The human LT system. III. Characterization of a high molecular weight LT class (complex) composed of the various smaller MW LT classes and subclasses in association with Ig-like molecules.

Cytotoxic activity (lymphotoxin (LT)) present in supernatants from lectin stimulated human lymphocytes in vitro is composed of a heterogeneous system of biological macromolecules which can be separated into multiple classes and subclasses on the basis of their molecular weight and charge. These studies further characterize a large molecular weight human LT class, termed complex (MW >200,000 d), which elutes in the void volume off Sephadex G-150 or Ultrogel AcA 44. Immunological studies on the complex, employing various rabbit anti-LT class and subclass antisera, revealed this material is a macromolecular assemblage of the smaller MW α, β, γ LT classes and subclasses. Furthermore, the reactivity of this material with anti-human Fab′₂ (IgG) indicates these smaller molecular weight LT components can associate with immunoglobulin or Ig-like molecules. The materials present in the LT complex class appear to be noncovalently associated, since conditions of high ionic strength dissociate certain small MW LT components, while low ionic strength buffers may cause these components to reaggregate with the complex. When subjected to velocity sedimentation on sucrose gradients or gel filtration on Ultrogel AcA 22, LT complex activity elutes as several discrete peaks of activity in the 200,000 to 1,000,000 MW range. These findings suggest the concept that LT molecules can form discrete and specific macromolecular structures which contain the smaller MW LT classes. Moreover, these structures can also associate with immunoglobulin-like molecules to form secondary LT-Ig complexes. This may have important biological significance in explaining how nonspecific cell toxins could play a role in specific or nonspecific cell lytic reactions in vitro.     

The human LT system. II. Immunological relationships of LT molecules released by mitogen activated human lymphocytes in vitro.

Materials with LT activity present in supernatants from PHA stimulated human lymphocytes in vitro are very heterogeneous and can be separated into multiple molecular weight classes, termed complex, α, β, and γ. Several of these classes can be further resolved into subclasses by other physical and chemical methods. The immunologic relationships of these materials one to another were examined employing various rabbit anti-humn LT sera which will neutralize LT activity on L-929 cells in vitro. These studies reveal: (a) LT activities are due to a distinct group of substances which are immunologically related one to another and can exist in several molecular weight forms; (b) a high MW class of molecules, termed complex, appears to contain all currently known LT classes and subclasses; (c) LT classes and subclasses both have common (public) and discrete (private) antigenic specificities; (d) human LT classes and subclasses do not appear to share Ag determinants with materials with LT activity released by lectin stimulated lymphoid cells from rabbit, rat, hamster, guinea pig, or mouse; and (e) human LT molecules are not immunologically related to cell toxins released by glass adherent human peripheral blood monocytes or PMN cells. These data indicate human LT molecules form a “discrete system” of lymphocyte derived cell toxins, which can associate together into various related but different MW forms in the supernatant.     

The human LT system. IV. Studies on the large MW LT complex class: association of these molecules with specific antigen binding receptor(s) in vitro.

The present studies demonstrate that a portion of lymphotoxin (LT) cell-lytic activity present in supernatants from: 1) lectin (Con A, PHA) stimulated nonimmune; or 2) antigen (soluble or cellular) stimulated immune human lymphocytes in vitro, is associated with immunoglobulin (Ig) or “Ig-like” receptor molecule(s). This concept was supported by three findings: 1) LT activity in these supernatants was partially inhibited by heterologous anti-human (IgG) Fab′₂ antisera; 2) LT activity present in soluble antigen stimulated immune human lymphocyte supernatants could specifically bind to and be eluted from Sepharose 4B columns to which the specific stimulating antigen was covalently attached; and 3) LT activity present in primary one-way mixed lymphocyte culture (MLC) supernatants could be removed by absorption on the specific stimulator cells. The amount of total LT activity found to be associated with “Ig” in these supernatants was variable, but ranged from 5 to 20% in lectin stimulated cell supernatants to 20 to 50% in antigen or MLC stimulated supernatants. Physical-chemical studies on the molecular weight class of LT molecules having reactivity with anti-Fab′₂ sera, as well as antigen binding capacity, revealed these properties reside in the large (>200,000) MW LT class, termed complex. The nature and biological significance of these “antigen specific” LT complexes, as they relate to mechanisms of cytotoxicity in vitro, will be discussed.     

The human LT system. V. A comparison of the relative lytic effectiveness of various MW human LT classes on 51Cr-labeled allogeneic target cells in vitro: enhanced lysis by LT complexes associated with Ig-like receptor(s).

The present studies examine the in vitro cell-lytic capacity of various molecular weight (MW) human lymphotoxin (LT) classes obtained from lectin-activated normal or immune lymphocytes on allogeneic target cells. The findings reveal that the high-MW complex class of LT is up to 100 times more effective than the smaller MW LT forms (α, β, and γ) in causing lysis of various allogeneic cell types including lymphoid cells in vitro. Moreover, the data suggest that lectin-stimulated alloimmune cells (MLC sensitized) release complex LT forms in association with a specific antigen-binding receptor(s), and that these complexes are from 3 to 10 times more effective on the sensitizing target cell than complexes obtained from lectin-stimulated nonimmune cells. Positive evidence that complex-induced lysis involved LT was indicated by the finding that lysis was completely neutralized by incubation with heterologous antisera directed against a refined human α₂-LT subclass (anti-α₂) and partially neutralized with anti-human Fab₂′ serum. These findings support the concept that LT molecules may represent a system of related cell-lytic molecules. While the smaller MW forms are only weakly lytic by themselves, they can be assembled into highly lytic complexes which may be focused or directed by an antigen-binding receptor(s).     

In vitro lymphocyte cytotoxicity. I. Evidence of multiple cytotoxic molecules secreted by mitogen activated human lymphoid cells in vitro.

Multiple families of cytotoxic molecules [Lymphotoxin (LT)] have been identified in phytohemagglutinin (PHA-P) activated human lymphocyte supernatants and lymphocyte homogenates, using gel filtration chromatography on Sephadex G-150. These macromolecules have molecular weights of 80–90,000, 50,000, and 10–15,000 daltons and have been termed LT₂, LT₂ and LT₃, respectively. They are secreted by cells from a variety of lympboid tissues, i.e., tonsil, adenoid, and peripheral blood. The kinetics of appearance of the cytotoxins indicate that all three are present within 16 hr after lymphocyte activation. However, while LT₁ and LT₂ persist in these cultures through day 5, LT₃ is not detectable after day 3. These molecules can also be detected when either PHA or concanavalin A are employed as the stimulating agent. Moreover, the relative amounts of LT₁, LT₂ and LT₃ activity in a given supernatant vary dramatically from culture to culture. Extracellular levels of LT accumulate and peak by 4 to 5 days in culture, however, intracellular levels of LT reach a maximum on day 3 and decrease to very low levels on day 5. Mitogen-stimulated lymphocytes at 3 days contain intracellular levels of LT which are several logs higher than that detectable in unstimulated cells. This observation suggests that both the biosynthesis and secretion of lymphotoxin is governed by a regulatory control process(es).     

Stabilization and functional studies of high-molecular-weight murine lymphotoxins

High levels of lymphotoxin-like activity (LT) were found in supernatants from secondarily stimulated immune mouse splenocytes activated with concanavalin A (Con A) in vitro. Splenocytes obtained from C57Bl/6 mice immune to the P815 mastocytoma were restimulated in vitro with mitomycin C-treated P815 cells, and then stimulated with Con A. High levels of unstable LT activity are rapidly (2–4 hr) released by these lectin-stimulated splenocytes. The introduction of a crosslinking agent, glutaraldehyde, was found to stabilize this LT activity and allowed us to perform more defined biochemical studies and to examine the functional activities of the LT classes. The lytic activity in these supernatants resided in the high-molecular-weight classes, termed Complex (Cx > 200,000 daltons) and alpha-heavy (α_H 130,000–160,000 daltons). It was found that the Cx and α_H LT classes from the secondarily stimulated immune splenocytes cause lysis of allogeneic target cells, P815 and EL-4, in a 16-hr ⁷⁵Semethionine release assay, and in some cases, this lysis was specific for the sensitizing target cell.     

Cytotoxic activity of lymphocytes. VIII. Lymphotoxin activity in cell-free extracts of activated lymphocytes.

Cell-free extracts of human lymphocytes activated by PHA contain a cytotoxin that kills mouse L cells. Such cells elaborate two different kinds of toxins into the culture supernatant fluids, called α- and β-lymphotoxin (-LT), which differ in size, stability, and antigenicity. The amount of intracellular toxin is 1 to 24% of that found in supernatants of different tonsil donors. Equal amounts of intracellular toxin appear in both microsomal fraction (100,000g pellet) and soluble supernatant fractions of the cell-free extracts (CFE). The toxin can be solubilized from the membrane by digestion with papain or extraction with a nonionic detergent, but not by repeated sonication. The molecular weight of both the microsomal and soluble cellular cytotoxin is 45,000 ± 5000. The intracellular toxin differs from the extracellular toxins secreted by the same cells in two major characteristics: one, although its size approximates that of supernatant β-LT (and is smaller than the 76,000 M_r α-LT), antibody-inhibiting α-LT but not β-LT inhibits both the microsomal and soluble CFE-LT. Two, the intracellular LT does not display the charge heterogeneity so characteristic of supernatant α-LT. Supernatant α-LT and CFE-LT are similar in their patterns of inactivation by heating to 80 °C and treatments with sodium dodecylsulfate (SDS), guanidine, proteases, and heavy metal ions, and are similarly unaffected by treatment with 8 M urea, N-ethylmaleimide, and sodium periodate. These results suggest that the single polypeptide intracellular LT is the precursor of the more complex secreted α-LT molecule.     

Inhibition of human NK-induced cell lysis and soluble cell-lytic molecules with anti-human LT antisera and various saccharides

The present study examines and compares the cytolysis of K-562 and MOLT-4 cells mediated by human natural killer (NK) cells from fresh peripheral blood and lymphotoxins (LT) derived from human lymphoid cell populations after lectin stimulation in vitro. Lymphotoxins were obtained from 5-hr concanavalin A (Con A)-restimulated human peripheral blood lymphocytes (PBL) which were precultured for 5 days in medium and fetal calf serum or with allogeneic human B-lymphoid cell lines. Two classes of probes were employed in both direct (cell) and indirect (supernatant) induced target-cell lysis: (a) various saccharides and (b) antibodies reactive with human LT forms. Two sugars, N-acetylglucosamine and α-methylmannoside, were able to inhibit direct cell lysis of both MOLT-4 and K-562 target cells. However, saccharide inhibition was distinct for each type of target even when effector cells were obtained from the same donor. These same saccharides were also able to inhibit 20–30% of the total LT activity in a supernatant for L-929 cells and 50–90% of the lytic activity on MOLT-4 cells. Anti-human F(ab′)₂ (IgG) and rabbit anti-α₂ LT sera blocked direct cell lysis of MOLT-4 and K-562 targets in 50% of the experiments. The anti-α₂ LT serum only recognizes a portion of the LT forms in these supernatants. These results reveal that, while both direct and indirect cell lysis are complex phenomena, they may both occur in some cases by a common mechanism(s).     

α-d-Galactosidase activity and galactomannan and galactosylsucrose oligosaccharide depletion in germinating legume seeds

Germinating seeds of lucerne, guar, carob and soybean initially depleted raffinose series oligosaccharides and then galactomannan. This depletion was accompanied by a rapid increase and then a decrease in α-galactosidase levels. Lucerne and guar contained two α-galactosidase activities, carob three and soybean four. One of these in each plant, from its location in the endosperm, time of appearance and kinetic behaviour, appeared to be primarily involved in galactomannan hydrolysis. This enzyme in lucerne had MW of 23 000 and could not be separated from β-mannanase by (NH₄)₂SO₄ fractionation, DEAE, CM or SE-cellulose chromatography or gel filtration, but only by polyacrylamide gel electrophoresis. In guar, carob and soybean, it could be separated by ion-exchange chromatography and gel filtration. In lucerne, carob and guar most of the total increase in activity was due to this enzyme. The other α-galactosidases had MWs of about 35 000 and could be separated from β-mannanase by dissection, ion exchange cellulose chromatography and gel filtration. They were located in the cotyledon-embryo and appeared to be primarily involved in galactosylsucrose oligosaccharide hydrolysis.     

Multiple forms of α-galactosidase in mature leaves of Cucurbita pepo

α-D-Galactosidase has been purified from mature leaves of Cucurbita pepo using pH and ammonium sulphate fractionation, Sephadex gel filtration and DEAE Sephadex gel chromatography. Gel filtration produced one peak of α-galactosidase activity from which three distinct enzyme forms were resolved on DEAE Sephadex and designated LI, LII and LIII. Purirications obtained were ca 75, 120 and 30 fold for LI, Lll and LIII respectively. Ll was slightly contaminated with β-galactosidase and LII with β-fructosidase activity. All forms hydrolysed the α-galactosyl linkages of raffinose and stachyose. Differences between each form were found in their pH optima, reactivity toward metal ions, thermal stability and K_m values using either p-nitrophenyl-α-D-galactoside (NPG) or raffinose as substrates. All forms were inhibited by NPG at high concentrations and by α-D-galactose. It is proposed that α-galactosidases may be components of a lysosomal system in plant cells.     

The enzymic synthesis,by transglucosylation of a homologous series of glycosidically substituted malto-oligosaccharides,and their use as amylase substrates

(1 → 4)-α-d-Glucan 4-glucosyltransferase (EC2.4.1.19) of klebsiella pneumoniae transforms maltose (G2) into d-glucose (G1) and a mixture of malto-oligosaccharides (G₂—G₉), and maltotriose (G3) into G_l—G_ll in addition to cyclo-hexa-, -hepta-, and -octa-amyloses (cG_6—8). It produces a similar mixture, but with higher amounts of G₂—G₁₁, by transfer from cyclohexaamylose to G₁. By using p-nitrophenyl α- and β-d-glucosides, 4 methylumbelliferyl α-d-glucoside, and strophanthyl α-d-glucoside as acceptors and cyclohexaamylose as donor, a homologous series of substituted malto-oligosaccharides having chain lengths of up to 12 d-glucose residues was produced. High-pressure liquid chromatography on Bio-Gel P₂ permitted separation of these products of transferase activity on analytical and preparative scales. By the same technique, the nitration product of phenyl hepta-O-acetyl-α-maltoside, after deacetylation, was separated into about equal amounts of the o- and p-isomers. The synthetic p-nitrophenyl α-maltoside (_pNPG₂) was used to identify the first member of the series of biochemical transfer-products. p-Nitrophenyl maltotrioside (_pNPG₃) and maltotetraoside (_pNPG₄) were shown to be the higher homologues. They are very good substrates for human and pig-pancreatic alpha amylase. This substrate behavior may be measured conveniently in the case ofpNPG3 by the rapid liberation of nitrophenolate; the enzyme used _pNPG₄ only on addition of α-d-glucosidase. Human-parotis amylase of equal starch-splitting activity as the pancreatic enzyme acts upon _pNPG₃ and _pNPG₄ but about 100 times more slowly.     

The human LT system. VII. Release of soluble forms and delivery to target L-929 cells by lectin-preactivated human lymphocytes in the absence of protein synthesis and secretory processes.

We have investigated the effects of inhibitors of cellular protein synthesis (emetine, cycloheximide) and secretion (colchicine, cytochalasin B) on the capacity of primary or secondary lectin-activated human lymphocytes to release LT molecules or to cause lectin-induced destruction (LICC) of murine L-929 cells in vitro. Our findings reveal: (a) agents which inhibit protein synthesis or secretion block the release of LT activity into the supernatant and LICC when primary lectin-stimulated human adenoid lymphocytes are employed as effector cells; (b) these same agents are ineffective at blocking LT release or LICC when 3- or 5-day lectin-prestimulated lymphocytes are employed; and (c) anti-human α-LT serum blocks LICC of L-929 cells mediated by primary or secondary lectin-activated human lymphocytes. The difference in participation of effector cellular processes in LICC between primary and secondary lectin-stimulated cells correlates with the findings that preactivated lymphoid cells possess high levels of preformed intracellular, as well as membrane associated, LT molecules, and that release of these materials into the supernatant or delivery to the target cell can occur independently of active protein biosynthesis or classical secretory systems.     

The human LT system. XII. Purification and functional studies of LT and "TNF-like" LT forms from a continuous human T cell line

A clone of the continuous human T cell line HUT-102, termed YM 1.2, can spontaneously release alpha-LT in vitro. However, when stimulated with phorbol myristic acetate, these cells release other LT forms. These LT forms were purified to homogeneity by DEAE chromatography, column isoelectric focusing, and polyacrylamide gel electrophoresis. One LT form, termed LT-2, is a 79,000 m.w. component in aqueous solution and composed of 21,000 m.w. subunits. This form is immunologically related to macrophage-derived TNF and has a lytic capacity in vitro on K-562, Molt-4F, and Raji cells similar to that described for cytotoxins derived from NK effector cells, termed NK-CF. A second LT form, termed LT-3, is a single 69,000 m.w. peptide which could not be reduced into the smaller subunits. This form expresses antigens in common with both alpha-LT and TNF, because both anti-LT and anti-TNF were required to completely neutralize cell lytic activity in vitro. Functional testing revealed that the LT-3 form is lytic on all continuous cells tested in vitro, including NK-resistant target cells. The LT-3 component appears similar by immunologic, biochemical, and functional criteria to the LT form derived from primary human cytolytic T cells in vitro. At the levels tested, none of these LT-TNF forms had measurable effects on primary fibroblasts in vitro.     

Blood Group Substance-degrading Enzymes Obtained from Streptomyces sp.

The blood group B substance-degrading activity of Streptomyces 9917S₂ is induced by galactosides as α-galactosidase activity is. Purification of the α-galactosidase was attempted by chromatography on DEAE-Sephadex and Sephadex. The purified preparation was shown to be free from α- and β-glucosidases, β-galactosidase, α- and β-glucosaminidases, and α- and β-galactosaminidases activities. The blood group B substance-degrading activity was present only in this fraction. This enzyme preparation cleaves α-(1→3)- and α-(1→6)-galactosidic linkages. The activity is inhibited by d-galactose, melibiose, and raffinose and also by l-arabinose and d-xylose.     

Biphasic nature in the autoxidation reaction of human oxyhemoglobin

In comparison with myoglobin molecule as a reference, we have studied the autoxidation rate of human oxyhemoglobin (HbO₂) as a function of its concentration in 0.1 M buffer at 35°C and in the presence of 1 mM EDTA. At pH 6.5, HbA showed a biphasic autoxidation reaction that can be described completely by a first-order rate equation containing two rate constants — k_f, for fast autoxidation of the α-chain, and k_s, for slow autoxidation of the β-chain, respectively. When tetrameric HbO₂ was dissociated into αβ-dimers by dilution, the value of k_f increased markedly to an extent comparable with the autoxidation rate of horse heart oxymyoglobin (MbO₂). The rate constant k_s, on the other hand, was found to remain at an almost constant value over the whole concentration range from 1.0 × 10⁻³ M to 3.2 × 10⁻⁶ M in heme. At pH 8.5 and pH 10.0, however, the autoxidation of HbO₂ was monophasic, and no enhancement in the rate was observed by diluting hemoglobin solutions. Taking into consideration the effects of 2,3-diphosphoglyceric acid and chloride anion on the autoxidation rate of HbO₂, we have characterized the differential susceptibility of the α- and β-chains to the autoxidation reaction in aqueous solution.     

Glycosidases. Ligands for affinity chromotagraphy: II. Syntheses of p-aminophenyl 1-thio-L-fucopyranosides

Syntheses of p-aminophenyl 1-thio-α-L- and β-L-fucopyranosides are described. 1,2,3,4-Tetra-O-acetyl-α-L-fucopyranose, on heating with p-nitrothiophenol in the presence of p-toluenesulfonic acid under diminished pressure, gave a mixture of p-nitrophenyl 2,3,4-tri-O-acetyl-1-thio-α- and β-L-fucopyranosides, which was separated by chromatography on silica gel. When the reaction was carried out in the presence of zinc chloride at atmospheric pressure, the β-anomer was the exclusive product. Deacetylation of the aryl α-L- and α-L-thiofucopyranosides with sodium methoxide, followed by catalytic hydrogenation in the presence of palladium on barium sulfate, afforded the respective aminophenyl 1-thiofucopyranosides. The aryl thiofucopyranosides thus synthesized were tested for their inhibitory activity toward clam α-L-fucosidase. The p-aminophenyl 1-thio α-L-fucopyranoside showed a competitive-type inhibition, with a K_i of 0.71mM.     

Immobilization of the α-amylase of Bacillus amyloliquifaciens TSWK1-1 for the improved biocatalytic properties and solvent tolerance

The α-amylase of Bacillus amyloliquifaciens TSWK1-1 (GenBank Number, GQ121033) was immobilized by various methods, including ionic binding with DEAE cellulose, covalent coupling with gelatin and entrapment in polyacrylamide and agar. The immobilization of the purified enzyme was most effective with the DEAE cellulose followed by gelatin, agar and polyacrylamide. The K _m increased, while V _max decreased upon immobilization on various supports. The temperature and pH profiles broadened, while thermostability and pH stability enhanced after immobilization. The immobilized enzyme exhibited greater activity in various non-ionic surfactants, such as Tween-20, Tween-80 and Triton X-100 and ionic surfactant, SDS. Similarly, the enhanced stability of the immobilized α-amylase in various organic solvents was among the attractive features of the study. The reusability of the immobilized enzyme in terms of operational stability was assessed. The DEAE cellulose immobilized α-amylase retained its initial activity even after 20 consequent cycles. The DEAE cellulose immobilized enzyme hydrolyzed starch with 27 % of efficiency. In summary, the immobilization of B. amyloliquifaciens TSWK1-1 α-amylase with DEAE cellulose appeared most suitable for the improved biocatalytic properties and stability.     

Synthesis and properties of some O-(2,2-dialkoxyethyl)glycolaldehydes

β-d-Mannosidase (β-d-mannoside mannohydrolase EC 3.2.1.25) was purified 160-fold from crude gut-solution of Helix pomatia by three chromatographic steps and then gave a single protein band (mol. wt. 94,000) on SDS-gel electrophoresis, and three protein bands (of almost identical isoelectric points) on thin-layer iso-electric focusing. Each of these protein bands had enzyme activity. The specific activity of the purified enzyme on p-nitrophenyl β-d-mannopyranoside was 1694 nkat/mg at 40° and it was devoid of α-d-mannosidase, β-d-galactosidase, 2-acet-amido-2-deoxy-d-glucosidase, (1→4)-β-d-mannanase, and (1→4)-β-d-glucanase activities, almost devoid of α-d-galactosidase activity, and contaminated with <0.02% of β-d-glucosidase activity. The purified enzyme had the same K_m for borohydride-reduced β-d-manno-oligosaccharides of d.p. 3–5 (12.5mm). The initial rate of hydrolysis of (1→4)-linked β-d-manno-oligosaccharides of d.p. 2–5 and of reduced β-d-manno-oligosaccharides of d.p. 3–5 was the same, and o-nitrophenyl, methylumbelliferyl, and naphthyl β-d-mannopyranosides were readily hydrolysed. β-d-Mannobiose was hydrolysed at a rate ～25 times that of 6¹-α-d-galactosyl-β-d-mannobiose and 6³-α-d-galactosyl-β-d-mannotetraose, and at ～90 times the rate for β-d-mannobi-itol.