Studies of the ADP/ATP carrier of mitochondria with fluorescent ADP analogue formycin diphosphate

The ADP/ATP carrier was studied by a fluorescent substrate, formycin diphosphate which is the only fluorescent ADP analogue to bind. Its low quantum yield, short decay time and spectral overlap with tryptophan has as yet prevented its wider use.By incorporating fluorescent acceptors of formycin diphosphate fluorescence, anthracene-maleimide and vinylanthracene, into the membrane, these difficulties were circumvented. Only bound formycin diphosphate transfers energy to the probes so that the secondary emission of these probes is a measure for membrane-bound formycin diphosphate.The fluorescent transfer is inhibited by ADP, bongkrekate and carboxy-atractylate whether added before or after incubation of formycin diphosphate showing that only binding to the adenine nucleotide carrier is measured. It also shows directly that the earlier demonstrated ADP fixation by bongkrekate is indeed a displacement into the matrix.The fluorescence decay time of the bound formycin diphosphate is measured as 1.95 ns compared to 0.95 ns of the free formycin diphosphate, indicating that formycin diphosphate is bound at the carrier in a non-polar environment.The depolarization decay time was found to be larger than 15 ns, indicating that carrier-bound formycin diphosphate is immobile within this time period.     

Studies of the ADP/ATP carrier of mitochondria with fluorescent ADP analogue formycin diphosphate.

The ADP/ATP carrier was studied by a fluorescent substrate, formycin diphosphate which is the only fluorescent ADP analogue to bind. Its low quantum yield, short decay time and spectral overlap with tryptophan has as yet prevented its wider use. By incorporating fluorescent acceptors of formycin diphosphate fluorescence, anthracene-maleimide and vinylanthracene, into the membrane, these difficulties were circumvented. Only bound formycin diphosphate transfers energy to the probes so that the secondary emission of these probes is a measure for membrane-bound formycin diphosphate. The fluorescent transfer is inhibited by ADP, bongkrekate and carboxyatractylate whether added before or after incubation of formycin diphosphate showing that only binding to the adenine nucleotide carrier is measured. It also shows directly that the earlier demonstrated ADP fixation by bongkrekate is indeed a displacement into the matrix. The fluorescence decay time of the bound formycin diphosphate is measured as 1.95 ns compared to 0.95 ns of the free formycin diphosphate, indicating that formycin diphosphate is bound at the carrier in a non-polar environment. The depolarization decay time was found to be larger than 15 ns, indicating that carrier-bound formycin diphosphate is immobile within this time period.     

Inhibition of the cytotoxicity of protein toxins by a novel plant metabolite,Mansonone-D

We have studied the effect of several structurally related mansonones on the cytotoxicity of plant and bacterial toxins in Vero and BER-40, a brefeldin A-resistant mutant of Vero cells. Mansonone-D (MD), a sesquiterpenoid ortho-naphthoquinone, inhibited the cytotoxicity of ricin, modeccin, Pseudomonas toxin, and diphtheria toxin in Vero cells to different extents. The inhibition of ricin cytotoxicity was dose dependent and reversed upon removal of the drug. Protection of ricin cytotoxicity was also observed in the presence of cycloheximide, indicating that de novo protein synthesis is not required for the protective effect. Although MD inhibited the degradation and excretion of ricin, the binding and internalization of ricin was not affected. In contrast, MD strongly reduced the specific binding of diphtheria toxin in Vero cells. Fluorescence microscopic studies show that MD treatment dramatically alters the morphology of the Golgi apparatus in Vero cells. The kinetic studies reveal that the protection of ricin cytotoxicity is the consequence of decreased toxin translocation to the cytosol in MD-treated cells. The reactive ortho-quinone moiety of MD is important for the protective effect as thespesone, a para-naphthoquinone with a heterocyclic ring structure identical to that of MD, did not inhibit the cytotoxicity of toxins. Thespone, a dehydromansonone-D, lacking two hydrogens from the heterocyclic dihydrofuran ring of MD, inhibited the cytotoxicity of ricin, but was albeit less potent than MD. Neither mansonone-E nor mansonone-H with reactive ortho-quinone moiety, but with a different heterocyclic structure, had any effect on the cytotoxicity of ricin indicating that the protective effect of MD is specifically related to the overall structure of the metabolite. J. Cell. Physiol. 176:40–49, 1998. Published 1998 Wiley-Liss, Inc.

1 This article was prepared by a group of United States government employees and non-United States government employees, and as such is subject to 17 U.S.C. Sec. 105.

     

In vitro fusion of endocytic vesicles: Effects of reagents that alter endosomal pH

Ricin, a plant toxin that binds to galactose-terminated glycoproteins and glycolipids on the cell surface, is internalized into endosomes before reaching the cytosol where it exerts its toxic activity. Fusion of early endosomes containing ricin or transferrin was demonstrated by using postnuclear supernatant fractions from K-562 cells. For both ligands, fusion depended on time, temperature, and ATP and was blocked by preincubation with N-ethylmaleimide. Some reagents that increase endosomal pH, the ionophores monensin and nigericin and the weak base chloroquine, stimulated the rate of fusion. However, bafilomycin A₁, a specific inhibitor of vacuolar H⁺-ATPases, did not alter the rate of fusion. Moreover, it reduced or eliminated stimulation caused by monensin, nigericin, or chloroquine. Thus, the increased rate of fusion did not correlate with the higher lumenal pH of the endosome. The results suggest instead that fusion was stimulated by reagents that promoted accumulation of cations within the vesicles. © 1996 Wiley-Liss, Inc.

1 This article is a U.S. Government work and, as such, is in the public domain in the United States of America.

     

Why does β-cyclodextrin prefer to bind nucleotides with an adenine base rather than other 2′-deoxyribonucleoside 5′-monophosphates?

β-Cyclodextrin (β-CD), which resides in the α-hemolysin (αHL) protein pore, can act as a molecular adapter in single-molecule exonuclease DNA sequencing approaches, where the different nucleotide binding behavior of β-CD is crucial for base discrimination. In the present contribution, the inclusion modes of β-CD towards four 2′-deoxyribonucleoside 5′-monophosphates (dNMPs) were investigated using quantum mechanics (QM) calculations. The calculated binding energy suggests that the binding affinity of dAMP to β-CD are highest among all the dNMPs in solution, in agreement with experimental results. Geometry analysis shows that β-CD in the dAMP complex undergoes a small conformational change, and weak interaction analysis indicates that there are small steric repulsion regions in β-CD. These results suggest that β-CD has lower geometric deformation energy in complexation with dAMP. Furthermore, topological analysis and weak interaction analysis suggest that the number and strength of intermolecular hydrogen bonds and van der Waals interactions are critical to dAMP binding, and they both make favorable contributions to the lower interaction energy. This work reveals the reason why β-CD prefers to bind dAMP rather than other dNMPs, while opening exciting perspectives for the design of novel β-CD-based molecular adapters in the single-molecule exonuclease method of sequencing DNA.

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Graphical Abstract The binding affinity of β-cyclodextrin towards four 2′-deoxyribonucleoside 5′-monophosphates was investigated using quantum mechanics calculations

     

Effect of 5-deazaflavin on energy transduction during catalysis by Escherichia coli DNA photolyase.

DNA photolyase from Escherichia coli contains 1,5-dihydroFAD (FADH2) plus 5,10-methenyltetrahydropteroylpolyglutamate. The action spectrum observed for apoenzyme reconstituted with 5-deazaFADH2 (EdFADH2) matched its absorption spectrum after correction for the presence of a small amount of inactive 5-deazaFADox. The quantum yield for dimer repair with EdFADH2 (phi EdFADH2 = 0.110) was 6-fold lower than that observed with apoenzyme reconstituted with FADH2. Excited-state redox potential calculations indicate that 5-deazaFADH2 singlet is a better one-electron donor (E = -3.5 V) than FADH2 singlet (E = -2.7 V). Other studies indicate that the quantum yield for electron transfer from reduced flavin singlet to pyrimidine dimer (0.88) is unaffected when FADH2 is replaced by 5-deazaFADH2. Enhanced back electron transfer from pyrimidine dimer radical to flavin radical may account for the decreased quantum yield observed with EdFADH2 since, in the ground state, 5-deazaFADH. is a better oxidant than FADH.. The action spectrum observed for apoenzyme reconstituted with 5-deazaFADH2 plus 5,10-CH(+)-H4folate (EPtedFADH2) matched the absorption spectrum determined for enzyme-bound 5-deazaFADH2, indicating that the pterin chromophore was inactive as a sensitizer. This differs from results obtained with native enzyme, where pterin acts as a sensitizer via efficient singlet-singlet energy transfer to FADH2. The quantum yield for dimer repair by 5-deazaFADH2 bound to EPtedFADH2 (phi EPtedFADH2 = 0.0318) was 28.9% of that observed for EdFADH2. Spectroscopic studies indicate that singlet-singlet energy transfer in EPtedFADH2 is very efficient but only occurs in the "wrong" direction, i.e., from excited 5-deazaFADH2 to pterin.(ABSTRACT TRUNCATED AT 250 WORDS)     

A review of: “Membrane Mimetic Chemistry J. H. Fendler John Wiley and Sons,New York, 1982 Hardcover, 522 pages, $59.95”

Formycin B [9-deazainosine] was reacted with epoxy-activated Sepharose 68 to form an affinity resin for purine nucleoside phosphorylase (PNPase). This resin had a large capacity (7,600 units/ml) for the enzyme from Escherichia coli. Enzyme retention was dependent on high ionic strength. Although this property is reminiscent of hydrophobic interaction chromatography, analogous resins prepared with pseudouridine or monoethanolamine instead of with formycin B, did not retain the enzyme even at high ionic strength. Furthermore, hypoxanthine facilitated elution of the enzyme from the resin. It appeared, therefore, that the enzyme was not bound simply by hydrophobia interactions. A simple two-step purification procedure for PNPase from Escherichia coli was devised using this resin. Overall recovery was 50%, and purity of the final preparation was greater than 95%. This resin was also useful in the purification of PNPase from human erythrocytes. The ether linkage between formycin B and Sepharose 6B, together with the carbon-to-carbon linkage between the pentose and heterocyclic moieties of formycin B, provided stability to both chemical and enzymatic degradation. After 5 years of use and exposure to a variety of biological preparations, the resin showed no detectable decrease in its ability to bind PNPase.     

蓖麻毒素A链突变体(MRTA)的分子设计

利用同源模建的方法,借助分子力学优化、分子动力学模拟退火设计构建了删除部分氨基酸序列的蓖麻毒素Ａ链突变体（ＭＲＴＡ）。采用泊松—玻尔兹曼方程对比分析了蓖麻毒素Ａ链（ＲＴＡ）与ＭＲＴＡ表观静电势分布,研究ＲＴＡ与ＭＲＴＡ蛋白表面静电性质;通过半经验量子化学ＡＭ１与分子力学结合方法探讨ＲＴＡ与ＭＲＴＡ功能域氨基酸前线分子轨道性质、能级分布,从理论上预测ＭＲＴＡ功能活性     

蓖麻毒素A链突变体(MRTA)的分子设计

利用同源模建的方法,借助分子力学优化,分子力学模拟退火设计构建了删除部分氨基酸序列的蓖麻毒素Ａ链突变体。采用泊松－玻尔兹曼方程对比分析了蓖麻毒素Ａ链与ＭＲＴＡ表现静电势分布,研究了ＲＴＡ与ＭＲＴＡ蛋白表面静电性质;     

X-ray analysis of substrate analogs in the ricin A-chain active site.

Ricin A-chain is an N-glycosidase that hydrolyzes the adenine ring from a specific adenosine of rRNA. Formycin monophosphate (FMP) and adenyl(3'-->5')guanosine (ApG) were bound to ricin A-chain and their structures elucidated by X-ray crystallography. The formycin ring stacks between tyrosines 80 and 123 and at least four hydrogen bonds are made to the adenine moiety. A residue invariant in this enzyme class, Arg180, appears to hydrogen bond to N-3 of the susceptible adenine. Three hypothetical models for binding a true hexanucleotide substrate, CGAGAG, are proposed. They incorporate adenine binding, shown by crystallography, but also include geometry likely to favor catalysis. For example, efforts have been made to orient the ribose ring in a way that allows solvent attack and oxycarbonium stabilization by the enzyme. The favored model is a simple perturbation of the tetraloop structure determined by nuclear magnetic resonance for similar polynucleotides. The model is attractive in that specific roles are defined for conserved protein residues. A mechanism of action is proposed. It invokes oxycarbonium ion stabilization on ribose by Glu177 in the transition state. Arg180 stabilizes anion development on the leaving adenine by protonation at N-3 and may activate a trapped water molecule that is the ultimate nucleophile in the depurination.     

Insight on the interaction of polychlorobiphenyl with nucleic acid–base

The interaction between one polychlorobiphenyl (3,3′,4,4′,-tetrachlorobiphenyl, coded PCB77) and the four DNA nucleic acid–base is studied by means of quantum mechanics calculations in stacked conformations. It is shown that even if the intermolecular dispersion energy is the largest component of the total interaction energy, some other contributions play a non negligible role. In particular the electrostatic dipole-dipole interaction and the charge transfer from the nucleobase to the PCB are responsible for the relative orientation of the monomers in the complexes. In addition, the charge transfer tends to flatten the PCB, which could therefore intercalate more easily between DNA base pairs. From these seminal results, we predict that PCB could intercalate completely between two base pairs, preferably between Guanine:Cytosine pairs.

Identification of the adenine binding site in the ricin toxin A-chain by fluorescence,CD, and electron spin resonance spectroscopy

CD, electron spin resonance, and fluorescence spectroscopy have been utilized to study the adenine binding site of ricin and its toxic A-subunit. At acidic (4.5) and physiological (7.3) pH, adenine or a spin-labeled analogue of adenine, N⁶-(2,2,6,6-tetramethyl-1-oxypiperidin-4-yl) adenine, alters the near uv CD spectra of the ricin A-chain as well as intact ricin, whereas the far uv CD spectra of all proteins remain unchanged. Electron spin resonance data show that the adenine spin-labeled analogue interacts strongly with the A-chain both at pH 4.5 and 7.3, but no or very weak binding is observed for the intact ricin or the isolated B-chain. The adenine spin label gets highly immobilized (2A_II = 65.5G) by the A-chain. The apparent dissociation constant K_d for the toxic A-chain ligand complex is 1.55 × 10^?4 M and 5.6 × 10^?5 M at pH 7.3 and 4.5, respectively. Fluorescence intensity of ricin A-chain bound 1,8-anilinonaphthalenesulfonic acid (ANS) decreases by ～55% at pH 4.5 with the addition of the spin-labeled analogue of adenine, implying that both the ANS and adenine spin label (ADSL) bind to the hydrophobic domain of the A-chain. Fluorescence of the only intrinsic tryptophan probe of the A-chain is also efficiently quenched by ADSL, indicating that the tryptophan residue and the hydrophobic adenine binding site are closely located. All spectroscopic measurements indicate that adenine or its spin-labeled analogue has a single binding site adjacent to the TRP211 residue in the A-chain. Expansion of the A-chain globule and subsequent exposure of the hydrophobic binding site seem to be responsible for the increased binding of adenine at pH 4.5. © 1993 John Wiley & Sons, Inc.     

Formycin triphosphate-terbium complex: a novel spectroscopic probe for phosphoryl transfer enzymes

The conditions under which the fluorescent pyrazolopyrimidine nucleotide formycin A triphosphate (7-amino-3-(beta-D-(5'- tripolyphosphate)ribofuranosyl)pyrazolo[4,3-d]pyrimidine, FTP) forms a 1:1 complex in solution with Tb3+ have been characterized. The complex has a dissociation constant of approx. 10(-7) M. Within the complex, the luminescence of Tb3+ is dramatically sensitized by energy transfer from formycin. The value for 50% transfer efficiency, F?rster's R0 (F?rster, T. (1964) in Modern Quantum Chemistry (Sinanoglu, O., ed.), pp. 93-137, Academic Press, New York) was determined to be 3.34 +/- 0.4 A, and the effective distance between the donor and acceptor transition dipoles, R, in the complex was estimated to be 6.6 +/- 1.0 A. The quantum yield of Tb3+ in the complex is sensitive to the number of O-H oscillators bound to the Tb3+, which allows determination of the number of waters bound to it (approx. 4). Preliminary results show that the complex binds to the phosphoryl transfer enzyme hexokinase in the presence of the glucose analogs N-acetylglucosamine, frucose and xylose, which are not phosphorylated by the enzyme. The binding occurs with a loss of energy efficiency consistent with a new distance from the effective transition dipole of formycin to that of terbium of approx. 9.6 A. The FTP-terbium complex can be used as both a spectroscopic and an X-ray diffraction probe. Studies with this compound should be most valuable for correlating solution and crystallographic data.     

Ricin A-chain structural determinant for binding substrate analogues: A molecular dynamics simulation analysis

Ricin A-chain is a cytotoxic protein that attacks ribosomes by hydrolyzing a specific adenine base from a highly conserved, single-stranded rRNA hairpin containing the tetraloop sequence GAGA. Molecular-dynamics simulation methods are used to analyze the structural determinant for three substrate analogues bound to the ricin A-chain molecule. Simulations were applied to the binding of the dinucleotide adenyl-3′,5′-guanosine employing the x-ray crystal structure of the ricin complex and a modeled CGAGAG hexanucleotide loop taken from the NMR solution structure of a 29-mer oligonucleotide hairpin. A third simulation model is also presented describing a conformational search of the docked 29-mer structure by using a simulated-annealing method. Analysis of the structural interaction energies for each model shows the overall binding dominated by nonspecific interactions, which are mediated by specific arginine contacts from the highly basic region on the protein surface. The tetraloop conformation of the 29-mer was found to make specific interactions with conserved protein residues, in a manner that favored the GAGA sequence. A comparison of the two docked loop conformations with the NMR structure revealed significant positional deviations, suggesting that ricin may use an induced fit mechanism to recognize and bind the rRNA substrate. The conserved Tyr-80 may play an important confirmational entropic role in the binding and release of the target adenine in the active site. Proteins 27:80–95 © 1997 Wiley-Liss, Inc.     

Quantum and molecular dynamics study for binding of macrocyclic inhibitors to human alpha-thrombin

Molecular dynamics simulations followed by quantum mechanical calculation and Molecular Mechanics Poisson-Boltzmann Surface Area (MM-PBSA) analysis have been carried out to study binding of proline- and pyrazinone-based macrocyclic inhibitors (L86 and T76) to human alpha-thrombin. Detailed binding interaction energies between these inhibitors and individual protein fragments are calculated using DFT method based on a new quantum mechanical approach for computing protein-ligand interaction energy. The analysis of detailed interaction energies provides insight on the protein-ligand binding mechanism. Study shows that T76 and L86 bind to thrombin in a very similar "inhibition mode" except that T76 has relatively weaker binding interaction with Glu(217). The analysis from quantum calculation of binding interaction is consistent with the MM-PBSA calculation of binding free energy, and the calculated free energies for L86/T76-thrombin binding agree well with the experimental data.     

How does modification of adenine by hydroxyl radical influence the stability and the nature of stacking interactions in adenine-cytosine complex?

This study reports on ab initio calculations of adenine - cytosine complexes in two different context alignments appearing in B-DNA. The influence of adenine modification by hydroxyl radical on the stability of the complexes is also discussed. The analysis was performed on over 40 crystallographic structures for each of the sequence contexts. In most cases, modification of adenine by hydroxyl radical leads to less negative intermolecular interaction energies. The issue of the influence of alteration of structural base step parameters on the stability of modified and unmodified adenine - cytosine complexes is also addressed. Analysis of the dependence of intermolecular interaction energy on base step parameters reveals that for twist and shift modification of adenine by hydroxyl radical leads to quite different interaction energy profiles in comparison with unmodified complexes. In order to elucidate the physical origins of this phenomenon, i.e. to analyze how the modification of adenine by hydroxyl radical is reflected in the change of intermolecular interaction energy components, a variational-perturbational decomposition scheme was applied at the MP2/aug-cc-pVDZ level of theory.     

Quantum mechanics study on the selectivity of alkali metal cations by a novel fluorescent chemosensor

The selectivity of alkali metal cations (Na⁺ and K⁺) by a novel fluorescent chemosensor was investigated by quantum mechanics calculations. The binding energy calculations of the cationic complexes indicate that both of the aza-18-crown-6 rings bind Na⁺ more strongly than K⁺ and ring A favors both of Na⁺ and K⁺ comparing to ring B. The order of the stability implied by Gibbs free energy study agrees with that by binding energy calculation. Solvent effect was further investigated. Due to the large difference of solvation energies, the order of the stability of complexes changes in water.     

SNX4 in Complex with Clathrin and Dynein: Implications for Endosome Movement

Background

Sorting nexins (SNXs) constitute a family of proteins classified by their phosphatidylinositol (PI) binding Phox homology (PX) domain. Some members regulate intracellular trafficking. We have here investigated mechanisms underlying SNX4 mediated endosome to Golgi transport.

Methodology/Principal Findings

We show that SNX4 forms complexes with clathrin and dynein. The interactions were inhibited by wortmannin, a PI3-kinase inhibitor, suggesting that they form when SNX4 is associated with PI(3)P on endosomes. We further localized the clathrin interacting site on SNX4 to a clathrin box variant. A short peptide containing this motif was sufficient to pull down both clathrin and dynein. Knockdown studies demonstrated that clathrin is not required for the SNX4/dynein interaction. Moreover, clathrin knockdown led to increased Golgi transport of the toxin ricin, as well as redistribution of endosomes.

Conclusions/Significance

We discuss the possibility of clathrin serving as a regulator of SNX4-dependent transport. Upon clathrin release, dynein may bind SNX4 and mediate retrograde movement.     

Purification and characterization of a flavin-binding storage protein from the hemolymph of Galleria mellonella

The 85K storage protein that accumulates in the hemolymph of Galleria mellonella during the final larval instar was isolated and purified from newly molted pupae. The separation of fresh hemolymph proteins from larvae or pupae by different chromatographic and electrophoretic procedures indicated the native protein had a Mr of 170,000 and consisted of two identical 85K subunits. Crosslinking experiments using fresh hemolymph followed by Western blotting also indicated a dimeric structure for the native protein. Analyses of the dimer purified from pupal hemolymph indicated that 85K was a glycoprotein, containing approximately 6.5% neutral sugar and about 1.9% amino sugar. Like other insect flavin-binding proteins, 85K has a relatively high histidine content but an uncharacteristically high arginine content. The purified 85K dimer did not bind riboflavin, suggesting that the integrity of the molecule had been altered during purification. However, 85K purified in low yield by Affi-Gel Blue chromatography, did bind riboflavin, indicating that under certain, undefined conditions the functional integrity of the protein could be retained during purification. © 1994 Wiley-Liss, Inc.

1 This article is a US Government work and, as such, is in the public domain in the United States of America.