Interactions between human blood serum inhibitors and native and modified dextran proteinases--terrilytin and trypsin]

Interactions between native terrylytin and trypsin and their derivatives modified by water-soluble dextrans on one hand and human blood serum inhibitors on the other, were studied. It was shown that modification of the enzymes results in changes in the type of their inhibition by blood serum due to a decrease of affinity of polymeric enzyme forms for alpha 2-macroglobulin and alpha 1-antitrypsin. The inhibition constants for native and modified forms of terrylytin and trypsin were calculated. The effects of steric and electrostatic factors on the interaction between inhibitors of blood and polymeric forms of proteinases are discussed.     

Kinetic properties of butyrylcholinesterases immobilised on pH-sensitive field-effect transistor surface and inhibitory action of steroidal glycoalkaloids on these enzymes

The inhibitory action of steroid glycoalkaloids alpha-solanine, alpha-chaconine and tomatine on horse and human serum butyryl cholinesterases immobilized on the pH-sensitive field-effect transistors has been studied. Using acetyl- and butyryl choline as substrates, the optimal pH and the apparent kinetic parameters (< K(m) >, < V(max) >) of immobilized butyryl cholinesterases have been calculated in the absence of inhibitors. The affinity of each enzyme to glycoalkaloids has been estimated from calculation of apparent inhibition constants < K(i) > and inhibition coefficients i(0.5). Application of the studied cholinesterases for biosensoric determination of glycoalkaloids in the wide range of concentrations (10(-7)-10(-4) M) in different media has been discussed.     

Human cationic and anionic trypsins: differences of interaction with alpha 1-proteinase inhibitor

Human cationic (trypsin 1) and anionic (trypsin 2) trypsins were obtained by controlled activation of purified trypsinogens 1 and 2, respectively. The interactions of trypsin 1 and trypsin 2 with human alpha 1-proteinase inhibitor (alpha 1PI) were analysed and compared by studies in vitro. The enzymatic activity and inhibitory capacity measurements were assessed using Glp-Gly-Arg-Nan as substrate. The association rate constants showed that the inhibition of trypsin 2 occurred more than 10 times faster than that of trypsin 1. The equimolar complexes obtained between either trypsin and alpha 1PI were visualized by electrophoresis followed by immunoblotting. The inhibition of the two trypsins was temporary i.e. the complexes trypsin 1-alpha 1PI and trypsin 2-alpha 1PI broke down with time yielding inactive alpha 1PI (Mr 50,000) and active enzyme. But the stability time for trypsin 1-alpha 1PI was much larger than that of trypsin 2-alpha 1PI. In vivo, alpha 1PI is not able to control the activity of trypsin 1 except when alpha 2-macroglobulin (alpha 2M) is already saturated. According to the delay times of inhibition calculated from normal concentrations in serum, alpha 1PI inhibits trypsin 2 as fast as alpha 2M inhibits trypsin 1. These results suggest that a significant role can be assigned to alpha 1PI in the inhibition of trypsin 2 in physiological conditions and of trypsin 1 in pathological ones.     

Study of the complex between porcine plasmin and alpha2-macroglobulin (author's transl)]

Porcine plasmin (EC 3.4.21.7) is obtained from plasminogen activated by human urokinase. This enzyme can bind, in an equimolecular ratio, to an alpha2-macroglobulin isolated from porcine serum. The number of active sites of plasmin has been determined through a burst titration of nitroaniline during the presteady-state hydrolysis of an amide substrate (N-alpha-carbobenzoxy-L-arginine-p-nitroanilide). The kinetic constants relative to a very sensitive ester substrate (N-alpha-carbobenzoxy-L-lysine nitrophenylester) hydrolysis have been measured. The binding of plasmin to alpha2-macroglobulin results in a complete inhibition of proteolytic activity, a reduction of active sites number and a decrease of esterolytic activity towards this substrate. In the complex, the residual activity (about 60%) is protected from protein inhibitors. Absorbance difference spectra show that 1 mol of alpha2-macroglobulin binds 1 mol of plasmin and 2 mol of trypsin. When plasmin is first bound to alpha2-macroglobulin, only 1 mol of trypsin can gain access tothe second site without removing the plasmin, showing that a steric hindrance is implicated in the inhibition performed by alpha2-macroglobulin binding.     

Kinetics of trypsin inhibition by its specific inhibitors

The kinetics of inhibition of trypsin by its specific inhibitors, pancreatic trypsin inhibitor, ovomucoid trypsin inhibitor, and soybean trypsin inhibitor, has been studied by following the hydrolysis of benzoylarginine ethyl ester in the presence of the inhibitor, and the results have been analyzed with the method described previously [Tian & Tsou (1982) Biochemistry 21, 1028]. The results obtained are consistent with the following: (a) The enzyme binds with the pancreatic inhibitor irreversibly to form an inactive complex. (b) The binding with the ovomucoid inhibitor to form the inactive complex is reversible. (c) An intermediate is formed before the relatively stable inactive complex with the soybean inhibitor, and both steps are reversible. The respective microscopic rate constants are determined by suitable plots of the apparent rate constants under different substrate and inhibitor concentrations. The second-order rate constants for the initial binding step thus obtained are in accord with the apparent inactivation rate constants determined by measuring the activity remaining with a stopped-flow apparatus equipped with a multimixing system after the enzyme-inhibitor mixture has been incubated for different time intervals.     

DTNB对人肌肌酸激酶不可逆抑制作用的研究

本文研究了DTNB对人肌肌酸激酶的不可逆抑制作用.研究结果表明,与兔肌肌酸激酶不同,人肌肌酸激酶分子中有四个可反应SH.用邹承鲁作图法定量处理结果表明,在这四个可反应的SH中,有一个快反应SH,两个慢反应SH且这两个慢反应SH是酶的必需基团,此外还有一个反应很慢的SH.用邹承鲁提出的在抑制剂存在条件下,酶活性不可逆改变动力学方法,测定了一系列动力学常数,并对DTNB的作用机制进行了探讨.     

Interaction of ovomucoid from duck egg white with serine proteinases

The interaction of highly purified duck egg white ovomucoid with trypsin and chymotrypsin was studied. It was found that the ovomucoid molecule contains two equally effective trypsin-binding sites which, in their turn, comprise lysine residues and one independent chymotrypsin-binding site. The values of inhibition constants were determined and the changes in free energy, enthalpy and entropy during the ovomucoid interaction with trypsin and chymotrypsin were established. It was shown that the inhibitor affinity for the enzymes does not change at low degrees of free amino groups modification.     

Effect of experimental conditions on strong biocomplimentary pairing in high-performance monolithic disk affinity chromatography

The effect of flow-rate on quantitatively determined binding parameters for several biocomplementary pairs in affinity mode high-performance monolithic disk affinity chromatography (HPMDAC) has been investigated using frontal analysis approach. Affinity interactions were evaluated from linearized adsorption isotherms and dynamic dissociation constants of the complexes K(diss.) and the theoretical adsorption capacities Q(max) were calculated. HPMDAC isolation of a typical protein trypsin from both buffered solution and artificial mixture as well as biospecific extraction of antibodies against bovine serum albumin and recombinant protein G from such complex mixtures as blood serum and cellular lysate were examined. Immobilized counterparts soybean trypsin inhibitor, bovine serum albumin, and human immunoglobulin G were used in chromatographic experiments. The maximum adsorption capacities obtained at different flow-rates were compared with those determined at static conditions. The dependence of quantitative parameters on the surface density of immobilized ligands has also been explored. Finally, a series of experiments was carried out to evaluate the dependence of dynamic affinity binding on temperature for two complementary pairs.     

Effect of temperature and pH on carbamoylation and phosphorylation of serum cholinesterases. Theoretical interpretation of activation energies in complex reactions

1. The effect of temperature and pH was studied on the kinetics of inhibition of horse serum and human serum cholinesterase by four organophosphorus compounds and five carbamates. 2. For all compounds, and at each pH and temperature, the inhibition followed the kinetics of a bimolecular reaction with the inhibitor in excess, and with a negligible concentration of the Michaelis complex. 3. The second-order rate constants (k(a)) for inhibition of human serum cholinesterase by one organophosphate and one carbamate increased from 5 degrees to 40 degrees C with an apparent activation energy of 46kJ/mol (11kcal/mol). 4. The k(a) constant for inhibition of horse serum cholinesterase increased with temperature from 5 degrees to 30 degrees C, and then decreased from 30 degrees to 40 degrees C. The theoretical interpretation of such an unusual effect of temperature is derived. 5. The increase of k(a) with pH (human serum cholinesterase) followed the dissociation curve for a single group on the enzyme (pK7.5). 6. Rate constants for decarbamoylation (k(+3)) were determined, and the time-course of inhibition was calculated from the k(a) and k(+3) constants.     

Chlorpheniramine binding to human serum albumin by fluorescence quenching measurements.

The binding of chlorpheniramine to human serum albumin has been studied by fluorescence quenching, as a function of temperature; the experimental data could only be fitted to the Stern-Volmer modified equation. A statistical analysis of the results was performed in order to determine the significance of the constants calculated by this equation, as well as their thermodynamic parameters. The chlorpheniramine binding to human serum albumin accounts for almost half of the binding of this antihistaminic agent to human plasma proteins.     

The substrate specificity of trypsin. The interrelationship between the structure and reactivity for quasi-substrates, derivatives of O-alkylmethylphosphonic acid and carboxylic acids

The kinetics of trypsin phosphorylation by thioesters of O-n-alkylmethylphosphonic acids, and reactivation of corresponding phosphoryl enzymes as well as kinetics of trypsin-catalyzed hydrolysis of p-nitrophenylcarboxylates have been studied. The rate constants for phosphorylation and dephosphorylation of trypsin depend on hydrophobicity of non-polar fragments in both substrate series in the same degree. On the other hand, the deacylation rate constants for a series of acyl trypsins do not change significantly while the apparent Michaelis constants change consistently with variations of non-polar acyl substituent. The study of substrate specificity of trypsin in terms of the transition state theory has allowed to elucidate the basis for low reactivity of trypsin towards the quasisubstrates.     

The inhibition of proteolytic enzyme activity by humic acids]

The inhibitory effect of peat humic acids on the hydrolysis of N-acetyl-L-tyrosine ethyl ester and N-benzoyl-L-leucine methyl ester by alpha-chymotrypsin and subtilism has been studied. Samples of humic acids with M(W) approximately 18,000 have been used in experiments. The results of kinetic studies indicates the mixed type of inhibition of proteinase activity by humic acids. The meanings of inhibition constants under the action of humic acids on alpha-chymotrypsin and subtilism have been calculated.     

Inhibition of Human Blood Acetylcholinesterase and Butyrylcholinesterase by Some Alkaloids

A comparative study has been carried out on effects of berberine (diisoquinoline alkaloid) and sanguinarine and chelidonine (benzophenanthridine alkaloids( on erythrocyte acetylcholinesterase and serum butyrylcholinesterase from human blood. The studied alkaloids have been shown to be strong reversible inhibitors of the cholinesterase activity. Acetylcholinesterase is more sensitive to their action, than butyrylcholinesterase. The type of reversible inhibition was determined, and inhibitor constants were calculated. It is revealed that the character of inhibition is identical for the both cholinesterases. Berberine and sanguinarine are competitive-noncompetitive inhibitors, whereas chelidonine, a competitive inhibitor.     

Conditions which affect initiation of animal cell division by trypsin and thrombin

It has been well documented that trypsin or thrombin initiate proliferation of quiescent secondary chick embryo cells. However, there has been less certainty about the ability of these proteases to initiate division of quiescent mammalian cells. Accordingly, we studied the conditions under which quiescent chick embryo (CE), mouse embryo (ME), and human diploid foreskin (HF) cells respond to trypsin or thrombin Extended culture of these cell strains in serum-free medium increased the initiation of cell division by both proteases. Under these conditions, CE cell number was increased 90% over controls by trypsin and 70% by thrombin. In contrast, quiescent ME and HF cells both responded better to thrombin than trypsin, giving maximal increases, respectively, of 70 and 40% over controls with thrombin and 22 and 14% with trypsin. Calf serum inhibited the initiation of these cell strains, particularly the ME cells, by both trypsin and thrombin. This inhibition of initiation could be attributed to decreased proteolytic activity in the case of trypsin, but not thrombin In contrast to the cell strains tested, quiescent cultures of the 3T3 cell line showed no detectable increase in cell number with trypsin or thrombin in the absence of serum, and only a slight increase in cell number with thrombin in the presence of serum. However, in the presence of plasma, 3T3 cell number increased up to 20% with thrombin Initiation of cell division by proteases has been reported and confirmed mostly for early passage cell strains rather than cell lines. Our experiments with CE cells indicate that this is possibly the result of a rapid decline in protease responsiveness upon serial subculture. With these cells we found a decline in response first to trypsin, then thrombin, and finally serum Throughout these studies, we compared the ability of trypsin and thrombin to initiate cell division under various conditions. We found several differences between the two proteases, indicating that they initiate cell division by somewhat different mechanisms.     

Different sensitivity to trypsin of the human platelet plasma and intracellular membrane Ca2+ pumps

The Ca2+ pumps associated with human platelet plasma and intracellular membranes have been further characterized by their sensitivity to trypsin. (a) Tryptic degradation of the Ca2+-ATPases has been followed by immunoblotting. It resulted in fragmentation into peptides of 80, 55, 35, and 24 kDa for both enzymes. Subcomplete hydrolysis obtained with a ratio of trypsin/membrane protein of 0.05-0.1 for the two Ca2+ pumps resulted in the total disappearance of the 100-, 80-, and 35-kDa fragments. However, maximum degradation was reached within 1 min for the intracellular enzyme but needed 5 min of incubation for the plasma membrane enzyme. (b) This effect of trypsin has been correlated with its effect on both the Ca2+-ATPase activities. The plasma membrane enzyme showed a maximum inhibition of 50-60% which was obtained using a trypsin/protein ratio of 0.1 and 5 min of incubation. A much higher trypsin sensitivity was observed for the intracellular enzyme because the maximum inhibition reached 80% after only 1 min of incubation. (c) Finally, the two Ca2+ transport systems studied showed different trypsin reactivities; the Ca2+ uptake by the plasma membrane vesicles was inhibited by 20-25%, and this maximum inhibition was observed after 5 min of incubation with trypsin. In contrast, the Ca2+ transport associated with the intracellular membrane vesicles was difficult to detect after trypsin treatment. Taken together, the results show that the two Ca2+ pumps can be distinguished by their trypsin sensitivity.     

A STUDY OF THE EQUILIBRIUM BETWEEN THE SO CALLED "ANTITRYPSIN" OF THE BLOOD AND TRYPSIN

1. The retarding effect of plasma on the action of trypsin can be measured quantitatively. 2. The nature of the reaction involved in effecting the retardation has been subjected to an experimental study. 3. Evidence is presented which indicates that the equilibrium between the inhibitive agent and trypsin is reached practically instantaneously and is rapidly and completely reversible. 4. This equilibrium has been studied by experiments in which we have observed (1) the effect of adding increasing amounts of plasma to a constant amount of trypsin, (2) the effect of varying the amount of trypsin while the plasma was constant, (3) the effect of dilution on the trypsin-plasma mixture. 5. The results of these experiments are discussed and it is stated that they are in quantitative agreement with the law of mass action. 6. An equation was found which fits the curves for the experiments mentioned in (4). This equation was developed from the assumption that 1 molecule of trypsin combined with 1 molecule of inhibitor to form 1 molecule of trypsin-inhibitor compound. The agreement between the results calculated by this equation and the observed results is satisfactory. It is pointed out that the equation contains two arbitrary constants and the bearing this fact may have on the calculated results is discussed. 7. We conclude from the results of our study that we have adduced evidence which suggests the following statement regarding the so called "antitryptic" property of blood. The inhibitive agent and trypsin combine to form an inactive but dissociable compound. The reaction in equilibrium is expressed by the equation Trypsin + inhibitor ⇌ trypsin-inhibitor The conditions of equilibrium are apparently governed by the law of mass action. The behavior of the equilibrium is therefore similar to the behavior of other equilibria between different inhibitive agents and enzymes discussed in the paper.     

Properties and immunochemical reactivities of carboxy-modified human serum albumin.

Seven carboxy modified and four amino modified derivatives of human serum albumin have been prepared and studied by optical rotatory dispersion measurements, gel filtration, immunoelectrophoresis, immunodiffusion and by use of an ammonium sulphate technique. It is found that carboxy groups are of major importance for the maintenance of the structure and function of human serum albumin, and that carboxy modification has a much more profound effect than amino modification has to the same relative extent.     

Use of diafiltration in the study of interactions between technetium (95mTcO4-) and albumin

Reversible binding of pertechnetate (95mTcO-4) by human serum albumin (HSA) has been investigated by "wash-in" experiments, in the presence of a large excess of HSA. Equilibrium constants have been determined in the range of temperature between 5 and 37 C. Thermodynamic parameters of the process have been calculated. The marked influence of temperature on the association reaction should be taken into consideration when carrying out investigations on the metabolism of technetium in poikilotherms.     

Inhibition of human pancreatic proteinases by human plasma alpha2-antiplasmin and antithrombin

Human plasma alpha1-antitrypsin inhibits human pancreatic trypsin, chymotrypsin and elastase, which are massively released into the blood stream during acute pancreatitis. To examine whether the plasma proteins of individuals with genetic deficiency of alpha1-antitrypsin are protected against the deleterious action of these enzymes by other inhibitors, we have tested their inhibition by alpha2-antiplasmin and antithrombin. We have determined the inhibition rate constants kass and calculated d(t), the in vivo inhibition time. Surprisingly, trypsin is inhibited faster by alpha2-antiplasmin [kass=2.5 x 10(6) M(-1)S(-1), d(t)=2.3 s] and antithrombin [kass=1.7 x 10(5) M(-1)s(-1), d(t)=5.8 s] than by alpha1-antitrypsin [d(t)=17 s or 116 s in alpha1-antitrypsin-sufficient or alpha1-antitrypsin-deficient individuals, respectively]. Low molecular weight heparin accelerates the inhibition of trypsin by antithrombin by a factor of 16 [d(t)=0.36 s]. Antithrombin and alpha2-antiplasmin are not physiological inhibitors of chymotrypsin and elastase. These enzymes are, however, physiologically inhibited by alpha1-antitrypsin and alpha1-antichymotrypsin even in alpha1-antitrypsin-deficient individuals. We conclude that (i) low molecular weight heparin may be helpful in the management of acute pancreatitis, and (ii) genetically determined alpha1-antitrypsin deficiency probably does not lead to a significantly increased risk of plasma protein degradation during this disease.     

Structural basis for accelerated cleavage of bovine pancreatic trypsin inhibitor (BPTI) by human mesotrypsin

Human mesotrypsin is an isoform of trypsin that displays unusual resistance to polypeptide trypsin inhibitors and has been observed to cleave several such inhibitors as substrates. Whereas substitution of arginine for the highly conserved glycine 193 in the trypsin active site has been implicated as a critical factor in the inhibitor resistance of mesotrypsin, how this substitution leads to accelerated inhibitor cleavage is not clear. Bovine pancreatic trypsin inhibitor (BPTI) forms an extremely stable and cleavage-resistant complex with trypsin, and thus provides a rigorous challenge of mesotrypsin catalytic activity toward polypeptide inhibitors. Here, we report kinetic constants for mesotrypsin and the highly homologous (but inhibitor sensitive) human cationic trypsin, describing inhibition by, and cleavage of BPTI, as well as crystal structures of the mesotrypsin-BPTI and human cationic trypsin-BPTI complexes. We find that mesotrypsin cleaves BPTI with a rate constant accelerated 350-fold over that of human cationic trypsin and 150,000-fold over that of bovine trypsin. From the crystal structures, we see that small conformational adjustments limited to several side chains enable mesotrypsin-BPTI complex formation, surmounting the predicted steric clash introduced by Arg-193. Our results show that the mesotrypsin-BPTI interface favors catalysis through (a) electrostatic repulsion between the closely spaced mesotrypsin Arg-193 and BPTI Arg-17, and (b) elimination of two hydrogen bonds between the enzyme and the amine leaving group portion of BPTI. Our model predicts that these deleterious interactions accelerate leaving group dissociation and deacylation.