Periodate-induced transformation of human peripheral blood lymphocytes and the resultant oxidation of membrane sialyl, galactosyl and fucosyl residues

Oxidation of human peripheral mononuclear cells with sodium periodate results in lymphocyte activation. Period-date, at optimal mitogenic concentrations, oxidizes membrane sialyl residues (NeuNAc) essentially into the 7 carbon analogue (C7-NeuNAc). Fucosyl and galactosyl residues are also oxidized by periodate, since propane 1,2-diol and glycerol are isolated in acid hydrolysates of lymphocytes oxidized by periodate and reduced by tritiated borohydride. The neuraminidase pretreatment of lymphocytes induces a 40-50% decrease of their response to periodate. Neuraminidase treatment of 108 human peripheral lymphocytes liberated 9.6 microgram NeuNAc (31 nmol), representing 68.5% of the total content. The neuraminidase treatment dramatically enhances the recovery of glycerol in hydrolysates of lymphocytes treated successively with periodate and tritiated borohydride.     

The extent of oxidative mitogenesis does not correlate with the degree of aldehyde formation of the T lymphocyte membrane

Chemical oxidation of T lymphocytes with periodate or the combined action of the enzymes neuraminidase and galactose oxidase (NAGO) results in T cell activation. The latter process includes the production of interleukin 2 (IL 2) and the induction of IL 2 receptors. Because membrane-bound aldehydes act in the transmission of the oxidative mitogenic signal, we designed a comparative study in human thymocytes and peripheral blood leukocytes in order to determine a possible correlation between the degree of the membrane aldehydes generated chemically or enzymatically and the extent of the resulting activation. The differences between periodate- and NAGO-induced aldehydes were demonstrated by flow cytometry of cells stained with a novel fluoresceinated hydrazide and by an electrophoretic procedure performed with biocytin hydrazide and 125I-streptavidin. In both cellular systems, periodate oxidation resulted in stronger formation of aldehydes than NAGO oxidation. However, the IL 2 receptor induced by NAGO formation and the resultant activation were significantly higher than those induced by periodate. The degree of aldehyde formation on peripheral blood leukocytes was also considerably higher than that of thymocytes, yet similar patterns of [3H]thymidine uptake were observed in the mitogenic assays of both cellular systems. The data indicate that no correlation exists between the extent of aldehyde formation and the degree of oxidative mitogenesis. It is thus suggested that relatively few (or maybe only one) membrane-bound aldehyde-containing molecules act in the transmission of the oxidative mitogenic signal.     

Generation of a soluble IFN-gamma inducer by oxidation of galactose residues on macrophages

Depletion of macrophages from human peripheral blood mononuclear cells (PBMC) caused a marked decrease in galactose oxidase and sodium periodate, but not a calcium ionophore, stimulated Interferon-gamma (IFN-gamma) production. Reconstitution of such depleted cultures with galactose oxidase treated macrophages, but not lymphocytes, restored IFN-gamma levels to those of control nonfractionated PBMC. Thus, galactose oxidase seemed to act on macrophages which in turn stimulated lymphocyte production of IFN-gamma. Unlike human cells which have terminal galactose residues on glycoproteins, murine cell glycoproteins terminate their oligosaccharide component in the order N-acetyl-neuraminic acid followed by D-galactose, N-acetyl-glucosamine, and glycoprotein. Galactose oxidase or sodium periodate only activated murine macrophages to stimulate lymphocyte IFN-gamma production after exposing D-galactose residues by the removal of the terminal N-acetyl-neuraminic acid residues with neuraminidase. Removal of such exposed terminal galactose residues with beta-galactosidase inhibited the effect of galactose oxidase on murine macrophages. Taken together, these results strongly suggest that oxidation of terminal galactose residues on macrophages is the initial site of action of galactose oxidase and sodium periodate. Studies with Boyden chambers have shown that galactose oxidase-treated macrophages released a soluble factor which stimulates lymphocyte production of IFN-gamma. Based on these findings, it appears that the oxidation of terminal galactose residues on the surface of macrophages leads to the induction and transmission of a soluble signal for lymphocyte production of IFN-gamma.     

Control of proliferation in mitogen responsive human peripheral blood lymphocytes: restimulation of cells stimulated by sodium periodate.

Human peripheral blood lymphocytes are stimulated to a greater extent by sodium periodate when cells are incubated in medium containing human serum than when incubated in medium with fetal calf serum. NaIO4 STIMULATION CAN BE REVERSED BY TREATMENT WITH SODIUM BOROHYDRIDE BUT CELLS ALREADY COMMITTED TO DIVISION ARE NOT AFFECTED BY BOROHYDRATE TREATMENT. Maximal commitment to DNA synthesis of a NaIO4 oxidized cell suspens-on occurs after about 28 hr of incubation in medium. The committal time after periodate stimulation is identical to that after stimulation with concanavalin A. Cells treated with periodate and then reduced with borohydride immediately after oxidation are refractory to further per-odate stimulation. Cells stimulated with periodate and then incubated for 6 hr before treatment with borohydride can be restimulated with periodate, indicating a turnover of membrane sites in the 6 hr period. Periodate-stimulated cells divide only once in response to the stimulation. The progeny of cells which were stimulated with periodate can be restimulated by treatment with either periodate or concanavalin A.     

The effect of periodate oxidation and α-mannosidase treatment of Dolichos biflorus lectin

The effects of periodate and α-mannosidase treatment of the Dolichos biflorus lectin were determined. Destruction by periodate of 16% of the mannose residues of the lactin had no effect on its ability to agglutinate type A erythrocytes, precipitate blood group A + H substance or to be precipitated by concanavalin A. Removal of up to 40% of the mannose by either periodate or α-mannosidase rendered the lecton nonprecipitable by concanavalin A. The lectrin treated by α-mannosidase retained its ability to agglutinate erythrocytes and precipitate blood group A + H substance, but the lectin treated with periodate lost most of its activity.The results suggest that the complete integrity of the carbohydrate unit of the lectin is not necessary for its activity and that the periodate may be affecting the protein portion of the molecule as well as its carbohydrate residues. No conversion of form A to form B of the lectin was observed with either periodate oxidation or α-mannosidase treatment.     

Direct evidence for sialic acid oxidation in periodate-induced lymphocyte proliferation.

Normal mouse spleen cells treated with periodate were stimulated to undergo blastogenesis. In contrast spleen cells from nude mice did not respond to periodate. Such a treatment of normal and nude spleen cells led to the oxidation of the cell surface sialic acid residues with formation of N-AN8. Prior treatment with neuraminidase of normal spleen cells greatly impaired their capacity to respond to periodate activation with a decrease in the amount of N-AN8 formed.     

The requirement for cell surface galactosyl residues during oxidative activation of normal and chronic lymphocytic leukemia lymphocytes.

Galactose oxidase stimulated normal and leukemic lymphocytes to undergo DNA synthesis and cell division. Although the response of normal lymphocytes to galactose oxidase was enhanced with neuraminidase pretreatment, substantial activation of leukemic lymphocytes required pretreatment with neuraminidase. Leukemic lymphocytes exhibited maximal response to neuraminidase-galactose oxidase later than that observed in normal lymphocytes. Treatment of lymphocytes with trypsin diminished their response to galactose oxidase. When lymphocytes were pretreated with β-galactosidase to specifically remove cell surface galactosyl residues, the response to galactose oxidase was prevented. The response of normal and leukemic lymphocytes to sodium periodate was also reduced after treatment with galactose oxidase. These data support the concept that oxidation of cell surface galactosyl residues is critical during lymphocyte activation.     

Behavior of aldehyde moieties involved in the activation of suppressor cells by sodium periodate

The treatment of mouse spleen cells with periodate at the optimal mitogenic concentration (1 mM) induces the activation of suppressor cells of the in vitro antibody response and leads to the formation of aldehydes on the carbohydrate termini of the surface sialoglycoconjugates. These aldehyde moieties are found on the C8 (N-AN 8) and the C7 (N-AN 7) derivatives of sialic acid. Immediate borohydride reduction prevents the activation of the suppressor cells. Data from this work show that borohydride reduction must be performed within the first 6 hr to prevent the generation of suppressor cells; 18 hr after the initial periodate oxidation, borohydride treatment did not reverse the in vitro suppressive activity of periodate-treated cells. The kinetics of the disappearance of aldehydes from the cell surface were studied by using [3H]borohydride labeling and chromatographic analysis of sialic acid derivatives. About 70 to 80% of the aldehyde moieties were found to be present 6 hr after periodate oxidation. After 18 hr, 50 to 70% of the aldehyde had disappeared from the lymphocyte membrane. Oxidized sialyl residues disappear completely after 60 hr of culture. This period corresponds to the de novo synthesis of sialic acid residues on the surface of periodate-activated cells. The two classes of oxidized sialyl-glycoconjugates were found to behave in different ways. In effect, our data showed that the aldehydes remaining at 18 hr are mainly located on the gangliosides, whereas the aldehyde moieties located on high m.w. glycoproteins disappear from the cell surface between 9 and 18 hr. This would suggest that the remaining aldehydes located on gangliosides are not directly involved in the expression of suppressive activity.     

Preparation of neuraminidase-resistant human alpha 1-protease inhibitor and its clearance in rat blood circulation

The sialic acid residues of human alpha 1-protease inhibitor were modified by periodate oxidation and subsequent reductive amination with ethanolamine and sodium cyanoborohydride. The modified inhibitor retained its original trypsin inhibitory activity and was not digested by neuraminidase from Clostridium perfringens. The modified inhibitor disappeared from rat blood circulation at the same rate as the native inhibitor.     

Periodate oxidation and alkaline degradation of heparin-related glycans

Heparin, heparan sulphate, and various derivatives thereof have been oxidised with periodate at pH 3.0 and 4° and at pH 7.0 and 37°. Whereas oxidation under the latter conditions destroys all of the nonsulphated uronic acids, treatment with periodate at low pH and temperature causes selective oxidation of uronic acid residues. The reactivity of uronic acid residues depends on the nature of neighbouring 2-amino-2-deoxyglucose residues. d-Glucuronic acid residues are susceptible to oxidation when flanked by N-acetylated amino sugars, but resistant when adjacent residues are either unsubstituted or N-sulphated. L-Iduronic acid residues in their natural environment (2-deoxy-2-sulphoamino-d-glucose) are resistant to oxidation, whereas removal of N-sulphate groups renders a portion of these residues periodate-sensitive. Oxidised uronic acid residues in heparin-related glycans may be cleaved by alkali, producing a series of oligosaccharide fragments. Thus, periodate oxidation-alkaline elimination provides an additional method for the controlled degradation of heparin.     

The kinetics of suppression of proliferation of oxidized murine lymphoid cells by sodium borohydride reduction.

Murine splenic lymphoid cells are stimulated to proliferate following mild oxidation with sodium periodate. To assess the class of cells responding, we used periodate treatment alone or in association with concanavalin A, a T-cell mitogen, or lipopolysaccharide (LPS), primarily a B-cell mitogen. Brief periodate treatment followed by culturing with concanavalin A gave no additive proliferative response to that seen using concanavalin A alone, while culturing periodate-treated cells with LPS gave approximately an additive response. Furthermore, periodate failed to stimulate spleen cells from neonatally thymectomized mice while LPS produced significant stimulation of proliferation, suggesting that periodate is stimulating a class of T lymphoid cells or a subpopulation of T cells. Studies were performed to determine an optimal concentration of borohydride which would suppress proliferation in lymphoid cells initially oxidized with periodate. It was observed that 2 mM borohydride would suppress proliferation of oxidized cells yet permit a normal response of these cells to another T-cell mitogen, concanavalin A. Higher concentrations of borohydride, from 3 to 5 mM, would also suppress proliferation of oxidized cells but would interfere with the ability of these cells to respond to concanavalin A, perhaps due to cell damage. Studies were performed to determine when it was possible to suppress periodate-induced mitogenesis by reducing with borohydride at various times after the initial oxidation. It was observed that 2 mM borohydride treatment could suppress stimulation through 8 hr after the original periodate oxidation and that from 12 hr through 20 hr after the initial periodate oxidation, borohydride was incapable of inhibiting proliferation. Additional studies demonstrate that optimal mitogenesis induced by periodate or concanavalin A is contingent upon a serum factor.     

Oxidation of methionine residues in lutropin

Bovine lutropin and its subunits were submitted to oxidation by sodium periodate or chloramine T. Methionine residues were easily oxidized but partial destruction of fucose was observed. After oxidation treatment most of the lutropin exhibits the same elution volume in gel filtration as the native hormone. Sucrose gradient sedimentation or gel filtration experiments show however that the oxidation of isolated subunits is accompanied by aggregation of conformational changes even in the case of porcine beta subunit which contains only one methionine residue, unit and intact alpha subunit exhibit very low residual activity.     

The effects of sodium metaperiodate on T and B lymphocytes.

The differential mitogenic response of T and B lymphocytes to sodium metaperiodate has been investigated. It was found that periodate treatment leads to lymphocyte stimulation in spleen cells from Balb/c mice but not in spleen cells from the congenitally athymic nu/nu mice. In addition, treatment of Balb/c spleen cells with anti-θ serum plus complement lowers the mitogenic response to periodate and to concanavalin A without affecting the response to lipopolysaccharide. These results suggest a requirement for the presence of T lymphocytes in the initiation of a response to periodate. Spleen cells from nude mice also react with periodate, and their ability to respond to B cell mitogens is impaired after treatment with the chemical reagent.     

Enzymatic and chemical oxidation of gangliosides in cultured cells: effects of choleragen.

Cell surface glycolipids of normal human fibroblasts and NCTC2071 cells (transformed mouse fibroblasts) were labeled by incubating the intact cells with either galactose oxidase or sodium periodate, followed by reduction of the oxidized sugar residues with NaB3H4. In intact human fibroblasts, incorporation of 3H was increased with increasing time of exposure to galactose oxidase prior to treatment with NaB3H4. Following limited exposure to galactose oxidase, more label was incorporated into the larger glycolipids. Although labeling of the monosialoganglioside GM1 was maximal by 16 h, not all of the GM1 in the intact cells appeared to be accessible to galactose oxidase, since 10 to 12 times more GM1 was labeled when cells were disrupted before incubation with the enzyme. The human fibroblasts contained approximately 8 X 10(6) molecules of GM1 per cell. Maximal binding of choleragen (5 X 10(5) molecules of [125I]choleragen per cell) completely prevented cholevented oxidation of GM1 in intact fibroblasts by galactose oxidase but only partially protected the sialic acid moiety of GM1 from oxidation by periodate. Choleragen had little effect on the enzymatic or chemical oxidation of other glycolipids. NCTC 2071 cells do not contain endogenous GM1 but incorporate exogenous GM1 from the culture medium. When bound to NCTC 2071 cells, exogenous GM1 was protected by choleragen from oxidation by galactose oxidase or whether endogenous or taken up from the incubation medium, are, after interaction with choleragen, less accessible to oxidation by periodate or galactose oxidase.     

Structural characterization of the O-polysaccharide of the lipopolysaccharide produced by Salmonella milwaukee O:43 (group U) which possesses human blood group B activity.

The O-polysaccharide of the lipopolysaccharide produced by Salmonella milwaukee O:43 (group U) was shown by composition analysis, methylation, periodate oxidation, and 1H and 13C nuclear magnetic resonance spectroscopic analytical methods to be a polymer of branched pentasaccharide repeating units having the structure: [formula: see text] The blood-group activity of the O-polysaccharide was established by its serological reactivity with a specific monoclonal antibody to human blood group B, using passive hemagglutination and ELISA assays, indicating the common antigenic epitope to be a nonreducing terminal trisaccharide unit composed of L-Fucp and D-Galp (1:2) residues.     

Properties of human neutral bronchial mucins after modification of the peptide or the carbohydrate moieties.

Trypsin and pronase treatment of purified human neutral bronchial mucins released small fragments from the C-terminal end of these molecules and resulted in slight increases in their sedimentation coefficient presumably reflecting conformational changes. The antigenic determinant of neutral bronchial mucins which appears to be located on this C-terminal fragment is destroyed by pronase or by treatments such as periodate oxidation or galactose oxidase-bromine oxidation which modify the carbohydrate moieties. Thus, both amino acid and carbohydrate residues are involved in the structure of the antigenic determinant.     

Periodate inactivation of ovotransferrin and human serum transferrin

Azari and Phillips (Azari, P., and Phillips, J. L. 1970 Arch. Biochem. Biophys. 138, 32-38) reported that periodate treatment of iron-free ovotransferrin causes a rapid loss of iron-binding activity and an oxidation of 3 to 5 tyrosines and 1 tryptophan. Rapid inactivation and loss of tyrosine in ovotransferrin has been confirmed, and the work extended to human serum transferrin and effects of denaturing concentrations of urea. Extensive (> 80%) inactivations of both ovotransferrin and human serum transferrin were observed when approximately 4 tyrosines were destroyed. Amino acid analysis and 360-MHz 1H NMR spectra confirmed that tyrosines are the only residues rapidly oxidized; the correlation of tyrosine loss with the loss of iron-binding activity suggests strongly that the tyrosines involved are those that function as ligands to metal ions bound to the protein. NMR spectra also showed that periodate oxidation causes local changes of structure in ovotransferrin (presumably at the metal-binding sites) but does not grossly alter the conformation. The addition of 5 to 8 M urea greatly retarded the inactivation and losses of tyrosine.     

Structural studies of the O-specific polysaccharide from Serratia marcescens N.C.T.C. 1377

The putative O-specific polysaccharide of Serratia marcescens N.C.T.C. 1377 is a partially acetylated glucorhamnan. By means of 1H- and 12C-n.m.r. spectroscopy, methylation analysis, and periodate oxidation, it was shown that the polymer has a disaccharide repeating-unit for which the following structure is proposed: leads to 4)-alpha-D-Glcp-(1 leads to 3)-beta-L-Rhap-(1-leads. O-Acetyl groups are probably located at C-2 of the rhamnopyranosyl residues. Except for the extent of O-acetylation, the polysaccharide is identical with the corresponding product from S. marcescens Bizio (A.T.C.C. 264), for which a different structure has previously been proposed.     

Some quantitative histochemical studies of the periodic acid oxidation of glycogen in situ

Synposis The periodic acid oxidation of the glycogens in sections of ox liver fixed in Carnoy's fluid has been studied quantitatively. It was found that in 0.02 M acetate buffer at pH 5.0 the oxidation was rapid at first but levelled off after I hr. Even after prolonged oxidation (12 days), not more than 23–24% of the total available glycogen was oxidized. However, in the presence of electrolytes (e.g. 0.2.m sodium chloride) the oxidation was much greater. After 2.5 hr, for example, 40% of the available glycogen was oxidized. There was little difference in the velocity of oxidation in sections mounted on glass-slides and free-floating ones, or in free-floating sections of different thicknesses.Mounted and unmounted sections consumed on average 11–17 times more periodate than could be accounted for by the oxidation of their glycogen content.The results are interpreted in terms of a complex formed between periodate ions and the cuter glucosyl residues of the glycogen aggregate. The negative charge on the complex, it is suggested, prevents free periodate ions approaching and oxidizing the inner glycosyl residues.     

Immunochemical and chemical studies on streptococcal group-specific carbohydrates.

Structural studies on the carbohydrates of Groups A, C, and A-variant (AV) streptococci have utilized periodate oxidation, permethylation analysis, and immunochemical comparison of intact and periodate-oxidized polysaccharides. The data indicate that a similar 1,2- and 1,3-linked rhamnose chain is present in both the A and AV carbohydrates. The group A carbohydrate contains in addition N-acetylglucosamine residues at nonreducing terminals, whereas the AV is a homopolymer of rhamnose. There is some evidence that Group Ccarbohydrate contains the same rhamnose chain, but structural comparisons to the A and AV carbohydrates are complicated by the presence of intrachain N-acetylgalactosamine residues. Periodate oxidation and permethylation analysis show that while approximately 50% of the N-acetylgalactosamine of the Group C carbohydrate occupies terminal positions, the remainder is present as 1,3-linked units. Removal of the nonreducing terminal hexosamine units from the Group A carbohydrate by periodate treatment significantly enhanced its cross-reactivity with AV antiserum, whereas no enhancement was observed after similar treatment of the Group C carbohydrate. The data indicate the presence of an alpha-1,3-linked N-acetylgalactosamine disaccharide at the nonreducing terminal of the Group C carbohydrate.