Conformation of NAD+ bound to yeast and horse liver alcohol dehydrogenase in solution. The use of the proton-proton transferred nuclear Overhauser enhancement

Changes in reduced viscosity of nuclear lysates from rat liver cells have been studied, in conditions of very low shear stress by the use of an oscillating viscometer, as a function of incubation time in alkaline (pH 12.5) and neutral (pH 8.0) solutions. In non-denaturing conditions, nuclear DNA showed a stepwise, time-dependent increase of reduced viscosity, which suggests that it behaves as a single hydrodynamic unit that progressively changes its radius and viscoelastic properties because of a very slow unfolding, through discrete successive transitions, from a highly superpacked structure toward a linear relaxed B-form fiber. Experimental conditions shown to reduce chromatin-DNA superpacking without changing DNA length (e.g. G₁ cycling versus G₀ non-cycling liver cells, or young versus old rat liver cells) dramatically increased the initial value of reduced viscosity and its time-dependent increment. Conversely, in denaturing conditions, reduced viscosity increased in the initial phase (probably because DNA unfolding prevails on DNA unwinding), then exhibited a plateau level (when unfolding balances unwinding), and subsequently decreased progressively to the value of sheared DNA (when unwinding becomes more rapid due to the progressive breakage of phosphodiester bridges in alkali). Experimental conditions known to induce DNA single- or double-strand breaks (i.e. the use of liver cells from rats treated with dimethylnitrosamine or 2-acetylaminofluorene, or of liver cells exposed to X-rays) caused in both neutral and alkaline solution an increment in the initial reduced viscosity and in the slope of its time-dependent increase, which may be related to a reduction of chromatin-DNA superpacking. Moreover, it became evident in denaturing conditions that a decrease of the maximum viscosity and of the time taken to reach it both related to a reduced DNA length. These viscoelastic properties are constantly correlated with independent DNA structural measurements on the same nuclear lysates, to discriminate the effect due to mere aggregation and disaggregation.     

NMR studies of novel inhibitors bound to farnesyl-protein transferase.

Farnesyl-protein transferase (FPTase) catalyzes the posttranslational farnesylation of the cysteine residue located in the carboxyl-terminal tetrapeptide of the Ras oncoprotein. Prenylation of this residue is essential for the membrane association and cell-transforming activities of ras. Inhibitors of FPTase have been demonstrated to inhibit ras-dependent cell transformation and thus represent a potential therapeutic strategy for the treatment of human cancers. The FPTase-bound conformation of a tetrapeptide inhibitor, CVWM, and a novel pseudopeptide inhibitor, L-739,787, have been determined by NMR spectroscopy. Distance constraints were derived from two-dimensional transferred nuclear Overhauser effect experiments. Ligand competition experiments identified the NOEs that originate from the active-site conformation. Structures were calculated with the combination of distance geometry and restrained energy minimization. Both peptide backbones are shown to adopt nonideal reverse-turn conformations most closely approximating a type III beta-turn. These results provide a basis for understanding the spatial arrangements necessary for inhibitor binding and selectivity and may aid in the design of therapeutic agents.     

Effects of substrate binding on the dynamics of RNase A: Molecular dynamics simulations of UpA bound and native RNase A

RNase A has been extensively used as a model protein in several biophysical and biochemical studies. Using the available structural and biochemical results, RNase A-UpA interaction has been computationally modeled at an atomic level. In this study, the molecular dynamics (MD) simulations of native and UpA bound RNase A have been carried out. The gross dynamical behavior and atomic fluctuations of the free and UpA bound RNase A have been characterized. Principal component analysis is carried out to identify the important modes of collective motion and to analyze the changes brought out in these modes of RNase A upon UpA binding. The hydrogen bonds are monitored to study the atomic details of RNase A-UpA interactions and RNase A-water interactions. Based on these analysis, the stability of the free and UpA bound RNase A are discussed. © 1997 John Wiley & Sons, Inc. Biopoly 42: 505–520, 1997     

A Small-Molecule Probe Induces a Conformation in HIV TAR RNA Capable of Binding Drug-Like Fragments

The HIV-1 transactivation response (TAR) element-Tat interaction is a potentially valuable target for treating HIV infection, but efforts to develop TAR-binding antiviral drugs have not yet yielded a successful candidate for clinical development. In this work, we describe a novel approach toward screening fragments against RNA that uses a chemical probe to target the Tat-binding region of TAR. This probe fulfills two critical roles in the screen: by locking the RNA into a conformation capable of binding other fragments, it simultaneously allows the identification of proximal binding fragments by ligand-based NMR. Using this approach, we have discovered six novel TAR-binding fragments, three of which were docked relative to the probe-RNA structure using experimental NMR restraints. The consistent orientations of functional groups in our data-driven docked structures and common electrostatic properties across all fragment leads reveal a surprising level of selectivity by our fragment-sized screening hits. These models further suggest linking strategies for the development of higher-affinity lead compounds for the inhibition of the TAR-Tat interaction.     

Three-dimensional structure of the mammalian tachykinin peptide neurokinin A bound to lipid micelles

The solution structure of NKA, a decapeptide of mammalian origin, has been characterized by CD spectropolarimetry and 2D proton nuclear magnetic resonance (2D 1H-NMR) spectroscopy in both aqueous and membrane mimetic solvents. Unambiguous NMR assignments of protons have been made with the aid of correlation spectroscopy (DQF-COSY and TOCSY) experiments and nuclear Overhauser effect spectroscopy (NOESY and ROESY) experiments. The distance constraints obtained from the NMR data have been utilized to generate a family of structures, which have been refined using restrained energy minimization and dynamics. These data show that in water NKA prefers to be in an extended chain conformation whereas a helical conformation is induced in the central core and the C-terminal region (D4-M10) of the peptide in the presence of perdeuterated dodecylphosphocholine (DPC) micelles, a membrane model system. Though less defined the N-terminus also displays some degree of order and a possible turn structure. The conformation adopted by NKA in the presence of DPC micelles represents a structural motif typical of neurokinin-2 selective agonists and is similar to that reported for eledoisin in hydrophobic environment.     

RNase A oligomerization through 3D domain swapping is favoured by a residue located far from the swapping domains

Bovine pancreatic ribonuclease A forms 3D domain-swapped oligomers by lyophilization from 40% acetic acid solutions or if subjected to various thermally-induced denaturation procedures.Considering that the intrinsic swapping propensity of bovine seminal RNase, the only member of the pancreatic-type RNase super-family that is dimeric in nature, is decreased from 70 to 30% if Arg80 is substituted by Ser (the corresponding residue in native RNase A), we introduced the opposite mutation in position 80 of the pancreatic enzyme. Our aim was to detect if the RNase A tendency to aggregate through domain swapping could increase.Aggregation of the S80R-RNase A mutant was induced either through the ‘classic’ acetic acid lyophilization, or through a thermally-induced method. The results indicate that the S80R mutant aggregates to a higher extent than the native protein, and that the increase occurs especially through N-terminal swapping.Additional investigations on the dimeric and multimeric species formed indicate that the S80R mutation increases their stability against regression to monomer, and does not significantly change their structural and functional features.     

Structural basis for ubiquitin recognition by SH3 domains

The SH3 domain is a protein-protein interaction module commonly found in intracellular signaling and adaptor proteins. The SH3 domains of multiple endocytic proteins have been recently implicated in binding ubiquitin, which serves as a signal for diverse cellular processes including gene regulation, endosomal sorting, and protein destruction. Here we describe the solution NMR structure of ubiquitin in complex with an SH3 domain belonging to the yeast endocytic protein Sla1. The ubiquitin binding surface of the Sla1 SH3 domain overlaps substantially with the canonical binding surface for proline-rich ligands. Like many other ubiquitin-binding motifs, the SH3 domain engages the Ile44 hydrophobic patch of ubiquitin. A phenylalanine residue located at the heart of the ubiquitin-binding surface of the SH3 domain serves as a key specificity determinant. The structure of the SH3-ubiquitin complex explains how a subset of SH3 domains has acquired this non-traditional function.     

用ESR研究水合作用对RNase A分子动力学性质的影响

通过ＲＮａｓｅ Ａ的水合等温线,确定ＲＮａｓｅ Ａ吸附水时所处的相对湿度及其水合值的关系;将标记上自旋探针（马来酰亚胺氮氧自由基）的ＲＮａｓｅ Ａ溶液经透析后冷冻干燥并装入样品管后,在不同相对湿度下与水相互作用,待吸附平衡后将样品管密封测其ＥＳＲ波谱,找出谱图上的Ａｍａｘ与ＲＮａｓｅＡ水合值的关系;从而建立了含微量水的ＲＮａｓｅＡ分子运动与其水含量关系的检测方法,得到导致ＲＮａｓｅＡ分子开始运动的     

Folding Topology of a Bimolecular DNA Quadruplex Containing a Stable Mini-hairpin Motif within the Diagonal Loop

We describe the NMR structural characterisation of a bimolecular anti-parallel DNA quadruplex d(G₃ACGTAGTG₃)₂ containing an autonomously stable mini-hairpin motif inserted within the diagonal loop. A folding topology is identified that is different from that observed for the analogous d(G₃T₄G₃)₂ dimer with the two structures differing in the relative orientation of the diagonal loops. This appears to reflect specific base stacking interactions at the quadruplex-duplex interface that are not present in the structure with the T₄-loop sequence. A truncated version of the bimolecular quadruplex d(G₂ACGTAGTG₂)₂, with only two core G-tetrads, is less stable and forms a heterogeneous mixture of three 2-fold symmetric quadruplexes with different loop arrangements. We demonstrate that the nature of the loop sequence, its ability to form autonomously stable structure, the relative stabilities of the hairpin loop and core quadruplex, and the ability to form favourable stacking interactions between these two motifs are important factors in controlling DNA G-quadruplex topology.     

Effects of chemical modifications in the partition behavior of proteins in aqueous two‐phase systems: A case study with RNase A

Chemical modification of proteins is gaining importance due to the improvement in properties and the broader range of applications that these protein conjugates have. Once modified, several purification strategies need to be applied to isolate the conjugates of interest. Aqueous two‐phase systems (ATPS) are an attractive alternative for the primary recovery of proteins and their conjugates. However, to better understand which biochemical parameters affect in greater degree the partition behavior of these modified proteins in ATPS, it becomes necessary to characterize the partition behavior of different species. In this work, ribonuclease A (RNase A) was selected as a model protein to address the partition behavior of chemically modified proteins in ATPS. Native, mono‐PEGylated, Uniblue A, Dabsyl Chloride, and Direct Red 83 chemically modified RNase A's were partitioned in 16 different polyethylene glycol (PEG)–potassium phosphate ATPS. Results suggest that while the effects of system design parameters govern the partition of native RNase A, the behavior of the chemically modified species is more influenced by the physicochemical characteristics of the modifying molecules, that in most cases promote partition toward the top polymer‐rich phase with recovery percentages as high as 86%. It has been found that both, the hydrophobicity and molecular weight of the modifying species play a preponderant role in conjugate partition behavior since as hydrophobicity increases partition is promoted towards the PEG‐rich phase balancing the effect of the molecular weight of the modifying molecules that tends to shift partition towards the salt rich phase. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29: 378–385, 2013     

SESAME: A least-squares approach to the evaluation of protein structures computed from NMR data

Summary A method is proposed for defining a probability distribution on an ensemble of protein conformations from a 2D NOE spectrum, while at the same time back-calculating the experimental spectrum from the ensemble. This enables one to assess the relative quality and significance of the conformations, and to test the consistency of the ensemble as a whole with the experimental spectrum. The method eliminates the need to integrate the cross-peak intensities and is surprisingly insensitive to random noise in the spectrum. In this communication, these advantages are demonstrated by applying the method to simulated data, for which the correct result is already known.Abbreviations NOE nuclear Overhauser effect - BPTI basic pancreatic trypsin inhibitor - rmsd root-mean-square deviation     

Interactions of the cytotoxic RNase A dimers with the cytosolic ribonuclease inhibitor

Ribonuclease A (RNase A) dimers have been recently found to be endowed with some of the special, i.e., non-catalytic biological activities of RNases, such as antitumor and aspermatogenic activities. These activities have been so far attributed to RNases which can escape the neutralizing action of the cytosolic RNase inhibitor (cRI). However, when the interactions of the two cytotoxic RNase A dimers with cRI were investigated in a quantitative fashion and at the molecular level, the dimers were found to bind cRI with high affinity and to form tight complexes.     

Production and introduction of a novel immunotoxin based on engineered RNase A for inducing death to Her1-positive cell lines

The present study was performed to design an immunotoxin consisting of engineered RNase A and scFv of Cetuximab. To accomplish this study goal, at first to evade RNase A from its inhibitors in the cytoplasm, six amino acids of RNase A were substituted, then the physicochemical features of engineered RNase A were assessed. To investigate the interaction between the engineered RNase A and the ribonuclease inhibitor, protein–protein docking was performed. After engineering the RNase A, it was theoretically conjugated with scFv of Cetuximab using a cleavable linker to produce scFv-engineered RNase A. Then, wild-RNase A (14 kD), engineered RNase A (14 kD) and scFv-engineered RNase A (42 kDa) were expressed in the BL21 (DE3) strain of Escherichia coli and purified by Ni-NTA columns. To confirm the expressed proteins, western blot analysis was performed. The functioning of wild-RNase A and engineered RNase A were investigated by RNA fragmentation assay. Finally, to evaluate the cytotoxicity of scFv-engineered RNase A, a dose–response cytotoxicity assay was performed on Her1-positive and Her1-negative cell lines. The results showed that engineered RNase A could maintain its structure and disulfide bonds and evade its inhibitor. Expression and purification were successfully conducted and both enzymes could degrade yeast RNA. The result of cytotoxicity showed that the engineered immunotoxin could induce cell death to Her1-positive cell lines with an IC₅₀ of 50 nM. It appears that scFv-engineered RNase A can be a promising molecule for use.     

Purification and characterization of two basic spermatid-specific proteins isolated from the dog-fish Scylliorhinus caniculus

In dog-fish spermatid nuclei two intermediate proteins S1 and S2 replace histones before the setting down of protamines. These spermatid-specific proteins were isolated by carboxymethyl-cellulose chromatography and purified by high pressure liquid chromatography. S1 and S2 are characterized by a high content of basic residues and by the lack of cysteine and phenylalanine. The determination of their amino acid composition and of their N- and C-terminal sequences prove that each protein corresponds to a specific molecule which can be considered neither as a histone hydrolytic product nor as a protamines precursor.     

Enhanced stability of cis Pro-Pro peptide bond in Pro-Pro-Phe sequence motif

Identification of sequence motifs that favor cis peptide bonds in proteins is important for understanding and designing proteins containing turns mediated by cis peptide conformations. From (1)H NMR solution studies on short peptides, we show that the Pro-Pro peptide bond in Pro-Pro-Phe almost equally populates the cis and trans isomers, with the cis isomer stabilized by a CHc...pi interaction involving the terminal Pro and Phe. We also show that Phe is over-represented at sequence positions immediately following cis Pro-Pro motifs in known protein structures. Our results demonstrate that the Pro-Pro cis conformer in Pro-Pro-Phe sequence motifs is as important as the trans conformer, both in short peptides as well as in natively folded proteins.     

The binding of pentaammineruthenium (III) to RNase B and RNase A+d(pA)4 in the crystalline state

The binding of pentaammineruthenium (III) to ribonuclease A and B both free and complexed with d(pA)₄ has been examined in the crystalline state through the application of X-ray diffraction and difference Fourier techniques. In crystals of native RNase B, the reagent was observed to have many binding sites, some entirely electrostatic in nature and others consistent with coordination to histidine residues. The primary histidine in the latter case was 105 with 119 also partially substituted. In crystals of RNase A+d(pA)₄ complex only a single, extremely strong site of substitution was observed, and this was 2.4 Å from the native position of the imidazole ring of histidine 105. Thus, the results of these X-ray diffraction studies appear to be quite consistent with the findings of earlier NMR studies and with the results obtained in crystals of the gene 5 DNA binding protein.     

Chemical characterization of cyanogen bromide fragments from the beta-chain of human complement factor C3

The isolated beta-chain of human complement factor C3 (C3 beta) was fragmented by cyanogen bromide. Nine fragments were defined by gel filtration and high-pressure liquid chromatography, and characterized with respect to their Mr, amino acid composition and N-terminal amino acid sequence. Approx. 30% of the primary structure of C3 beta was determined. Alignment of the 3 N-terminal fragments allowed determination of 61 of the amino terminal residues of C3 beta. This region demonstrated 40% homology with the sequence in the N-terminal segment of the alpha-chain of the cobra venom factor.     

The spatial structure of the axially bound methionine in solution conformations of horse ferrocytochrome c and Pseudomonas aeruginosa ferrocytochrome c 551 by 1H NMR

A generally applicable method for the determination of the spatial structure of the heme iron-bound methionine in c-type ferrocytochromes at atomic resolution is presented. It relies primarily on measurements of nuclear Overhauser effects between the individual hydrogen atoms of the axial methionine, and between individual hydrogens of the methionine and the heme group. Four different methionine conformers, corresponding to the four possible stereospecific assignments for the methionine methylene proton resonances, are generated by a structural interpretation of the nuclear Overhauser effects with the use of an interactive computer graphics technique. A unique structure and unique stereospecific resonance assignments are then obtained by discriminating between these four conformers on the basis of van der Waals' constraints and heme ring current effects on the chemical shifts. The use of the method is illustrated with studies of horse ferrocytochrome c and Pseudomonas aeruginosa ferrocytochrome c 551. Comparison with the crystal structures shows close coincidence between the methionine conformations in solution and in single crystals of these proteins.Abbreviations NMR nuclear magnetic resonance - NOE nuclear Overhauser effect - TOE truncated driven nuclear Overhauser effect     

Crystallographic structure of the nuclease domain of 3'hExo, a DEDDh family member, bound to rAMP

A human 3'-5'-exoribonuclease (3'hExo) has recently been identified and shown to be responsible for histone mRNA degradation. Functionally, 3'hExo and a stem-loop binding protein (SLBP) target opposite faces of a unique highly conserved stem-loop RNA scaffold towards the 3' end of histone mRNA, which is composed of a 6 bp stem and a 4 nt loop, followed by an ACCCA sequence. Its Caenorhabditis elegans homologue, ERI-1, has been shown to degrade small interfering RNA in vitro and to function as a negative regulator of RNA interference in neuronal cells. We have determined the structure of the nuclease domain (Nuc) of 3'hExo complexed with rAMP in the presence of Mg2+ at 1.6 A resolution. The Nuc domain adopts an alpha/beta globular fold, with four acidic residues coordinating a binuclear metal cluster within the active site, whose topology is related to DEDDh exonuclease family members, despite a very low level of primary sequence identity. The two magnesium cations in the Nuc active site are coordinated to D134, E136, D234 and D298, and together with H293, which can potentially act as a general base, provide a platform for hydrolytic cleavage of bound RNA in the 3' --> 5' direction. The bound rAMP is positioned within a deep active-site pocket, with its purine ring close-packed with the hydrophobic F185 and L189 side-chains and its sugar 2'-OH and 3'-OH groups hydrogen bonded to backbone atoms of Nuc. There are striking similarities between the active sites of Nuc and epsilon186, an Escherichia coli DNA polymerase III proofreading domain, providing a common hydrolytic cleavage mechanism for RNA degradation and DNA editing, respectively.