Resolution of protein disulphide-isomerase and glutathione-insulin transhydrogenase activities by covalent chromatography

A thermostable alkaliphilic protein-disulfide isomerase from Bacillus subtilis DR8806: cloning, expression, biochemical characterization and molecular dynamics simulation

Disulfide bonds are among the most important factors related to correct folding of the proteins. Protein disulfide isomerase (PDI) is the enzyme responsible for the correct formation and isomerization of these bonds. It is rarely studied so far and none of them showed industrial properties. In this study, the gene encoding for a putative PDI from Bacillus subtilis DR8806 was identified, cloned and expressed in Escherichia coli. It was encoded a 23.26kDa protein. The enzyme was purified by GST affinity chromatography with a specific activity of 1227u/mg. It was active and stable over a wide range of temperature (20-85°C) and pH (4.5-10) with an optimum at 65°C and pH 5.5. Its activity was enhanced by Mn²⁺ and Co²⁺ while Ag⁺ and Zn²⁺ decreased it. Some of the known PDI inhibitors such as Tocinoic acid and Bactiracin did not affect its activity. In-silico analysis shows the five amino acids changes in the protein sequence regarding to the consensus sequence of PDIs, have a positive impact toward the protein thermal stability. This was further confirmed by molecular dynamics simulations. By considering the overall results, the enzyme might be a potential candidate for applications in the respective industries.

Protein disulfide isomerase: a critical evaluation of its function in disulfide bond formation

Disulfide bond formation is probably involved in the biogenesis of approximately one third of human proteins. A central player in this essential process is protein disulfide isomerase or PDI. PDI was the first protein-folding catalyst reported. However, despite more than four decades of study, we still do not understand much about its physiological mechanisms of action. This review examines the published literature with a critical eye. This review aims to (a) provide background on the chemistry of disulfide bond formation and rearrangement, including the concept of reduction potential, before examining the structure of PDI; (b) detail the thiol-disulfide exchange reactions that are catalyzed by PDI in vitro, including a critical examination of the assays used to determine them; (c) examine oxidation and reduction of PDI in vivo, including not only the role of ERo1 but also an extensive assessment of the role of glutathione, as well as other systems, such as peroxide, dehydroascorbate, and a discussion of vitamin K-based systems; (d) consider the in vivo reactions of PDI and the determination and implications of the redox state of PDI in vivo; and (e) discuss other human and yeast PDI-family members.

Inactivation of protein disulfide isomerase by alkylators including alpha,beta-unsaturated aldehydes at low physiological pHs

Protein disulfide isomerase (PDI) is known to contain the thioredoxin box motif with a low pKa cysteine residue. To investigate the reactivity of PDI with thiol modifiers at low physiological pHs, either the reduced (PDIred) or oxidized form (PDIoxid) of PDI was exposed to various alkylating ragents. When PDI was incubated with iodoacetamide at pH 6.3 for 30 min at 38 degrees C, a remarkable inactivation (>90%) of PDIred was caused by iodoacetamide (IC50=8 microM). However, PDIoxid was only slightly inactivated (approximately 18%) by iodoacetamide. Similarly, PDIred was significantly inactivated by N-ethylmaleimide (NEM), but PDIoxid was not. When the inactivation by these alkylators was analyzed by pseudo-first order kinetics, NEM (k3=1.75x10(-2) s(-1); K(i)=124 microM) was observed to be more potent than iodoacetamide (k3=9.1x10(-3) s(-1); K(i)=311 microM). Interestingly, the inactivation of PDIred by iodoacetamide was greater at pH 6.3 than pH 7.0, in contrast to a similar inactivation potency of NEM at both pHs. Moreover, the maximal inactivation of PDIred or PDIoxid by iodoacetamide was mainly observed around pH 6.0. In addition, PDIred was found to be inactivated by acrolein (IC50=10 microM) at pH 6.3, and this inactivation was also greater at pH 6.3 than at pH 7. Based on these results, we suggest that PDIred is susceptible to inactivation by alkylators including endogenous alpha,beta-unsaturated aldehydes at low physiological pHs.

Simultaneous existence of cinnamomin (a type II RIP) and small amount of its free A- and B-chain in mature seeds of camphor tree

Cinnamomin, a type II ribosome-inactivating protein (RIP), was isolated from the mature seeds of camphor tree (Cinnamomum camphora). In this paper, small amount of free A- and B-chain of cinnamomin were found to be present in the mature seed cell of C. camphora besides the intact cinnamomin. Our results demonstrated that camphorin, a type I RIP previously reported to coexist with cinnamomin in the seeds of C. camphora, actually was the A-chain of cinnamomin. The percentage of free A- and B-chain in the total cinnamomin was 2.6-2.8% in the seed extract. Of these free A- and B-chain approximate 80% already existed in the seed cell, only about 20% were produced during the purification operation. As the enzymatic activity to reduce disulfide bond of cinnamomin in the seed extract of C. camphora was detected, we proposed that the free A- and B-chain were derived from the enzymatic reduction of the interchain disulfide bond of cinnamomin. It was demonstrated that the endogenous type II RIPs of several plant species, such as Cinnamomum porrectum, Cinnamomum bodinieri and Ricinus communis, could be enzymatically reduced into the free A- and B-chain in their respective seed cells. The function of the free A-chain in the seed cell and the possibility that metabolic enzymes might be involved in the reduction of the interchain disulfide bond of type II RIPs in vivo are discussed.

Sulfhydryl regulation of L-selectin shedding: phenylarsine oxide promotes activation-independent L-selectin shedding from leukocytes

The L-selectin adhesion molecule mediates leukocyte recruitment to inflammatory sites and lymphocyte trafficking through the peripheral lymph nodes. In response to leukocyte activation, L-selectin is proteolytically released from the cell surface, disabling leukocytes from the subsequent L-selectin-dependent interactions. We have found that L-selectin shedding is sensitive to sulfhydryl chemistry; it is promoted by thiol-oxidizing or -blocking reagents and inhibited by reducing reagents. Phenylarsine oxide (PAO), a trivalent arsenical that interacts with vicinal dithiols, is most potent in inducing rapid shedding of L-selectin from isolated neutrophils, eosinophils, and lymphocytes as well as from neutrophils in whole blood. PAO does not cause cell activation, nor does it interfere with integrin function or alter the expression of several other cell surface molecules at the low concentrations that induce L-selectin shedding. PAO is not required to enter the cell to induce L-selectin shedding. TAPI-2 ((N-(D,L-[2-(hydroxyaminocarbonyl)-methyl]-4-methylpentanoyl)-L-3-(tert-butyl)-alanyl-l -alanine, 2-aminoethyl amide), which has previously been shown to inhibit the activation-dependent L-selectin shedding, is also capable of inhibiting PAO-induced L-selectin shedding. We hypothesize that PAO-induced L-selectin shedding involves a regulatory molecule, such as protein disulfide isomerase (PDI), an enzyme that plays a role in the formation and rearrangement of disulfide bonds, contains PAO-binding, vicinal dithiol-active sites, and is expressed on the neutrophil surface. Cell surface expression of PDI, L-selectin shedding induced by PDI-blocking Abs and by bacitracin, a known inhibitor of PDI activity, and direct binding of PDI to PAO, provide supporting evidence for this hypothesis.

The essential function of protein-disulfide isomerase is to unscramble non-native disulfide bonds

Protein-disulfide isomerase (PDI) is an abundant protein of the endoplasmic reticulum that catalyzes dithiol oxidation and disulfide bond reduction and isomerization using the active site CGHC. Haploid pdi1 delta Saccharomyces cerevisiae are inviable, but can be complemented with either a wild-type rat PDI gene or a mutant gene coding for CGHS PDI (shufflease). In contrast, pdi1 delta yeast cannot be complemented with a gene coding for SGHC PDI. In vitro, shufflease is an efficient catalyst for the isomerization of existing disulfide bonds but not for dithiol oxidation or disulfide bond reduction. SGHC PDI catalyzes none of these processes. These results indicate that in vivo protein folding pathways contain intermediates with non-native disulfide bonds, and that the essential role of PDI is to unscramble these intermediates.

Characterization of the covalent chromatography of thymidylate synthase on thiopropyl-Sepharose 6B

We have examined the covalent chromatography of Lactobacillus casei thymidylate synthase on thiopropyl-Sepharose 6B resin. This enzyme is a dimer of identical subunits, each of which contains one active site that features a catalytic sulfhydryl group (Cys-198). Reversible coupling was achieved via the attack of one of the enzyme's two catalytic cysteine residues, causing displacement of 2-thiopyridone, the reactive moiety of the resin. To establish the usefulness of this matrix for immobilization and the conditions required for chromatography, model studies were conducted with 2,2'-dithiodipyridine. The chemical modification of thymidylate synthase with 2,2'-dithiodipyridine was shown to be specific for the catalytic sulfhydryl groups of the native dimer, titrating 1.51 sulfhydryl groups, while 2.93 cysteines were modified in the GnHCl-denatured protein. The former reaction, which resulted in total loss of enzyme activity, was reversible with complete recovery of control activity within 30 min after addition of 100 mM 2-mercaptoethanol. Characterization of the protein pools generated in the covalent chromatography procedure indicated that the enzyme fraction washing through the column without attachment had substantially lower catalytic and ligand binding activities than the original protein stock; conversely, the enzyme fraction eluted from the column by 2-mercaptoethanol exhibited higher levels of these activities. Gel electrophoresis studies further illustrated that the unique application of the covalent chromatography technique described herein fractionated homogeneous thymidylate synthase protein into enzyme pools exhibiting distinct biochemical properties. As immobilization reaction times were increased beyond 6 h, the coupling of thymidylate synthase was demonstrated to occur through more than one enzymic sulfhydryl group. Interestingly, no covalent coupling was detected in attempts using activated thiol-Sepharose 4B, a result underlining the importance of the structure of the resin linker arm in enzyme immobilization.

The reactivities and ionization properties of the active-site dithiol groups of mammalian protein disulphide-isomerase

1. The number of reactive thiol groups in mammalian liver protein disulphide-isomerase (PDI) in various conditions was investigated by alkylation with iodo[14C]acetate. 2. Both the native enzyme, as isolated, and the urea-denatured enzyme contained negligible reactive thiol groups; the enzyme reduced with dithiothreitol contained two groups reactive towards iodoacetic acid at pH 7.5, and up to five reactive groups were detectable in the reduced denatured enzyme. 3. Modification of the two reactive groups in the reduced native enzyme led to complete inactivation, and the relationship between the loss of activity and the extent of modification was approximately linear. 4. Inactivation of PDI by alkylation of the reduced enzyme followed pseudo-first-order kinetics; a plot of the pH-dependence of the second-order rate constant for inactivation indicated that the essential reactive groups had a pK of 6.7 and a limiting second-order rate constant at high pH of 11 M-1.s-1. 5. Since sequence data on PDI show the presence within the polypeptide of two regions closely similar to thioredoxin, the data strongly indicate that these regions are chemically and functionally equivalent to thioredoxin. 6. The activity of PDI in thiol/disulphide interchange derives from the presence of vicinal dithiol groups in which one thiol group of each pair has an unusually low pK and high nucleophilic reactivity at physiological pH.

Purification and characterization of protein disulphide-isomerase from the unicellular green alga Chlamydomonas reinhardii. A 120 kDa dimer antigenically distinct from the vertebrate enzyme

Protein disulphide-isomerase (PDI) has been isolated from the unicellular green alga Chlamydomonas reinhardii and purified by (NH4)2SO4 precipitation, gel filtration and DEAE-Sephacel, hydroxyapatite and f.p.l.c. chromatography. The active algal enzyme is a 120 kDa dimer with a subunit molecular mass of 60 kDa when determined by SDS/PAGE. Although similar in size to the previously isolated vertebrate PDIs, the algal enzyme is antigenically distinct, polyclonal antibodies against the algal PDI showing no cross-reactivity with the vertebrate enzyme on immunoblots, and vice versa. The anti-(algal PDI) antiserum did not inhibit algal PDI activity, and C. reinhardii PDI could be immobilized on anti-PDI-Protein A-Sepharose in active form. In contrast with the situation in vertebrates, where PDI functions as a subunit of prolyl 4-hydroxylase, the C. reinhardii PDI is not associated with the algal prolyl 4-hydroxylase.

Protein disulphide-isomerase from human placenta and rat liver. Purification and immunological characterization with monoclonal antibodies

The purification of human placenta and rat liver protein disulphide-isomerase (PDI, EC 5.3.4.1) and the production of a panel of monoclonal antibodies against these proteins are described. The physical and enzymic properties of human PDI and rat PDI were similar; immunological characterization revealed the presence of unique, as well as shared, antigenic determinants. Although purified rat liver PDI was present as three forms differing slightly in Mr value, evidence was presented that the multiple forms represent proteolytic degradation products of a single 59,000-Mr species. Purified human PDI had an apparent Mr of 61,200. Two of the monoclonal antibodies against human PDI partially inactivated the enzyme, and one of these in indirect immunoprecipitation led to the precipitation of all glutathione:insulin transhydrogenase activity from a crude extract of human placenta. Results of immunofluorescence experiments with HT-29 human colon carcinoma cells were consistent with localization of PDI in the nuclear membrane and cell cytoplasm.

Protein disulfide-isomerase retains procollagen prolyl 4-hydroxylase structure in its native conformation

Protein disulfide-isomerase was isolated as a homogeneous protein from 15-day-old chick embryos. The enzyme has a molecular weight of 56,000 in SDS-polyacrylamide gel electrophoresis. Its Km value for randomly cross-linked ribonuclease, a protein used as a substrate for the enzyme, was 0.3 microM, and the Km value for DTT was 1.0 microM. Its optimum pH was 7.5 and its optimum temperature, 33 degrees C. The maximal velocity of pure protein disulfide-isomerase from chick embryos under optimal conditions was about 29,000 units/g. Protein disulfide-isomerase was able to activate purified prolyl 4-hydroxylase 2- to 3-fold, the activation being higher for enzyme stored for a longer time. This activation is probably due to the repairing of disulfide exchanges occurring in the prolyl 4-hydroxylase structure during purification and storage. Prolyl 4-hydroxylase activity was very stable in microsomes, however, and protein disulfide-isomerase was unable to increase the microsomal prolyl 4-hydroxylase activity, suggesting that prolyl 4-hydroxylase retains its native conformation in microsomes. Protein disulfide-isomerase was able to reactivate prolyl 4-hydroxylase inactivated by mild H2O2 treatment. The activity obtained after this treatment and protein disulfide-isomerase incubation corresponded to the amount of prolyl 4-hydroxylase tetramer found after H2O2 treatment. The data suggest that protein disulfide-isomerase is able to activate only the tetramer part of the enzyme preparation.(ABSTRACT TRUNCATED AT 250 WORDS)

The thiol-proteindisulfide oxidoreductase in human mononuclear cells of blood and bone marrow

The in vivo function of the thiol-proteindisulfide oxidoreductase (TPO, EC 1.8.4.2; proteindisulfide isomerase, EC 5.3.4.1) in biosynthesis of immunoglobulin was investigated by studying the enzyme content in human lymphoid and other cells by an immunocytochemical method. In contrast to peripheral blood, B lymphocytes which showed no or no demonstrable TPO, normal as well as malignant bone marrow plasma cells (all Ig classes) were found to contain abundant amounts of this enzyme. TPO containing plasma cells were identified by double-staining techniques. This finding suggests that TPO is involved in the terminal step of B cell differentiation and immunoglobulin biosynthesis. Besides plasma cells, approximately 10% of mononuclear marrow cells as yet unidentified medium-sized and large cells, exhibited also strong anti-TPO reactivity. Furthermore, using surface-cytoplasmic double staining methods, monocytes from human peripheral blood could be identified to represent the only cytoplasmic TPO-containing normal mononuclear blood cells.

Nonspecific reaction of a thiol: protein disulfide oxidoreductase with the disulfide bonds of insulin

A thiol: protein disulfide oxidoreductase from bovine liver was isolated after separation from protein disulfide isomerase. The enzyme, after activation (reduction) with glutathione, was reacted with stoichiometric amounts of insulin and the sulfhydryl groups of the partially reduced hormone were labeled with iodo (l-14C)acetamide. After separation of the insulin chains, the radioactivity was found in both the peptides, with a ratio A-chain/B-chain equal to 2/1.

Production and characterization of a monoclonal antibody to rat liver thiol: protein-disulfide oxidoreductase/glutathione-insulin transhydrogenase

Rat liver thiol:protein-disulfide oxidoreductase/glutathione-insulin transhydrogenase (glutathione:protein disulfide oxidoreductase, EC 1.8.4.2) was purified and found to give two bands on sodium dodecyl sulfate polyacrylamide gel electrophoresis. A monoclonal antibody was produced against this enzyme preparation and found to remove all the insulin degrading activity of purified preparations of the enzyme. This monoclonal antibody was also found to react with the two different forms of the enzyme observed on gel electrophoresis. These results suggest that glutathione-insulin transhydrogenase can exist in more than one state.

Protein disulphide-isomerase of chick-embryo tendon

Protein disulphide-isomerase can be partially purified from the high-speed-supernatant fraction of extensively disrupted chick-embryo tendon tissue. The catalytic properties of the preparation resemble those of the enzyme from mammalian liver. Gel electrophoresis and isoelectric focusing show the enzyme to be very acidic, with pI 4.4 +/- 0.3. Gel filtration indicates an Mr for the active enzyme of 140 000. The enzyme can be partially purified by preparative gel filtration or isoelectric focusing, but its limited stability has prevented purification to homogeneity; active fractions from both gel filtration and isoelectric focusing show two major polypeptide components by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. The major polypeptides present in partially purified preparations have Mr 45 000 and 55 000; the latter band co-distributes with the enzyme activity in fractionations by both gel filtration and isoelectric focusing. The subcellular location of the enzyme cannot be established from work on homogenates of whole tissue, which are extensively disrupted. In homogenates from isolated tendon cells, the enzyme is located in a vesicle fraction that is excluded from Sepharose 2B but is of low density and can only be sedimented at very high speeds. This fraction is identified as deriving from the endoplasmic reticulum on the grounds of marker-enzyme studies and electron microscopy.

Immunological identity between bovine preparations of thiol:protein-disulphide oxidoreductase, glutathione-insulin transhydrogenase and protein-disulphide isomerase

Five preparations of bovine thiol:protein-disulphide oxidoreductase/glutathione-insulin transhydrogenase (EC 1.8.4.2) and one preparation of bovine liver protein-disulphide isomerase (EC 5.3.4.1) from four different laboratories showed immunological identity in double immunodiffusion and rocket-line immunoelectrophoresis. Consequently, thiol:protein-disulphide oxidoreductase/glutathione-insulin transhydrogenase and protein-disulphide isomerase, formerly classified as two separate enzymes, should be considered as alternative activities of the same enzyme.

Structural properties of homogeneous protein disulphide-isomerase from bovine liver purified by a rapid high-yielding procedure

Protein disulphide-isomerase from bovine liver was purified to homogeneity as judged by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, two-dimensional electrophoresis and N-terminal amino acid analysis. The preparative procedure, a modification of that of Carmichael, Morin & Dixon [(1977) J. Biol. Chem. 252, 7163-7167], is much faster and higher-yielding than previous procedures, and the final purified material is of higher specific activity. The enzyme has Mr 57 000 as determined by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, both in the presence and in the absence of thiol compounds. Gel-filtration studies on Sephadex G-200 indicate an Mr of 107 000, suggesting that the native enzyme is a homodimer with no interchain disulphide bonds. Ultracentrifugation studies give a sedimentation coefficient of 3.5S, implying that the enzyme sediments as the monomer. The isoelectric point, in the presence of 8 M-urea, is 4.2, and some microheterogeneity is detectable. The amino acid composition is comparable with previous analyses of this enzyme from bovine liver and of other preparations of thiol:protein disulphide oxidoreductases whose relation to protein disulphide-isomerase has been controversial. The enzyme contains a very high proportion of Glx + Asx residues (27%). The N-terminal residue is His. The pure enzyme has a very small carbohydrate content, determined as 0.5-1.0% by the phenol/H2SO4 assay. Unless specific steps are taken to remove it, the purified enzyme contains a small amount (5 mol/mol of enzyme) of Triton X-100 carried through the purification.

Kinetics and specificity of homogeneous protein disulphide-isomerase in protein disulphide isomerization and in thiol-protein-disulphide oxidoreduction

The protein disulphide-bond isomerization activity of highly active homogeneous protein disulphide-isomerase (measured by re-activation of 'scrambled' ribonuclease) is enhanced by EDTA and by phosphate buffers. As shown for previous less-active preparations, the enzyme has a narrow pH optimum around pH 7.8 and requires the presence of either a dithiol or a thiol. The dithiol dithiothreitol is effective at concentrations 100-fold lower than the monothiols reduced glutathione and cysteamine. The enzyme follows Michaelis-Menten kinetics with respect to these substrates; Km values are 4,620 and 380 microM respectively. The enzyme shows apparent inhibition by high concentrations of thiol or dithiol compounds (greater than 10 X Km), but the effect is mainly on the extent of reaction, not the initial rate. This is interpreted as indicating the formation of significant amounts of reduced ribonuclease in these more reducing conditions. The purified enzyme will also catalyse net reduction of insulin disulphide bonds by reduced glutathione (i.e. it has thiol:protein-disulphide oxidoreductase or glutathione:insulin transhydrogenase activity), but this requires considerably higher concentrations of enzyme and reduced glutathione than does the disulphide-isomerization activity. The Km for reduced glutathione in this reaction is an order of magnitude greater than that for the disulphide-isomerization activity, and the turnover number is considerably lower than that of other enzymes that can catalyse thiol-disulphide oxidoreduction. Conventional two-substrate steady-state analysis of the thiol:protein-disulphide oxidoreductase activity indicates that it follows a ternary-complex mechanism. The protein disulphide-isomerase and thiol:protein-disulphide oxidoreductase activities co-purify quantitatively through the final stages of purification, implying that a single protein species is responsible for both activities. It is concluded that previous preparations, from various sources, that have been referred to as protein disulphide-isomerase, disulphide-interchange enzyme, thiol:protein-disulphide oxidoreductase or glutathione:insulin transhydrogenase are identical or homologous proteins. The assay, nomenclature and physiological role of this enzyme are discussed.

Resolution of sulphydryl oxidase from gamma-glutamyltransferase in bovine milk by covalent chromatography on cysteinylsuccinamidopropyl-glass

1. Sulphydryl oxidase from bovine milk was purified by covalent affinity chromatography on cysteinylsuccinamidopropyl-glass. Selective immobilization of the oxidase occurs through formation of a mixed disulphide between the enzyme and the substrate cysteinyl-glass matrix. Reductive elution of the bound protein can be accomplished with small thiols such as reduced glutathione (GSH), dithiothreitol or cysteine. This method leads to approx. 4000-fold purification of the enzyme from whey. Furthermore, complete resolution of sulphydryl oxidase from gamma-glutamyltransferase was achieved with this procedure. 2. Antibodies prepared against this purified enzyme quantitatively precipitated 95% of the GSH-oxidative activity from detergent-solubilized skim-milk membranes, whereas 100% of the transferase activity remained in the supernatant fraction; these findings confirmed the distinction between these two enzymes. 3. Reverse-phase high-pressure-liquid-chromatographic analyses of assay mixtures containing both enzymes revealed an array of GSH derivatives generated by a combination of the oxidative and hydrolytic activities. However, purified sulphydryl oxidase yielded only GSSG with concomitant stoichiometric loss of GSH. 4. The chromatographic method described is simple and reproducible, and may be applicable to isolation of sulphydryl oxidase from other tissues.

A rapid and sensitive assay for protein disulphide isomerase activity

An assay procedure for the determination of protein disulphide isomerase activity is presented. The method is based on the reactivation of randomly cross-linked RNAase, the extent of RNAase reactivation being determined from the degradation of radioactively labelled RNA. The method is rapid and sensitive and allows one to test a large number of samples simultaneously.

Purification and properties of a new glutathione-dependent thiol:disulphide oxidoreductase from rat liver

A new GSSG-dependent thiol:disulphide oxidoreductase was extensively purified from rat liver cytosol. The enzymic protein shows molecular weight 40 000 as determined by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, and 43 000 as determined by thin-layer gel filtration on Bio-Gel P-100. The pI is 8.1. This enzyme converts rat liver xanthine dehydrogenase into an oxidase, in the presence of oxidized glutathione. Other disulphide compounds are either inactive or far less active than oxidized glutathione in the enzymic oxidation of rat liver xanthine dehydrogenase. The enzyme also catalyses the reduction of the disulphide bond of ricin and acts as a thioltransferase and as a GSH:insulin transhydrogenase. The enzymic activity was measured in various organs of newborn and adult rats.

Detection of protein disulphide-isomerase in sheep pancreas fractions

Conclusions

The use of diethylpyrocarbonate to inhibit endogenous ribonuclease in sheep pancreas allows the detection of protein-disulphide-isomerase activity in homogenates, at specific activities of up to 4 units/g. This is higher than the specific activity in sheep liver homogenates (about 2 units/g) or in homogenates of other sheep tissues (16). It is thus evident that high levels of protein-disulphide-isomerase activity are present in sheep pancreas. This is consistent both with the postulated general role of protein disulphide-isomerase in protein biosynthesis (10,11) and with the in vitro action of the enzyme on its conventional substrate scrambled ribonuclease, since pancreas is the major site of ribonuclease synthesis.

Role of disulfide interchange enzyme in immunoglobulin synthesis

The role of disulfide interchange enzyme in protein biosynthesis was evaluated by studying the enzyme from mouse lymphoid tissue. The enzyme isolated from lymphoid cells was shown to have no tissue-specific characteristics. It was identical with the enzyme synthesized by mouse liver in its biochemical and immunological properties and its capacity to promote both disulfide bond formation and insulin degradation. In contrast to liver, the levels of enzyme in lymphoid tissues were found to vary with immunoglobulin secretory activity, Assays of lymphoid cells and their transformed counterparts showed that the enzyme contents of cells actively secreting immunoglobulin were 1-2 orders of magnitude higher than that of unstimulated B cells or non-immunoglobulin-producing T cells. The increase in enzyme levels paralleled the increase in immunoglobulin synthesis after antigen or mitogen stimulation and was independent of the class of immunoglobulin produced. This correlation indicated that the enzyme plays a critical role in the formation of intramonomer bonds common to all immunoglobulin molecules. Supporting data were obtained by assaying the ability of the enzyme to promote the polymerization of mouse pentamer IgM in vitro. The enzyme was found to catalyze the formation of the interchain bonds required for monomer IgM assembly but not the formation of the intermonomer bonds required for pentamer assembly. The sum of these results provides strong evidence that disulfide interchange enzyme functions in the in vivo synthesis protein disulfide bonds.

Resolution of thiol-containing proteins by sequential-elution covalent chromatography

Elution of complex protein mixtures on a matrix containing reactive disulphide bonds (Thiopropyl-Sepharose 6B, Pharmacia) results in immobilisation of thiol-containing molecules. Specific protein fractions can be displaced from the gel using different low-molecular-weight reducing agents. Thus a single sequential elution can separate and resolve thiol-containing proteins in a rapid and convenient step. The method is illustrated with reference to beef liver thiol : disulphide oxidoreductases.

Bovine liver thiol-protein disulphide oxidoreductases. An alternative method for differential purification and resolution of protein disulphide-isomerase and glutathione-insulin transhydrogenase

1. Protein disulphide-isomerase (EC 5.3.4.1) and glutathione-insulin transhydrogenase (EC 1.8.4.2) activities in bovine liver were studied in parallel during purification of 'thiol-protein disulphide oxidoreductase' by the procedure of Carmichael, Morin & Dixon [(1977) J Biol. Chem. 252, 7163-7167]. The two activities showed no quantitative co-purification and were partially resolved by (NH4)SO4 precipitation, indicating that distinct enzymes are present. 2. Protein disulphide-isomerase was purified by a relatively rapid method involving a combination of the early stages of the Carmichael procedure and covalent chromatography, with a new stepwise elution procedure. Ion-exchange chromatography yields a homogeneous preparation of mol.wt. 57 000. 3. The relationship between protein disulphide-isomerase, glutathione-insulin transhydrogenase and 'thiol-protein disulphide oxidoreductase' is discussed.