Aptamer to ribozyme: the intrinsic catalytic potential of a small RNA

The discovery of RNA-based catalysis 23 years ago dramatically changed the way biologists and biochemists thought of RNA. In the recent past, several ribozymes structures have provided some answers as to how catalysis is accomplished and how it relates to RNA structure and folding. However, there is still little information as to how catalytic activity evolved. Here we show that the small malachite green-binding aptamer has intrinsic catalytic potential that can be realized by designing the proper substrate. The charge distribution within the RNA binding pocket stabilizes the transition state of an ester hydrolysis reaction and thus accelerates the overall reaction. The results suggest that electrostatic forces can contribute significantly to RNA-based catalysis. Moreover, even simple RNA structures that have not been selected for catalytic properties can have a basic catalytic potential if they encounter the right substrate. This provides a possible starting point for the molecular evolution of more complex ribozymes.     

Structure and Energetics of Ligand–Fluorine Interactions with Galectin-3 Backbone and Side-Chain Amides: Insight into Solvation Effects and Multipolar Interactions

Multipolar fluorine–amide interactions with backbone and side-chain amides have been described as important for protein–ligand interactions and have been used to improve the potency of synthetic inhibitors. In this study, fluorine interactions within a well-defined binding pocket on galectin-3 were investigated systematically using phenyltriazolyl-thiogalactosides fluorinated singly or multiply at various positions on the phenyl ring. X-ray structures of the C-terminal domain of galectin-3 in complex with eight of these ligands revealed potential orthogonal fluorine–amide interactions with backbone amides and one with a side-chain amide. The two interactions involving main-chain amides seem to have a strong influence on affinity as determined by fluorescence anisotropy. In contrast, the interaction with the side-chain amide did not influence affinity. Quantum mechanics calculations were used to analyze the relative contributions of these interactions to the binding energies. No clear correlation could be found between the relative energies of the fluorine–main-chain amide interactions and the overall binding energy. Instead, dispersion and desolvation effects play a larger role. The results confirm that the contribution of fluorine–amide interactions to protein–ligand interactions cannot simply be predicted, on geometrical considerations alone, but require careful consideration of the energetic components.     

NMR chemical shift perturbation study of the N-terminal domain of Hsp90 upon binding of ADP,AMP-PNP,geldanamycin, and radicicol

Hsp90 is one of the most abundant chaperone proteins in the cytosol. In an ATP-dependent manner it plays an essential role in the folding and activation of a range of client proteins involved in signal transduction and cell cycle regulation. We used NMR shift perturbation experiments to obtain information on the structural implications of the binding of AMP-PNP (adenylyl-imidodiphosphate-a non-hydrolysable ATP analogue), ADP and the inhibitors radicicol and geldanamycin. Analysis of (1)H,(15)N correlation spectra showed a specific pattern of chemical shift perturbations at N210 (ATP binding domain of Hsp90, residues 1-210) upon ligand binding. This can be interpreted qualitatively either as a consequence of direct ligand interactions or of ligand-induced conformational changes within the protein. All ligands show specific interactions in the binding site, which is known from the crystal structure of the N-terminal domain of Hsp90. For AMP-PNP and ADP, additional shift perturbations of residues outside the binding pocket were observed and can be regarded as a result of conformational rearrangement upon binding. According to the crystal structures, these regions are the first alpha-helix and the "ATP-lid" ranging from amino acids 85 to 110. The N-terminal domain is therefore not a passive nucleotide-binding site, as suggested by X-ray crystallography, but responds to the binding of ATP in a dynamic way with specific structural changes required for the progression of the ATPase cycle.     

Dissimilar Ligands Bind in a Similar Fashion: A Guide to Ligand Binding-Mode Prediction with Application to CELPP Studies

The molecular similarity principle has achieved great successes in the field of drug design/discovery. Existing studies have focused on similar ligands, while the behaviors of dissimilar ligands remain unknown. In this study, we developed an intercomparison strategy in order to compare the binding modes of ligands with different molecular structures. A systematic analysis of a newly constructed protein–ligand complex structure dataset showed that ligands with similar structures tended to share a similar binding mode, which is consistent with the Molecular Similarity Principle. More importantly, the results revealed that dissimilar ligands can also bind in a similar fashion. This finding may open another avenue for drug discovery. Furthermore, a template-guiding method was introduced for predicting protein–ligand complex structures. With the use of dissimilar ligands as templates, our method significantly outperformed the traditional molecular docking methods. The newly developed template-guiding method was further applied to recent CELPP studies.     

Halogen bonding at the active sites of human cathepsin L and MEK1 kinase: efficient interactions in different environments

In two series of small‐molecule ligands, one inhibiting human cathepsin L (hcatL) and the other MEK1 kinase, biological affinities were found to strongly increase when an aryl ring of the inhibitors is substituted with the larger halogens Cl, Br, and I, but to decrease upon F substitution. X‐ray co‐crystal structure analyses revealed that the higher halides engage in halogen bonding (XB) with a backbone C?O in the S3 pocket of hcatL and in a back pocket of MEK1. While the S3 pocket is located at the surface of the enzyme, which provides a polar environment, the back pocket in MEK1 is deeply buried in the protein and is of pronounced apolar character. This study analyzes environmental effects on XB in protein–ligand complexes. It is hypothesized that energetic gains by XB are predominantly not due to water replacements but originate from direct interactions between the XB donor (C_aryl? X) and the XB acceptor (C?O) in the correct geometry. New X‐ray co‐crystal structures in the same crystal form (space group P2₁2₁2₁) were obtained for aryl chloride, bromide, and iodide ligands bound to hcatL. These high‐resolution structures reveal that the backbone C?O group of Gly61 in most hcatL co‐crystal structures maintains water solvation while engaging in XB. An aryl? CF₃‐substituted ligand of hcatL with an unexpectedly high affinity was found to adopt the same binding geometry as the aryl halides, with the CF₃ group pointing to the C?O group of Gly61 in the S3 pocket. In this case, a repulsive F₂C? F???O?C contact apparently is energetically overcompensated by other favorable protein–ligand contacts established by the CF₃ group.     

Characterization of Structure and Dynamics of the Guanidine-II Riboswitch from Escherichia coli by NMR Spectroscopy and Small-Angle X-ray Scattering (SAXS)

Riboswitches are regulatory RNA elements that undergo functionally important allosteric conformational switching upon binding of specific ligands. The here investigated guanidine-II riboswitch binds the small cation, guanidinium, and forms a kissing loop-loop interaction between its P1 and P2 hairpins. We investigated the structural changes to support previous studies regarding the binding mechanism. Using NMR spectroscopy, we confirmed the structure as observed in crystal structures and we characterized the kissing loop interaction upon addition of Mg²⁺ and ligand for the riboswitch aptamer from Escherichia coli. We further investigated closely related mutant constructs providing further insight into functional differences between the two (different) hairpins P1 and P2. Formation of intermolecular interactions were probed by small-angle X-ray scattering (SAXS) and NMR DOSY data. All data are consistent and show the formation of oligomeric states of the riboswitch induced by Mg²⁺ and ligand binding.     

Water makes the difference: rearrangement of water solvation layer triggers non-additivity of functional group contributions in protein-ligand binding

The binding of four congeneric peptide-like thermolysin inhibitors has been studied by high-resolution crystal structure analysis and isothermal titration calorimetry. The ligands differ only by a terminal carboxylate and/or methyl group. A surprising non-additivity of functional group contributions for the carboxylate and/or methyl groups is detected. Adding the methyl first and then the carboxylate group results in a small Gibbs free energy increase and minor enthalpy/entropy partitioning for the first modification, whereas the second involves a strong affinity increase combined with large enthalpy/entropy changes. However, first adding the carboxylate and then the methyl group yields reverse effects: the acidic group attachment now causes minor effects, whereas the added methyl group provokes large changes. As all crystal structures show virtually identical binding modes, affinity changes are related to rearrangements of the first solvation layer next to the S(2)' pocket. About 20-25 water molecules are visible next to the studied complexes. The added COO(-) groups perturb the local water network in both carboxylated complexes, and the attached methyl groups provide favorable interaction sites for water molecules. Apart from one example, a contiguously connected water network between protein and ligand functional groups is observed in all complexes. In the complex with the carboxylated ligand, which still lacks the terminal methyl group, the water network is unfavorably ruptured. This results in a surprising thermodynamic signature showing only a minor affinity increase upon COO(-) group attachment. Because the further added methyl group provides a favorable interaction site for water, the network can be reestablished, and a strong affinity increase with a large enthalpy/entropy signature is then detected.     

A tale of two targets: differential RNA selectivity of nucleobase-aminoglycoside conjugates

Aminoglycoside antibiotics are RNA-binding polyamines that can bind with similar affinities to structurally diverse RNA targets. To design new semisynthetic aminoglycosides with improved target selectivity, it is important to understand the energetic and structural basis by which diverse RNA targets recognize similar ligands. It is also imperative to discover how novel aminoglycosides could be rationally designed to have enhanced selectivity for a given target. Two RNA drug targets, the prokaryotic ribosomal A-site and the HIV-1 TAR, provide an excellent model system in which to dissect the issue of target selectivity, in that they each have distinctive interactions with aminoglycosides. We report herein the design, synthesis, and binding activity of novel nucleobase-aminoglycoside conjugates that were engineered to be more selective for the A-site binding pocket. Contrary to the structural design, the conjugates bind the A-site more weakly than does the parent compound and bind the TAR more tightly than the parent compound. This result implies that the two RNA targets differ in their ability to adapt to structurally diverse ligands and thus have inherently different selectivities. This work emphasizes the importance of considering the inherent selectivity traits of the RNA target when engineering new ligands.     

Comparative Binding Energy (COMBINE) Analysis for Understanding the Binding Determinants of Type II Dehydroquinase Inhibitors

Herein we report comparative binding energy (COMBINE) analyses to derive quantitative structure–activity relationship (QSAR) models that help rationalize the determinants of binding affinity for inhibitors of type II dehydroquinase (DHQ2), the third enzyme of the shikimic acid pathway. Independent COMBINE models were derived for Helicobacter pylori and Mycobacterium tuberculosis DHQ2, which is an essential enzyme in both these pathogenic bacteria that has no counterpart in human cells. These studies quantify the importance of the hydrogen bonding interactions between the ligands and the water molecule involved in the DHQ2 reaction mechanism. They also highlight important differences in the ligand interactions with the interface pocket close to the active site that could provide guides for future inhibitor design.     

Understanding binding selectivity toward trypsin and factor Xa: the role of aromatic interactions

A congeneric series of four bis-benzamidine inhibitors sharing a dianhydrosugar isosorbide scaffold in common has been studied by crystal structure analysis and enzyme kinetics with respect to their binding to trypsin and factor Xa. Within the series, aromatic interactions are an important determinant for selectivity discrimination among both serine proteases. To study the selectivity-determining features in detail, we used trypsin mutants in which the original binding site is gradually substituted to finally resemble the factor Xa binding pocket. The influence of these mutations has been analyzed on the binding of the closely related inhibitors. We present the crystal structures of the inhibitor complexes obtained by co-crystallizing an "intermediate" trypsin mutant. They could be determined to a resolution of up to 1.2 A, and we measured the inhibitory activity (K(i)) of each ligand against factor Xa, trypsin, and the various mutants. From these data we were able to derive a detailed structure-activity relationship which demonstrates the importance of aromatic interactions in protein-ligand recognition and their role in modulating enzyme selectivity. Pronounced preference is experienced to accommodate the benzamidine anchor with meta topology in the S(1) specificity pocket. One ligand possessing only para topology deviates strongly from the other members of the series and adopts a distinct binding mode addressing the S(1)' site instead of the distal S(3)/S(4) binding pocket.     

Antofine analogues can inhibit tobacco mosaic virus assembly through small-molecule-RNA interactions

The extra unpaired base(s) or bulged structures of nucleic acids are capable either of forming complexes with nucleic-acid-binding proteins or of acting as binding sites for small molecules. We are interested in developing bulge-specific agents as potential drugs or chemical tools in biological research. Antofine can selectively bind with DNA and RNA bulged structures (Xi et al., Bioorg. Med. Chem. Lett. 2006, 16, 4300-4304). Furthermore, a series of antofine analogues suitable for selective binding with TMV RNA rather than with TMV coat protein (CP) were found. Biochemical studies indicated that antofine and its analogues disrupt in vitro virus assembly through small-molecule-RNA interactions. A structural model to illustrate these effects has been proposed. It is suggested that antofine analogues bind selectively with RNA bulged structures and therefore disrupt interaction between TMV RNA and TMV CP.     

Sequence Elements Distal to the Ligand Binding Pocket Modulate the Efficiency of a Synthetic Riboswitch

Synthetic riboswitches can serve as sophisticated genetic control devices in synthetic biology, regulating gene expression through direct RNA–ligand interactions. We analyzed a synthetic neomycin riboswitch, which folds into a stem loop structure with an internal loop important for ligand binding and regulation. It is closed by a terminal hexaloop containing a U‐turn and a looped‐out adenine. We investigated the relationship between sequence, structure, and biological activity in the terminal loop by saturating mutagenesis, ITC, and NMR. Mutants corresponding to the canonical U‐turn fold retained biological activity. An improvement of stacking interactions in the U‐turn led to an RNA element with slightly enhanced regulatory activity. For the first position of the U‐turn motif and the looped out base, sequence–activity relationships that could not initially be explained on the basis of the structure of the aptamer–ligand complex were observed. However, NMR studies of these mutants revealed subtle relationships between structure and dynamics of the aptamer in its free or bound state and biological activity.     

Novel Topology in Semiconducting Tetrathiafulvalene Lanthanide Metal-Organic Frameworks

Tetrathiafulvalene tetrabenzoate (TTFTB) and several lanthanide ions self-assemble into metal-organic frameworks (MOFs) that exhibit a novel topology, a (3,3,3,6,6)-coordinated net, which features an unusual ligand coordination mode and stacking motif. The Yb and Lu MOFs are electrically conductive, with pellet conductivity values of 9(7) × 10⁻⁷ and 3(2) × 10⁻⁷ S/cm, respectively. The crystallographically-determined bond lengths indicate partial oxidation of the ligand, with close S ⋅ ⋅ ⋅ S contacts between ligands providing likely charge transport pathways in the material. Magnetometry reveals temperature-independent paramagnetism, consistent with the presence of ligand-based radicals, as well as weak antiferromagnetic coupling between Yb³⁺ centers. These results illustrate the diversity of MOF structures and properties that are accessible with the TTFTB ligand owing to its electroactive nature, propensity for intermolecular interactions, and conformational flexibility.     

Monovalent ion dependence of neomycin B binding to an RNA aptamer characterized by spectroscopic methods

Understanding the interactions of small molecules like antibiotics with RNA is a prerequisite for the development of novel drugs. In this study we address structural and thermodynamic features of such interactions by using a simple model system: the binding of the highly charged antibiotic neomycin B to a short hairpin RNA molecule. Nucleotide A16, which acts as a flap over the neomycin B binding pocket, was substituted by the fluorescent adenine analogue 2-aminopurine (2-AP). Steady-state and time-resolved fluorescence measurements were complemented by UV-melting and circular dichroism studies. The binding of neomycin B at three sites was found to have a strong inverse correlation with Na(+) concentration. For the highest-affinity site, both fluorescence and UV absorption experiments were consistent with a model assuming at least three neomycin NH(3) (+) groups participating in addition to hydrogen bonds in electrostatic interactions with the RNA. The variation of fluorescence intensity and lifetime upon neomycin B binding indicated unstacking of 2-AP16 from neighbouring bases as it flipped over the binding pocket. RNA conformational changes upon binding of the antibiotic were confirmed by circular dichroism. The two weaker binding sites were characterized as unspecific binding to the aptamer, while the high-affinity binding event was shown to be highly specific even at high ionic concentration. In addition, 2-AP was confirmed to be a noninvasive fluorescent probe; it serves as a sensitive spectroscopic tool to investigate details of the interactions between small molecules and RNA.     

High Resolution Crystal Structures of the Cerebratulus lacteus Mini-Hb in the Unligated and Carbomonoxy States

The nerve tissue mini-hemoglobin from Cerebratulus lacteus (CerHb) displays an essential globin fold hosting a protein matrix tunnel held to allow traffic of small ligands to and from the heme. CerHb heme pocket hosts the distal TyrB10/GlnE7 pair, normally linked to low rates of O(2) dissociation and ultra-high O(2) affinity. However, CerHb affinity for O(2) is similar to that of mammalian myoglobins, due to a dynamic equilibrium between high and low affinity states driven by the ability of ThrE11 to orient the TyrB10 OH group relative to the heme ligand. We present here the high resolution crystal structures of CerHb in the unligated and carbomonoxy states. Although CO binds to the heme with an orientation different from the O(2) ligand, the overall binding schemes for CO and O(2) are essentially the same, both ligands being stabilized through a network of hydrogen bonds based on TyrB10, GlnE7, and ThrE11. No dramatic protein structural changes are needed to support binding of the ligands, which can freely reach the heme distal site through the apolar tunnel. A lack of main conformational changes between the heme-unligated and -ligated states grants stability to the folded mini-Hb and is a prerequisite for fast ligand diffusion to/from the heme.     

Crystal Structure of Human Soluble Adenylate Cyclase Reveals a Distinct,Highly Flexible Allosteric Bicarbonate Binding Pocket

Soluble adenylate cyclases catalyse the synthesis of the second messenger cAMP through the cyclisation of ATP and are the only known enzymes to be directly activated by bicarbonate. Here, we report the first crystal structure of the human enzyme that reveals a pseudosymmetrical arrangement of two catalytic domains to produce a single competent active site and a novel discrete bicarbonate binding pocket. Crystal structures of the apo protein, the protein in complex with α,β‐methylene adenosine 5′‐triphosphate (AMPCPP) and calcium, with the allosteric activator bicarbonate, and also with a number of inhibitors identified using fragment screening, all show a flexible active site that undergoes significant conformational changes on binding of ligands. The resulting nanomolar‐potent inhibitors that were developed bind at both the substrate binding pocket and the allosteric site, and can be used as chemical probes to further elucidate the function of this protein.     

Analysis of cation-π interactions to the structural stability of RNA binding proteins

Cation-π interactions play an important role to the stability of protein structures. In this work, we have analyzed the influence of cation-π interactions in RNA binding proteins. We observed cation-π interactions in 32 out of 51 RNA binding proteins and there is a strong correlation between the number of amino acid residues and number of cation-π interactions. The analysis on the influence of short (<±3 residues), medium (±3 or ±4 residues) and long range contacts (>±4 residues) showed that the cation-π interactions are mainly formed by long-range contacts. The cation-π interaction energy for Arg-Trp is found to be the strongest among all interacting pairs. Analysis on the preferred secondary structural conformation of the residues involved in cation-π interaction indicates that the cationic Lys and Arg prefer to be in α-helices and β-strands, respectively, whereas the aromatic residues prefer to be in strand and coil regions. Most of the cation-π interactions forming residues in RNA binding proteins are conserved among homologous sequences. Further, the cation-π interactions have distinct roles to the stability of RNA binding proteins in addition to other conventional non-covalent interactions. The results observed in the present study will be useful in understanding the contribution of cation-π interactions to the stability of RNA binding proteins.