Antibody-antigen interactions measured by surface plasmon resonance: global fitting of numerical integration algorithms

The interactions between adenylate kinase (AK) and a monoclonal antibody against AK (McAb3D3) were examined by means of optical biosensor technology, and the sensograms were fitted to four models using numerical integration algorithms. The interaction of a solution of McAb3D3 with immobilized AK follows a double exponential function and the data fitted well to an inhomogeneous ligand model. The interaction of a solution AK with immobilized McAb3D3 follows a single exponential function and the data fitted well to a pseudo-first order reaction model. The true association constants of AK binding to McAb3D3 in solution were obtained from competition BIAcore measurements. The difference in results obtained with solid-phase BIAcore and competition BIAcore may be due to rebinding of the dissociated analyte to the immobilized surface. The results obtained with BIAcore are compared to those obtained by ELISA methods. We suggest that the best method for analysis of BIAcore data is direct, global fitting of sensorgrams to numerical integration algorithms corresponding to the different possible models for binding.     

Conformational adjustments of SNase R and its N-terminal fragments probed by monoclonal antibodies

Two monoclonal antibodies specific for staphylococcal nuclease R (SNase R) (McAb2C9 and McAb1B8) were prepared and used to probe protein folding during peptide elongation, by measuring antibody binding to seven N-terminal fragments (SNR141, SNR135, SNR121, SNR110, SNR102, SNR79 and SNR52) of SNase R. Comparative studies of the conformations of the N-terminal fragments have shown that all seven fragments of SNase R have a certain amount of residual structure, indicating that folding may occur during elongation of the nascent peptide chain. We show that the binding abilities of the intact enzyme and its seven fragments to the monoclonal antibodies are not simply proportional to the length of the peptide chain, suggesting that there may be continuous conformational adjustment in the nascent peptide chain as new C-terminal amino acids are added. A folding intermediate close in structure to the native state but with structural features in common with SNR121 is highly populated in 0.6 M GuHCl, and is also formed transiently during folding.     

聚乙二醇修饰的单克隆抗体的某些生物活性

 不久前我们报道了PEG-1900修饰的McAb的某些理化性质,本文主要报道经PEG-1900修饰的McAb在某些生物活性方面的变化。与天然的McAb相比,修饰的McAb有以下的变化:(1)抗原性与免疫原性下降;(2)抗体活性下降;(3)在体内存活的时间延长;(4)对温度及pH的抵抗力增强。修饰的酶与天然的酶相比,酶活性有所下降,但下降的程度要比修饰的McAb小得多。     

Preparation and characterization of monoclonal antibodies against adenylate kinase

Six hybridoma cell lines that can continuously secrete monoclonal antibodies against adenylate kinase (AK) have been produced. The characteristics including the subclass and molecular weight of monoclonal antibodies manufactured by these strains are also determined. Further studies show that the two monoclonal antibodies McAb3D3 and McAMD8 bind easily with AK absorbed on microtitration plates, with affinity constants of 8.4 × 108 M-1 and 9.6 × 108 M-1, while their interactions to AK in solution are much weaker, with affinity constants of 7.0 × 104 M-1 and 3.9×106M-1, respectively. Thus, McAb3D3 and McAMD8 react preferentially to the immobilized AKs. Since pro-teins are often partially denatured when absorbed on microtitration plates, it is suggested that both McAb3D3 and McAMD8 are directed against non-native AK.     

The kinetic study of arginine kinase from the sea cucumber Stichopus japonicus with 5,5'-dithiobis-(2-nitrobenzoic acid)

The Stichopus japonicus arginine kinase (AK) is a significant dimeric enzyme. Its modification and inactivation course with 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) and the reactivation course of DTNB-modified AK by dithiothreitol were investigated on the basis of the kinetic theory of the substrate reaction during the modification of enzyme activity. The results show that the modification is a biphasic course while the inactivation is monophasic, with one essential reactive cysteine per subunit. The Cys274 (numbering from the Stichopus sequence) is exposed to DTNB and is near the ATP binding site. The modified AK can be reactivated by an excess concentration of dithiothreitol in a monophasic kinetic course. The presence of ATP or the transition-state analog markedly slows the apparent reactivation rate constant. The analog components, arginine-ADP-Mg2+ can induce conformational changes of the modified enzyme, but adding NO3- cannot induce further changes that occur with the native enzyme. The reactive cysteines' location and its role in the catalysis of AK are discussed. The results suggest that the cysteine may be located in the hinge area of the two domains of AK. The reactive cysteine of AK, which was proposed to be Cys274, may play an important role not in the binding of the transition-state analog but in the conformational changes caused by the transition-state analog.     

化学修饰单克隆抗体模拟谷胱甘肽过氧化物酶

化学修饰具有底物谷胱甘肽（ＧＳＨ）结合部位的单克隆抗体（４Ａ４）,使其结合部位上的丝氨酸（Ｓｅｒ）转变成谷胱甘肽过氧化物酶（ＧＰＸ）的催化基团硒代半胱氨酸（Ｓｅ－Ｃｙｓ）,因而产生高活力的含硒抗体酶（Ｓｅ－ａｂｚｙｍｅ）．突变的４Ａ４（ｍ４Ａ４）的ＧＰＸ活力达到了天然酶活力的１９％,并对ｍ４Ａ４的酶学性质和动力学性质进行了研究;硒代谷胱甘肽（ＧＳｅＨ）连到４Ａ４结合部位,其ＧＰＸ活力由３．８６Ｕ／μｍｏｌ提高到５９８．９Ｕ／μｍｏｌ用黄嘌呤氧化酶／次黄嘌呤为中心的心肌线粒体自由基损伤模型证明Ｓｅ－ａｂｚｙｍｅ（ｍ４Ａ４）可减轻活性氧对线粒体的损伤。     

Alkaline unfolding and salt-induced folding of arginine kinase from shrimp Feneropenaeus chinensis under high pH conditions

The structural and functional properties of arginine kinase (AK) in alkaline conditions in the absence or presence of salt have been investigated. The conformational changes of AK during alkaline unfolding and salt-induced folding at alkaline pH were monitored using intrinsic fluorescence emission, binding of the fluorescence probe 1-anilino-8-naphthalenesulfonate and circular dichroism. The results for the alkaline unfolded enzyme showed that much lower pH (11.0) was required to cause the complete loss of AK activity than was required to cause an obvious conformational change of the enzyme. Compared with the completely unfolded state in 5 M urea, the high pH denatured enzyme had some residual secondary and tertiary structure even at pH 13.0. Increasing the ionic strength by adding salt at pH 12.75 resulted in the formation of a relatively compact tertiary structure and a little new secondary structure with hydrophobic surface enhancement. These results indicate that the partially folded state formed under alkaline conditions may have similarities to the molten globule state which is compact, but it has a poorly defined tertiary structure and a native-like secondary structure.     

Chemical modification studies on arginine kinase: essential cysteine and arginine residues at the active site

Chemical modification was used to elucidate the essential amino acids in the catalytic activity of arginine kinase (AK) from Migratoria manilensis. Among six cysteine (Cys) residues only one Cys residue was determined to be essential in the active site by Tsou's method. Furthermore, the AK modified by DTNB can be fully reactivated by dithiothreitol (DTT) in a monophasic kinetic course. At the same time, this reactivation can be slowed down in the presence of ATP, suggesting that the essential Cys is located near the ATP binding site. The ionizing groups at the AK active site were studied and the standard dissociation enthalpy (ΔH°) was 12.38 kcal/mol, showing that the dissociation group may be the guanidino of arginine (Arg). Using the specific chemical modifier phenylglyoxal (PG) demonstrated that only one Arg, located near the ATP binding site, is essential for the activity of AK.     

Effects of aspartic acid and potassium chloride on arginine kinase from shrimp

The aspartic acid (Asp)-induced unfolding and the salt-induced folding of arginine kinase (AK) were studied in terms of enzyme activity, intrinsic fluorescence emission spectra, 1-anilino-8-naphthalenesulfonate (ANS) fluorescence spectra and far-UV circular dichroism (CD) spectra. The results showed that Asp caused inactivation and unfolding of AK with no aggregation during AK denaturation. The unfolding of the whole molecule and the inactivation of AK in different Asp concentrations were compared. Much lower Asp concentration was required to induce inactivation than to produce significant conformational changes of the enzyme molecule. However, with further addition of Asp, the molar ellipticity at 222 and 208 nm, the wavelength shift and the emission intensity of ANS hardly changed. Asp denatured AK was reactivated by dilution. In addition, potassium chloride (KCl) induced the molten globule state with a compact structure after AK was denatured with 7.5 mM Asp. These results collectively elucidate the osmotic effect of Asp anions for the molten globule formed during unfolding process. They also suggest that the effect of Asp differed from that of other denaturants such as guanidine hydrochloride or urea during AK folding. The molten globule state indicates that intermediates exist during AK folding.     

Kinetics of an individual transmembrane helix during bacteriorhodopsin folding

The kinetics of an individual helix of bacteriorhodopsin have been monitored during folding of the protein into lipid bilayer vesicles. A fluorescence probe was introduced at individual sites throughout helix D of bacteriorhodopsin and the changes in the fluorescence of the label were time-resolved. Partially denatured, labelled bacteriorhodopsin in SDS was folded directly into phosphatidylcholine lipid vesicles. Stopped-flow mixing of the reactants allowed the folding kinetics to be monitored with millisecond time resolution by time-resolving changes in the label fluorescence, intrinsic protein fluorescence as well as in the absorption of the retinal chromophore. Monitoring specific positions on helix D showed that two kinetic phases were altered compared to those determined by monitoring the average protein behaviour. These two phases, of 6.7 s(-1) and 0.33 s(-1), were previously assigned to formation of a key apoprotein intermediate during bacteriorhodopsin folding. The faster 6.7s(-1) phase was missing when time-resolving fluorescence changes of labels attached to the middle of helix D. The amplitude of the 0.33 s(-1) phase increased along the helix, as single labels were attached in turn from the cytoplasmic to the extracellular side. An interpretation of these results is that the 6.7 s(-1) phase involves partitioning of helix D within the lipid headgroups of the bilayer vesicle, while the 0.33 s(-1) phase could reflect transmembrane insertion of this helix. In addition, a single site on helix G was monitored during folding. The results indicate that, unlike helix D, the insertion of helix G cannot be differentiated from the average protein behaviour. The data show that, while folding of bacteriorhodopsin from SDS into lipids is a co-operative process, it is nevertheless possible to obtain information on specific regions of a membrane protein during folding in vitro.     

Molecular stabilization effects of interactions between anti-metatype antibodies and liganded antibody.

Anti-metatype antibodies have been described as antibodies which recognize ligand-induced conformational changes in the antibody variable region. Additionally, anti-metatype antibodies, produced by multiple immunizations with liganded high affinity monoclonal anti-fluorescein antibody 4-4-20, enhanced the lifetime of monoclonal antibody 4-4-20-fluorescein complex. To better understand the mechanism of the delayed dissociation rate, deuterium oxide was used to probe the liganded active site. The rate and extent of deuterium oxide-mediated fluorescence enhancement of bound ligand served to monitor the conformational dynamics of the active site in the presence and absence of anti-metatype antibodies. Results showed that anti-metatype antibodies reduced the rate and extent of deuterium oxide-mediated fluorescence enhancement of 4-4-20, a single-chain derivative of 4-4-20 (consisting of the variable domains and a polylinker), and idiotypically related monoclonal anti-fluorescein antibodies suggesting that anti-metatype stabilized the liganded active site. Size exclusion liquid chromatography was utilized to isolate the liganded antibody-anti-metatype complex. Liganded single chain antibody 4-4-20 was mixed with 10-fold molar excess anti-metatype Fab fragments, and a major complex eluted with an apparent M(r) 249,000. The apparent molecular weight of this complex inferred that one liganded single chain antibody was bound by five antimetatype Fab fragments. Spectral analysis confirmed these results and the characteristic delayed rate of ligand dissociation was also observed for the isolated complex. The results suggest that anti-metatype antibodies stabilize the liganded conformation by forming a large, stable, macromolecular complex.     

A new monoclonal anti-idiotypic catalytic antibody with a CPA-like activity.

IIF9D8, a new monoclonal anti-idiotypic catalytic antibody with a CPA esterase-like activity was elicited by ID11D7, the monoclonal competitive inhibitory antibody to CPA. The hydrolysis of hippuryl-DL-phenyllactic acid by McAb IIF9D8 follows the Michaelis-Menten kinetics. The Km value and kcat are 0.036 M and 0.598 min(-1), respectively, and the rate acceleration (kcat/kuncat) is 30500. Compared with the previous McAb 32C3 induced by polyclonal antibodies to CPA, McAb IIF9D8 shows higher catalytic efficiency The catalytic antibodies with the catalytic properties similar to natural enzymes could be obtained by this approach.     

Modification of phospholipids in erythrocyte membranes by phospholipase D. A fluorescence and ESR spectroscopic study

The conversion of more than 65% of the phospholipids in human erythrocyte membranes to phosphatidyl-methanol and phosphatidic acid by incubation with phospholipase D and methanol increased the dissociation constant of the fluorescence probe ANS compared to untreated membranes, but did not affect the number of binding sites and the limiting fluorescence enhancement at maximal binding (Imax). On the contrary, the cationic fluorescence probe dansylcadaverin showed additional binding sites without a change in Kd and an increase of Imax upon incubation with phospholipase D treated erythrocyte membranes compared to incubations of membranes with the original phospholipid pattern. The characteristic temperature-dependence of the quenching of the membrane protein fluorescence by a membrane-bound nitroxide-labeled stearic acid was not influenced by the modification of the phospholipids. A slight reduction of the order parameter, S, determined by ESR-spectroscopy with the same nitroxide spin-labeled fatty acid incorporated into modified membranes compared to controls was found at 40 degrees C, but not at 25 degrees C. The results were interpreted as an indication of membrane domains that retained their physical properties and lipid composition during the incubation with phospholipase D.     

Mechanisms of ligand binding by monoclonal anti-fluorescyl antibodies

Binding of fluorescyl ligand by five IgG anti-fluorescyl hybridoma proteins (4-4-20, 6-10-6, 20-4-4, 20-19-=1, 20-20-3) was examined. Relative reduction in fluorescence of bound fluorescein, deuterium oxide (D2O)-induced enhancement of fluorescence, and the effects of pH on binding kinetics were measured for each clone. Individual hybridoma proteins (all of which bind fluorescein with relatively high affinity) exhibited significant differences in the relative contribution of various forces (hydrophobicity, hydrogen bonding, ionic interactions) to binding and hence, affinity. The extent of such variations in binding mechanisms among monoclonal antibodies binding the same hapten is indicative of the extreme functional diversity of active sites. In addition, ligand binding by clone 20-20-3 was examined in greater detail. ABsorption spectra of ligand bound by purified intact antibody, Fab fragments, and reassociated heavy and light chains indicated that protonation of the fluorescyl ligand by a residue within the active site contributed significantly to the binding free energy. Comparative dissociation rates of fluorescein and a structural analog, rhodamine 110, were used to quantitatively substantiate the contribution of this interaction. Association and dissociation rate studies with fluorescein and antibody indicated that: 1) the active site appeared to undergo a conformational change upon ligand binding, and 2) neither intact disulfides nor intersite cooperativity affected the dissociation rate of bound ligand. Observed mechanisms of ligand binding are discussed in terms of proposed mechanisms of antibody affinity maturation and diversity.     

Fluorescence measurements of immune complexes of Mab 4-4-20 with isomeric haptens.

Relative differences in the active site environment of a monoclonal antibody when covalently bound to two isomeric haptens were studied using fluorescence quenching and lifetime measurements. Murine monoclonal antibody 4-4-20, a well-characterized high affinity antifluorescein antibody, served as the model IgG protein. Isomeric haptenic probes comparatively studied were fluorescein-5-isothiocyanate (FITC I, the immunogen) and fluorescein-6-isothiocyanate (FITC II). In kinetic binding studies, the association rate for the interaction of 4-4-20 with FITC I was greater than 2,000 times faster than the reaction with FITC II. Fluorescence lifetimes for FITC I covalently bound to 4-4-20 were 3.89 ns and 0.37 ns, indicative of hapten bound outside and inside the active site, respectively. Fluorescence lifetime for FITC II within the active site was indistinguishable from bound FITC I, indicating that interactions with active site residues which resulted in a decreased lifetime were similar for both isomers. A decreased lifetime for active site bound FITC I was consistent with the 90-95% quenching of fluorescein fluorescence. Dynamic fluorescence quenching experiments with iodide and FITC I in the active site showed no solvent accessibility, whereas bound FITC II showed significant accessibility. These results suggest that the difference in bond angle which accompanies binding of isomer II relative to isomer I within the active site probably leads to steric constraints resulting in a more open configuration of the 4-4-20 active site.     

一株抗H5亚型禽流感病毒血凝素蛋白单克隆抗体的广谱中和活性

以H5N1禽流感病毒株Ck/HK/Yu22/02作为抗原,应用常规杂交瘤技术和血凝抑制实验筛选出抗H5亚型禽流感病毒血凝素蛋白的单抗8H5,单抗8H5经免疫荧光鉴定具有很好的H5特异性.选择33株2002～2006年不同地域,不同宿主中分离的不同遗传变异亚系的H5N1病毒代表株,对单抗8H5分别进行血凝抑制实验及中和试验分析,结果显示单抗8H5对所有H5亚型病毒均有较强反应,而对非H5亚型标准病毒株均不反应,说明8H5是一株广谱性抗H5特异性中和单抗,并提示单抗8H5的HA识别表位可能是一个相当保守的中和表位.并且单抗8H5双抗夹心系统的初步评价显示了其在诊断应用上的前景.     

Hidden intermediates in Mango III RNA aptamer folding revealed by pressure perturbation

Fluorescent RNA aptamers have the potential to enable routine quantitation and localization of RNA molecules and serve as models for understanding biologically active aptamers. In recent years, several fluorescent aptamers have been selected and modified to improve their properties, revealing that small changes to the RNA or the ligands can modify significantly their fluorescent properties. Although structural biology approaches have revealed the bound, ground state of several fluorescent aptamers, characterization of low-abundance, excited states in these systems is crucial to understanding their folding pathways. Here we use pressure as an alternative variable to probe the suboptimal states of the Mango III aptamer with both fluorescence and NMR spectroscopy approaches. At moderate KCl concentrations, increasing pressure disrupted the G-quadruplex structure of the Mango III RNA and led to an intermediate with lower fluorescence. These observations indicate the existence of suboptimal RNA structural states that still bind the TO1-biotin fluorophore and moderately enhance fluorescence. At higher KCl concentration as well, the intermediate fluorescence state was populated at high pressure, but the G-quadruplex remained stable at high pressure, supporting the notion of parallel folding and/or binding pathways. These results demonstrate the usefulness of pressure for characterizing RNA folding intermediates.     

The topology of the glutamine and ATP binding sites of human asparagine synthetase.

Human asparagine synthetase was examined using a combination of chemical modifiers and specific monoclonal antibodies. The studies were designed to determine the topological relation between the nucleotide binding site and the glutamine binding site of the human asparagine synthetase. The purified recombinant enzyme was chemically modified at the glutamine binding site by 6-diazo-5-oxo-L-norleucine (DON), and at the ATP binding site by 8-azidoadenosine 5'-triphosphate (8-N3ATP). The effects of chemical modification with DON included a loss of glutamine-dependent reactions, but no effect on ATP binding as measured during ammonia-dependent asparagine synthesis. Similarly, modification with 8-N3ATP resulted in a loss of ammonia-dependent asparagine synthesis, but no effect on the glutaminase activity. A series of monoclonal antibodies was also examined in relation to their epitopes and the sites modified by the two covalent chemical modifiers. It was found that several antibodies were prevented from binding by specific chemical modification, and that the antibodies could be classified into groups correlating to their relative binding domains. These results are discussed in terms of relative positions of the glutamine and ATP binding sites on asparagine synthetase.     

Na,K-ATPase extracellular surface probed with a monoclonal antibody that enhances ouabain binding.

The Na,K-stimulated ATPase is inhibited by extracellular cardiac glycosides, which bind to the enzyme's alpha subunit. We used a monoclonal antibody, VG4, as a probe of the extracellular surface. The antibody was specific for Na,K-ATPase and bound to intact cells. The epitope was mapped to the first extracellular loop (H1-H2) of alpha, using a combination of techniques including trypsinolysis, N-terminal sequence of a fragment containing the determinant, and analysis of the effects of species-specific sequence differences. The antibody inhibited Na,K-ATPase activity under certain circumstances, indicating that the H1-H2 loop participates in conformational changes that are transmitted to the active site. Mutations in the H1-H2 loop have been shown by others to affect ouabain affinity. Ouabain and the antibody acted synergistically to inhibit the enzyme, which seemingly supported the hypothesis that the H1-H2 loop is an essential part of the cardiac glycoside binding site. Direct measurements of the binding of [3H]ouabain, however, indicated that VG4 enhanced rather than inhibited binding, presumably by promoting favorable conformation changes. The data suggest the possibility that the cardiac glycoside binding site may be intramembrane rather than extracellular.