溴化氰活化右旋糖酐对胰岛素共价修饰的研究

本文用溴化氰活化右旋糖酐对胰岛素进行共价修饰,对修饰胰岛素若干性质作了研究.修饰胰岛素无论对正常小鼠、还是对糖尿病模型小鼠的降血糖活性均较天然胰岛素明显提高;修饰胰岛素对糖尿病模型小鼠,在用药后0.5至6.5小时期间,平均降血糖幅度为70.3%,而天然胰岛素是59.1%,且作用时间延长.本文还探讨了修饰胰岛素的口服降血糖效果.     

双链聚乙二醇与超氧化物歧化酶共价结合物的理化和免疫学性质

用三聚氯氰活化单甲氧基聚乙二醇,得到了双链聚乙二醇(PEGm₂).以PEGm₂修饰牛血Cu,Zn-SOD,得到了氨基修饰率为30％,残余活力为80％的纯PEGm₂-SOD.修饰酶的荧光光谱及圆二色谱均有改变;盐酸胍变性及胃蛋白酶水解实验结果表明,修饰酶的稳定性高于天然酶;免疫学实验表明,与天然酶比较,修饰酶的免疫原性及抗原抗体反应性大为降低.     

聚乙二醇修饰超氧化物歧化酶的初步研究

目的:对玉米超氧化物歧化酶(SOD)进行共价修饰,以提高其稳定性.方法:以分子量为6000Da的活化聚乙二醇(PEG)为修饰剂,对玉米超氧化物歧化酶(SOD)进行共价修饰,并确定最佳反应条件.将天然SOD与PEG-SOD分别进行热稳定性、酸碱稳定性及抗蛋白酶稳定性的比较实验.结果:在最佳反应时间10h、最佳反应温度4℃时PEG与SOD反应获得的PEG-SOD比天然SOD在热、酸、碱及抗酶解三方面的稳定性均有不同程度的提高.结论:玉米超氧化物歧化酶经PEG修饰后稳定性显著提高.     

棕榈酰化超氧化物歧化酶的制备及性质研究

为了增强超氧化物歧化酶的稳定性,用棕榈酸对其进行了修饰,在修饰条件下,酶分子表面氨基修饰率为55％时,酶的活力回收为63％。修饰后的酶在耐热、耐酸、耐碱、抗有机溶剂变性和抗蛋白水解能力上均高于天然超氧化物歧化酶,为将超氧化物歧化酶作成实用药物和进一步扩大其应用范围创造了条件。     

不同修饰剂对尿激酶化学修饰的对比研究

近年来为了解除某些酶制剂的抗原性,提高某些酶对环境的稳定性和延长其在体内的半衰期,以充分发挥其临床效果,国内外曾用PEG,Dextran及其硫酸酯,肝素钠等水溶性大分子对某些酶制剂的自由氨基进行共价修饰,取得了较好效果。但是由于各个实验室所修饰的酶不同,所用修饰剂及其活化方法也不同,所以对这些修饰剂或活化方法的修饰效果难以进行比较。因此我们用不同修饰剂采取不同活化方法对同一种酶——尿激酶进行修     

聚乙二醇对菠萝蛋白酶的化学修饰

方法:用琥珀酸酐法活化的聚乙二醇对菠萝蛋白酶进行化学修饰,得到菠萝蛋白酶的修饰酶,对比研究三种菠萝蛋白酶:修饰酶、混合酶、天然酶的热稳定性及酸碱稳定性,考察金属离子对三种菠萝蛋白酶的影响。结果:当在55℃水浴保温100min后天然酶活力只保留20%,混合酶活力保留37%,修饰酶活力保留58%;在pH3.0-4.5及pH6.0-7.0的条件下,修饰酶活力高于天然酶活力。当Ca2 的浓度达到0.05mg/mL时,修饰酶的活力高达257.66%;当Mg2 的浓度达到0.035mg/mL时,修饰酶的活力高达147.25%。一价离子Na 对三种菠萝蛋白酶无明显影响。结论:修饰的菠萝蛋白酶对温度和pH值的稳定性均比天然酶有很大程度的提高。混合酶的活力介于天然酶和修饰酶之间说明聚乙二醇对菠萝蛋白酶有一定的保护作用。二价离子Ca2 、Mg2 对三种菠萝蛋白酶活力均有不同程度的激活作用。     

长半衰期重期人超氧化物歧化酶的研制及性质

一种双亲有机化合物聚苯乙烯马来酸丁酯（ＳＭＡ）经酰胺键与重组人铜锌超氧化物歧化酶（ｒｈＣｕ／ＺｎＳＯＤ）共价交联,制得修饰酶,当４２％游离氨基被修饰时,保留酶活力为８８％。酶蛋白主链结构在修饰前后变化不大。与天然酶相比,修饰酶的生物半衰期延长了２２倍,抗蛋白水解酶能力亦有所增强。     

基于海藻酸钠羟基改性的MPEG原位共价修饰微胶囊及抗蛋白性能

目的:通过对海藻酸钠链段羟基位点改性制备甲氧基聚乙二醇(MPEG)原位共价修饰的海藻酸钠/壳聚糖(AC)微胶囊,在保证MPEG修饰微胶囊机械强度不受影响的基础上,有效提高表面MPEG修饰密度,实现兼具良好机械稳定性及抗蛋白性能的微胶囊制备方法。方法:利用溴化氰对海藻酸钠羟基进行活化并将末端氨基的点击化学linker(BAT)接枝在主链上进而制备MPEG原位共价修饰微囊A_(B(OH))CP_N,用球磨法表征微囊机械强度,用Ig G和Fgn为模型考察微囊表面抗蛋白吸附性能,以L929细胞在其二维模拟平板膜上的黏附情况作为衡量指标,考察MPEG修饰微胶囊表面细胞粘附情况,并最终通过体内移植考察MPEG修饰微囊的生物相容性。结果:基于海藻酸钠羟基位点的MPEG原位共价修饰微胶囊能够实现与常规条件制备的微胶囊接近的机械强度;同时与对照组相比Ig G吸附量降低87.4%,Fgn吸附量降低75.5%,实现了良好的抗蛋白吸附性能;二维模拟平板膜表面L929细胞粘附情况显著改善,细胞粘附数与对照组相比降低了76.9%;体内移植结果证明MPEG修饰微囊细胞粘附极少,微囊与纤维层分离明显。结论:基于海藻酸钠羟基位点的MPEG原位修饰能够实现兼具良好机械稳定性及抗蛋白吸附性能的微胶囊。     

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。     

化学修饰解除天冬酰胺酶抗原性研究

本文报道了用活化的单甲氧基聚乙二醇PEG_2在底物保护的条件下修饰天冬酰胺酶。结果,修饰酶在抗原抗体结合能力完全消失的同时,酶活力保持30％以上,且修饰酶的抗胰蛋白酶水解能力明显增强,体外半衰期延长17倍,免疫原性显著下降。     

Essentiality of the active-site arginine residue for the normal catalytic activity of Cu,Zn superoxide dismutase.

Chemical modification of bovine and yeast Cu,Zn superoxide dismutases with phenylglyoxal diminishes the catalytic activities by greater than or equal to 98%, and treatment of these enzymes with butanedione plus borate leads to greater than or equal to 96% inactivation. The activity loss is accompanied by the modification of less than two arginine residues per subunit with no concomitant loss of Cu or Zn. The phenylglyoxal-modified enzymes require at least a 20-fold greater concentration of cyanide for 50% inhibition than do the corresponding native enzymes. Polyacrylamide-gel electrophoresis and activity staining of the phenylglyoxal-inactivated enzymes demonstrate that the residual activity is largely associated with modified forms that bear lower net positive charge than the native superoxide dismutases.     

Improvement in the persistence of microbial asparaginase and glutaminase in the circulation of the rat by chemical modifications

Three enzymes used in cancer chemotherapy (asparaginases from Escherichia coli and Erwinia carotovora and glutaminase from Achromobacter) were each reacted with four amino specific reagents (ethyl acetimidate, O-methylisourea, succinic anhydride, and formaldehyde/sodium borohydride). The half-lives of the modified enzymes measured in the blood of rats showed that guanidation, acetimidation and reductive alkylation were more likely to increase the persistence of the native enzymes than succinylation. However, the improvement in the persistence of any one enzyme after any one modification could not be predicted from the results with the others. It was concluded that changes in persistence caused by each modification were due to the different effects on the tertiary structure of each native enzyme. The advantages of chemical modification for increasing the persistence of enzymes over other methods such as encapsulation or aggregation are discussed.     

Enhanced Cofactor and Allosteric Effector Activity of 3′-Pyrophospho Coenzyme A and Its Acetate

To prepare a chemically modified urokinase that does not dissociate into two peptide fragments upon reduction of its disulfide bridge, we cross-linked the enzyme intramolecularly with various bifunctional imidoesters. The enzyme underwent the intramolecular cross-linking most moderately by the reaction at 4^QC for 5 hr with 3mm dimethyl suberimidate in 0.1 M potassium phosphate buffer (pH 9.0). The cross-linked urokinase isolated by gel filtration with a yield of 25 % showed a specific activity of 76,000 International Units/mg protein, which corresponds to 53% of that of the native enzyme. Although the modified enzyme was similar to the native urokinase in some properties such as the autocatalytic self-digestion and the low affinity to fibrin, it showed higher in vivo and in vitro stabilities than the native one.     

Modification of subsite Lys residue induced a large increase in maltosidase activity of Taka-amylase A.

A cross-linked modification of Taka-amylase A (TAA) by o-phthalaldehyde gave two enzymes, M1- and M2-TAA, which had optimum pH lower than that of native TAA by 0.5 to 1.0 pH units. The modified enzymes showed higher maltosidase activity, and produced glucose even at the initial period of hydrolysis, in contrast to the native TAA. The modification caused more than a 500-fold decrease in the k0 value of native TAA for alpha-amylase activity, but a definite increase in k0 value of 109. 1 min-1 (native TAA) to 460.0 min-1 (M1-TAA) and 147.1 min-1 (M2-TAA) for maltotriose was evidence for improvement of maltosidase activity of modified enzymes.     

Chemical modification of Escherichia coli RNA polymerase by diethyl pyrocarbonate: evidence of histidine requirement for enzyme activity and intrinsic zinc binding

RNA polymerase (RPase) from Escherichia coli contains five subunits (alpha 2 beta beta' sigma) and two intrinsic Zn ions located in the beta and beta' subunits. This enzyme was rapidly inactivated by diethyl pyrocarbonate (DEP) at pH 6.0 and 25 degrees C. The difference spectrum of the DEP-inactivated and native RPases showed a single peak at 240 nm indicating the formation of N-carbethoxyhistidines. No decrease in absorbance at 278 nm, due to O-carbethoxytyrosine, or modification of amino and sulfhydryl groups was observed. Inactivated RPase with six to nine histidines being modified could be fully reactivated by incubation with 0.5 M hydroxylamine at pH 6.0 and room temperature for 1 h. No structural difference was detected between the native and modified enzymes as evidenced by UV/visible and fluorescence spectra, sodium dodecyl sulfate-polyacrylamide gel electrophoretic pattern, or gel filtration properties. Substrate ATP at 0.11 and 1.14 mM concentrations provided, respectively, 25% and 90% protection against DEP inactivation, while template DNA did not. These results suggest that one or more histidine residues is/are in close proximity to the substrate binding site. The pH dependence of the DEP inactivation of RPase suggested the modification of histidine at the active site with a pK value of 6.9. The inactivation of RPase by DEP and the formation of N-carbethoxyhistidine displayed a similar second-order rate constant of approximately 0.9 mM-1 min-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cancer therapy with chemically modified enzymes. I. Antitumor properties of polyethylene glycol-asparaginase conjugates

The covalent attachment of monomethoxypolyethylene glycol (PEG) to asparaginases from Escherichia coli and Vibrio succinogenes by new coupling methodology produced conjugates that are active, stable, without significant immune response, and with greatly extended plasma half-lives in mice. Therapeutic efficacies were greater for the PEG-asparaginases than for the unmodified asparaginases in mice infected with the L5178Y lymphosarcoma or the 6C3HED tumor. Large single doses of native or modified enzymes were more effective against tumors than the same amount of enzyme given in smaller doses over several days.     

A kinetic and fluorimetric investigation of papain modified at tryptophan-69 and -177 by N-bromosuccinimide

A systematic study of the modification of papain (its thiol group protected as a disulphide with mercaptoethanol) by N-bromosuccinimide, showed that 2 molar equiv. modified tryptophan-69 and 4 molar equiv. modified tryptophan-69 and -177. The Michaelis parameters for the catalysed hydrolysis of N-benzyloxycarbonylglycine p-nitrophenyl ester by these modified enzymes were determined. The enzymic activity of the modified enzymes was not seriously impaired, but modification of tryptophan-177 raised the apparent pK(a) of the acidic limb of the pH profile by more than 1 pH unit for both k(cat.) and k(cat.)/K(m). The fluorescence spectra (excitation at 288nm) of the modified enzymes showed that tryptophan-69 contributed about 8% to the fluorescence intensity, whereas tryptophan-177 contributed about 46% at neutral pH. However, the contribution of tryptophan-177 was quenched at low pH and its fluorescence intensity showed sigmoidal pH-dependence, with an apparent pK(a) of 4.2. Histidine-159, which is in close contact with tryptophan-177, is considered to be the residue responsible for the fluorescence quenching. When tryptophan-177 was modified, presumably generating a less hydrophobic micro-environment, the apparent pK(a) determined kinetically was raised to about 5.4. By comparing the Michaelis parameters of native papain, papain modified at tryptophan-69 and papain modified at tryptophan-69 and -177 with N-benzyloxycarbonylglycylglycine amide and N-benzyloxycarbonylglycyltryptophan amide, tryptophan-69 and tryptophan-177 were shown to be structural features of the S(2) and S(1)' subsites respectively.     

Superactivation of thermolysin by acylation with amino acid N-hydroxysuccinimide esters.

Synthesis of a series of active N-hydroxysuccinimide esters of aliphatic and aromatic amino acids has yielded a new class of reagents for the covalent modification of proteolytic enzymes such as thermolysin. The activities of aliphatic acyl amino acid thermolysins are from 1.7 to 3.6 times greater than that of the native enzyme when hydrolyzing durylacryloyl-Gly-Leu-NH2, the substrate employed most widely. By comparison, the aromatic acylamino acid derivatives are "superactive," their activities being as much as 70-fold greater. Apparently, the aromatic character of the amino acid introduced is a critical variable in the determination of the functional response. The increased activity is completely restored to that of the native enzyme by deacylation with nucleophiles, such as hydroxylamine, and the rate of restoration of native activity is a function of the particular acyl group incorporated. Preliminary evidence regarding the chemical properties of the modified enzyme suggests that tyrosine, rather than lysine, histidine, or arginine, may be the residue modified. The functional consequences of successive modification with different reagents, moreover, indicate that each of them reacts with the same protein residue. The competitive inhibitors beta-phenyl-propionyl-Phe and Zn-2+ do not prevent modification with these active esters. Hence, the site(s) of their inhibitory action differ(s) from that at which modification occurs. The structure of the substrate is also a significant variable which determines the rate at which each acyl amino acid thermolysin hydrolyzes peptides. Depending on the particular substrate, the activity of aromatic derivatives can be as much as 400-fold greater than that of the native enzyme, and the resultant activity patterns can be ordered in a series characteristic for each enzyme derivative.     

Thrombolytic action of urokinase preparation covalently bound to modified thrombin

Urokinase was covalently bounded with modified thrombin. Thrombin was modified by carbodiimide and 1, 12-dodecamethylenediamine. In this conjugate thrombin is not catalytically active and does not induce platelets aggregation. The catalytic properties of modified urokinase do not essentially differ from native enzyme but its thermostability increases. The modified urokinase thrombolytic effect is at least 10-fold higher than the native one. In femoral arteries of experimental thrombosis the conjugate urokinase-thrombin brings about total thrombolytic effect as early as 1.5 hours after injection (2500 IU per 1 kg of the animals weight). The causes of the observed effect were discussed.     

Peroxidase activity of catalase modified by progesterone

Catalase conjugates with 3, 7, 9 and 42 progesterone molecules were obtained by the reaction between the enzyme and N-oxy-succinimide ether of 3-0-carboxymethyloxime of progesterone. The enzyme modified by 42 progesterone molecules is effective in o-dianisidine oxidation by hydrogen peroxide and has a kcat/KM value of 512 M-1 s-1. The catalase conjugates with 3, 7 and 9 progesterone molecules exhibit a high activity during o-dianisidine oxidation by cumene hydroperoxide. The activity of conjugates is higher than that of the native non-modified enzyme in the same reaction. The maximum effectiveness was observed for catalase modified by 7 progesterone molecules. This conjugate is characterized by kcat/KM of 99,000 M-1 s-1 at 30 degrees C. The effect of the degree of enzyme modification on the kinetic parameters of o-dianisidine oxidation by H2O2 and cumene hydroperoxide is discussed.