Acceptor specificity and tissue distribution of three human alpha-3-fucosyltransferases

Based on the capacity to transfer alpha-L-fucose onto type-1 and type-2 synthetic blood group H and sialylated acceptors, a comparison of the alpha-3-fucosyltransferase activities of different human tissues is shown. Three distinct acceptor specificity patterns are described: (I) myeloid alpha-3-fucosyltransferase pattern, in which leukocytes and brain enzymes transfer fucose actively onto H type-2 acceptor and poorly onto sialylated N-acetyllactosamine: (II) plasma alpha-3-fucosyltransferase (EC 2.4.1.152), in which plasma and hepatocyte enzymes transfer, in addition, onto the sialylated N-acetyllactosamine; (III) Lewis alpha-3 4-fucosyltransferase (EC 2.4.1.65), in which gall-bladder kidney and milk enzymes transfer, in addition, onto type-1 acceptors. The small amount (less than 10%) of alpha-3-fucosyltransferase activity found in the plasma of an alpha-3-fucosyltransferase-deficient individual had a myeloid-type acceptor pattern, suggesting that this small proportion of the plasma enzyme is derived from leukocytes. In addition to the three acceptor specificity patterns, these enzyme activities can be differentiated by their optimum pH: 8.0-8.7 for the enzymes from myeloid cells and brain. 7.2-8.0 for liver enzymes and 6.0-7.2 for gallbladder enzymes. Milk samples had two alpha-3-fucosyltransferase activities, the Lewis or alpha-3/4-fucosyltransferase under control of the Lewis gene and an alpha-3-fucosyltransferase with plasma acceptor pattern which was independent of the control of the Lewis gene. The apparent affinity for GDP-fucose of the myeloid-like enzyme was weaker than those of the plasma and Lewis-like enzymes. The apparent affinities for H type 2 and sialylated N-acetyllactosamine were stronger for exocrine secretions as compared to the plasma and myeloid enzymes. The plasma type of alpha-3-fucosyltransferase activity was more sensitive to N-ethylmaleimide and heat inactivation than the samples with myeloid-like alpha-3-fucosyltransferase activity.     

Serum concentration of alpha-2-macroglobulin, alpha-1-antitrypsin and alpha-2-antichymotrypsin in patients with lung carcinoma

Serum concentration of alpha-2-macroglobulin, alpha-1-antitrypsin and alpha-2-antichymotrypsin was evaluated in 26 patients with lung carcinoma. We observed an evident decrease in alpha-2-M and alpha-1-antitrypsin level and no differences between tested and control groups in alpha-1-antichymotrypsin concentration. The deficiency of protease inhibitors may be due to the increased level of protease activity in malignant cells. Infiltration of granulocytes near tumor and released enzymes from them may exhaust proteolytic inhibitory capacity, too. Increased protease activity is associated with transformation and uncontrolled proliferation, therefore antiproteases may be accepted as anticancerogenic factors. Further investigations are needed to bring us closer to understanding this question.     

Action of neopullulanase. Neopullulanase catalyzes both hydrolysis and transglycosylation at alpha-(1----4)- and alpha-(1----6)-glucosidic linkages.

The transglycosylation reaction catalyzed by neopullulanase was analyzed. Radioactive oligosaccharides were produced when the enzyme acted on maltotriose in the presence of [U-14C]glucose. Some of the radioactive oligosaccharides had only alpha-(1----4)-glucosidic linkages, but others were suggested to have alpha-(1----6)-glucosidic linkages. The existence of alpha-(1----6)-glucosidic linkages in the products from maltotriose with neopullulanase was proven by proton NMR spectroscopy and methylation analysis. We previously reported that the one active center of neopullulanase catalyzes the hydrolysis of alpha-(1----4)- and alpha-(1----6)-glucosidic linkages (Kuriki, T., Takata, H., Okada, S., and Imanaka, T. (1991) J. Bacteriol. 173,6147-6152). These facts proved that neopullulanase catalyzed all four types of reactions: hydrolysis of alpha-(1----4)-glucosidic linkage, hydrolysis of alpha-(1----6)-glucosidic linkage, transglycosylation to form alpha-(1----4)-glucosidic linkage, and transglycosylation to form alpha-(1----6)-glucosidic linkage. The four reactions are typically catalyzed by alpha-amylase, pullulanase, cyclomaltodextrin glucanotransferase, and 1,4-alpha-D-glucan branching enzyme, respectively. These four enzymes have some structural similarities to one other, but reactions catalyzed by the enzymes are considered to be distinctive: the four reactions are individually catalyzed by each of the enzymes. The experimental results obtained from the analysis of the reaction of the neopullulanase exhibited that the four reactions can be catalyzed in the same mechanism.     

Proteolytic inactivation of alpha-1-anti-chymotrypsin. Sites of cleavage and generation of chemotactic activity.

The effect of several microbial and mammalian proteinases on the inhibitory activity of human plasma alpha-1-anti-chymotrypsin (alpha-1-Achy) has been tested. Most of these enzymes caused rapid inactivation of the inhibitor by cleavage at single sites within the reactive-site loop between P5 Lys and P3' Leu, with additional cleavages also being detected in some cases near the NH2 terminus of the native protein. In contrast, two of the enzymes tested failed to inactivate alpha-1-Achy, although they could cause removal of peptides near the NH2 terminus. Studies of neutrophil chemotaxis revealed that native or NH2-terminally truncated alpha-1-Achy was not stimulatory. However, testing of two enzymatically inactivated forms of the inhibitor (alpha-1-Achy), cleaved at widely different positions within the reactive-site loop, indicated that they had become potent chemoattractants at concentrations within the nanomolar range. Competition studies using proteolytically inactivated alpha-1-proteinase inhibitor suggested that the chemotactic activity of the two inactivated serpins was probably mediated by the same mechanism. The physiological relevance of this chemotactic activity is underscored by the results of plasma elimination studies which indicate that alpha-1-Achy is eliminated at approximately the same rate as native alpha-1-Achy, thus prolonging chemotactic stimuli within the tissues.     

Characterization of Amylolytic Enzymes, Having Both alpha-1,4 and alpha-1,6 Hydrolytic Activity, from the Thermophilic Archaea Pyrococcus furiosus and Thermococcus litoralis

Extracellular pullulanases were purified from cell-free culture supernatants of the marine thermophilic archaea Thermococcus litoralis (optimal growth temperature, 90 degrees C) and Pyrococcus furiosus (optimal growth temperature, 98 degrees C). The molecular mass of the T. litoralis enzyme was estimated at 119,000 Da by electrophoresis, while the P. furiosus enzyme exhibited a molecular mass of 110,000 Da under the same conditions. Both enzymes tested positive for bound sugar by the periodic acid-Schiff technique and are therefore glycoproteins. The thermoactivity and thermostability of both enzymes were enhanced in the presence of 5 mM Ca, and under these conditions, enzyme activity could be measured at temperatures of up to 130 to 140 degrees C. The addition of Ca also affected substrate binding, as evidenced by a decrease in K(m) for both enzymes when assayed in the presence of this metal. Each of these enzymes was able to hydrolyze, in addition to the alpha-1,6 linkages in pullulan, alpha-1,4 linkages in amylose and soluble starch. Neither enzyme possessed activity against maltohexaose or other smaller alpha-1,4-linked oligosaccharides. The enzymes from T. litoralis and P. furiosus appear to represent highly thermostable amylopullulanases, versions of which have been isolated from less-thermophilic organisms. The identification of these enzymes further defines the saccharide-metabolizing systems possessed by these two organisms.     

Transfection of a human alpha-(1,3)fucosyltransferase gene into Chinese hamster ovary cells. Complications arise from activation of endogenous alpha-(1,3)fucosyltransferases

In order to isolate a human gene encoding an alpha-(1,3)fucosyltransferase (alpha-(1,3)Fuc-T), genomic DNA from HL-60 cells was transfected by several methods into Chinese hamster ovary (CHO) cells. Colonies expressing alpha-(1,3)Fuc-T activity were identified by their ability to bind a monoclonal antibody (anti-SSEA-1) that recognizes the carbohydrate product of alpha-(1,3)Fuc-T action. CHO cells do not express alpha-(1,3)Fuc-T activity but contain at least two, silent alpha-(1,3)Fuc-T genes previously identified by their activation in the rare, dominant mutants LEC11 and LEC12. These CHO enzymes were shown to be distinguishable from the alpha-(1,3)Fuc-T activity of HL-60 cells by the latter's comparative inability to transfer fucose to paragloboside and fetuin. Based on these criteria, only 11 isolates from more than 70 putative transfectants examined were found to stably express an alpha-(1,3)Fuc-T activity typical of HL-60 cells. Genomic DNA from two of these isolates was used to generate five independent secondary transfectants with HL-60-like alpha-(1,3)Fuc-T activity. Southern analysis revealed a common DNA fragment that hybridized to an Alu probe in each secondary, providing evidence that a human alpha-(1,3)Fuc-T gene had been transfected. However, in all transfection experiments, isolates that expressed alpha-(1,3)Fuc-T activities similar to CHO-encoded enzymes were also obtained. Several lines of evidence indicated that these cells arose from activation of endogenous CHO alpha-(1,3)Fuc-T genes as a consequence of DNA transfection. These false positives complicated the identification of transfectants expressing a human alpha-(1,3)Fuc-T gene and represent an important consideration in experiments to transfect other glycosyltransferase genes.     

Physicochemical properties of alpha- and beta-fibrinogenases of Trimeresurus mucrosquamatus venom.

alpha- and beta-Fibrinogenases (EC 3.4.21.5) were purified from Trimeresurus mucrosquamatus venom by the technique of recycling chromatography. Both enzymes were single polypeptide chains and homogeneous as judged by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis and ultracentrifugation. The sedimentation constants of alpha- and beta-fibrinogenases were 2.52 and 3.04 respectively. The molecular weight of alpha-fibrinogenase was 21 500--23 400, and that of beta-fibrinogenase was 25 000--26 000. The contents of proline, glycine and tryptophan were higher in beta-fibrinogenase than in alpha-fibrinogenase. The isoelectric points of alpha- and beta-fibrinogenases were pH 8.1 and 5.7 respectively. The optimal pH of alpha-fibrinogenase was about 7.4 and that of beta-fibrinogenase was around 8.5. The activity of alpha-fibrinogenase was completely destroyed after 30 min at 60 degrees C, pH 5.6, 7.4 and 9.0, while that of beta-fibrinogenase was not significantly affected by the same treatment. Both enzymes showed proteolytic activities toward fibrinogen and casein, but were devoid of phospholipase A, alkaline phosphomonoesterase and phosphodiesterase activities of the crude venom. The tosyl-L-arginine methylester esterase activity of beta-fibrinogenase was about 17 times that of the crude venom, while alpha-fibrinogenase was completely devoid of this activity. The fibrinogenolytic activity of alpha-fibrinogenase was markedly inhibited by EDTA and cysteine, while that of beta-fibrinogenase was inhibited markedly by phenylmethane sulfonylfluoride and slightly by tosyl-L-lysine chloromethylketone and cysteine.     

The rapid, simple and improved preparation of high specific activity alpha-[32P]dATP and alpha-[32P]ATP.

An improved method is described for the rapid and simple preparation of alpha-[32P]dATP and alpha-[32P]ATP from 32Pi in good yields and with specific activities from 20 - 150 Ci/mmol. The two-step procedure involves the chemical synthesis of the mononucleotide followed by its enzymic conversion to the triphosphate with myokinase (EC 2.7.4.3) and pyruvate kinase (EC 2.7.1.40) in the presence of trace amounts of dATP or ATP to prime the reaction. The two steps are carried out in the same reaction flask and the only purification step required is a step-wise elution from a column of DEAE-cellulose.     

Comparison of the chemical, physical, and survival properties of normal and Z-variant alpha-1-antitrypsins.

A procedure has been developed for the purification of Z-type alpha-1-antitrypsin (alpha-1-AT) which is rapid, gentle, and results in good yields. From 4 units (750 ml) of fresh human plasma, obtained from two individuals possessing the Pizz phenotype, 53 mg of pure Z-type alpha-1-AT was obtained. The preparation was homogeneous by the criteria of polyacrylamide gel electrophoresis, both in the presence and absence of sodium dodecyl sulfate, and by analytical ultracentrifugation. When compared to pure alpha-1-AT from plasma of individuals possessing the normal PiMM phenotype, the two proteins were indistinguishable with respect to amino acid composition, sedimentation coefficient (s20w of 3.33 for both M and Z), molecular weight (51,000 by sodium dodecyl sulfate gel electrophoresis and 47,000 by sedimentation equilibrium for both M and Z), and trypsin-combining ratio (0.91 for Z and 0.99 for M). The only difference which was observed between the variant forms of alpha-1-AT was in the carbohydrate composition. The Z-type alpha1-AT contains between 20 and 25% less carbohydrate than the M-type alpha-1-AT. Specifically, the Z-type alpha-1-AT is deficient in 1 glucosamine residue, 3 neutral sugar residues (1 mannose and 2 galactose), and 2 sialic acid residues. Although the Z-variant is deficient in sialic acid, its survival time in the serum of a rabbit was not significantly different from that of M-type alpha-1-AT.     

Isolation, chemical, and physical properties of alpha-1-antitrypsin.

A method of isolation of alpha-1-antitrypsin (alpha-1-AT) in good yield from normal human plasma is described. A key step was affinity chromatography employing an antiserum which had been depleted of alpha-1-AT antibodies. The final preparations were homogeneous by immunological and physicochemical criteria. The specific activity of the purified alpha-1-AT was 0.363 mg of active bovine trypsin inhibited per 1.0 mg of inhibitor. Polyacrylamide gel patterns at both alkaline and acid pH of highly pure preparations frequently, but not invariably, showed multiple hands. Molecular weight studies by sedimentation equilibrium ultracentrifugation in aqueous buffer and in 6 M guanidine as well as sodium dodecyl sulfate polyacrylamide gel electrophoresis suggest that alpha-1-AT is a single polypeptide chain having a molecular weight of 49,500. Other physical and chemical properties of the inhibitor are described. A limited N-terminal sequence (Glu-Asp-Pro-Gln-Gly-Asx-Ala-Ala) was obtained. It was found that alpha-1-AT easily forms polymers and higher aggregates when exposed to denaturing agents such as 8 M urea and 6 M guanidine. The results suggest that aggregation is determined by both covalent and noncovalent forces.     

The interaction of alpha-1-antitrypsin with soluble and sepharose-bound elastase.

The products resulting from the interaction of alpha-1-antitrypsin with elastase were examined with polyacrylamide gel electrophoresis in the presence and absence of sodium dodecyl sulfate, and by affinity chromatography. Five products of the reaction can be identified by polyacrylamide disc gel electrophoresis. Two products are complexes between alpha-1-antitrypsin and elastase (73 800 and 58 300 daltons). Two additional products are identical to fragments of alpha-1-antitrypsin which can be washed from a column of Sepharose-bound elastase immediately after alpha-1-antitrypsin is applied to the column. The larger component about 50 000 daltons, reacts with antiserum to alpha-1-antitrypsin, and does not inhibit enzymes. Together, these two products have an amino acid analysis similar to alpha-1-antitrypsin. These two fragments are probably hydrolytic products of the interaction of elastase with alpha-1-antitrypsin which is biologically inactive. The fifth product is probably a fragment of alpha-1-antitrypsin missing from the low molecular weight complex. The components of the complexes can be separated from each other by a mild nucleophilic attack. Small quantities of alpha-1-antitrypsin can be displaced from the elastase affinity column by phenyl methane sulfonyl fluoride. In conclusion, porcine pancreatic elastase forms two complexes with alpha-1-antitrypsin. One or both complexes can be split by alkali.     

Rat plasma murinoglobulin: isolation, characterization, and comparison with rat alpha-1- and alpha-2-macroglobulins

Murinoglobulin, a newly identified mouse plasma protein with trypsin-protein esterase activity (Saito, A. & Sinohara, H. (1985) J. Biol. Chem. 260, 775-781), was also found in rat plasma and purified to apparent homogeneity. The serum level of rat murinoglobulin was 14.1 mg/ml, amounting to 1/3 of the total serum globulin fraction. Rat murinoglobulin was a monomeric glycoprotein (Mr = 210,000) containing 12% carbohydrate. Rat plasma contained two isoforms of murinoglobulin, termed I and II, which showed complete immunological identity on double diffusion analysis using rabbit antiserum raised against isoform I or II. These antisera also showed partial cross-reactivity towards mouse murinoglobulin and rat alpha-1-macroglobulin but not towards rat or human alpha-2-macroglobulin. The chemical compositions, peptide mapping patterns and electrophoretic mobilities of the two isoforms resembled each other but clearly differed from those of rat alpha-1- or alpha-2-macroglobulin. Rat murinoglobulin inhibited the proteolytic activity of trypsin towards casein and remazol brilliant blue hide powder. The inhibition as to the latter substrate was greater than that as to the former. When molar ratios of inhibitor to trypsin were low, murinoglobulin and the two alpha-macroglobulins stimulated the amidolytic activity of trypsin towards a synthetic substrate. At higher ratios, however, murinoglobulin, but not the alpha-macroglobulins, inhibited the same activity. The trypsin-protein esterase activity of murinoglobulin and the two alpha-macroglobulins was impaired by a molar excess of soybean trypsin inhibitor. Murinoglobulin and the two alpha-macroglobulins were inactivated by methylamine with a concomitant unmasking of the thiol group. Murinoglobulin was much more sensitive to soybean trypsin inhibitor and methylamine than the two alpha-macroglobulins.     

Structure of bovine alpha-1,3-galactosyltransferase and its complexes with UDP and DPGal inferred from molecular modeling

A homology model of alpha-1,3-galactosyltransferase (alpha-1,3-GalT), the retaining enzyme responsible for the formation of alpha-galactosyl epitopes, has been developed by means of molecular modeling using the SpsA glycosyltransferase structure. A protein-ligand docking approach was used to model alpha-1,3-GalT complexed with UDP and UDP-Gal. The comparison of structural features found in the alpha-1,3-GalT homology model with available structural data on this class of enzymes revealed similarities in the UDP-binding pocket. In the predicted structure of the complexes, the pyrophosphate interacts with the DVD motif (Asp-225, Val-226, and Asp-227) of alpha-1,3-GalT through the Mn(2+) cation. The uridine part of the UDP binds into the well-defined cavity that consists of Phe-134, Tyr-139, Ile-140, Val-136, Arg-194, Arg-202, Lys-209, Asp-173, His-218, and Thr-137 in a conformation that is generally observed in the crystal structures of other glycosyltransferase complexes.     

Recognition of the alpha-1 and alpha-2 domains of H-2 molecules by allospecific cloned T cells

Previously we had shown that allospecific bulk cultures of cytolytic T lymphocytes lysed the products of cloned class I major histocompatibility genes expressed after DNA-mediated gene transfer. In these experiments, performed by using cloned allospecific T cell effectors, a T cell hybridoma, and recombinant DNA technology, we have been able to map determinants recognized by these T cell clones to the alpha-1 domain of H-2Dd and the alpha-2 domain of H-2Ld (four of eight clones). Target cells used were L cells (H-2k), expressing wild type or hybrid H-2 antigens of H-2d origin. Thus, for the first time determinants recognized by cloned T cells are found in the recombined alpha-1 and alpha-2 domains.     

3alpha-, 7alpha- and 12alpha-hydroxysteroid dehydrogenase activities from Clostridium perfringens.

25 strains of Clostridium perfringens were screened for hydroxysteroid dehydrogenase activity; 19 contained NADP-dependent 3alpha-hydroxysteroid dehydrogenase and eight contained NAD-dependent 12alpha-hydroxysteroid dehydrogenase active against conjugated and unconjugated bile salts. All strains containing 12alpha-hydroxysteroid dehydrogenase also contained 3alpha-hydroxysteroid dehydrogenase although 12alpha-hydroxysteroid dehydrogenase was invariably in lesser quantity than the 3alpha-hydroxysteroid dehydrogenase. In addition, 7alpha-hydroxysteroid dehydrogenase activity was evident only when 3alpha, 7alpha, 12alpha-trihydroxy-5beta-cholanoate was substrate but notably absent when 3alpha, 7alpha-dihydroxy-5beta-cholanoate was substrate. The oxidation product 12alpha-hydroxy-3, 7-diketo-5beta-cholanoate is rapidly further degraded to an unknown compound devoid of either 3alpha- or 7alpha-OH groups. Group specificity of these enzymes was confirmed by thin-layer chromatography studies of the oxidation products. These enzyme systems appear to be constitutive rather than inducible. In contrast to C. perfringens. Clostridium paraputrificum (five strains tested) contained no measurable hydroxysteroid dehydrogenase activity. pH studies of the C. perfringens enzymes revealed a sharp pH optimum at pH 11.3 and 10.5 for the 3alpha-OH- and 12alpha-OH-oriented activities, respectively. Kinetic studies gave Km estimates of approx. 5 X 10(-5) and 8 X 10(-4) M with 3alpha, 7a-dihydroxy-5beta-cholanoate and 3alpha, 12alpha-dihydroxy-5beta-cholanoate as substrates for two respective enzymes. 3alpha-hydroxysteroid dehydrogenase was active against 3alpha-OH-containing steroids such as androsterone regardless of the sterochemistry of the 5H (Both A/B cis and A/B trans steroides were substrates). There was no activity against 3beta-OH-containing steroids. The 3alpha- and 12alpha-hydroxysteroid dehydrogenase activities, although differing in cofactor requirements cannot be distinguished by their appearance in the growth curve, their mobility on disc gel electrophoresis, elution volume on passage through Sephadex G-200 or heat inactivation studies.     

Human platelets release alpha-6-L-fucosyltransferase upon activation

Previously we have shown that human platelets release alpha-6-L-fucosyltransferase (EC 2.4.1.68) during coagulation of blood [(1987) Glycoconjugate J. 4, 43-49]. Here we report that agonists which induce platelet aggregation bring about release of the enzyme. In quantitative terms the release of alpha-6-L-fucosyltransferase by washed, aggregated platelets was very similar to that occurring during blood coagulation.     

Spectral studies on two genetic forms of the human serum proteinase inhibitor, alpha-1-antitrypsin.

alpha-1-antitrypsin, the major inhibitor of proteolytic enzymes in human serum, was isolated from normal individuals (protease inhibitor type MM) and from those with an inherited deficiency (protease inhibitor type ZZ) of circulatory protein. The two proteins were compared by circular dichroism spectroscopy, and by fluorescence quenching experiments using anionic (I-), and neutral (acrylamide) probes. Both proteins share a similar secondary structure, i.e. approximately 45--50% alpha-helix and 15--20% beta-structure. Evidence was accumulated to show that the microenvironment in the vicinity of the three tryptophanyl residues is altered in Z form as compared to the M form as shown by (a) the absence of the positive dichroic band in the region 290--300 nm of the circular dichroism spectra, (b) a greater than 50% increase in quantum yield in the tryptophanyl fluorescence emission spectra, (c) an increased accessibility of tryptophan to quenching by iodide, and (d) acrylamide quenching experiments which indicate that all tryptophanyl residues in the Z protein are quenched equally or that quenching is dominated by a single residue, while in the M protein, heterogeneous quenching occurs. The potential significance of these findings in terms of alpha-1-antitrypsin deficiency state are discussed.     

Epinephrine stimulates inositol phospholipid metabolism by activating alpha-2 adrenergic receptors in human platelets

The metabolism of inositol phospholipids in response to epinephrine was investigated in intact human platelets. In platelets prelabelled with [3H]-myo-inositol in Ca2+-free HEPES buffer containing 10 mM LiCl, epinephrine caused an accumulation of inositol-1-phosphate in a concentration-dependent manner. The EC50 value for epinephrine was 5 microM. Yohimbine (1 microM), a selective alpha-2 adrenergic receptor antagonist, inhibited 88% of the epinephrine (10 microM) response, whereas prazosin (1 microM), a selective alpha-1 adrenergic receptor antagonist, failed to inhibit the response. Yohimbine inhibited the epinephrine (10 microM) response in a concentration-dependent manner. The inhibition constant (Ki) value for yohimbine was 60.3 nM. These data indicate that epinephrine stimulates phosphoinositide (PI) turnover by activating adrenergic receptors of the alpha-2 type in human platelets. In addition, this PI response elicited by epinephrine was found to be inhibited in a concentration-dependent manner by treatment of platelets with dibutyryl cyclic AMP and 8-bromo-cyclic GMP which are known as potent inhibitors for platelet activation, and may therefore be a useful biochemical index for the study of the function of human alpha-2 adrenergic receptors.