays two low-energy coordination arrangements that are dynamically connected through a facile rotation of the cation. The inclusion of the bulkier phosphoric acid cation demands significant stretching of the valinomycin backbone. Interestingly, the H4PO4+ cation achieves ample positional and rotational mobility inside valinomycin. The valinomycin backbone is capable of adopting barrel-like configurations when the cation occupies a region close to the center of the cavity, and funnel-like configurations when it diffuses to positions close to the exit face. This can accommodate the cation in varying coordination arrangements, characterized by different H-bonding between the four POH arms and the ester carbonyl groups of the macrocycle.

Complexes of Crown Ether Macrocycles with Methyl Guanidinium: Insights into the Capture of Charge in Peptides.

Crown ethers are well known as modulating agents of protein function and interactions. The action of crown ethers is driven by an alteration of the charged moieties of proteins through the capping of cationic amino acid side chains. This study evaluates the conformational features involved in the binding of crown ethers to the side chain of arginine. For this purpose, isolated complexes of methyl guanidinium with 12-crown-4 and 18-crown-6 are characterized with infrared action vibrational spectroscopy and quantum chemical computations. The conformational landscapes of the two complexes comprise an extensive ensemble of conformations close in energy. In the 12-crown-4 complex, the crown ether has the plane of its backbone approximately perpendicular to that of the guanidinium moiety and coordinates to two or three of its NHδ+ bonds. In the 18-crown-6 complex, the crown ether backbone is partially folded and tilted with respect to guanidinium and fixes its position in order to facilitate up to a four-fold coordination in the complex. The access of the complexes to multiple conformations leads to broad band structures in the N-H stretching region of their vibrational spectra.

Intra-cavity proton bonding and anharmonicity in the anionophore cyclen.

Proton bonding drives the supramolecular chemistry of a broad range of materials with polar moieties. Proton delocalization and electronic charge redistribution have a profound impact on the structure of proton-bound molecular frameworks, and pose fundamental challenges to quantum chemical modelling. This study provides insights into the structural and spectral signatures of the intramolecular proton bond formed in a benchmark polyazamacrocycle anionophore (cyclen, 1,4,7,10-tetraazacyclododecane). Infrared action spectroscopy is employed to characterize the macrocycle, isolated in protonated form. In its most stable configuration, protonated cyclen adopts an open arrangement of Cs symmetry with a particularly strong NHδ+N bond across the cavity. The quantum chemical analysis of the infrared spectrum reveals intrinsic difficulties for the accurate description of the vibrational modes of the system. The reconciliation of the computational predictions with experiment demands a careful anharmonic treatment of the proton motion, which exposes the limitations of current methods. Best results are obtained with the incorporation of anharmonicity only to the fundamental modes directly related to motions of the proton. However, the full anharmonic treatment of the system fails to describe correctly the vibrations related to the macrocycle backbone. The results should serve as motivation for new developments in the modelling of proton bonded systems.

Guanidinium/ammonium competition and proton transfer in the interaction of the amino acid arginine with the tetracarboxylic 18-crown-6 ionophore.

The recognition of arginine plays a central role in modern proteomics and genomics. Arginine is unique among natural amino acids due to the high basicity of its guanidinium side chain, which sustains specific interactions and proton exchange biochemical processes. The search for suitable macrocyclic ionophores constitutes a promising route towards the development of arginine receptors. This study evaluates the conformational features involved in the binding of free arginine by the polyether macrocycle (18-crown-6)-tetracarboxylic acid. Infrared action vibrational spectroscopy and quantum-chemical computations are combined to characterize the complexes with net charges +1 and +2. The spectrum of the +1 complex can be explained in terms of a configuration predominantly stabilized by a robust bidentate coordination of guanidinium with a carboxylate group formed from the deprotonation of one side group of the crown ether. The released proton is transferred to the amino terminus of arginine, which then coordinates with the crown ether ring. In an alternative type of conformation, partly consistent with experiment, the amino terminus is neutral and the guanidinium group inserts into the crown ether cavity. In the +2 complexes, arginine is always doubly protonated and the most stable conformations are characterized by a tripodal coordination of the ammonium -NH3+ group of arginine with the oxygen atoms of the macrocycle ring, while the interactions of the amino acid with the side carboxylic acid groups of the crown ether acquire a remarkable lesser role.

Preferential host-guest coordination of nonactin with ammonium and hydroxylammonium.

The biological activity of the macrocycle nonactin is intimately related to its ionophore properties and ability to act as a selective cation carrier. The competitive binding of small protonated amines constitutes a particularly key issue in the biochemistry of nonactin, which finds application in sensing and extraction technologies. In this study, isolated complexes of nonactin with ammonium and hydroxylammonium are investigated with infrared action spectroscopy and quantum chemical computations. The focus of the investigation is on the coordination achieved by the protonated guest with the oxygen atoms of either the oxolane groups or the carboxyl groups in the ester linkages of the macrocyle host and their relative contributions to the stability of the complexes. The experimental and computational data converge to a preferred coordination arrangement associated with a tight binding of the N-H δ+ bonds with the oxolane groups. In the N H 4 + complex, this results in a compact complex of S 4 symmetry. In contrast, symmetry is disrupted in the NH3OH+ complex, as it incorporates a bifurcated coordination of the -OH bond with a carbonyl group and an oxolane group of the host, involving also a more stretched arrangement of the nonactin backbone. These gas-phase conformations are in agreement with the structures postulated for these complexes in condensed phases, from previous Raman and crystallographic experiments.

Benchmark Ditopic Binding of Cl- and Cs+ by the Macrocycle Hexacyclen.

The ditopic binding of organic and inorganic anions and cations constitutes a distinct feature of polyazamacrocycles that underlies their action as intermediate docking and exchange ionophoric sites for tailored supramolecular synthesis and sensors. This work investigates the Cl- and Cs+ complexes formed by hexacyclen (1,4,7,10,13,16-hexaazacyclooctadecane, ha18c6), a benchmark building block of ion-pair polyamine receptors. IR action spectroscopy is employed to characterize the anionic and cationic complexes under controlled environmental conditions in an ion trap. This allows for accurate modeling of the isolated complexes with quantum chemical computations. A comparison of the experimental and computational spectra serves to assess the low-energy conformers dominantly populated at room temperature, which comprise, in both cases, three structures of Cs , C2 , and C3v symmetry with relative energies within about 5 kJ mol-1 . The ion-pair complex Cl- -ha18c6-Cs+ is predicted to host the cation and anion on opposite sides of the macrocycle in a C3v conformation that does not correlate with the lowest energy structures of the binary complexes. This indicates that the formation of the ion-pair complex in its most stable conformation demands a rearrangement of the hexacyclen ring structure upon the incorporation of the counterion.

Isolated complexes of the amino acid arginine with polyether and polyamine macrocycles, the role of proton transfer.

The distinct basicity of the guanidinium side-group of arginine (Arg) sustains specific interactions involved in essential biochemical processes. The sensing of arginine is therefore key in modern biotechnology and bioanalysis. In this context, the development of molecular receptors based on crown ether building blocks has demonstrated great potential. We investigate the complexes formed by arginine with two benchmark macrocycles, 12-crown-4 (1,4,7,10-tetraoxacyclododecane) and its N-substituted analog cyclen (1,4,7,10-tetraazacyclododecane). Isolated complexes with a net charge +1 are characterized with infrared action vibrational spectroscopy and quantum mechanical computations in order to determine the most stable coordination arrangements and to elucidate the location of the protons involved. Remarkably, although arginine retains a net positive charge in its complex with 12-crown-4, it becomes zwitterionic in the cyclen complex. In this latter case, the guanidinium group remains protonated while a proton transfer from the carboxylic group occurs, leading to a charged -NH2+ moiety in cyclen. Natural bond orbital analysis is employed to characterize the intermolecular H-bonds responsible for the stability of both complexes. Protonated arginine interacts with 12-crown-4 through the guanidinium side group, in a conformation that resembles the one expected for crown-Arg binding in peptidic chains. In contrast, the cyclen complex involves the coordination of the carboxylate anionic group with a N-H bond of the protonated amine group cyclen, and plausible but less relevant interactions with the guanidinium group.

On the ionophoric selectivity of nonactin and related macrotetrolide derivatives.

Nonactin and its analogs constitute a central class of macrocycles with an antibiotic activity closely related to their selective ionophoric behavior. In this study, we apply experimental and computational methods to revisit the specificity of cation binding and transport by three nactin variants differing in structural properties, such as the position of the ester linkages, the nature of the side groups, or the flexibility of the backbone. On the one hand, electrospray ionization mass spectrometry and infrared spectroscopy are employed to expose the selectivity of the liquid-liquid (water-chloroform) extraction of alkali cations by nonactin and to demonstrate that the cation complexes are partially hydrated in the organic phase. Furthermore, laser desorption mass spectrometry is employed to determine the intrinsic cation affinities of nonactin under solvent-free conditions. On the other hand, density functional theory calculations are performed to characterize the conformations of the alkali cation complexes of the three nactins, and to assess the role of intermolecular and solvent interactions in determining their relative stability. Depending on the structure of the macrocycle, the cation complexes adopt either a cage-like conformation or a tweezer-like conformation. The computations show that the partial hydration of those different conformations in the organic phase, determine the distinct cation extraction selectivities that are observed experimentally.

Isolated alkali cation complexes of the antibiotic ionophore nonactin: correlation with crystalline structures.

The antibiotic activity of nonactin is sustained by its ability to transport K+ across lipophilic phases, e.g., the cell membranes. Such a feature can be traced back to a specific ionophoric behavior and to a balanced hydrophobicity modulated by the formation of a cation complex. In this study, the dominant conformations and coordination arrangements in the alkali cation complexes (Na+, K+, Cs+) of nonactin are characterized by means of action vibrational spectroscopy and quantum chemical computations. The low energy conformers of the complexes comprise compact inclusion structures, in which the cation interacts with a varying number of oxygen atoms of the carbonyl and oxolane ring groups of the nonactin macrocycle. The spectroscopy experiments indicate that the three alkali complexes explored are formed in a S4 conformation. This is in contrast with previous crystallography studies, which concluded that the symmetry of the most stable conformer of the complex changes qualitatively with the cation size, from C2 for Na+ to S4 for K+ and Cs+. Computations with different hybrid density functionals lead to contradictory predictions that appear to be quite sensitive to the modelling of the long range interactions in the coordination arrangements. The stabilization of the nonactin-Na+ complex in the C2 or S4 forms emerges as a subtle feature that may be tuned with an appropriate control of the environmental conditions, and constitutes a challenging benchmark to confront novel computational methods for supramolecular systems.

Enhanced cation recognition by a macrocyclic ionophore at the air-solution interface probed by mass spectrometry.

Interfacial environments have the potential to drive unexpected events of supramolecular recognition, leading to advances in the development of novel functional materials and molecular sensing techniques. We present experimental evidence for a noticeable enhancement of the cation binding specificity of a prototype calixarene macrocycle (cesium ionophore II) at the air-solution interface, in comparison to bulk solution and to isolated solvent-less conditions. A rationalization of this intriguing finding is outlined, with the support of quantum calculations, in terms of the 'half-solvation' conditions provided by the interface and of conformational effects posed by the backbone structure and the side chains of the macrocyclic ionophore. The investigation involves the introduction of a mass spectrometry method to determine the relative abundances of interfacial complexes that should be of general application in the field and guide future advances in analytical techniques based on molecular recognition.

Binding Selectivity of Macrocycle Ionophores in Ionic Liquids versus Aqueous Solution and Solvent-free Conditions.

The understanding of supramolecular recognition in room-temperature ionic liquids (RTILs) is key to develop the full potential of these materials. In this work, we provide insights into the selectivity of the binding of alkali metal cations by standard cyclodextrin and calixarene macrocycles in RTILs. A direct laser desorption/ionization mass spectrometry approach is employed to determine the relative abundances of the inclusion complexes formed through competitive binding in RTIL solutions. The results are compared with the binding selectivities measured under solvent-free conditions and in water/methanol solutions. Cyclodextrins and calixarenes in which the peripheral OH groups are substituted by bulkier side groups preferentially bind to Cs(+) . Such specific ionophoric behavior is substantially enhanced by solvation effects in the RTIL. This finding is rationalized with the aid of quantum mechanical calculations, in terms of the conformational features and steric interactions that drive the solvation of the inclusion complexes by the bulky RTIL counterions.

Transport of spherical colloids in layered phases of binary mixtures with rod-like particles.

The transport properties of colloids in anisotropic media constitute a general problem of fundamental interest in experimental sciences, with a broad range of technological applications. This work investigates the transport of soft spherical colloids in binary mixtures with rod-like particles by means of Monte Carlo and Brownian Dynamics simulations. Layered phases are considered, that range from smectic phases to lamellar phases, depending on the molar fraction of the spherical particles. The investigation serves to characterize the distinct features of transport within layers versus those of transport across neighboring layers, both of which are neatly differentiated. The insertion of particles into layers and the diffusion across them occur at a smaller rate than the intralayer diffusion modulated by the formation of transitory cages in its initial stages. Collective events, in which two or more colloids diffuse across layers in a concerted way, are described as a non-negligible process in these fluids.

Cations in a molecular funnel: vibrational spectroscopy of isolated cyclodextrin complexes with alkali metals.

The benchmark inclusion complexes formed by α-cyclodextrin (αCD) with alkali-metal cations are investigated under isolated conditions in the gas phase. The relative αCD-M(+) (M=Li(+), Na(+), K(+), Cs(+)) binding affinities and the structure of the complexes are determined from a combination of mass spectrometry, infrared action spectroscopy and quantum chemical computations. Solvent-free laser desorption measurements reveal a trend of decreasing stability of the isolated complexes with increasing size of the cation guest. The experimental infrared spectra are qualitatively similar for the complexes with the four cations investigated, and are consistent with the binding of the cation within the primary face of the cyclodextrin, as predicted by the quantum computations (B3LYP/6-31+G*). The inclusion of the quantum-chemical cation disrupts the C(6) symmetry of the free cyclodextrin to provide the optimum coordination of the cations with the -CH(2)OH groups in C(1), C(2) or C(3) symmetry arrangements that are determined by the size of the cation.

A Dynamic Proton Bond: MH+·H2O ⇌ M·H3O+ Interconversion in Loosely Coordinated Environments.

The interaction of organic molecules with oxonium cations within their solvation shell may lead to the emergence of dynamic supramolecular structures with recurrently changing host-guest chemical identity. We illustrate this phenomenon in benchmark proton-bonded complexes of water with polyether macrocyles. Despite the smaller proton affinity of water versus the ether group, water in fact retains the proton in the form of H3O+, with increasing stability as the coordination number increases. Hindrance in many-fold coordination induces dynamic reversible (ether)·H3O+ ⇌ (etherH+)·H2O interconversion. We perform infrared action ion spectroscopy over a broad spectral range to expose the vibrational signatures of the loose proton bonding in these systems. Remarkably, characteristic bands for the two limiting proton bonding configurations are observed in the experimental vibrational spectra, superimposed onto diffuse bands associated with proton delocalization. These features cannot be described by static equilibrium structures but are accurately modeled within the framework of ab initio molecular dynamics.

Wetting of a Hydrophobic Surface: Far-IR Action Spectroscopy and Dynamics of Microhydrated Naphthalene.

The interaction of water and polycyclic aromatic hydrocarbons is of fundamental importance in areas as diverse as materials science and atmospheric and interstellar chemistry. The interplay between hydrogen bonding and dipole-π interactions results in subtle dynamics that are challenging to describe from first principles. Here, we employ far-IR action vibrational spectroscopy with the infrared free-electron laser FELIX to investigate naphthalene with one to three water molecules. We observe diffuse bands associated with intermolecular vibrational modes that serve as direct probes of the loose binding of water to the naphthalene surface. These signatures are poorly reproduced by static DFT or Møller-Plesset computations. Instead, a rationalization is achieved through Born-Oppenheimer Molecular Dynamics simulations, revealing the active mobility of water over the surface, even at low temperatures. Therefore, our work provides direct insights into the wetting interactions associated with shallow potential energy surfaces while simultaneously demonstrating a solid experimental-computational framework for their investigation.