Trityl-derivatized carbohydrates immobilized on a polystyrene microplate

Carbohydrate biosensors, including carbohydrate arrays, are attracting increased attention for the comprehensive and high-throughput investigation of protein-carbohydrate interactions. Here, we describe an effective approach to fabricating a robust microplate-based carbohydrate array capable of probing protein binding and screening for inhibitors in a high-throughout manner. This approach involves the derivatization of carbohydrates with a trityl group through an alkyl linker and the immobilization of the trityl-derivatized carbohydrates (mannose and maltose) onto microplates noncovalently to construct carbohydrate arrays. The trityl carbohydrate derivative has very good immobilization efficiency for polystyrene microplates and strong resistance to aqueous washing. The carbohydrate arrays can probe the interactions with the lectin Concanavalin A and screen this protein for the well-known inhibitors methyl α-d-mannopyranoside and methyl α-d-glucopyranoside in a high-throughput manner. The method described in this paper represents a convenient way of fabricating robust noncovalent carbohydrate arrays on microplates and offers a convenient platform for high-throughput drug screening.     

Monitoring enzyme catalysis in the multimeric state: Direct observation of Arthrobacter 4-hydroxybenzoyl-coenzyme A thioesterase catalytic complexes using time-resolved electrospray ionization mass spectrometry

The ability to examine real-time reaction kinetics for multimeric enzymes in their native state may offer unique insights into understanding the catalytic mechanism and its interplay with three-dimensional structure. In this study, we have used a time-resolved electrospray mass spectrometry approach to probe the kinetic mechanism of 4-hydroxybenzoyl-coenzyme A (4-HBA-CoA) thioesterase from Arthrobacter sp. strain SU in the millisecond time domain. Intact tetrameric complexes of 4-HBA-CoA thioesterase with up to four natural substrate (4-HBA-CoA) molecules bound were detected at times as early as 6 ms using an online rapid-mixing device directly coupled to an electrospray ionization time-of-flight mass spectrometer. Species corresponding to the formation of a folded tetramer of the thioesterase at charge states 16+, 17+, 18+, and 19+ around m/z 3800 were observed and assigned as individual tetramers of thioesterase and noncovalent complexes of the tetramers with up to four substrate and/or product molecules. Real-time evaluation of the reaction kinetics was accomplished by monitoring change in peak intensity corresponding to the substrate and product complexes of the tetrameric protein. The mass spectral data suggest that product 4-HBA is released from the active site of the enzyme prior to the release of product CoA following catalytic turnover. This study demonstrates the utility of this technique to provide additional molecular details for an understanding of the individual enzyme states during the thioesterase catalysis and ability to observe real-time interactions between enzyme and substrates and/or products in the millisecond time range.     

Discovery of PI-1840, a Novel Noncovalent and Rapidly Reversible Proteasome Inhibitor with Anti-tumor Activity

The proteasome inhibitor bortezomib is effective in hematologic malignancies such as multiple myeloma but has little activity against solid tumors, acts covalently, and is associated with undesired side effects. Therefore, noncovalent inhibitors that are less toxic and more effective against solid tumors are desirable. Structure activity relationship studies led to the discovery of PI-1840, a potent and selective inhibitor for chymotrypsin-like (CT-L) (IC₅₀ value = 27 ± 0.14 nm) over trypsin-like and peptidylglutamyl peptide hydrolyzing (IC₅₀ values >100 μm) activities of the proteasome. Furthermore, PI-1840 is over 100-fold more selective for the constitutive proteasome over the immunoproteasome. Mass spectrometry and dialysis studies demonstrate that PI-1840 is a noncovalent and rapidly reversible CT-L inhibitor. In intact cancer cells, PI-1840 inhibits CT-L activity, induces the accumulation of proteasome substrates p27, Bax, and IκB-α, inhibits survival pathways and viability, and induces apoptosis. Furthermore, PI-1840 sensitizes human cancer cells to the mdm2/p53 disruptor, nutlin, and to the pan-Bcl-2 antagonist BH3-M6. Finally, in vivo, PI-1840 but not bortezomib suppresses the growth in nude mice of human breast tumor xenografts. These results warrant further evaluation of a noncovalent and rapidly reversible proteasome inhibitor as potential anticancer agents against solid tumors.     

Expansion of the σ-hole concept

The term “σ-hole” originally referred to the electron-deficient outer lobe of a half-filled p (or nearly p) orbital involved in forming a covalent bond. If the electron deficiency is sufficient, there can result a region of positive electrostatic potential which can interact attractively (noncovalently) with negative sites on other molecules (σ-hole bonding). The interaction is highly directional, along the extension of the covalent bond giving rise to the σ-hole. σ-Hole bonding has been observed, experimentally and computationally, for many covalently-bonded atoms of Groups V–VII. The positive character of the σ-hole increases in going from the lighter to the heavier (more polarizable) atoms within a Group, and as the remainder of the molecule becomes more electron-withdrawing. In this paper, we show computationally that significantly positive σ-holes, and subsequent noncovalent interactions, can also occur for atoms of Group IV. This observation, together with analogous ones for the molecules (H₃C)₂SO, (H₃C)₂SO₂ and Cl₃PO, demonstrates a need to expand the interpretation of the origins of σ-holes: (1) While the bonding orbital does require considerable p character, in view of the well-established highly directional nature of σ-hole bonding, a sizeable s contribution is not precluded. (2) It is possible for the bonding orbital to be doubly-occupied and forming a coordinate covalent bond. Figure Two views of the calculated electrostatic potential on the 0.001 au molecular surface of SiCl₄. Color ranges, in kcal/mole, are: purple, negative; blue, between 0 and 8; green, between 8 and 11; yellow, between 11 and 18; red, more positive than 18. The top view shows three of the four chlorines. In the center is the σ-hole due to the fourth Cl−Si bond, its most positive portion (red) being on the extension of that bond. In the bottom view are visible two of the σ-holes on the silicon. In both views can be seen the σ-holes on the chlorines, on the extensions of the Si−Cl bonds; their most positive portions are green     

Modeling the noncovalent interactions at the metabolite binding site in purine riboswitches

We present gas phase quantum chemical studies on the metabolite binding interactions in two important purine riboswitches, the adenine and guanine riboswitches, at the B3LYP/6-31G(d,p) level of theory. In order to gain insights into the strucutral basis of their discriminative abilities of regulating gene expression, the structural properties and binding energies for the gas phase optimized geometries of the metabolite bound binding pocket are analyzed and compared with their respective crystal geometries. Kitaura-Morokuma analysis has been carried out to calculate and decompose the interaction energy into various components. NBO and AIM analysis has been carried out to understand the strength and nature of binding of the individual aptamer bases with their respective purine metabolites. The Y74 base, U in case of adenine riboswitch and C in case of guanine riboswitch constitutes the only differentiating element between the two binding pockets. As expected, with W:W cis G:C74 interaction contributing more than 50% of the total binding energy, the interaction energy for metabolite binding as calculated for guanine (-46.43 Kcal/mol) is nearly double compared to the corresponding value for that of adenine (-24.73 Kcal/mol) in the crystal context. Variations in the optimized geometries for different models and comparison of relative contribution to metabolite binding involving four conserved bases reveal the possible role of U47:U51 W:H trans pair in the conformational transition of the riboswitch from the metabolite free to metabolite bound state. Our results are also indicative of significant contributions from stacking and magnesium ion interactions toward cooperativity effects in metabolite recognition.     

Adamantane-platinum conjugate hosted in β-cyclodextrin: enhancing transport and cytotoxicity by noncovalent modification

This work reports the synthesis of a complex of a carboplatin analog having tethered adamantane that is encapsulated in the hydrophobic cavity of β-cyclodextrin (βCD) and its cytotoxic activity towards human neuroblastoma cells (SK-N-SH). We found that this inclusion complex of βCD adamantane carboplatin analog exhibited higher cytotoxicity towards SK-N-SH cells than carboplatin itself, and the inclusion complex exhibited a higher binding to plasmid pBR322 deoxyribonucleic acid (DNA) than carboplatin. Confocal fluorescence images of SK-N-SH cells treated with βCD having an attached fluorescein isothiocyanate (FITC)-tag exhibited fluorescence in the vicinity of the nuclei of the neuroblastoma cells. Direct measurements of the platinum content in SK-N-SH cells using inductively coupled plasma mass spectrometry (ICP-MS) indicated that the uptake rate of carboplatin was about 4 times higher than βCD adamantane carboplatin analog inclusion complex. When compared to carboplatin, we believe that the higher cytotoxicity of inclusion complex towards SK-N-SH cells is due to its higher DNA binding ability as compared to carboplatin, and more efficient delivery to the nucleus of the cell. This work suggests that the advantage of deliberate noncovalent modification with βCD through host-guest chemistry may also be broadly applicable to other anticancer agents as well.     

Specific type of interactions in the quaternary system of Cu(II), adenosine 5'-triphosphate, 1,11-diamino-4,8-diazaundecane and uridine

Complexation reactions in the quaternary system Cu/ATP/3,3,3-tet/Urd have been studied. The stability constants of the complexes of the Cu(ATP)(3,3,3-tet)H(x)(Urd) type have been determined by computer analysis of the potentiometric titration. On the basis of the results of spectroscopic as well as equilibrium studies, the mode of interactions has been proposed. Metal ions coordinate phosphate groups of ATP and nitrogen atoms of polyamine. It has been established that in the conditions of the complex Cu(ATP)(3,3,3-tet) formation, uridine introduced into the Cu(II)/ATP/3,3,3-tet ternary system is involved in hydrogen bonding with the endocyclic nitrogen atoms N(1) and N(7) of the ATP purine ring and formation of the adduct Cu(ATP)(3,3,3-tet)H(Urd) is observed. Introduction of metal ions into the system changes substantially the mode of interactions between complementary base pairs relative to that proposed in the Watson and Crick model.     

An innovative strategy for sulfopeptides analysis using MALDI-TOF MS reflectron positive ion mode

Sulfation of tyrosine residues is a key posttranslational modification in the regulation of various cellular processes. As such, the detection and localization of tyrosine sulfation is an essential step toward the elucidation of the physiological and pathological roles of this process. Despite substantial advances, intact sulfated peptides are still difficult to detect by MALDI-MS due to the extreme lability of the sulfo-moiety. The present report demonstrates for the first time how intact sulfated peptides can be directly and specifically detected by MALDI-MS in positive reflectron mode by using pyrenemethylguanidine (pmg) as a noncovalent derivatizing agent and an ionization enhancer. This new method allows the determination of the degree of sulfation of sulfopeptides pure or in mixtures. Moreover, the observation of specific peaks in the mass spectra enables a rapid and unambiguous discrimination between phospho- and sulfopeptides.     

Coordination geometry isomerism induced by N-H?Cl, C-H?Cl, C-H?N, C-H?π and π?π supramolecular interactions in mercury(II) complexes with tripyridylimidazole chelating ligands

Reaction of HgCl₂ with trans-(±)2-(2,5-di(pyridin-2-yl)-4,5-dihydro-1H-imidazol-4-yl)pyridine (L1) and cis-(±)-(phenyl(2,4,5-tri(pyridin-2-yl)-4,5-dihydroimidazol-1- yl)methanone (L2) gives mononuclear complexes, 1 and 2. In these complexes L1 and L2 behave as tridentate and bidentate chelating ligands, giving distorted trigonal bipyramidal and tetrahedral coordination geometries, respectively. X-ray diffraction studies revealed a series of N-H?Cl, C-H?Cl, C-H?N and C-H?π interactions in 1 giving a 3D network, and N-H?Cl, C-H?Cl, C-H?π and π?π interactions in 2 giving a 2D network in the crystal lattice. Since both ligands should have a similar binding capacity to the mercury ions, the variations observed for coordination number and geometry should be a consequence of supramolecular stabilizing effects.     

质粒pUC18 DNA的螺线管型超螺旋结构

理论上,游离的超螺旋DNA可以采取两种结构形式：互缠式超螺旋和螺线管型超螺旋。前者早已被透射电子显微镜和原子力显微术的研究所证实,而后者却仍然缺乏足够的证据。使用温和的清亮裂解液法,从DNA拓扑酶野生型大肠杆菌HB101细胞抽提质粒pUC18 DNA。经CsCl-EB平衡密度梯度超离心分离获得超螺旋pUC18 DNA和松弛型pUC18 DNA(DNA Ⅱ）。纯化DNA分别用疏水必不容放亲水性溶剂系统的细胞色素单分子层展开技术制备电子显微镜标本。观察结果显示：在疏水性的甲酰胺－水展开系统中,DNA采取通常的互缠式结构;在含有1.5mmol/L醋酸铵的水介质中制备的超螺旋DNA标本,DNA采取线圈型结构,测得pUC18 DNA（单体）分子这种结构的外直径约为43.8nm,内直径约为2nm。在相同亲水介质中松弛型pUC18 DNA采取典型的螺线管型结构,其单体平均外直径约为53.1nm,内直径约为17.2nm。表明：在疏水介质中超螺旋DNA趋向于采取互缠式结构,而在亲水介质中DNA则要取螺线管型结构。DNA链之间可能存在非共价相互作用以维持这种结构。螺线管型结构可能是水溶液中的超螺旋DNA分子普遍的存在形式。