On the role of the collagen carbohydrate residues in the platelet. Collagen interaction.

It has been proposed that the platelet : collagen interaction is mediated in part by the collagen carbohydrate residues. To test this hypothesis we have oxidized monomeric and polymeric collagen with sodium periodate under conditions specifically designed to minimize destruction of periodate-susceptible bonds other than in the carbohydrate residues. Oxidation of the collagen significantly reduced its ability to interact with platelets. The extent of inhibition paralleled the extent of carbohydrate destruction. Oxidation with periodate also delayed the polymerization of the monomeric collagen, but even after polymerization the oxidized collagen failed to initiate the release reaction. These observations suggest that the collagen carbohydrate residues may be either near to or part of the site(s) on the collagen molecule required for platelet adhesion.     

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.     

Histochemical detection of sialic acid residues using periodate oxidation

Synopsis The use of low concentrations of periodate for the detection of sialic acid residues in tissue sections has been investigated. Oxidation of aqueous solutions of sugar glycosides with 0.4mm periodate revealed that sialic acid was oxidized more rapidly than other sugars found in glycoproteins. Sequential treatment of tissue sections with 0.4mm periodate for 30 min followed by Schiff's reagent stained sialic acid residues but other sugar components were not stained under these conditions.     

The role of carbohydrate in the glycoenzyme invertase of Neurospora crassa.

Data obtained concerning the carbohydrate moieties of the glycoenzyme invertase (EC 3.2.1.26, beta-D-fructofuranoside fructohydrolase) from Neurospora crassa were consistent with a linkage of some carbohydrate chains by O-glycosidic bonds to serine and threonine residues; the possibility of N-glycosylamine linkage of some of the carbohydrate to the amide group of asparagine is also indicated. The invertase was remarkably stable on storage at low temperatures. Oxidation of the carbohydrate residues in the enzyme by sodium periodate markedly affected the heat-stability of the enzyme. It is suggested that the carbohydrate moieties function as stabilizers of the tertiary structure of the glycoenzyme.     

Periodate oxidation of sperm-whale myoglobin and the role of the methionine residues in the antigen–antibody reaction

1. Oxidation of sperm-whale metmyoglobin and its apoprotein with periodate has been investigated under various conditions of pH and temperature to find those under which the reagent acted with specificity. 2. At pH6.8 and 22 degrees consumption of periodate ceased in 3(1/2)hr. at 43 moles of periodate/mole of myoglobin. The two methionine residues, the two tryptophan residues, the three tyrosine residues and two histidine residues were oxidized; serine increased in the hydrolysates from 6 to 9 residues/mol. 3. At pH5.0 and 22 degrees , consumption levelled off in 4(1/2)hr. at 26 moles of periodate/mole of myoglobin and resulted in the modification of the two methionine residues, the two tryptophan residues, the three tyrosine residues and two histidine residues; serine increased from 6 to 7 residues/mol. and, also, ferrihaem suffered considerable oxidation. 4. Oxidation at pH5.0 and 0 degrees resulted at completion (4hr.) in the consumption of 22 moles of periodate/mole of myoglobin and in the modification of the methionine, tyrosine and tryptophan residues. Spectral studies indicated oxidation of the haem group. This derivative reacted very poorly with rabbit antisera to MbX (the major component no. 10 obtained by CM-cellulose chromatography; Atassi, 1964). 5. Oxidation of apomyoglobin at pH5.0 and 0 degrees was complete in 4hr. with the consumption of 7.23 moles of periodate/mole of apoprotein. The rate of oxidation in decreasing order was: methionine; tryptophan; tyrosine; and after 7hr. of reaction the following residues/mol. were oxidized: methionine, 2.0; tryptophan, 1.6; tyrosine, 0.99. No peptide bonds were cleaved. Metmyoglobin prepared from the 7hr.-oxidized apoprotein showed that the reactivity with antisera to MbX had diminished considerably. 6. Milder oxidation of apoprotein (2 molar excess of periodate, pH5.0, 0 degrees , 2hr.) resulted in the modification of 1.66 residues of methionine/mol. Metmyoglobin prepared from this apoprotein was identical with native MbX spectrally, electrophoretically and immunochemically. It was concluded that the methionine residues at positions 55 and 131 were not essential parts of the antigenic sites of metmyoglobin.     

Evaluation of periodate/lysine/paraformaldehyde fixation as a method for cross-linking plasma membrane glycoproteins

Fixation by periodate/lysine/paraformaldehyde, a method purported to cross-link specifically plasma membrane glycoproteins, was evaluated using Novikoff rat ascites hepatocellular carcinoma cells. Cells were treated with periodate/lysine, periodate/glycine, and periodate/lysine/paraformaldehyde and subsequently reduced with NaB3H4. The glycoproteins labeled with 3H were resolved by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate and visualized by fluorography. The effects of reactant concentrations on 3H-labeling of cellular components, cell viability, and cross-linkage of 3H-labeled proteins were examined. The effect of increasing the localized density of plasma membrane glycoproteins on the extent of cross-linkage by periodate and lysine was investigated using cells in which patching of the plasma membrane glycoproteins had been induced by ferritin-conjugated concanavalin A/rabbit antiferritin antiserum. Also investigated was the periodate-independent to mixtures of periodate and lysine or glycine. Results of these studies did not support a mechanism of cross-linking involving reaction between the free base lysin and aldehyde groups on periodate oxidized carbohydrate residues but suggested a complex interaction between periodate oxidized plasma membrane glycoproteins and polymeric complexes of lysine and formaldehyde.U     

Structural studies on carcinoembryonic antigen. Periodate oxidation.

Periodate oxidation has been applied to examine the carbohydrate structure of carcinoembryonic antigen (CEA) and the possible role of the carbohydrate residues in its antigenic activity. Sialic acid (N-acetylneuraminic acid) and fucose were completely destroyed, and galactose and mannose were partially destroyed by a single periodate treatment. Serial periodate treatment (Smith degradation) destroyed additional amounts of galactose and mannose as well as significant amounts of N-acetylglucosamine. Prior removal of sialic acid by neuraminidase treatment led to increased destruction of galactose by periodate. Antigenic activity persisted indicating that the residues destroyed played little, if any, part in the antigenicity of CEA. These results yield an initial view of the structural arrangement of the carbohydrate residues in the CEA molecule.     

Sulfation as a collagen-specific reaction The ultrastructure of sulfate collagen,basement membranes and reticulin fibers as shown by topo-optical staining reactions

Summary Sulfation induces hyperbasophilia in connective tissue structures (fibrillary collagen, basement membranes and reticulin fibers), which appear metachromatic with toluidine blue at pH 1.0 and strongly birefringent with inversion of their positive birefringence into negative birefringence indicating transversally oriented and closely packed dye molecules on the micellar surface of collagen. Quantitative studies of the sulfation induced topooptical staining reaction following blocking of the vicinal glycol groups by periodate and the enzymatic removal of AMP support the view that carbohydrate glycol groups play only a minor part and the OH side-groups of the collagen peptide chains play the major part in the sulfation reaction of fibrillary collagen and basement membranes.After blocking of the vicinal glycol groups of carbohydrate components by periodate, sulfation induced toluidine blue hyperbasophilia with strong negative birefringence associated with selective proteolytic sensitivity are collagen-specific characeteristics due to sulfate esterification on the OH groups of the peptide chains of collagen, which provide new approach to the study of the ultrastructure of connective tissue elements in physiology and pathology.     

Studies on the metabolism of the protozoa: The molecular structure of the reserve polysaccharide from Astasia ocellata

1. The flagellate Astasia ocellata synthesizes as reserve carbohydrate a water-insoluble polysaccharide (paramylon) containing chains of beta-(1-->3)-linked d-glucose residues. 2. The average chain length, determined by methylation analysis, is about 43, and the minimum degree of polymerization from periodate oxidation data is 50-55. Most of the molecules are therefore essentially linear.     

Oxidation of the capsular polysaccharide of pneumococcal type IV by periodate

The immunologically specific capsular polysaccharide of pneumococcal type IV was oxidized with periodate before removal, and after partial and almost complete removal of pyruvic acid residues. Destruction of the D-galactose residues was approximately proportional to the extent of removal of pyruvic acid residues, with relatively little effect on immunological specificity until more than one-third of the D-galactose residues had been affected. The residues of the three amino sugars, 2-amino-2-deoxy-D-galactose, 2-amino-2-deoxymannose, and 2-amino-2,6-dideoxygalactose (fucosamine) were resistant to periodate oxidation and appeared to be separated from each other by one or more residues of (1→4)-linked O-pyruvyl-D-galactose. There was also evidence for nonreducing end-groups of O-pyruvyl-D-galactose. The pyruvyl residues are acetal-linked, possibly to positions 3 and 6 of D-galactose residues.     

Platelet adhesion to collagen. Factors affecting Mg2(+)-dependent and bivalent-cation-independent adhesion.

Platelet adhesion to collagens immobilized on plastic has been measured, with the following results. (1) Human, but not rabbit, platelets adhered readily to pepsin-extracted monomeric collagens in an Mg2(+)-dependent manner. (2) Rabbit platelets adhered to a monomeric collagen extracted without pepsin by a process that was cation-independent; human platelet adhesion to this collagen exhibited a cation-independent element. (3) Human platelet adhesion to polymeric collagens, including intact native fibres and those reconstituted from pepsin-extracted monomeric collagens, exhibited appreciable cation-independence; adhesion of rabbit platelets to these collagens occurred only by a cation-independent process; pepsin treatment of the intact fibres caused a reduction in cation-independent binding. Two mechanisms of adhesion can therefore be distinguished, one Mg2(+)-dependent, expressed by human, but not rabbit, platelets, the other cation-independent and exhibited by platelets of both species. Mg2(+)-dependent and cation-independent adhesion sites are located within the triple helix of collagen, but the latter sites are only expressed in collagen in polymeric form. In neither case is the helical conformation of the sites essential for their binding activity. Cation-independent adhesion sites are also located in the pepsin-sensitive non-helical telopeptides of collagen and can be expressed in both monomeric and polymeric collagens. Chemical modification of collagen lysine residues indicates that specific lysine residues may be involved in Mg2(+)-dependent adhesion. Adhesion using human citrated platelet-rich plasma is Mg2(+)-independent. Plasma contains factors, conceivably the adhesive proteins fibronectin and von Willebrand factor, that promote the Mg2(+)-independent mechanism.     

Reversed phase chromatographic analysis of Nostoc and Euglena isoleucyl-tRNAs aminoacylated in vitro in homologous and heterologous systems.

To investigate the mechanisms governing collagen interaction with blood platelets, the effects of side-chain modifications on collagen-induced platelet aggregation and release of serotonin were studied. Since many chemical modifications alter the ability of collagen to form fibers that, according to current theory, may complicate interpretation of data, we eliminated this possibility by using collagen stabilized in a native-type fibrillar structure by treatment with either glutaraldehyde or ultraviolet irradiation. Acetylation, methylation, succinylation, treatment with 2,4-dinitrofluorobenzene, 2,4,6-trinitrobenzene sulfonic acid or 1,2-cyclohexanedione, and deguanidination with hypobromite were used to modify collagen side-chain reactive groups: amino, carboxyl, hydroxyl and guanidino. Both unmodified monomeric dispersed and fibrillar collagen preparations initiated platelet aggregation and release, although the kinetics and magnitude of the response were different. Monomeric collagen which had been modified by deguanidination, methylation or succinylation, failed to polymerize in physiological conditions and did not induce platelet aggregation and release. However, none of the chemical modifications of stabilized native-type collagen fibers, except treatment with hypobromite or cyclohexanedione, had an effect on collagen-induced platelet aggregation and release. Both hypobromite and cyclohexanedione modified guanidino groups of arginyl residues. Results showed that the ability of a collagen sample to induce platelet aggregation and release of serotonin is dependent on the arginine content of fibrillar collagen. These data demonstrate that manipulation of amino, carboxyl and hydroxyl groups is unimportant as long as the native-type fibrillar structure is maintained, and that arginyl residues are directly involved in collagen-platelet interaction. Moreover, the data suggest that only the arginyl residues in the Y position of the tripeptide unit Gly-X-Y of collagen are responsible.     

Collagen-induced platelet aggregation and release. II critical size and structural requirements of collagen

To investigate the mechanisms governing collagen interaction with blood platelets, the effects of side-chain modifications on collagen-induced platelet aggregation and release of serotonin were studied. Since many chemical modifications alter the ability of collagen to form fibers that, according to current theory, may complicate interpretation of data, we eliminated this possibility by using collagen stabilized in a native-type fibrillar structure by treatment with either glutaraldehyde or ultraviolet irradiation. Acetylation, methylation, succinylation, treatment with 2,4-dinitrofluorobenzene, 2,4,6-trinitrobenzene sulfonic acid or 1,2-cyclohexanedione, and deguanidination with hypobromite were used to modify collagen side-chain reactive groups: amino, carboxyl, hydroxyl and guanidino. Both unmodified monomeric dispersed and fibrillar collagen preparations initiated platelet aggregation and release, although the kinetics and magnitude of the response were different. Monomeric collagen which had been modified by deguanidination, methylation or succinylation, failed to polymerize in physiological conditions and did not induce platelet aggregation and release. However, none of the chemical modifications of stabilized native-type collagen fibers, except treatment with hypobromite or cyclohexanedione, had an effect on collagen-induced platelet aggregation and release. Both hypobromite and cyclohexanedione modified guanidino groups of arginyl residues. Results showed that the ability of a collagen sample to induce platelet aggregation and release of serotonin is dependent on the arginine content of fibrillar collagen.These data demonstrate that manipulation of amino, carboxyl and hydroxyl groups is unimportant as long as the native-type fibrillar structure is maintained, and that arginyl residues are directly involved in collagen-platelet interaction. Moreover, the data suggest that only the arginyl residues in the Y position of the tripeptide unit Gly-X-Y of collagen are responsible.     

Collagen-induced platelet aggregation and release. I effects of side-chain modifications and role of arginyl residues

To investigate the mechanisms governing collagen interaction with blood platelets, the effects of side-chain modifications on collagen-induced platelet aggregation and release of serotonin were studied. Since many chemical modifications alter the ability of collagen to form fibers that, according to current theory, may complicate interpretation of data, we eliminated this possibility by using collagen stabilized in a native-type fibrillar structure by treatment with either glutaraldehyde or ultraviolet irradiation. Acetylation, methylation, succinylation, treatment with 2,4-dinitrofluorobenzene, 2,4,6-trinitrobenzene sulfonic acid or 1,2-cyclohexanedione, and deguanidination with hypobromite were used to modify collagen side-chain reactive groups: amino, carboxyl, hydroxyl and guanidino. Both unmodified monomeric dispersed and fibrillar collagen preparations initiated platelet aggregation and release, although the kinetics and magnitude of the response were different. Monomeric collagen which had been modified by deguanidination, methylation or succinylation, failed to polymerize in physiological conditions and did not induce platelet aggregation and release. However, none of the chemical modifications of stabilized native-type collagen fibers, except treatment with hypobromite or cyclohexanedione, had an effect on collagen-induced platelet aggregation and release. Both hypobromite and cyclohexanedione modified guanidino groups of arginyl residues. Results showed that the ability of a collagen sample to induce platelet aggregation and release of serotonin is dependent on the arginine content of fibrillar collagen.These data demonstrate that manipulation of amino, carboxyl and hydroxyl groups is unimportant as long as the native-type fibrillar structure is maintained, and that arginyl residues are directly involved in collagen-platelet interaction. Moreover, the data suggest that only the arginyl residues in the Y position of the tripeptide unit Gly-X-Y of collagen are responsible.     

Effect of the 807 C/T polymorphism in glycoprotein la on blood platelet reactivity

The 807 C/T dimorphism in the GPla gene has been shown to affect GPlalla receptor density, which can affect platelet adhesiveness to collagens. In this work, we studied platelet function mediated by GPlalla. The 807 T/T genotype was associated with increased platelet adhesion to monomeric collagen after activation with ADP, but not following activation with thrombin and U46619. Adhesion to fibrillar collagen and PFA-100 closure time were not different between carriers of the C/C and T/T genotypes. Also, to monitor the role of the 807 C/T polymorphism in the sensitivity to platelet antagonists, anti-GPlalla monoclonal antibodies (Gi9) were used. Irrespective of the 807 C/T genotype, Gi9 inhibited the ADP-induced platelet adhesion to the monomeric collagen-coated surface stronger than adhesion evoked by thrombin. Moreover, Gi9 significantly inhibited platelet adhesion to both monomeric and fibrillar collagen in 807 T/T carriers, whereas in 807 C/C subjects, Gi9 blocked only adhesion to monomeric collagen. Our results indicate that the 807 T/T genotype is related to increased platelet activation induced by ADP and higher platelet sensitivity to GPlalla antagonists.     

Rigid structural requirement of the 5' terminus of mRNA for translational activity.

Oxidation by sodium periodate of the ribose cis-diol of the 5′ terminal of liver mRNA to the corresponding dialdehyde virtually destroyed its template activity in the wheat germ translation system. The rigid structural requirement for the ribose cis-diol is indicated by the failure of reduction of the dialdehyde to the corresponding primary alcohols to restore the template activity of the mRNA. Sodium periodate alone inhibited the translational system at concentrations above 0.25 mM. Purification of the periodate oxidized mRNA by sucrose density gradient centrifugation or exclusion on Sephadex G-100 did not increase its template activity. Periodate oxidized mRNA was not inhibitory to translation of untreated mRNA.     

Periodate oxidation of sodium alginate in water and in ethanol-water mixture: a comparative study

Periodate oxidation of sodium alginate in aqueous solution as well as a dispersion in 1:1 ethanol-water was examined. The oxidation proceeded smoothly in both media, and the kinetics of oxidation was surprisingly similar. Polymer cleavage was observed in both media, but it was extensive in ethanol-water. The weight-average molar mass (Mw) of the oxidized product obtained from aqueous solution showed a gradual decrease with increase in the periodate concentration, whereas, except for very high periodate equivalent, the change in Mw was not reflected with increase in concentration of periodate in ethanol-water. The oxidized alginate obtained from the ethanol-water mixture was found to be more efficient in crosslinking proteins such as gelatin, leading to hydrogels. Oxidation of a dispersion has the advantage of generating large quantities of the oxidized alginate in higher yield with one reaction using less solvent.     

Binding of human monomeric type I collagen to platelets

Interaction of platelets with subendothelial collagen is important in primary hemostasis and thrombosis. Although activation of platelets by collagen polymers has been widely investigated, only insufficient data are available concerning the binding of genetically distinct collagen types in their triple helical (monomeric) form to platelets. We report on the binding of 125I-labeled human type I collagen to platelets. The binding assay was performed at 20 degrees C in the presence of arginine in order to prevent polymerization of the collagen monomers. The binding of monomeric 125I-labeled human type I collagen is dose- and time-dependent, saturable and specific, since it is competitively inhibited by unlabeled type I collagen, but not by unlabeled human type V collagen. Scatchard analysis reveals a class of specific high affinity binding sites with a Kd of 2.5 X 10(-8) M. These results suggest that platelets interact with type I collagen through specific binding sites, and that there are various different binding sites on the platelet membrane for the genetically distinct collagen types.     

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.     

The oxidation produced by hydrogen peroxide on Ca-ATP-G-actin

We report here that in vitro exposure of monomeric actin to hydrogen peroxide leads to a conversion of 6 of the 16 methionine residues to methionine sulfoxide residues. Although the initial effect of H2O2 on actin is the oxidation of Cys374, we have found that Met44, Met47, Met176, Met190, Met269, and Met355 are the other sites of the oxidative modification. Met44 and Met47 are the methionyl sites first oxidized. The methionine residues that are oxidized are not simply related to their accessibility to the external medium and are found in all four subdomains of actin. The conformations of subdomain 1, a region critical for the functional binding of different actin-binding proteins, and subdomain 2, which plays important roles in the polymerization process and stabilization of the actin filament, are changed upon oxidation. The conformational changes are deduced from the increased exposure of hydrophobic residues, which correlates with methionine sulfoxide formation, from the perturbations in tryptophan fluorescence, and from the decreased susceptibility to limited proteolysis of oxidized actin.