Preparation of a new doubly tethered chiral stationary phase based on (+)-(18-crown-6)-2,3,11,12-tetracarboxylic acid and its application

A new doubly tethered chiral stationary phase (CSP) based on (+)-(18-crown-6)-2,3,11,12-tetracarboxylic acid was prepared by attaching the second tethering group to silica gel through a carbon atom of the first tethering group of the corresponding singly tethered CSP, which was previously developed in our laboratory. The new doubly tethered CSP was applied successfully to the resolution of various racemic alpha-amino acids, amines and amino alcohols containing a primary amino group. In most cases, the chiral recognition efficiency of the new doubly tethered CSP was superior to that of the corresponding singly tethered one in the resolution of alpha-amino acids, amines and amino alcohols. In the resolution of some racemic primary amino compounds, the new doubly tethered and the corresponding singly tethered CSPs were complementary with each other. The chiral resolution behaviors on the new doubly tethered CSP were examined with the variation of the type and content of organic and acidic modifiers in aqueous mobile phase and the column temperature. The chiral resolution behaviors on the new doubly tethered CSP were generally quite similar to those on the corresponding singly tethered CSP. The stability of the new doubly tethered CSP was greater than that of the corresponding singly tethered CSP.     

典型蛋白质折叠中阳离子-π相互作用的特异性

蛋白质中的阳离子-π相互作用是带正电荷的氨基酸(Lys、Arg)和芳香族氨基酸(Phe、Tyr、Trp)之间的一种作用力.对α/β类蛋白中两种典型折叠类型(单绕和双绕)的研究表明:(1)单绕结构中阳离子-π相互作用的分布密度大约是双绕结构中的2.6倍;(2)在单绕结构中,样本所含氨基酸残基数量与样本中阳离子-π的数量有明显的相关性,在双绕结构中没有发现类似的相关性;(3)Lys、Arg与Tyr在单绕中比在双绕中更容易形成阳离子-π相互作用;(4)Arg-Tyr组合在单绕中出现的几率较大,Arg-Phe组合在双绕中出现的几率较大;(5)阳离子-π相互作用在65%的单绕样本中形成阵列或分布在结构的首尾间.     

Gas-phase zwitterion stabilization by a metal dication

Although solution-phase amino acids normally exist as zwitterions, this is not the case under gas-phase conditions, where the canonical structure is favored. Complexation to a metal ion can increase the relative zwitterion stability, but even then, the zwitterion (salt bridge, SB) form is not the most stable form of such singly charged complexes except for basic amino acids. Computation suggests enhanced SB stability for doubly charged complexes of weakly binding metal ions, but this has not hitherto been verified experimentally. Using infrared-spectroscopic characterization of the ion structure by multiple-photon infrared dissociation by the FELIX free electron laser, the Ba2+ complex of Trp has been shown to have the SB structure, and the presence of the nonzwitterionic (charge-solvated) form has been ruled out. The principal spectroscopic signatures of the SB structure are the appearance of the antisymmetric CO stretch of the carboxylate group at 1600 cm-1 and the umbrella mode of NH3 at 1400 cm-1.     

Assigning vibrational spectra of ferryl-oxo intermediates of cytochrome C oxidase by periodic orbits and molecular dynamics

Complexity is inherent in biological molecules not only because of the large number of atoms but also because of their nonlinear interactions responsible for chaotic behaviours, localized motions, and bifurcation phenomena. Thus, versatile spectroscopic techniques have been invented to achieve temporal and spatial resolution to minimize the uncertainties in assigning the spectra of complex molecules. Can we associate spectral lines to specific chemical bonds or species in a large molecule? Can energy stay localized in a bond for a substantial period of time to leave its spectroscopic signature? These longstanding problems are investigated by studying the resonance Raman spectra of ferryl-oxo intermediates of cytochrome c oxidase. The difference spectra of isotopically substituted ferryl oxygen ((16)O minus (18)O) in the cytochrome c oxidase recorded in several laboratories show one or two prominent positive peaks which have not been completely elucidated yet. By applying the hierarchical methods of nonlinear mechanics, and particularly the study of periodic orbits in the active site of the enzyme, in conjunction with molecular dynamics calculations of larger systems which include the embraced active site by the protein and selected protonated/deprotonated conformations of amino acids, we translate the spectral lines to molecular motions. It is demonstrated that for the active site stable periodic orbits exist for a substantial energy range. Families of periodic orbits which are associated with the vibrations of Fe(IV)=O bond mark the regions of phase space where nearby trajectories remain localized, as well as assign the spectral bands of the active site in the protein matrix. We demonstrate that proton movement adjacent to active site, which occurs during the P --> F transition, can lead to significant perturbations of the Fe(IV)=O isotopic difference vibrational spectra in cytochrome c oxidase, without a change in oxidation state of the metal sites. This finding links spectroscopic characteristics to protonation events occurring during enzymatic turnover.     

新型室温熔盐二(三氟甲基磺酸酰)亚胺锂-乙酰胺体系的谱学研究

从分析二(三氟甲基磺酸酰)亚胺锂(LiTFSI)与乙酰胺形成熔盐的作用机制出发,通过红外和拉曼光谱的谱学分析并应用非局部密度泛函方法进行量化计算来对二者的相互作用进行了讨论.发现乙酰胺通过Li—O键与LiTFSI中Li+配位而破坏了LiTFSI的离子键,形成很大的配位阳离子,且正电荷被屏蔽在乙酰胺分子中;而TFSI-离子中电荷的部分离域导致电荷被终端—CF3基团屏蔽在整个分子中,这样两个大的阴阳离子间的库伦作用很弱;同时Li—O配位也导致乙酰胺分子间的氢键断裂,因而室温下体系以液体状态稳定存在.     

Computational design of protein–ligand binding: Modifying the specificity of asparaginyl‐tRNA synthetase

A method for computational design of protein–ligand interactions is implemented and tested on the asparaginyl‐ and aspartyl‐tRNA synthetase enzymes (AsnRS, AspRS). The substrate specificity of these enzymes is crucial for the accurate translation of the genetic code. The method relies on a molecular mechanics energy function and a simple, continuum electrostatic, implicit solvent model. As test calculations, we first compute AspRS‐substrate binding free energy changes due to nine point mutations, for which experimental data are available; we also perform large‐scale redesign of the entire active site of each enzyme (40 amino acids) and compare to experimental sequences. We then apply the method to engineer an increased binding of aspartyl‐adenylate (AspAMP) into AsnRS. Mutants are obtained using several directed evolution protocols, where four or five amino acid positions in the active site are randomized. Promising mutants are subjected to molecular dynamics simulations; Poisson‐Boltzmann calculations provide an estimate of the corresponding, AspAMP, binding free energy changes, relative to the native AsnRS. Several of the mutants are predicted to have an inverted binding specificity, preferring to bind AspAMP rather than the natural substrate, AsnAMP. The computed binding affinities are significantly weaker than the native, AsnRS:AsnAMP affinity, and in most cases, the active site structure is significantly changed, compared to the native complex. This almost certainly precludes catalytic activity. One of the designed sequences has a higher affinity and more native‐like structure and may represent a valid candidate for Asp activity. © 2009 Wiley Periodicals, Inc. J Comput Chem, 2010     

PIGMENT COMPLEXES OF LIGHT-HARVESTING CHLOROPHYLL a/b BINDING PROTEIN ARE STABILIZED BY A SEGMENT IN THE CARBOXYTERMINAL HYDROPHILIC DOMAIN OF THE PROTEIN*

In order to identify segments of light-harvesting chlorophyll a/6-binding protein (LHCP) that are important for pigment binding, we have tested various LHCP mutants regarding their ability to form stable pigment-protein complexes in an in vitro reconstitution assay. Deletion of 10 C-terminal amino acids in the LHCP precursor, pLHCP, did not significantly affect pigment binding, whereas deletion of one additional amino acid, a tryptophan, completely abolished the formation of stable pigment-protein complexes. This tryptophan, however, can be exchanged with other amino acids in full-length pLHCP without noticeably altering the stability or spectroscopic properties of pigment complexes made with these mutants. Thus, the tryptophan residue is not likely to be involved in a highly specific interaction stabilizing the complex. A double mutant of LHCP lacking 66 N-terminal and 6 C-terminal amino acids still forms pigmented complexes that are virtually identical to those formed with the full-length protein concerning their pigment composition and spectroscopic properties. We conclude that about 30% of the polypeptide chain in LHCP is not involved in pigment binding.     

The nature of collision-induced dissociation processes of doubly protonated peptides: comparative study for the future use of matrix-assisted laser desorption/ionization on a hybrid quadrupole time-of-flight mass spectrometer in proteomics.

Comparative MS/MS studies of singly and doubly charged electrospray ionization (ESI) and matrix-assisted laser desorption/ionization (MALDI) precursor peptide ions are described. The spectra from these experiments have been evaluated with particular emphasis on the data quality for subsequent data processing and protein/amino acid sequence identification. It is shown that, once peptide ions are formed by ESI or MALDI, their charge state, as well as the collision energy, is the main parameter determining the quality of collision-induced dissociation (CID) MS/MS fragmentation spectra of a given peptide. CID-MS/MS spectra of singly charged peptides obtained on a hybrid quadrupole orthogonal time-of-flight mass spectrometer resemble very closely spectra obtained by matrix-assisted laser desorption/ionization post-source decay time-of-flight mass spectrometry (MALDI-PSD-TOFMS). On the other hand, comparison of CID-MS/MS spectra of either singly or doubly charged ion species shows no dependence on whether ions have been formed by ESI or MALDI. This observation confirms that, at the time of precursor ion selection, further mass analysis is effectively decoupled from the desorption/ionization event. Since MALDI ions are predominantly formed as singly charged species and ESI ions as doubly charged, the associated difference in the spectral quality of MS/MS spectra as described here imposes direct consequences on data processing, database searching using ion fragmentation data, and de novo sequencing when ionization techniques are changed.     

Blue shift of the isolated CD stretching band of CH2DOH in water induced by changes in the hydrogen-bonding pattern

The wavenumber shift in the CD stretching (ν(CD)) band of the monodeuterated methanol (CH(2)DOH) has been monitored in water-methanol mixtures. For the pure liquid, two dominant bands are observed at 2148 and 2176 cm(-1) in the ν(CD) region. The matrix isolation technique and spectral simulation based on quantum chemical calculations have revealed that these two bands are categorized into the C(1) mode and originate from methanol molecules participating in different hydrogen(H)-bonding patterns. The simulation results for methanol clusters have suggested that the 2148 cm(-1) band is concerned with the end-donor species in the H-bonding network. The relative intensity of the band near 2148 cm(-1) decreases with increasing water concentration, indicating that the population of the end-donor species decreases by the addition of water. This spectral change causes the blue shift in the mean center of the ν(CD) band of CH(2)DOH in water.     

Influences of peptide side chains on the metal ion binding site in metal ion-cationized peptides: Participation of aromatic rings in metal chelation

Aromatic side chains on amino acids influence the fragmentations of cationic complexes of doubly charged metal ions and singly deprotonated peptides. The metal ion interacts with an aromatic side chain and binds to adjacent amide nitrogens. When fragmentation occurs, this bonding leads to the formation of abundant metal-containing a-type ions by reactions that occur at the sites of amino acids that contain the aromatic side chain. Furthermore, formation of metal-containing immonium ions of the amino acids that contain the aromatic side chain also are formed. The abundant a-type ions may be useful in interpretation strategies in which it is necessary to locate in a peptide the position of an amino acid that bears an aromatic side chain.     

The effect of charge state and the localization of charge on the collision-induced dissociation of peptide ions

The effect that charge state has on the collision-induced dissociation (CID) of peptide ions is examined in detail for several representative peptides under high-energy collision conditions. The CID spectra of singly and doubly charged precursor ions (generated by fast-atom bombardment and electrospray ionization, respectively) are compared for several peptides with similar primary structure. It is shown that for peptides that contain highly basic amino acids, the dissociation of doubly charged ions is strongly influenced by the position of these residues within the peptide and the general observations reported concerning the dissociation of singly charged ions can be extended to precursors with higher charge states. Based on the dissociation behavior of the doubly charged ions of these peptides, it is demonstrated that two charges can reside in close proximity in the precursor ions, overcoming possible repulsion effects, when favored by a high concentration of basic sites. In addition)’ this work illustrates that in the case of doubly charged ions..the charge state of some fragment ions can be determined directly from the mass-to-charge ratio assignments of the CID spectrum.     

Far infrared spectroscopy on hemoproteins: A model compound study from 1800–100 cm

Infrared spectroscopy measurements on different hemoproteins and models of the active side have been completed for the spectral range from 1800 to 100 cm⁻¹ giving an overview on the contributions expected in the low frequency range. Little is known of the low frequency contribution of proteins in infrared. In order to detect the contributions of heme centers and protein moiety, a systematic study of the infrared spectroscopic properties of the porphyrin ring, the ferric porphyrines with different ligands (hemine and hematine), a heme with 11 amino acids (microperoxidase-11), cytochrome c and cytochrome c oxidase are compared at different pD values and an overview on the relative contributions of hemes, their ligands and the protein site can be provided in the low frequency region. Beside the well know amide I and II modes, the low frequency range is found to be dominated by the amide IV and VI mode around 530/580 cm⁻¹ for cytochrome c and cytochrome c oxidase, as well as further proteins like ferrodoxin. Below 300 cm⁻¹ amide VII modes, doming modes of the heme site and hydrogen-bonding signatures overlap to a broad peak with covering 100–250 cm⁻¹. As clear markers for the iron ligands, bands can be depicted at 388/378 cm⁻¹ (FeN, histidine ligand) and 345 cm⁻¹ FeCl. Furthermore the ring vibration of the protonated histidine is determined at 623 cm⁻¹.     

Conformational choice and selectivity in singly and multiply hydrated monosaccharides in the gas phase

Factors governing hydration, regioselectivity and conformational choice in hydrated carbohydrates have been examined by determining and reviewing the structures of a systematically varied set of singly and multiply hydrated monosaccharide complexes in the gas phase. This has been achieved through a combination of experiments, including infrared ion-depletion spectroscopy conducted in a supersonic jet expansion, and computation through molecular mechanics, density functional theory (DFT) and ab initio calculations. New spectroscopic and/or computational results obtained for the singly hydrated complexes of phenyl beta-D-mannopyranoside (beta-D-PhMan), methyl alpha-D-gluco- and alpha-D-galactopyranoside (alpha-D-MeGlc and alpha-D-MeGal), when coupled with those reported earlier for the singly hydrated complexes of alpha-D-PhMan, beta-D-PhGlc and beta-D-PhGal, have created a comprehensive data set, which reveals a systematic pattern of conformational preference and binding site selectivity, driven by the provision of optimal, co-operative hydrogen-bonded networks in the hydrated sugars. Their control of conformational choice and structure has been further revealed through spectroscopic and/or computational investigations of a series of multiply hydrated complexes; they include beta-D-PhMan.(H2O)2,3, which has an exocyclic hydroxymethyl group, and the doubly hydrated complex of phenyl alpha-L-fucopyranoside, alpha-L-PhFuc.(H2O)2, which does not. Despite the very large number of potential structures and binding sites, the choice is highly selective with binding invariably "focussed" around the hydroxymethyl group (when present). In beta-D-PhMan.(H2O)2,3, the bound water molecules are located exclusively on its polar face and their orientation is dictated by the (perturbed) conformation of the carbohydrate to which they are attached. The possible operation of similar rules governing the structures of hydrogen-bonded protein-carbohydrate complexes is proposed.     

Rational design to block amino acid editing of a tRNA synthetase

Investigations in chemical biology have focused on the synthesis of custom-designed proteins with site-specific incorporation of novel amino acids. Their success requires stable production of misacylated tRNAs. Utilization of aminoacyl-tRNA synthetases has been hindered because of enzyme molecular recognition mechanisms that ensure high fidelity of protein synthesis. Leucyl-tRNA synthetase naturally misaminoacylates chemically diverse standard and nonstandard amino acids, but contains a separate amino acid editing active site to hydrolyze incorrectly mischarged tRNAs. In this work, a rational mutagenesis design to block enzyme editing is described and involves substitution of bulky amino acids into the amino acid binding pocket of the hydrolytic active site. These engineered enzymes stably misacylated isoleucine to tRNALeu. The use of these mutant leucyl-tRNA synthetases has the potential to produce pools of mischarged tRNAs that are linked to nonstandard amino acids for in vitro translation. In addition, since many of the leucyl-tRNA synthetases do not interact with or rely upon the tRNA anticodon for identity, these enzymes may offer an excellent scaffold for the development of orthogonal tRNA synthetase/tRNA pairs that can potentially be used to customize protein synthesis.     

Analysis of intact proteins on a chromatographic time scale by electron transfer dissociation tandem mass spectrometry

Direct analysis of intact proteins on a chromatographic time scale is demonstrated on a modified linear ion trap mass spectrometer using sequential ion/ion reactions, electron transfer and proton transfer, to dissociate the sample and to convert the resulting peptide fragments to a mixture of singly and doubly charged species. Proteins are converted to gas-phase, multiply-charged, positive ions by electrospray ionization and then allowed to react with fluoranthene radical anions. Electron transfer to the multiply charged protein promotes random fragmentation of amide bonds along the protein backbone. Multiply charged fragment ions are then deprotonated in a second ion/ion reaction with even-electron benzoate anions. M/z values for the resulting singly and doubly charged ions are used to read a sequence of 15-40 amino acids at both the N-terminus and the C-terminus of the protein. This information, along with the measured mass of the intact protein, are employed to identify known proteins and to detect the presence of post-translational modifications. In this study, we analyze intact proteins from the Escherchia coli 70S ribosomal protein complex and identify 46 of the 55 known unique components in a single, 90 min, on-line, chromatography experiment. Truncated versions of the above proteins along with several post-translational modifications are also detected.     

Fragmentation of Singly,Doubly, and Triply Charged Hydrogen Deficient Peptide Radical Cations in Infrared Multiphoton Dissociation and Electron Induced Dissociation

Gas phase fragmentation of hydrogen deficient peptide radical cations continues to be an active area of research. While collision induced dissociation (CID) of singly charged species is widely examined, dissociation channels of singly and multiply charged radical cations in infrared multiphoton dissociation (IRMPD) and electron induced dissociation (EID) have not been, so far, investigated. Here, we report on the gas phase dissociation of singly, doubly and triply charged hydrogen deficient peptide radicals, [M + nH]^(n+1)+· (n = 0, 1, 2), in MS³ IRMPD and EID and compare the observed fragmentation pathways to those obtained in MS³ CID. Backbone fragmentation in MS³ IRMPD and EID was highly dependent on the charge state of the radical precursor ions, whereas amino acid side chain cleavages were largely independent of the charge state selected for fragmentation. Cleavages at aromatic amino acids, either through side chain loss or backbone fragmentation, were significantly enhanced over other dissociation channels. For singly charged species, the MS³ IRMPD and EID spectra were mainly governed by radical-driven dissociation. Fragmentation of doubly and triply charged radical cations proceeded through both radical- and charge-driven processes, resulting in the formation of a wide range of backbone product ions including, a-, b-, c-, y-, x-, and z-type. While similarities existed between MS³ CID, IRMPD, and EID of the same species, several backbone product ions and side chain losses were unique for each activation method. Furthermore, dominant dissociation pathways in each spectrum were dependent on ion activation method, amino acid composition, and charge state selected for fragmentation.     

Tuning the Catalytic Activity of a Pincer Complex of Rhodium(I) by Supramolecular and Redox Stimuli

We report the rhodium(I) complex [Rh(CNC−NDI)(CO)]⁺, in which CNC−NDI refers to a pincer-CNC ligand decorated with a naphthalenediimide moiety. Due to the presence of the planar CNC ligand and the naphthalenediimide moiety, the electronic nature of the complex can be modulated by means of supramolecular and redox stimuli, respectively. The metal complex shows a strong π–π-stacking interaction with coronene. This interaction has an impact on the electron-richness of the metal, as demonstrated by the shifting of the ν(CO) stretching band to a lower frequency. The addition of tetrabutylammonium fluoride facilitates the sequential one- and two-electron reduction of the NDI moiety of the ligand, thus resulting in a situation in which the ligand can increase its electron-donor strength in two levels. The nature of the interaction with the fluoride anion was studied computationally. The catalytic activity of the [Rh(CNC−NDI)(CO)]⁺ complex was tested in the cycloisomerization of alkynoic acids, where it is observed that the activity of the catalyst can be modulated between four levels of activity, which correspond to i) the use of the unmodified catalyst, ii) catalyst+coronene, iii) catalyst+2 equivalents of fluoride, and iv) catalyst+5 equivalents of fluoride.     

纳升级电喷雾离子源-四极杆-飞行时间质谱中磷酸化肽的离子抑制作用

目前磷酸化蛋白质组学研究中的主要技术是蛋白质酶解产生的磷酸化肽的质谱检测。但是实际样品中的磷酸化肽(特别是多磷酸化肽)很难被检测到。其原因普遍认为是由于质谱检测时,非磷酸化肽抑制磷酸化肽。但也有认为非磷酸化肽对磷酸化肽没有抑制作用。另外磷酸化肽之间是否存在离子抑制作用还没有报道。本文采用相同氨基酸序列的标准磷酸化肽和非磷酸化肽,将其单独和混合进行质谱检测,通过对比混合前后磷酸化肽的信号强度,证明了非磷酸化肽对磷酸化肽有离子抑制作用;单磷酸化肽对二磷酸化肽有一定的抑制作用,但不太显著;单磷酸化肽对三磷酸化肽、二磷酸化肽对三磷酸化肽均有显著的离子抑制作用。该研究为今后单磷酸化肽和多磷酸化肽的分段富集和检测提供了有力的证明。