单分子荧光共振能量转移技术

单分子荧光共振能量转移技术（single molecule fluorescence resonance energy transfer,smFRET）通过检测单个分子内的荧光供体及受体间荧光能量转移的效率,来研究分子构象的变化。在单分子探测技术发展之前,大多数的分子实验是探测分子的综合平均效应（ensemble averages）,这一平均效应掩盖了许多特殊的信息。单分子探测可以对体系中的单个分子进行研究,得到某一分子特性的分布状况,也可研究生物分子的动力学反应。介绍了近来单分子荧光共振能量转移技术的进展。     

NMR spectroscopic and molecular modeling investigations of the trans-sialidase from Trypanosoma cruzi

Nuclear magnetic resonance (NMR) spectroscopy was used to investigate the transfer of sialic acid from a range of sialic acid donor compounds to acceptor molecules, catalyzed by Trypanosoma cruzi trans-sialidase (TcTS). We demonstrate here that NMR spectroscopy is a powerful tool to monitor the trans-sialidase enzyme reaction for a variety of donor and acceptor molecules. The hydrolysis or transfer reactions that are catalyzed by TcTS were also investigated using a range of N-acetylneuraminosyl-based donor substrates and asialo acceptor molecules. These studies showed that the synthetic N-acetylneuraminosyl donor 4-methylumbelliferyl alpha-d-N-acetylneuraminide (MUN) is hydrolyzed by the enzyme approximately 3-5 times faster than either the disaccharide Neu5Acalpha(2,3)Galbeta1Me or the trisaccharide Neu5Acalpha(2,3)Lacbeta1Me. In the transfer reaction, we show that Neu5Acalpha(2,3)Lacbeta1Me is the most favorable substrate for TcTS and is a better substrate than the naturally-occurring N-acetylneuraminosyl donor alpha1-acid glycoprotein. In the case of MUN as the donor molecule, the transfer of Neu5Ac to different acceptors is significantly slower than when other N-acetylneuraminosyl donors are used. We hypothesize that when MUN is bound by the enzyme, the orientation and steric bulk of the umbelliferyl aglycon moiety may restrict the access for the correct positioning of an acceptor molecule. AutoDock studies support our hypothesis and show that the umbelliferyl aglycon moiety undergoes a strong pi-stacking interaction with Trp-312. The binding properties of TcTS towards acceptor (lactose) and donor substrate (Neu5Ac) molecules have also been investigated using saturation transfer difference (STD) NMR experiments. These experiments, taken together with other published data, have clearly demonstrated that lactose in the absence of other coligands does not bind to the TcTS active site or other binding domains. However, in the presence of the sialic acid donor, lactose (an asialo acceptor) was observed by NMR spectroscopy to interact with the enzyme's active site. The association of the asialo acceptor with the active site is an absolute requirement for the transfer reaction to proceed.     

Catalysis of phosphoryl group transfer. The role of divalent metal ions in the hydrolysis of lactic acid O-phenyl phosphate and salicylic acid O-aryl phosphates.

The spontaneous hydrolyses of lactic acid O-phenyl phosphate (I) and, to a lesser extent, 3-hydroxybutyric acid O-phenyl phosphate (II) have been investigated and compared with similar intramolecular and bimolecular reactions. Compared to bimolecular nucleophilic reactions, the reactivity of II is similar to other systems involving the formation of a six-membered ring intermediate, which suggests that the electrostatic barrier to attack of an anionic nucleophile on a phosphate diester anion is fully present in II. The reactivity of I, as compared to that of II, would suggest that at least a partial overcoming of the electrostatic barrier takes place upon closer approimation of the two reacting centers. The Mn-2+-catalyzed hydrolysis of I exhibits saturation kinetics, consistent with the enhanced reactivity of the metal ion-substrate complex. The binding constant for this complex, determined from kinetics, is in good agreement with that obtained by electron spin resonance (ESR) titration. It is argued that the complex of Mn-2+ with II, as observed by pulsed Fourier transform nuclear magnetic resonance (NMR) techniques, is a precursor to the complex of catalytic significance. The hydrolysis of I as catalyzed by a variety of divalent metal ions suggests an optimal metal ion size. The spontaneous and metal ion catalyzed hydrolyses of salicyclic acid O-aryl phosphates (IIIa-d) proceed through cyclic acyl phosphate intermediates after expulsion of phenol. Product studies on the parent compound have failed to detect phenyl phosphate as a product in either the spontaneous or metal ion catalyzed process. The dependence of the second-order rate constant for the metal-catalyzed hydrolysis on leaving group pKa, beta-1-g, decreases significantly relative to beta-1-g for the spontaneous hydrolysis. From the collective data a specific interation of the metal ion with a pentacovalent intermediate is inferred in the rate-determining step for esters I and III. The probable consequences of these mechanistic postulates for phosphoryl transfer reactions in biological systems are discussed.     

Optimization of Protease-Catalyzed Acyl Transfer Reactions. Determination of the Partition Constant Characterizing Nucleophile Efficiency

The partitioning of the acyl-enzyme between aminolysis by an added nucleophile and hydrolysis plays a key-role in protease-catalyzed acyl transfer reactions. It can be characterized by the partition constant, which is equal to the nucleophile concentration for which aminolysis and hydrolysis proceed at the same velocity. We describe a method for calculation of the partition constant from the product ratio which is based on the integrated rate equation. Therefore, it can be applied to reactions performed under synthesis-like conditions, i.e. a high degree of nucleophile consumption during the reaction. In principle, the dependence of the partition constant on nucleophile concentration can be determined from a single reaction. V8-protease-catalyzed acyl transfer reactions using Z-Glu-OMe as acyl donor and amino acid amides as nucleophiles were investigated as an application of the method. The central role of the partition constant in optimization of preparative protease-catalyzed acyl transfer reactions is discussed.     

Optimization of Protease-Catalyzed Acyl Transfer Reactions. Determination of the Partition Constant Characterizing Nucleophile Efficiency

The partitioning of the acyl-enzyme between aminolysis by an added nucleophile and hydrolysis plays a key-role in protease-catalyzed acyl transfer reactions. It can be characterized by the partition constant, which is equal to the nucleophile concentration for which aminolysis and hydrolysis proceed at the same velocity. We describe a method for calculation of the partition constant from the product ratio which is based on the integrated rate equation. Therefore, it can be applied to reactions performed under synthesis-like conditions, i.e. a high degree of nucleophile consumption during the reaction. In principle, the dependence of the partition constant on nucleophile concentration can be determined from a single reaction. V8-protease-catalyzed acyl transfer reactions using Z-Glu-OMe as acyl donor and amino acid amides as nucleophiles were investigated as an application of the method. The central role of the partition constant in optimization of preparative protease-catalyzed acyl transfer reactions is discussed.     

Peptide synthesis catalyzed by proteases. Elevated nucleophilic activity of naphthylamides of amino acids in acyl transfer reactions catalyzed by alpha-chymotrypsin

It was found that the reactivity of alpha-amino acid naphthylamides in acyl transfer reactions catalyzed by alpha-chymotrypsin exceeds by more than two orders of magnitude the effective reactivity of other C-protected derivatives of these compounds. A detailed kinetic analysis of the acyl transfer of the tert-butyl oxycarbonyl-L-methionine residue from its p-nitrophenyl ester to L-arginine naphthylamide was carried out. A minimal kinetic scheme of acyl transfer reactions is proposed, including together with the major process, i.e., acyl residue transfer to the nucleophil, the hydrolysis of the acyl enzyme-nucleophil complex and nucleophil binding by the free enzyme. The numeric values of some kinetic constants were determined. A theoretical analysis of the effect of hydrolysis of the acyl enzyme-nucleophil complex on the degree of nucleophil conversion into the peptide at initial acyl group donor and nucleophil concentrations was carried out.     

Electron transfers amongst cytochrome f, plastocyanin and photosystem I: kinetics and mechanisms

The review covers the theory and practice of the determination of kinetic constants for the electron transfer reactions in chloroplast thylakoid membranes between plastocyanin and cytochrome f in cytochrome bf complexes, and between plastocyanin and the reaction centre of photosystem I. Effects of ionic strength and pH are featured. The contribution of mutant studies is included. It is concluded that nearly all data from in vitro experiments can be interpreted with a reaction scheme in which an encounter complex between donor and acceptor is formed by long-range electrostatic attraction, followed by rearrangement during which metal centres become close enough for rapid intra-complex electron transfer. In vivo experiments so far cast doubt on this particular sequence, but their interpretation is not straightforward. Means of modelling the bimolecular complex between cytochrome f and plastocyanin are outlined, and two likely structures are illustrated. The complex formed by plastocyanin and photosystem I in higher plants involves the PsaF subunit, but its structure has not been fully determined.     

Adenosine diphosphoribose transfer reactions catalyzed by Bungarus fasciatus venom NAD glycohydrolase

Reactions catalyzed by purified Bungarus fasciatus venom NAD glycohydrolase were demonstrated to include ADP-ribose transfer from NAD to alcohols and to imidazole derivatives to produce a variety of ADP-ribosides. The formation of products was monitored by high performance liquid chromatography. In the enzyme-catalyzed alcoholysis of NAD, the ratio of n-alkyl-ADP-riboside formed to the hydrolytic product, ADP-ribose, increased linearly with alcohol concentration. The effectiveness of alcohols as acceptors of the ADP-ribose moiety in these reactions increased with increasing chainlength of the alcohol used. Linear positive chainlength effects extended from methanol to pentanol suggesting facilitation of these reactions by nonpolar interactions. In the methanolysis reaction, NADP, thionicotinamide adenine dinucleotide, nicotinamide-1, N6-ethenoadenine dinucleotide, and 3-acetylpyridine adenine dinucleotide were shown to be as effective as NAD as donor substrates. The NAD glycohydrolase-catalyzed ADP-ribose transfer to pyridine bases to form NAD analogs was studied at pyridine base concentrations above those determined to be saturating for the base exchange reaction. Under these conditions, the ratio of base exchange to hydrolysis of NAD was directly related to the pKa of the ring nitrogen of the pyridine base employed. In addition to alcoholysis and pyridine-base exchange reactions, the snake venom enzyme was demonstrated to catalyze an ADP-ribose transfer reaction to imidazole derivatives. Arginine methyl ester was ineffective as an ADP-ribose acceptor molecule in these reactions.     

On the donor substrate dependence of group-transfer reactions by hydrolytic enzymes: Insight from kinetic analysis of sucrose phosphorylase-catalyzed transglycosylation

Chemical group-transfer reactions by hydrolytic enzymes have considerable importance in biocatalytic synthesis and are exploited broadly in commercial-scale chemical production. Mechanistically, these reactions have in common the involvement of a covalent enzyme intermediate which is formed upon enzyme reaction with the donor substrate and is subsequently intercepted by a suitable acceptor. Here, we studied the glycosylation of glycerol from sucrose by sucrose phosphorylase (SucP) to clarify a peculiar, yet generally important characteristic of this reaction: partitioning between glycosylation of glycerol and hydrolysis depends on the type and the concentration of the donor substrate used (here: sucrose, α-d -glucose 1-phosphate (G1P)). We develop a kinetic framework to analyze the effect and provide evidence that, when G1P is used as donor substrate, hydrolysis occurs not only from the β-glucosyl-enzyme intermediate (E-Glc), but additionally from a noncovalent complex of E-Glc and substrate which unlike E-Glc is unreactive to glycerol. Depending on the relative rates of hydrolysis of free and substrate-bound E-Glc, inhibition (Leuconostoc mesenteroides SucP) or apparent activation (Bifidobacterium adolescentis SucP) is observed at high donor substrate concentration. At a G1P concentration that excludes the substrate-bound E-Glc, the transfer/hydrolysis ratio changes to a value consistent with reaction exclusively through E-Glc, independent of the donor substrate used. Collectively, these results give explanation for a kinetic behavior of SucP not previously accounted for, provide essential basis for design and optimization of the synthetic reaction, and establish a theoretical framework for the analysis of kinetically analogous group-transfer reactions by hydrolytic enzymes.     

Kinetics of electron transfer between plastocyanin and the soluble CuA domain of cyanobacterial cytochrome c oxidase

It has been shown that efficient functioning of photosynthesis and respiration in the cyanobacterium Synechocystis PCC 6803 requires the presence of either cytochrome c6 or plastocyanin. In order to check whether the blue copper protein plastocyanin can act as electron donor to cytochrome c oxidase, we investigated the intermolecular electron transfer kinetics between plastocyanin and the soluble CuA domain (i.e. the donor binding and electron entry site) of subunit II of the aa3-type cytochrome c oxidase from Synechocystis. Both copper proteins were expressed heterologously in Escherichia coli. The forward and the reverse electron transfer reactions were studied yielding apparent bimolecular rate constants of (5.1+/-0.2) x 10(4) M(-1) s(-1) and (8.5+/-0.4) x 10(5) M(-1) s(-1), respectively (20 mM phosphate buffer, pH 7). This corresponds to an apparent equilibrium constant of 0.06 in the physiological direction (reduction of CuA), which is similar to Keq values calculated for the reaction between c-type cytochromes and the soluble fragments of other CuA domains. The potential physiological role of plastocyanin in cyanobacterial respiration is discussed.     

Kinetics and mechanism of long-chain fatty acid transport into phosphatidylcholine vesicles from various donor systems

The kinetics of long-chain fatty acid (FA) transfer from three different donor systems to unilamellar egg phosphatidylcholine (EPC) vesicles containing the pH-sensitive fluorophore pyranine in the vesicle cavity were determined. The transfer of long-chain FA from three FA donors, FA vesicles, unilamellar EPC vesicles containing FA, and bovine serum albumin-FA complexes to pyranine-containing EPC vesicles is a true first-order process, indicating that the FA transfer proceeds through the aqueous phase and not through collisional contacts between the donor and acceptor. A collisional mechanism would be at least bimolecular, giving rise to second-order kinetics. Evidence from stopped-flow fluorescence spectroscopy using the pyranine assay (as developed by Kamp, F., and Hamilton, J. A. (1992) Proc. Natl. Acad. Sci. U.S.A. 89, 11367-11370) shows that the transverse or flip-flop motion of long-chain FA (from 14 to 22 C atoms) is immeasurably fast in both small and large unilamellar EPC vesicles and characterized by half-times t(1/2) < 5 ms. The rate-limiting step of FA transfer from these different donor systems to pyranine-containing EPC vesicles is the dissociation or desorption of the FA molecule from the donor. The desorption of the FA molecule is chain-length-dependent, confirming published data (Zhang et al. (1996) Biochemistry 35, 16055-16060): the first-order rate constant k(1) decreases by a factor of about 10 with elongation of the FA chain by two CH(2) groups. Similar rates of desorption are observed for the transfer of oleic acid from the three donors to pyranine-containing EPC vesicles with rate constants k(1) ranging from 0.4 to 1.3 s(-1). We also show that osmotically stressed, pyranine-containing EPC vesicles can give rise to artifacts. In the presence of a chemical potential gradient across the lipid bilayer of these vesicles, fast kinetic processes are observed with stopped-flow fluorescence spectroscopy which are probably due to electrostatic and/or osmotic effects.ne     

Pseudogene

Abstract

The article describes organic photochemical reactions in heterogeneous fields. The first part of the article includes an introduction of miscellaneous electrostatic fields adsorbing photoactive species and the second part summarizes the types of photochemical reactions in their fields. Photochemical reactions carried out in various heterogeneous fields, inorganic as well as organic, were classified by their reaction type, that is, unimolecular reactions, bimolecular reactions, energy transfer reactions, and electron transfer reactions.     

Kinetic mechanisms of two NAD:arginine ADP-ribosyltransferases: the soluble, salt-stimulated transferase from turkey erythrocytes and choleragen, a toxin from Vibrio cholerae

A subunit of choleragen and an erythrocyte ADP-ribosyltransferase catalyze the transfer of ADP-ribose from NAD to proteins and low molecular weight guanidino compounds such as arginine. These enzymes also catalyze the hydrolysis of NAD to nicotinamide and ADP-ribose. The kinetic mechanism for both transferases was investigated in the presence and absence of the product inhibitor nicotinamide by using agmatine as the acceptor molecule. To obtain accurate estimates of kinetic parameters, the transferase and glycohydrolase reactions were monitored simultaneously by using [adenine-2,8-3H]NAD and [carbonyl-14C]NAD as tracer compounds. Under optimal conditions for the transferase assay, NAD hydrolysis occurred at less than 5% of the Vmax for ADP-ribosylation; at subsaturating agmatine concentrations, the ratio of NAD hydrolysis to ADP-ribosylation was significantly higher. Binding of either NAD or agmatine resulted in a greater than 70% decrease in affinity for the second substrate. All data were consistent with a rapid equilibrium random sequential mechanism for both enzymes.     

Kinetic peculiarities of human tissue kallikrein: 1--substrate activation in the catalyzed hydrolysis of H-D-valyl-L-leucyl-L-arginine 4-nitroanilide and H-D-valyl-L-leucyl-L-lysine 4-nitroanilide; 2--substrate inhibition in the catalyzed hydrolysis of N alpha-p-tosyl-L-arginine methyl ester

Hydrolysis of D-valyl-L-leucyl-L-lysine 4-nitroanilide (1), D-valyl-L-leucyl-L-arginine 4-nitroanilide (2), and N alpha-p-tosyl-L-arginine methyl ester (3) by human tissue kallikrein was studied throughout a wide range of substrate concentrations. At low substrate concentrations, the hydrolysis followed Michaelis-Menten kinetics but, at higher substrate concentrations, a deviation from Michaelis-Menten behavior was observed. With the nitroanilides, a significant increase in hydrolysis rates was observed, while with the ester, a significant decrease in hydrolysis rates was observed. The results for substrates (1) and (3) can be accounted for by a model based on the hypothesis that a second substrate molecule binds to the ES complex to produce a more active or an inactive SES complex. The deviation observed for substrate (2) can be explained as a bimolecular reaction between the enzyme-substrate complex and a free substrate molecule.     

Specificity of the sarcoplasmic reticulum calcium ATPase at the hydrolysis step

The coupling of Ca2+ transport to ATP hydrolysis by the SR ATPase requires that the enzyme operate with considerable specificity, which is different at different steps. The limits of specificity of the calcium-free phosphorylated enzyme for transfer of its phosphoryl group to water have been examined. The rate of transfer of the phosphoryl group to the simple nucleophile methanol was compared to its transfer to water by following the formation of methyl phosphate from inorganic phosphate. The reverse reaction, hydrolysis of methyl phosphate, was compared to phosphate-water oxygen exchange. The reactions involving methanol as nucleophile or leaving group are at least 2-3 orders of magnitude slower than those involving water. This result indicates that the transition state for this reaction involves strong and specific interactions of the H2O molecule with the enzyme. These interactions may also involve the bound Mg2+ ion. The results also suggest that the difference in specificity between Ca2+ free and Ca2+ bound states of the enzyme involves significant differences in the structure of the catalytic site.     

Studies of the cellulolytic system of the filamentous fungus Trichoderma reesei QM 9414. Substrate specificity and transfer activity of endoglucanase I.

Endoglucanase I from the filamentous fungus Trichoderma reesei catalyses hydrolysis and glycosyl-transfer reactions of cello-oligosaccharides. Initial bond-cleaving frequencies determined with 1-3H-labelled cello-oligosaccharides proved to be substrate-concentration-dependent. Using chromophoric glycosides and analysing the reaction products by h.p.l.c., kinetic data are obtained and, as typical for an endo-type depolymerase, apparent hydrolytic parameters (kcat., kcat./Km) increase steadily as a function of the number of glucose residues. At high substrate concentrations, and for both free cellodextrins and their aromatic glycosides, complex patterns (transfer reactions) are, however, evident. In contrast with the corresponding lactosides and 1-thiocellobiosides, and in conflict with the expected specificity, aromatic 1-O-beta-cellobiosides are apparently hydrolysed at both scissile bonds, yielding the glucoside as one of the main reaction products. Its formation rate is clearly non-hyperbolically related to the substrate concentration and, since the rate of D-glucose formation is substantially lower, strong indications for dismutation reactions (self-transfer) are again obtained. Evidence for transfer reactions catalysed by endoglucanase I further results from experiments using different acceptor and donor substrates. A main transfer product accumulating in a digest containing a chromophoric 1-thioxyloside was isolated and its structure elucidated by proton n.m.r. spectrometry (500 MHz). The beta 1-4 configuration of the newly formed bond was proved.     

Theoretical study on primary reaction of photosynthetic bacteria

Theoretical calculation was carried out on the primary electron donor P_(870) of photosynthetic bacteria. The results show that: (ⅰ) the bimolecular structure of the primary electron donor is more advantageous in energy than monomolecular structure; (ⅱ) the initial configuration of primary electron donor is no longer stable and changes to the configuration with lower energy and chemical reactivity after the charge separation. In the P_(870), such structural change is completed through the rotation of C_3 acetyl, so the oxygen atom of acetyl interacts with the magnesium atom of another bacterio-chlorophyll molecule, and the total energy and chemical reactivity are reduced evidently. It is suggested that the structural change of the primary electron donor is important in preventing the occurrence of charge recombination during the primary reaction and maintaining the high efficiency of the conversion of sun-light to chemical energy. A new mechanism of primary reaction has been proposed, which can give r     

Pathways of chemical evolution of photosynthesis

The primary metabolism of protobionts was probably based on the electron transfer reactions regulated by catalysts or photosensitizing pigments. The action of photoreceptive pigments was inevitable in the case of electron transfer leading to light energy storage in the reaction products. The primitive tetrapyrrolic pigments formed abiogenically (porphin, chlorin) as well as their more complicated biogenic analogs (chlorophylls) are capable to photosensitize electron transfer in systems, having various degree of molecular complexity. The inorganic photosensitizers (titanim dioxide, zinc oxide, etc.). being excited in near UV are able to perform the same reactions as porphyrins —electron transfer from donor to acceptor molecule (including photoreduction of viologens) or water molecule photooxidation (oxygen liberation), coupled with reduction of ferric compounds and quinones. The inorganic photosensitizers are not used in biological evolution; actually the inorganic ions entered into tetrapyrrolic cycle, forming effective photocatalysts. Inclusion of pigments into primary membranes led to elaborated coupling between pigments and enzymatic systems. The involvement of the excited pigments into the biocatalytic electron transfer chain served as prerequisite of effective function of photosynthetic organisms.     

Bimolecular exon ligation by the human spliceosome bypasses early 3' splice site AG recognition and requires NTP hydrolysis

Here we report further characterization of an in vitro assay system for exon ligation by the human spliceosome in which the 3' splice site AG is supplied by a different RNA molecule than that containing the 5' splice and branch sites. By varying the time during splicing reactions when the 3' splice site AG is made available to the splicing machinery, we show that AG recognition need not occur until after lariat formation. Thus an early AG recognition event required for spliceosome formation and lariat formation on some mammalian introns is not required for exon ligation. Depletion/add-back studies and cold competitor challenge experiments reveal that commitment of a 3' splice site AG to exon ligation requires NTP hydrolysis. Because it both physically and kinetically uncouples exon ligation from spliceosome assembly and lariat formation, the bimolecular system will be a valuable tool for further mechanistic analysis of the second step of splicing.     

Engineering of substrate mimetics as novel-type substrates for glutamic acid-specific endopeptidases: design, synthesis, and application

This account reports on the development and function of novel substrate mimetics as artificial substrates for Glu-specific endopeptidases. Firstly, in an empirical way, various aliphatic and aromatic analogs of the already established carboxymethyl thioester-substrate mimetics were designed from simple structure-function relationship studies. The specificity of the newly developed substrates for Staphylococcus aureus V8 protease-catalyzed reactions have been examined by steady-state hydrolysis kinetic studies. Additionally, these studies were expanded to the use of the equally Glu-specific endopeptidase from Bacillus licheniformis (BL-GSE) which can easily be purified from alcalase in high yields. Finally, the novel substrate mimetics were used as acyl donor components in BL-GSE- and V8 protease-catalyzed model acyl transfer reactions. The results clarify the newly developed substrate mimetics as efficient acyl donors as well as BL-GSE as an attractive alternative to V8 protease for enzymatic peptide synthesis.