Elucidation of the mechanism and end products of glutaraldehyde crosslinking reaction by X-ray structure analysis

Glutaraldehyde has been used for several decades as an effective crosslinking agent for many applications including sample fixation for microscopy, enzyme and cell immobilization, and stabilization of protein crystals. Despite of its common use as a crosslinking agent, the mechanism and chemistry involved in glutaraldehyde crosslinking reaction is not yet fully understood. Here we describe feasibility study and results obtained from a new approach to investigate the process of protein crystals stabilization by glutaraldehyde crosslinking. It involves exposure of a model protein crystal (Lysozyme) to glutaraldehyde in alkaline or acidic pH for different incubation periods and reaction arrest by medium exchange with crystallization medium to remove unbound glutaraldehyde. The crystals were subsequently incubated in diluted buffer affecting dissolution of un-crosslinked crystals. Samples from the resulting solution were subjected to protein composition analysis by gel electrophoresis and mass spectroscopy while crosslinked, dissolution resistant crystals were subjected to high resolution X-ray structural analysis. Data from gel electrophoresis indicated that the crosslinking process starts at specific preferable crosslinking site by lysozyme dimer formation, for both acidic and alkaline pH values. These dimer formations were followed by trimer and tetramer formations leading eventually to dissolution resistant crystals. The crosslinking initiation site and the end products obtained from glutaraldehyde crosslinking in both pH ranges resulted from reactions between lysine residues of neighboring protein molecules and the polymeric form of glutaraldehyde. Reaction rate was much faster at alkaline pH. Different reaction end products, indicating different reaction mechanisms, were identified for crosslinking taking place under alkaline or acidic conditions.     

Some studies of crosslinking chitosan-glutaraldehyde interaction in a homogeneous system.

Chitosan dissolved in acetic acid reacted with glutaraldehyde solution, ranging in concentration from 0.10 to 25.0 x 10(-2) mol dm3. The modified polymers were characterized by means of carbon, hydrogen and nitrogen elemental analysis, scanning electron microscopy, X-ray diffractometry, 13C nuclear magnetic resonance (NMR), infrared and Raman spectroscopies. The uptake of metallic cations in aqueous medium was checked through copper. The obtained data from 13C NMR, infrared and Raman spectroscopies evidenced the formation of an ethylenic double bond in the chitosan glutaraldehyde interaction. These data suggest that free pendant amine groups of chitosan polymer interact with the aldehydic group of the glutaraldehyde to form stable imine bonds, due to the resonance established with adjacent double ethylenic bonds. The crosslinking is formed by the nonuniform length of chains and by terminal unities. The crosslinking formation can involve two chitosan unities belonging, or not, to the same polymeric chain. The sequence of reactions was established for a chitosan:glutaraldehyde molar proportion of 1:20. The degree of crystallinity and particle size decreased as the amount of glutaraldehyde was increased in the polymer. Physical and chemical properties are not just affected for the chitosan glutaraldehyde reaction, but are also affected strongly by the dissolution of the natural chitosan.     

Novel method of enzymes stabilization on crosslinked thermosensitive carriers

In this paper an immobilization of invertase on thermosensitive copolymers of N-isopropylacrylamide and 2-hydroxyethyl methacrylate or glycidyl methacrylate modified by aminolysis is evaluated. The method is based on the swelling properties of stimuli-sensitive polymers, which work like a pump that sucks up the enzyme on cooling and then on subsequent crosslinking of the enzyme. The attention was focused on the properties of the carrier–enzyme systems, particularly on the effect of crosslinking on their stability. Activity of TG8-NH₂ carrier was very low and independent on concentration of glutaraldehyde used, but carriers TH8 and TH8-NH₂ were more active, especially when 1.0 and 2.5 vol.% of glutaraldehyde were used. It was also observed, that preparations crosslinked by glutaraldehyde were more stable than preparations without crosslinking agent.     

Glutaraldehyde: behavior in aqueous solution, reaction with proteins, and application to enzyme crosslinking

Glutaraldehyde possesses unique characteristics that render it one of the most effective protein crosslinking reagents. It can be present in at least 13 different forms depending on solution conditions such as pH, concentration, temperature, etc. Substantial literature is found concerning the use of glutaraldehyde for protein immobilization, yet there is no agreement about the main reactive species that participates in the crosslinking process because monomeric and polymeric forms are in equilibrium. Glutaraldehyde may react with proteins by several means such as aldol condensation or Michael-type addition, and we show here 8 different reactions for various aqueous forms of this reagent. As a result of these discrepancies and the unique characteristics of each enzyme, crosslinking procedures using glutaraldehyde are largely developed through empirical observation. The choice of the enzyme-glutaraldehyde ratio, as well as their final concentration, is critical because insolubilization of the enzyme must result in minimal distortion of its structure in order to retain catalytic activity. The purpose of this paper is to give an overview of glutaraldehyde as a crosslinking reagent by describing its structure and chemical properties in aqueous solution in an attempt to explain its high reactivity toward proteins, particularly as applied to the production of insoluble enzymes.     

The role of dicarbonyl compounds in non-enzymatic crosslinking: a structure-activity study

The Maillard reaction is a complex network of reactions that has been shown to result in the non-enzymatic crosslinking of proteins. Recent attention has focussed on the role of alpha-dicarbonyl compounds as important in vivo contributors to protein crosslinking but, despite extensive research, the molecular mechanisms of the crosslinking reaction remain open to conjecture. In particular, no relationship between the structure of the carbonyl-containing compounds and their activity as crosslinking agents has been established. In an effort to elucidate a structure-reactivity relationship, a wide range of dicarbonyl compounds, including linear, cyclic, di-aldehyde and di-ketone compounds, were reacted with the model protein ribonuclease A and their crosslinking activity assessed. Methylglyoxal and glutaraldehyde were found to be the most efficient crosslinkers, whilst closely related molecules effected crosslinking at a much lower rate. Cyclopentan-1,2-dione was also shown to be a reactive crosslinking agent. The efficiency of methylglyoxal and glutaraldehyde at crosslinking is thought to be related to their ability to form stable heterocyclic compounds that are the basis of protein crosslinks. The reasons for the striking reactivity of these two compounds, compared to closely related structures is explained by subtle balances between competing pathways in a complex reaction network.     

The subcellular distribution of glucocorticoid-receptor complexes as studied by chemical crosslinking of intact HTC cells

Treatment of intact HTC cells with glutaraldehyde results in redistribution of glucocorticoid binding sites between cytosolic and nuclear fractions. The decrease in cytosolic receptors and their accumulation at the nuclear level were found to be directly related to the glutaraldehyde concentrations employed in our procedure and inversely related to the cell density of samples. When the data from eleven separate experiments were combined, and analyzed by linear regression of cytosolic and nuclear levels of receptor complexes vs the ratios between the DNA and glutaraldehyde concentration of our samples, two lines were obtained whose intercepts on the ordinate yielded values of cytosolic and nuclear receptors corresponding to 37.5 and 62.5% of the total cellular pool, respectively. When we compared the subcellular redistribution of glucocorticoid receptor to that of the cytosolic enzyme lactate dehydrogenase upon HTC cell crosslinking with glutaraldehyde, we found that the cytosolic and nuclear levels of the enzyme were 53.2 and 46.8% of the total content, respectively. If the subcellular distribution of glucocorticoid receptor is corrected for the artefactual redistribution induced by crosslinking, using the values obtained for lactate dehydrogenase, it can be concluded that glucocorticoid receptors in HTC cells are distributed between cytosol and nuclei in a ratio which is about 2:1. Our findings lend further support to theconclusion that only a portion of glucocorticoid receptor is cytosolic in intact cells.     

Electrochemical evaluation of glucose oxidase immobilized by different methods

Glucose oxidase electrodes were constructed on a platinum screen using polyacrylamide gel, glutaraldehyde crosslinking, and glutaraldehyde crosslinking with +0.04 volts dc on the platinum screen as the methods of enzyme immobilization. The electrodes were evaluated in an electrochemical cell for the oxidation of glucose at the enzyme electrode and the reduction of oxygen at a platinum auxiliary electrode, using constant current voltametry or under external load operation. The method of immobilization affected the extrapolated opencircuit potential as well as the half-cell potential and the steady current under external load operation. The charged glutaraldehyde electrode gave the best current performance; however, the small output (microamps) indicated that major problems in electron transfer from an enzyme catalyst to an external circuit must be resolved before such electrodes can be used in practical application.     

Crosslinking of Chitosan with Dialdehyde Derivatives of Nucleosides and Nucleotides. Mechanism and Comparison with Glutaraldehyde

In medical and pharmaceutical applications, chitosan is used as a component of hydrogels–macromolecular networks swollen in water. Chemical hydrogels are formed by covalent links between the crosslinking reagents and amino functionalities of chitosan. To date, the most commonly used chitosan crosslinkers are dialdehydes, such as glutaraldehyde (GA). We have developed novel GA like crosslinkers with additional functional groups–dialdehyde derivatives of uridine (oUrd) and nucleotides (oUMP and oAMP)–leading to chitosan-based biomaterials with new properties. The process of chitosan crosslinking was investigated in details and compared to crosslinking with GA. The rates of crosslinking with oUMP, oAMP, and GA were essentially the same, though much higher than in the case of oUrd. The remarkable difference in the crosslinking properties of nucleoside and nucleotide dialdehydes can be clearly attributed to the presence of the phosphate group in nucleotides that participates in the gelation process through ionic interactions with the amino groups of chitosan. Using NMR spectroscopy, we have not observed the formation of aldimine bonds. It can be concluded that the real number of crosslinks needed to cause gelation of chitosan chains may be less than 1%.     

金属硫蛋白导向血栓单抗化学偶联体的制备及性质研究

金属硫蛋白（ｍｅｔａｌｏｔｈｉｏｎｅｉｎ,简称ＭＴ）是一类低分子量、富含半胱氨酸的蛋白质,由于１个ＭＴ分子可结合７个金属离子,因此ＭＴ分子具有很强的金属结合特性［１,２］．本文一方面利用ＭＴ分子的高金属结合性能,另一方面利用苏州医学院血液研究所研制成...     

The reactions between formaldehyde,glutaraldehyde and osmium tetroxide,and their fixation effects on bovine serum albumin and on tissue blocks

Summary The reactions between osmium tetroxide and glutaraldehyde and formaldehyde were investigated. It was found that they react together to form intermediate products which then break down to form osmium black. Glutaraldehyde reacts much more rapidly with osmium tetroxide than formaldehyde. The rates of the reactions are increased by increasing the glutaraldehyde concentration or adding bovine serum albumin to the reaction mixture. The reaction rates increase with temperature. The mixtures of fixatives were also tried on tissues and the results paralleled the model experiments. The crosslinking of bovine serum albumin by osmium tetroxide, formaldehyde and glutaraldehyde singly and in mixtures was quantitatively assessed by viscosimetry, gel filtration and disc electrophoresis coupled with densitometry. The crosslinking of bovine serum albumin by pairs of fixatives was less than that produced by the most effective of the pair. After 5 min reaction osmium tetroxide was the most effective crosslinking agent according to viscosimetric experiments, but after one hour's reaction with bovine serum albumin, glutaraldehyde was revealed as the most effective crosslinking agent by gel filtration and electrophoresis.     

L-DOPA production from tyrosinase immobilized on nylon 6,6

The production of L-DOPA immobilized on chemically modified nylon 6,6 membranes was studied in a batch reactor. Tyrosinase was immobilized on nylon using glutaraldehyde as a crosslinking agent. The effects of membrane pore size and glutaraldehyde concentration upon enzyme uptake and L-DOPA production were investigated. Enzyme uptake was unaffected by glutaraldehyde concentration; approximately 70% uptake was observed when 25% w/v (group 1), 5% (group 2), and 3% (group 3) glutaraldehyde were used, indicating that glutaraldehyde was in excess. Similarly, uptake was the same for membranes with 0.20 and 10 mum pore sizes.Membranes produced using different levels of glutaraldehyde exhibited dramatically different capacities for L-DOPA production, despite the fact that enzyme uptake was equivalent. Membranes from groups 2 and 3 (5% and 3% glutaraldehyde) produced L-DOPA at a rate of 1.70 mg L(-1) h(-1) over 170 h in a 500-mL batch reactor. However, no free L-DOPA was detected when group 1 membranes were used. Experimental evidence suggests that L-DOPA was produced, but remained bound to these membranes via excess glutaraldehyde left over from the immobilization process. Membrane pore size also effected L-DOPA production; less production was observed when 10-mum membranes were used, despite equivalent enzyme uptake. The observed difference in production may be due to differences in the pore density on the two types of membranes which could affect the access of the substrate to the immobilized enzyme.The results of these studies indicate that tyrosinase can be effectively immobilized on nylon 6,6. L-DOPA production was optimal when 0.20-mum-pore-size membranes were activated with 3-5% glutaraldehyde. Stability studies indicated a 20% reduction in activity over 14 days when the immobilized enzyme was used under turnover conditions. (c) 1996 John Wiley & Sons, Inc.     

Enhancement of the detection of alkali-resistant phosphoproteins in polyacrylamide gels

Following their separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, labeled proteins obtained from cultured canine prostatic epithelial cells incubated with [35S]-methionine and [32P]phosphate were subjected to alkali treatment, a method that is currently used to detect phosphotyrosine-containing proteins. Significant amounts of 35S-labeled material were lost during the alkali treatment. The crosslinking of proteins within the gels by glutaraldehyde treatment eliminated protein losses and did not alter the efficiency of phosphoester bond hydrolysis by alkali treatment. Consequently, the time required to detect alkali-resistant phosphoproteins by autoradiography was greatly reduced. Prostatic phosphoproteins were also shown to contain phosphotyrosine, indicating the presence of tyrosine protein kinase activity in these proliferating epithelial cells.     

尺寸均一的壳聚糖微球的制备及其作为胰岛素控释载体的研究

采用新型微孔膜乳化技术制备了载胰岛素的壳聚糖微球。研究表明,要制备粒径均一的壳聚糖微球,必须将亲水性膜修饰成疏水性;制得的微球粒径和所采用的膜孔径之间存在很好的线性关系,使得微球粒径可控;以胰岛素为模型药物,主要考察了交联剂用量和交联时间对微球表面形态、药物包埋率和微球体外释药特性的影响。结果表明当氨基与醛基的摩尔比为1∶0.7、交联时间为1h时,所得载药微球的包埋率最高,随着戊二醛用量的增加和交联时间的延长,药物体外释放速率减慢。     

The effect of crosslinking of thin filament with glutaraldehyde on the contractility of muscle fiber

The effect of crosslinking of F-actin with glutaraldehyde on the contractility of muscle ghost fiber containing reconstituted thin filament (i.e. F-actin-tropomyosin-troponin complex) and irrigated with myosin was investigated. The results show that: (i) crosslinking inhibited development of isometric tension and shortening of the fiber in the presence of MgATP, (ii) superprecipitation of the complex of myosin with crosslinked thin filament was considerably delayed, (iii) crosslinking inhibited neither binding of myosin heads to the filament nor activation of myosin ATPase. It is suggested that alterations of actin structure due to the formation of intra- and/or intermonomer crosslinks can essentially affect the process of contractility.     

Inhibition of sliding movement of F-actin by crosslinking emphasizes the role of actin structure in the mechanism of motility

The effects of crosslinking of monomeric and polymeric actin with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), disuccinimidyl suberate (DSS) and glutaraldehyde on the interaction with heavy meromyosin (HMM) in solution and on the sliding movement on glass-attached HMM were examined. The Vmax values of actin-activated HMM ATPase decreased in the following order: intact actin = EDC F-actin greater than DSS actin greater than glutaraldehyde F-actin = glutaraldehyde G-actin greater than EDC G-actin. The affinity of actin for HMM in the presence of ATP decreased in the following order: DSS actin greater than glutaraldehyde F-actin = glutaraldehyde G-actin greater than intact actin greater than EDC F-actin greater than EDC G-actin. However, sliding movement was inhibited only in the case of glutaraldehyde-crosslinked F and G-actin and EDC-crosslinked G-actin. Interestingly, after copolymerization of "non-motile" glutaraldehyde or EDC-crosslinked monomers with "motile" monomers of intact actin sliding of the copolymers was observed and its rate was independent of the type of crosslinked monomer, i.e. of the manner of their interaction with HMM. These data strongly indicate that inhibition of the sliding of actin by crosslinking cannot be explained entirely by changes in the Vmax value or affinity for myosin heads. We conclude that movement is generated by interaction of myosin with segments of F-actin containing a number of intact monomers, and the mechanism of inhibition involves an effect of the crosslinkers on the structure of F-actin itself.     

Mechanical properties and water vapor transmission in some blends of cassava starch edible films

The continuous increase of consumer interest in quality, convenience and food quality has encouraged further research into edible films and coatings from natural polymers, such as polysaccharides. Ecoefficient products are the new generation of biobased products prepared with sustainable materials, that agree with ecological and economic requirements including environmentally acceptable disposal of post-user waste. The numerous potential applications of natural polymers such as polysaccharides stimulated the study with edible films based on cassava starch. Blends of glycerol (GLY) and polyethylene glycol (PEG) as plasticizers, and glutaraldehyde (GLU) as crosslinking agent were prepared in order to determine the mechanical properties and water vapor transmission of those films. A response surface methodology was applied on the results to identify the blend with the best mechanical properties and lowest water vapor transmission. The crosslinking effect of glutaraldehyde in the films can be observed. The plasticizing action of polyethylene glycol was restrained by more than 0.5 g of glutataraldehyde. The use of glycerol was less evident for this property even after 284 h of contact time with water vapor.     

A new method for the study of glutaraldehyde-induced crosslinking properties in proteins with special reference to the reaction with amino groups.

A new method for the study of glutaraldehyde reactions with proteins is presented. Glutaraldehyde-reacted protein is in a first step isolated and then in a second step reacted with aminohexyl groups bound to Sepharose particles. This reaction is linear at low protein concentrations and proceeds rapidly when proteins are reacted with 100-fold and 1000-fold molar excess of glutaraldehyde. This method enables the study of glutaraldehyde-induced crosslinking properties of the modified proteins as an isolated property with high reliability.     

耐热性碱性磷酸酯酶作为非放射性标记物的研究

通过生物素与亲和素－酶复合物系统或地高辛与抗地高辛－酶复合物系统可把酶间接标记到探针上．Ｒｅｎｚ等通过不同的化学方法直接把酶标记到探针上［１～３］．耐热性碱性磷酸酯酶ＦＤ－ＴＡＰ（ｔｈｅｒｍｏｓｔａｂｌｅａｌｋａｌｉｎｅｐｈｏｓｐｈａｔａｓｅ）具有耐...     

氨基化硅胶载体固定化纤维素酶的研究

用硅胶作载体,戊二醛作交联剂,制备了固定化的纤维素酶。对制备固定化纤维素酶的偶联剂浓度、pH、给酶量3个影响因素进行了研究,通过正交试验优化得出最佳的固定化条件:交联剂戊二醛浓度为1%,固定化pH值为5,固载量为每克载体100mg纤维素酶。     

氨基树脂固定化L-苏氨酸醛缩酶及其应用*

L-苏氨酸醛缩酶(L-Threonine aldolase,L-TA)可以催化甘氨酸和醛合成β-羟基-α-氨基酸。β-羟基-α-氨基酸具有两个手性中心,是多种手性药物的中间体。但是,游离的L-TA难以重复利用,分离纯化困难,严重阻碍了工业化应用。固定化技术可以有效解决这些问题。利用氨基树脂NAA固定化来源于Bacillus nealsonii的L-苏氨酸醛缩酶,采用戊二醛作为交联剂,经过条件优化确定最佳固定化条件为:加酶量13 U、载体量0.6 g、0.4%(V/V)戊二醛、活化时间2 h、pH 8.5、35℃、固定化5 h。在此条件下,固定化酶酶活回收率为85.7%。在30℃下半衰期可达59天,为游离酶的6.5倍。将其应用于合成L-syn-对甲砜基苯丝氨酸,使用460 h后,残余酶活为79.4%。进一步开发了载体再利用策略,将失活固定化酶表面的氨基用戊二醛活化后,再与新的游离酶进行固定化,实现载体的再利用。利用该方法载体可重复利用两次,制备的固定化酶仍能使用460 h。该方法大大降低了固定化成本,为固定化L-TA的工业化应用打下坚实的基础。