Project description:On the basis of X-ray crystal structures and electron paramagnetic resonance (EPR) measurements, it has been inferred that the O(2) binding to hemoglobin is stabilized by the hydrogen bonds between the oxygen ligands and the distal histidines. Our previous study by multinuclear nuclear magnetic resonance (NMR) spectroscopy has provided the first direct evidence of such H-bonds in human normal adult oxyhemoglobin (HbO(2) A) in solution. Here, the NMR spectra of uniformly (15)N-labeled recombinant human Hb A (rHb A) and five mutant rHbs in the oxy form have been studied under various experimental conditions of pH and temperature and also in the presence of an organic phosphate, inositol hexaphosphate (IHP). We have found significant effects of pH and temperature on the strength of the H-bond markers, i.e., the cross-peaks for the side chains of the two distal histidyl residues, α58His and β63His, which form H-bonds with the O(2) ligands. At lower pH and/or higher temperature, the side chains of the distal histidines appear to be more mobile, and the exchange with water molecules in the distal heme pockets is faster. These changes in the stability of the H-bonds with pH and temperature are consistent with the changes in the O(2) affinity of Hb as a function of pH and temperature and are clearly illustrated by our NMR experiments. Our NMR results have also confirmed that this H-bond in the β-chain is weaker than that in the α-chain and is more sensitive to changes in pH and temperature. IHP has only a minor effect on these H-bond markers compared to the effects of pH and temperature. These H-bonds are sensitive to mutations in the distal heme pockets but not affected directly by the mutations in the quaternary interfaces, i.e., α(1)β(1) and/or α(1)β(2) subunit interface. These findings provide new insights regarding the roles of temperature, hydrogen ion, and organic phosphate in modulating the structure and function of hemoglobin in solution.

Project description:Discovering the interaction mechanism and location of RNA binding proteins (RBPs) on RNA is critical for understanding gene expression regulation. Here, we apply selective 2’-hydroxyl acylation analyzed by primer extension (SHAPE) on in vivo transcripts to identify transcriptome-wide footprints (fSHAPE) on RNA when compared to protein-absent transcripts. Structural analyses indicate that fSHAPE precisely detects nucleotides whose base moieties hydrogen bond with protein and that fSHAPE patterns can predict binding sites of RBPs of interest. To illustrate, we demonstrate that fSHAPE correctly identifies known and novel iron response protein RNA elements. Furthermore, we enable selective interrogation of RNA-protein complexes by integrating SHAPE and fSHAPE with crosslinking and immunoprecipitation (eCLIP) of desired RBPs. To demonstrate, histone stem loop elements and their nucleotides that hydrogen bond with stem-loop binding protein were identified by SHAPE-eCLIP and fSHAPE-eCLIP. Together, these technologies greatly expand on strategies for understanding specific cellular RNA interactions in RNA-protein complexes.

Project description:Hydrogen bonds between protein side-chain hydroxyl (OH) and phosphate groups are one of the most common types of intermolecular hydrogen bonds in protein-DNA/RNA complexes. Using NMR spectroscopy, we identified and characterized the hydrogen bonds between tyrosine side-chain OH and DNA phosphate groups in a protein-DNA complex. These OH groups exhibited relatively slow hydrogen-exchange rates and sizable scalar couplings between hydroxyl 1H and DNA phosphate 31P nuclei across the hydrogen bonds. Information about intermolecular hydrogen bonds facilitates investigations of the DNA/RNA recognition by the protein.

Project description:NMR scalar couplings across hydrogen bonds represent direct evidence for the partial covalent nature of hydrogen bonds and provide structural and dynamic information on hydrogen bonding. In this article, we report heteronuclear 15N-31P and 1H-31P scalar couplings across the intermolecular hydrogen bonds between protein histidine (His) imidazole and DNA phosphate groups. These hydrogen-bond scalar couplings were observed for the Egr-1 zinc-finger-DNA complex. Although His side-chain NH protons are typically undetectable in heteronuclear 1H-15N correlation spectra due to rapid hydrogen exchange, this complex exhibited two His side-chain NH signals around 1H 14.3 ppm and 15N 178 ppm at 35 °C. Through various heteronuclear multidimensional NMR experiments, these signals were assigned to two zinc-coordinating His side chains in contact with DNA phosphate groups. The data show that the Nδ1 atoms of these His side chains are protonated and exhibit the 1H-15N cross-peaks. Using heteronuclear 1H, 15N, and 31P NMR experiments, we observed the hydrogen-bond scalar couplings between the His 15Nδ1/1Hδ1 and DNA phosphate 31P nuclei. These results demonstrate the direct involvement of the zinc-coordinating His side chains in the recognition of DNA by the Cys2His2-class zinc fingers in solution.

Project description:Hydrogen bonds are essential for protein structure and function, making experimental access to long-range interactions between amide protons and heteroatoms invaluable. Here we show that measuring distance restraints involving backbone hydrogen atoms and carbonyl- or α-carbons enables the identification of secondary structure elements based on hydrogen bonds, provides long-range contacts and validates spectral assignments. To this end, we apply specifically tailored, proton-detected 3D (H)NCOH and (H)NCAH experiments under fast magic angle spinning (MAS) conditions to microcrystalline samples of SH3 and GB1. We observe through-space, semi-quantitative correlations between protein backbone carbon atoms and multiple amide protons, enabling us to determine hydrogen bonding patterns and thus to identify β-sheet topologies and α-helices in proteins. Our approach shows the value of fast MAS and suggests new routes in probing both secondary structure and the role of functionally-relevant protons in all targets of solid-state MAS NMR.

Project description:Protein structures are stabilized by several types of chemical interactions between amino acids, which can compete with each other. This is the case of chalcogen and hydrogen bonds formed by the thiol group of cysteine, which can form three hydrogen bonds with one hydrogen acceptor and two hydrogen donors and a chalcogen bond with a nucleophile along the extension of the CS bond. A survey of the Protein Data Bank shows that hydrogen bonds are about 40-50 more common than chalcogen bonds, suggesting that they are stronger and, consequently, prevail, though not always. It is also observed that frequently a thiol group that forms a chalcogen bond is also involved, as a hydrogen donor, in a hydrogen bond.

Project description:Hydrogen-bonding interactions have been explored in catalysis, enabling complex chemical reactions. Recently, enantioselective nucleophilic fluorination with metal alkali fluoride has been accomplished with BINAM-derived bisurea catalysts, presenting up to four NH hydrogen-bond donors (HBDs) for fluoride. These catalysts bring insoluble CsF and KF into solution, control fluoride nucleophilicity, and provide a chiral microenvironment for enantioselective fluoride delivery to the electrophile. These attributes encouraged a 1H/19F NMR study to gain information on hydrogen-bonding networks with fluoride in solution, as well as how these arrangements impact the efficiency of catalytic nucleophilic fluorination. Herein, NMR experiments enabled the determination of the number and magnitude of HB contacts to fluoride for thirteen bisurea catalysts. These data supplemented by diagnostic coupling constants 1hJNH···F- give insight into how multiple H bonds to fluoride influence reaction performance. In dichloromethane (DCM-d2), nonalkylated BINAM-derived bisurea catalyst engages two of its four NH groups in hydrogen bonding with fluoride, an arrangement that allows effective phase-transfer capability but low control over enantioselectivity for fluoride delivery. The more efficient N-alkylated BINAM-derived bisurea catalysts undergo urea isomerization upon fluoride binding and form dynamically rigid trifurcated hydrogen-bonded fluoride complexes that are structurally similar to their conformation in the solid state. Insight into how the countercation influences fluoride complexation is provided based on NMR data characterizing the species formed in DCM-d2 when reacting a bisurea catalyst with tetra-n-butylammonium fluoride (TBAF) or CsF. Structure-activity analysis reveals that the three hydrogen-bond contacts with fluoride are not equal in terms of their contribution to catalyst efficacy, suggesting that tuning individual electronic environment is a viable approach to control phase-transfer ability and enantioselectivity.

Project description:Hydrogen bonding plays a crucial role in Brønsted acid catalysis. However, the hydrogen bond properties responsible for the activation of the substrate are still under debate. Here, we report an in depth study of the properties and geometries of the hydrogen bonds in (R)-TRIP imine complexes (TRIP: 3,3'-Bis(2,4,6-triisopropylphenyl)-1,1'-binaphthyl-2,2'-diylhydrogen phosphate). From NMR spectroscopic investigations 1H and 15N chemical shifts, a Steiner-Limbach correlation, a deuterium isotope effect as well as quantitative values of 1JNH,2hJPH and 3hJPN were used to determine atomic distances (rOH, rNH, rNO) and geometry information. Calculations at SCS-MP2/CBS//TPSS-D3/def2-SVP-level of theory provided potential surfaces, atomic distances and angles. In addition, scalar coupling constants were computed at TPSS-D3/IGLO-III. The combined experimental and theoretical data reveal mainly ion pair complexes providing strong hydrogen bonds with an asymmetric single well potential. The geometries of the hydrogen bonds are not affected by varying the steric or electronic properties of the aromatic imines. Hence, the strong hydrogen bond reduces the degree of freedom of the substrate and acts as a structural anchor in the (R)-TRIP imine complex.

Project description:RNA is a polymer with pivotal functions in many biological processes. RNA structure determination is thus a vital step toward understanding its function. The secondary structure of RNA is stabilized by hydrogen bonds formed between nucleotide basepairs, and it defines the positions and shapes of functional stem-loops, internal loops, bulges, and other functional and structural elements. In this work, we present a methodology for studying large intact RNA biomolecules using homonuclear 15N solid-state NMR spectroscopy. We show that proton-driven spin-diffusion experiments with long mixing times, up to 16 s, improved by the incorporation of multiple rotor-synchronous 1H inversion pulses (termed radio-frequency dipolar recoupling pulses), reveal key hydrogen-bond contacts. In the full-length RNA isolated from MS2 phage, we observed strong and dominant contributions of guanine-cytosine Watson-Crick basepairs, and beyond these common interactions, we observe a significant contribution of the guanine-uracil wobble basepairs. Moreover, we can differentiate basepaired and non-basepaired nitrogen atoms. Using the improved technique facilitates characterization of hydrogen-bond types in intact large-scale RNA using solid-state NMR. It can be highly useful to guide secondary structure prediction techniques and possibly structure determination methods.

Project description:In order to explore how specific atom-to-atom replacements change the electrostatic potentials on 1,3,4-chalcogenadiazole derivatives, and to deliberately alter the balance between intermolecular interactions, four target molecules were synthesized and characterized. DFT calculations indicated that the atom-to-atom substitution of Br with I, and S with Se enhanced the σ-hole potentials, thus increasing the structure directing ability of halogen bonds and chalcogen bonds as compared to intermolecular hydrogen bonding. The delicate balance between these intermolecular forces was further underlined by the formation of two polymorphs of 5-(4-iodophenyl)-1,3,4-thiadiazol-2-amine; Form I displayed all three interactions while Form II only showed hydrogen and chalcogen bonding. The results emphasize that the deliberate alterations of the electrostatic potential on polarizable atoms can cause specific and deliberate changes to the main synthons and subsequent assemblies in the structures of this family of compounds.