Highly tunable thiosulfonates as a novel class of cysteine protease inhibitors with anti-parasitic activity against Schistosoma mansoni

The development of a new class of cysteine protease inhibitors utilising the thiosulfonate moiety as an SH specific electrophile is described. This moiety has been introduced into suitable amino acid derived building blocks, which were incorporated into peptidic sequences leading to very potent i.e. sub micromolar inhibitors of the cysteine protease papain in the same range as the vinyl sulfone based inhibitor K11777. Therefore, their inhibitory effect on Schistosoma mansoni, a human blood parasite, that expresses several cysteine proteases, was evaluated. The homophenylalanine side chain containing compounds 27–30 and especially 36 showed promising activities compared with K11777 and warrant further investigations of these peptidic thiosulfonate inhibitors as new potential anti-parasitic compounds.     

Dimerization of papain induced by mercuric chloride and a bifunctional organic mercurial.

The bifunctional mercurial meso-1,4-bis(acetatomercuri)-2,3-diethoxybutane and mercuric chloride are capable of dimerizing papain, by the attachment of the thiol group of two molecules of papain to each molecule of reagent. This is evident from the titration data, gel filtration and sedimentation equilibrium. The conformational change of papain necessary for this reaction is discussed.     

Attachment of acetylcholinesterase to structures of the motor endplate.

The kinetics of AChE solubilization from intact motor endplates of mouse diaphragm, by collagenase, papain and hyaluronidase, was studied in parallel with the ultrastructural localization of AChE in treated neuromuscular junctions. Hyaluronidase did not solubilize more AChE from isolated motor endplate regions than Ringer's solution itself. Residual AChE activity could be demonstrated histochemically in motor endplates even after the plateau of solubilization by collagenase or papain was reached. Less than 35% of junctional AChE is left after collagenase, and less than 20% after papain treatment, as estimated by the percentage of AChE activity left in the isolated endplate region of the diaphragm after protease treatment. Cytochemically, both proteases had a similar effect on postsynaptic AChE. Residual AChE activity was distributed randomly, adhering to the sarcolemma of junctional clefts. Presynaptic AChE localized in the gap between axon terminal and Schwann cell appears to be resistant to collagenase but not to papain treatment. The mode of AChE attachment or the composition of the intercellular material in this gap may differ from that of the primary and secondary clefts.     

Irreversible inhibition of the human placental NADP-linked 15-hydroxyprostaglandin dehydrogenase/9-ketoprostaglandin reductase by glutathione thiosulfonate

Oxidation of glutathione disulfide by a mixture of performic and hydrochloric acids leads to the formation of several compounds that are stronger inhibitors than glutathione disulfide of the placental enzyme that possess both NADP-linked 15-hydroxyprostaglandin dehydrogenase and 9-ketoprostaglandin reductase activities. The only one of these inhibitors that has been identified is glutathione thiosulfonate. The others are unstable and may include glutathione sulfinyl sulfone and glutathione disulfone. Since the enzyme appears to have a glutathione binding site in close proximity to its active site and glutathione thiosulfonate reacts with free sulfhydryl groups, the effects of this thiosulfonate on the enzyme were examined in more detail. Glutathione thiosulfonate and methyl methanethiosulfonate cause a time-dependent irreversible inhibition of both the hydroxyprostaglandin dehydrogenase and the ketoprostaglandin reductase activities, presumably by reacting with a free sulfhydryl at the prostaglandin binding site. Experiments with PGA1-glutathione show that this sulfhydryl is not necessary for the catalytic activity of the enzyme as long as the substrate can bind at the glutathione site.     

Attachment of acetylcholinesterase to structures of the motor endplate

Summary The kinetics of AChE solubilization from intact motor endplates of mouse diaphragm, by collagenase, papain and hyaluronidase, was studied in parallel with the ultrastructural localization of AChE in treated neuromuscular junctions. Hyaluronidase did not solubilize more AChE from isolated motor endplate regions than Ringer's solution itself. Residual AChE activity could be demonstrated histochemically in motor endplates even after the plateau of solubilization by collagenase or papain was reached. Less than 35% of junctional AChE is left after collagenase, and less than 20% after papain treatment, as estimated by the percentage of AChE activity left in the isolated endplate region of the diaphragm after protease treatment. Cytochemically, both proteases had a similar effect on postsynaptic AChE. Residual AChE activity was distributed randomly, adhering to the sarcolemma of junctional clefts. Presynaptic AChE localized in the gap between axon terminal and Schwann cell appears to be resistant to collagenase but not to papain treatment. The mode of AChE attachment or the composition of the intercellular material in this gap may differ from that of the primary and secondary clefts.     

Irreversible inhibition of the human placental NADP-linked 15-hydroxyrpostaglandin dehydrogenase/9-ketoprostaglandin reductase by glutathione thiosulfonate

Oxidation of glutathione disulfide by a mixture of performic and hydrochloric acids leads to the formation of several compounds that are stronger inhibitors than glutathione disulfide of the placental enzyme that posses both NADP-linked 15-hydroxypyrostaglandin dehydrogenase and 9-ketoprostaglandin reductase activities. The only one of these inhibitors that has been identified is glutathione thiosulfonate. The others are unstble and may include glutathione sulfinyl sulfone and glutathione disulfone. Since the enzyme appears to have a glutathione binding site in close proximity to its active site and glutathione thiosulfonate reacts with free sulfhydryl groups, the effects of this thiosulfonate on the enzyme were examined in more detail. Glutahione thiosulfonate and methyl methanethiosulfonate cause a time-dependent irreversible inhibition of both the hydroxyprostaglandin dehydrogenase and the ketoprostaglandin reductase activities, presumably by reacting with a free sulfhydryl at the prostaglandin binding site. Experiments with PGA-glutathione show that this sulfhydryl is not necessary for the catalytic activity of the enzyme as long as the substrate can bind at the glutahione site.     

Conversion of the active-site cysteine residue of papain into a dehydro-serine, a serine and a glycine residue.

Photolysis of papain which had been inhibited with 2-bromo-2',4'-dimethoxyacetophenone regenerated papain, but also formed [deltaSer25]-papain (i.e. papain in which the active-site cysteine residue 25 was replaced by dehydroserine) via the intermediate dehydrocysteine analogue, [deltaCys25]-papain. Reduction with sodium borohydride gave [Ser25]papain. Both [Ser25]papain and [deltaSer25]-papain had binding properties similar to those of papain, but were devoid of enzymic activity. Their fluorescence properties were also investigated. Incubation of [deltaSer25]papain at pH 9.0 gave [Gly25]papain.     

Studies on quantum dots synthesized in aqueous solution for biological labeling via electrostatic interaction

3-Mercaptopropyl acid-stabilized CdTe nanoparticles synthesized in aqueous solution are effectively bound to a biomacromolecule, papain, via electrostatic interaction. The conjugation between the nanoparticles and the papain is demonstrated by UV-Vis absorption, photoluminescence spectroscopy, transmission electron microscopy, and fluorescence micrographs. The biological activity of papain is maintained after the conjugation. The effects of the quantity of papain and the size of nanoparticles on the fluorescence characteristics of the CdTe-papain bioconjugates were studied.     

Cysteine thiosulfonate in cystine metabolism

A sulfur-containing amino acid was observed in mammalian cystine metabolism, in vitro and in vivo, which we have characterized as 2-amino, 3-(thio-thiosulfonate)propionic acid (cysteine thiosulfonate). Its biosynthetic pathway appears to initiate with the cleavage of cystine by cystathionine γ-lyase to form thiocystine, which undergoes sulfinolysis to form cysteine thiosulfonate.     

Roles of the 29-138 disulfide bond of subtype A of human alpha interferon in its antiviral activity and conformational stability

Human alpha (leukocyte) interferons contain two disulfide bonds between Cys-1 and Cys-98 and between Cys-29 and Cys-138. Reduction of interferon under native conditions leads to irreversible loss of antiviral activity; reduction in denaturant, followed by oxidation in native conditions, leads to restoration of activity. This behavior, unusual for disulfide-containing proteins, was studied by using a thiosulfonate derivative of subtype A of human alpha interferon (IFN-alpha A). The disulfide-free thiosulfonate formed at 25 degrees C has essentially no antiviral activity, while maintaining a conformation related to that of native IFN-alpha A. This species can regain activity after regeneration of its 29-138 disulfide, by thiol-disulfide interchange in native buffer. Incubation of the disulfide-free thiosulfonate under nonreducing conditions at 37 degrees C generates a monomeric species that has lost its native conformation as well as its ability to regain antiviral activity after thiol-disulfide interchange. These results explain the difficulty in obtaining, under native conditions, a reduced species that regains activity upon oxidation; complete reduction of IFN-alpha A in 100 mM 2-mercaptoethanol requires 37 degrees C, a temperature that promotes conformational decay of the disulfide-free form.     

Topology of the selectivity filter of a TRPV channel: rapid accessibility of contiguous residues from the external medium

The transient receptor potential type V5 (TRPV5) channel is a six-transmembrane domain ion channel that is highly selective to Ca(2+). To study the topology of the selectivity filter using the substituted cysteine accessibility method (SCAM), cysteine mutants at positions 541-547 were studied as heterotetramers using dimeric constructs that couple the control channel in tandem with a cysteine-bearing subunit. Whole cell currents of dimeric constructs D542C, G543C, P544C, A545C, and Y547C were rapidly inhibited by positively charged 2-(trimethyl ammonium)methyl methane thiosulfonate bromide (MTSMT), 2-(aminoethyl)methane thiosulfonate bromide (MTSEA), and 2-(trimethyl ammonium)ethyl methane thiosulfonate bromide (MTSET) reagents, whereas D542C, P544C, and A545C were inhibited only by negatively charged sodium 2-(sulfonatoethyl)methane thiosulfonate (MTSES). In contrast, the I541C dimer remained insensitive to positive and negative reagents. However, I541C/D542G and I541C/D542N dimeric constructs were rapidly (<30 s) and strongly inhibited by positively and negatively charged methane thiosulfonate reagents, suggesting that removing two of the four carboxylate residues at position 542 disrupts a constriction point in the selectivity filter. Taken together, these results establish that the side chains of contiguous amino acids in the selectivity filter of TRPV5 are rapidly accessible from the external medium, in contrast to the three-dimensional structure of the selectivity filter in K(+) channels, where main chain carbonyls were shown to project toward a narrow permeation pathway. The I541C data further suggest that the selectivity filter of the TRPV5 channel espouses a specific conformation that restrains accessibility in the presence of four carboxylate residues at position 542.     

Sulfate reduction in a cell-free system ofChlorella

Summary During sulfate reduction in a cell-free system ofChlorella activated sulfate of APS is transferred to a thiosulfonate reductase. The sulfate thus bound to the thiosulfonate reductase (i.e. bound sulfite) is reduced to bound sulfide in a ferredoxin dependent reaction. This bound sulfide can be used with O-acetylserine as acceptor for cysteine biosynthesis; serine and O-phosphoserine are not used. An assaysystem for thiosulfonate reductase activity using methylviologen dependent reduction of S₂O₄ ^2– to S^2– is developed and a procedure for isolating thiosulfonate reductase fromChlorella cells is presented. During isolation of thiosulfonate reductase a low weight molecular factor, needed for optimal enzyme activity was lost. The bound sulfite seems to be attached to this factor. Reduction of APS or GS-SO₃H to the level of S^2– is inhibited by cysteine. 50% inhibition of GS-SO₃H reduction was found at a molar cysteine concentration of 6.8×10^–5.Abbreviations APS adenosine-phosphosulfate - PAPS 3-phosphoadenosine-5-phosphosulfate - GSH reduced glutathion - GS-SO₃H S-sulfoglutathion - fd ferredoxin - Mv methylviologen - DTT dithiothreitol     

Some properties of a papain–agarose reactor provided with a pH monitor

A small reactor of immobilized papain was used to gain some knowledge about the effect of immobilization upon the reactivity of the enzyme towards one substrate and various types of inhibitors. A buffer solution containing benzoyl–arginine ethyl ester as substrate was run through a small column of papain immobilized by attachment to agarose beads. The pH of the effluent was measured continuously and provided the data used to calculate the substrate conversion during passage through the reactor. The operation of the system was checked by determining the substrate conversion as a function of flow rate. It proved to operate as theory demanded. The rate and extent of inhibition were measured after addition of various inhibitors to the buffer–substrate solution. The following quantities of immobilized papain were found to be equal within ±20% to those of the free enzyme in solution: the overall activity, the K_m of benzoyl–arginine ethyl ester, the K_i of the competitive inhibitor benzoylamino-acetonitrile, the rate of inactivation by chloroacetic acid and by chloroacetamide, the rate of activation by cysteine of the mixed disulfide of papain and cysteine, and the rate of spontaneous reactivation of the KCNO–papain adduct. The inactivation by KCNO proved to be strongly pH dependent. This may explain why the rate of the latter reaction is only 66% of the rate with free enzyme. It is concluded that the rates and equilibrium constants measured in the present reactor system are within ±20% of the values of the dissolved enzyme, provided that the reactions are not strongly pH dependent. Calculation showed there was no diffusion limitation.     

小鼠Lewis肺癌组织中糖肽的分离纯化及其对肿瘤细胞与层粘连蛋白基质粘着的影响

小鼠Lewis肺癌组织经氯仿甲醇去除脂类,用木瓜蛋白酶消化,再经Sephadex柱层析分离得到总糖肽。它有明显地抑制小鼠Lewis肺癌细胞,S180肉瘤细胞及人巨细胞肺癌细胞与层粘连蛋白(Laminin,LN)基质粘着的作用;对层粘连蛋白受体(LN-R)与其配体的识别及结合也具有同样明显的阻断效应。糖肽的上述作用均具有剂量依赖性。进一步经ConA-Sepharose CL-4B亲和层析将总糖肽分为三个部分。与ConA不结合的糖肽部分对Lewis肺癌细胞与LN基质的粘着也具有剂量性抑制作用。     

Inhibition of rhinovirus attachment by neutralizing monoclonal antibodies and their Fab fragments.

Previous molecular and immunological studies have mapped four neutralization sites on human rhinovirus type 14 (B. Sherry, A. G. Mosser, R. J. Colonno, and R. R. Rueckert, J. Virol. 57:246-257, 1986). Eight monoclonal antibodies, one pair for each of the four target sites and all belonging to a single isotype, immunoglobulin G2a, were studied under conditions which resulted in 95% neutralization of infectious viral particles. All eight antibodies shifted the isoelectric point of virions from 6.7 to much more acidic forms, ranging from pI 1.8 to 3.2. In addition, antibodies targeted against three of the four neutralization sites caused significant aggregation of virions under the neutralization conditions employed. Aggregation could be reversed by digesting virus-antibody complexes with papain. Following papain digestion, the acidic pIs of three of the neutralized virus preparations returned to neutral and infectivity was restored. Membrane-binding assays with virus neutralized with a nonaggregating antibody showed a dose-related inhibition of virus attachment to cellular receptors. Purified Fab fragments at a 13- to 61-fold-higher concentration than intact antibodies caused a comparable isoelectric shift, neutralized virions in the absence of aggregation, and interfered with attachment of virions to host cell receptors in a membrane-binding assay. These findings suggest that neutralizing antibodies interfere with the attachment of rhinoviruses to cellular receptors and that bivalent attachment of antibody is not a prerequisite for neutralization.     

Complex Effects of Papain on Function and Inhibitor Sensitivity of the Red Cell Anion Exchanger AE1 Suggest the Presence of Different Transport Subsites

Band 3 (AE1), the anion exchanger of the human erythrocyte membrane, mediates not only fluxes of small hydrophilic anions (e.g., chloride, oxalate), but also the flip-flop of long-chain amphiphilic anions (e.g., dodecylsulfate). Treatment of erythrocytes with papain, long known to inhibit the transport of the former type of anions, accelerates the transport of the latter type. In an attempt to elucidate the basis of these opposite responses to papain, several small amphiphilic arylalkyl sulfonates and -sulfates were tested for the response of their transport, via AE1, to papain. Although all these probes are most likely transported by a flux and not by flip-flop, their transport was inhibited by papain only in some cases, but accelerated in others. Different responses to papain therefore most likely do not reflect differences between transport by flux or by flip. The transports of different species of anions also differed considerably in the changes of their sensitivity, to noncovalent and some covalent inhibitors, brought about by papain treatment. While oxalate transport remained as sensitive as in native cells, transports of small amphiphilic anions lost their sensitivity to a major extent, regardless of the inhibition or acceleration of their transport by papain. The results are discussed in the light of present concepts of the structural organisation of AE1, and interpreted in terms of a model of different transport subsites for different species of anions in this transporter. Received: 20 June 2000/Revised: 1 November 2000     

Membrane anchors of alkaline phosphatase and trehalase associated with the plasma membrane of larval midgut epithelial cells of the silkworm, Bombyx mori

The larval midgut epithelial cell of the silkworm, Bombyx mori, has two forms of alkaline phosphatase and trehalase, soluble and membrane-bound. Alkaline phosphatase and trehalase of the latter form are found in the brush border membrane and the basolateral membrane, respectively. In this work we studied the membrane anchors of these membrane-bound enzymes. Alkaline phosphatase was solubilized by phosphatidyl-inositol-specific phospholipase C, but not by papain. Conversely, trehalase was released from the membrane by papain, but not by phosphatidylinositol-specific phospholipase C. Both enzymes were solubilized in an amphiphilic form with 0.5% Triton X-100 plus 0.5% sodium deoxycholate (pH 7.0). The detergent-solubilized alkaline phosphatase and trehalase were converted to hydrophilic form on incubation with phosphatidylinositol-specific phospholipase C and papain, respectively. The effects of papain on solubilization and conversion of trehalase were completely inhibited by leupeptin. These results suggest that, in the silkworm larvae, alkaline phosphatase is anchored in the brush-border membrane via a glycosyl-phosphatidylinositol, while trehalase is associated with the basolateral membrane through a hydrophobic segment of the polypeptide.     

Sulfate-reducing pathway in Escherichia coli involving bound intermediates.

Although a sulfate-reducing pathway in Escherichia coli involving free sulfite and sulfide has been suggested, it is shown that, as in Chlorella, a pathway involving bound intermediates is also present. E. coli extracts contained a sulfotransferase that transferred the sulfonyl group from a nucleosidephosphosulfate to an acceptor to form an organic thiosulfate. This enzyme was specific for adenosine 3'-phosphate 5'-phosphosulfate, did not utilize adenine 5'-phosphosulfate, and transferred to a carrier molecule that was identical with thioredoxin in molecular weight and amino acid composition. In the absence of thioredoxin, only very low levels of the transfer of the sulfo group to thiols was observed. As in Chlorella, thiosulfonate reductase activity that reduced glutathione-S-SO3- to bound sulfide could be detected. In E. coli, this enzyme used reduced nicotinamide adenine dinucleotide phosphate and Mg2+, but did not require the addition of ferredoxin or ferredoxin nicotinamide adenine dinucleotide phosphate reductase. Although in Chlorella the thiosulfonate reductase appears to be a different enzyme from the sulfite reductase, the E. coli thiosulfonate reductase and sulfite reductase may be activities of the same enzyme.     

High-pressure-induced hemolysis in papain-digested human erythrocytes is suppressed by cross-linking of band 3 via anti-band 3 antibodies

Upon exposure of human erythrocytes to a high pressure of 200 mPa, both hemolysis and vesiculation occur. The hemolysis of erythrocytes at 200 mPa was enhanced by removal of sialic acids from the membrane surface with papain. However, such enhancement was suppressed by cross-linking of band 3 via an anti-band 3 antibody (AB3A), which recognizes the exofacial domain of band 3, or by clustering of band 3 via Zn2+. On the other hand, the size of high-pressure-induced vesicles increased from 423 to 525 nm in diameter upon exposure to papain of erythrocytes, but decreased to 444 nm with following treatment with AB3A. In these vesicles, the content of spectrin relative to band 3 was almost the same. Furthermore, the band 3-cytoskeleton interactions in erythrocyte membranes remained unaltered upon treatment with papain and AB3A. Flow cytometric analysis demonstrated that papain-pretreated erythrocytes mainly produce open ghosts at 200 mPa and that the production of such open ghosts is suppressed by AB3A. Thus, upon removal of negative charges from the membrane surface, open ghosts are readily produced due to the release of larger vesicles under pressure. Upon cross-linking of band 3 via AB3A, however, the release of smaller vesicles at 200 mPa is facilitated so that high-pressure-induced hemolysis is suppressed.     

Apparent extracellular glycoprotein turnover product from Candida albicans

Low molecular weight material was isolated from the culture medium of three strains of Candida albicans. This material was produced from exponentially growing cultures and it appeared from chemical analysis to represent the carbohydrate portion of cell surface glycoproteins. The material contained a few residual amino acids which were interpreted to represent the attachment points of carbohydrate to protein and the remanents protease cleavage sites. Some of this material could be generated artificially by treating intact cells with papain.