Topo-optical reactions and polarization optical analysis of human lymphocytes

The latent birefringence of lymphocyte membranes of various species may readily be studied and analysed by various topo-optical reactions. The membranes of glutaraldehyde-fixed and PBS-washed lymphocytes show continuous birefringence with thiazine- and quinoline dyes. According to polarization optical analysis thiazine dye-stained cells are radially positive, whereas quinoline dye-stained cells are radially negative spherites, i.e. thiazine dye molecules are in a perpendicular, quinoline dye molecules in a parallel orientation relative to the membrane surface. These findings suggest that in lymphocyte membranes glycoproteins are primarily responsible for the topo-optical reactions. The actual conformational state of the glycoprotein components is a decisive factor not only in dye binding but also in the orientation of dye molecules. Heparin treatment directs attention to an important interaction between heparin and membrane glycoproteins. With the aid of the critical electrolyte concentration (CEC) technique we were able to demonstrate an ultrastructural differences between human erythrocyte and human lymphocyte membranes. After this procedure the birefringence of erythrocyte membranes was lost, whereas that of lymphocyte membranes did not change. There were no differences between the topo-optical reactions of T and B lymphocytes.     

Topo-optical investigations of human erythrocyte glycocalyx conformational changes induced by dextran

Cell surface properties are involved in the aggregation process of red blood cells. Using the topo-optical toluidine blue reaction, conformational changes of the glycocalyx (main component glycophorin A) were found when red blood cells were incubated and fixed in the presence of dextran. Relative differences in optical path as a measure of red blood cell membrane anisotropy decreased in relation to dextran concentration during fixation. These conformational changes could not be detected by electrophoretic measurements. When incubating, fixing and staining red blood cells in the presence of dextran, anisotropy decreased only at low dextran concentrations and increased at rising dextran concentrations. This biphasic course of differences in optical path seems to be due to different effects of dextran superimposing upon each other: a disturbing influence on the spatial order of sialic acid carrying oligosaccharide side chains due to H-bond interaction, and an increase in the size of dye aggregates and suppression of the thermal motion of macromolecules at higher dextran concentrations.     

Polarization optical analysis of blood cell membranes

The present study deals with investigations of membrane structure using polarization topo-optical reactions. Polarization microscopy is a special field of biological submicroscopic morphology. It represents a powerful tool well able to reveal the features of organization of biological structures, and the regularity of macromolecules building cells and tissues - properties that cannot directly be studied by other approaches to complex biological systems. Only in "pure" systems can X-ray diffraction, or the analysis of circular dichroism and the dispersion of optical rotability provide data equivalent to those obtained by polarization microscopy in complex systems. One of the main drawbacks of molecular biology is that most information is relevant to isolated, purified particles or macromolecules. Thus, no conclusions can be drawn concerning the original arrangement of molecules. The gap between biochemical-biophysical and morphological approaches to molecular arrangement in complex structures is bridged by the polarization optical technique. As was pointed out in the introduction, polarization microscopy became a routine biological research method following the pioneering work of Romhányi. His enlightening topo-optical reactions (Romhányi 1960, 1963, 1966) were based on the oriented dye binding of the original charge carriers of regularly arranged tissue constituents. The second group of Romhányi's topo-optical reactions comprised procedures such as sulfation (Romhányi et al. 1973, 1974), the aldehyde-bisulfite-toluidine blue (ABT) reaction (Romhányi et al. 1974, 1975), the permanganate-bisulfite-toluidine blue (PBT) reaction (Fischer 1979, 1979a), and the sialic acid-specific reaction (Makovitzky 1980) all of which operate with induced dye-binding groups; i.e. dye-binding moieties on biological macromolecules are produced by specific chemical reactions.     

Two Arginine Residues of Streptococcus gordonii Sialic Acid-Binding Adhesin Hsa Are Essential for Interaction to Host Cell Receptors

Hsa is a large, serine-rich protein of Streptococcus gordonii DL1 that mediates binding to α2-3-linked sialic acid termini of glycoproteins, including platelet glycoprotein Ibα, and erythrocyte membrane protein glycophorin A, and band 3. The binding of Hsa to platelet glycoprotein Ibα contributes to the pathogenesis of infective endocarditis. This interaction appears to be mediated by a second non-repetitive region (NR2) of Hsa. However, the molecular details of the interaction between the Hsa NR2 region and these glycoproteins are not well understood. In the present study, we identified the amino acid residues of the Hsa NR2 region that are involved in sialic acid recognition. To identify the sialic acid-binding site of Hsa NR2 region, we prepared various mutants of Hsa NR2 fused with glutathione transferase. Fusion proteins harboring Arg340 to Asn (R340N) or Arg365 to Asn (R365N) substitutions in the NR2 domain exhibited significantly reduced binding to human erythrocytes and platelets. A sugar-binding assay showed that these mutant proteins abolished binding to α2-3-linked sialic acid. Furthermore, we established S. gordonii DL1 derivatives that encoded the corresponding Hsa mutant protein. In whole-cell assays, these mutant strains showed significant reductions in hemagglutination, in platelet aggregation, and in adhesion to human leukocytes. These results indicate that the Arg340 and Arg365 residues of Hsa play an important role in the binding of Hsa to α2-3-linked sialic acid-containing glycoproteins.     

Polarization optical investigation by topo-optical reactions of various blood platelet aggregates

Phases I and II (early and advanced) of platelet aggregation could readily be followed and studied by various topo-optical reactions. Our studies indicate that in the early stage (monitored by an aggregometer) aggregates show no alteration in membrane structure of platelet. In the advanced stage (phase II), in addition to membrane alteration, platelets 2-3 times larger than in the control were observed. These were stained selectively in the pH 1-2 range with thiazine dyes. After hyaluronidase digestion they lost the ability to stain and became birefringent. The elucidation of this phenomenon requires further study.     

The effect of oral contraceptives on rat platelet membrane glycoproteins

Female rats were administered oral contraceptives and the levels of sialic acid on platelet membrane and granule glycoproteins were compared to controls using a sialic acid assay and a fluorescein-conjugated wheat germ agglutinin binding assay and also by measuring the binding of ¹²⁵I-labelled wheat germ agglutinin to glycoprotein bands from platelets separated by polyacrylamide electrophoresis. The contraceptive-treated rats showed increased levels of glycoprotein sialylation which may partly explain the altered physiological function of the platelets.     

Characterization of human blood platelet membrane proteins and glycoproteins by their isoelectric point (pI) and apparent molecular weight using two-dimensional electrophoresis and surface-labelling techniques

Intact human blood platelets were radioactively labelled at the surface by techniques specific for proteins or glycoproteins. Labelled platelet samples were analyzed by a high-resolution two-dimensional separation system involving isoelectric focusing in the first dimension and discontinuous sodium dodecyl sulphate-polyacrylamide gel electrophoresis in the second. The major platelet membrane glycoprotein (GP) bands (Ib, IIb, IIIa and IIIb) were found to be highly heterogeneous even after removal of terminal sialic acid residues. Lactoperoxidase-catalyzed iodination of platelets showed that the major labelled proteins (Ib, IIb, IIIa and IIIb) had altered isoelectric points ($\text{p}\text{I}$) and molecular weights after neuraminidase treatment. A number of membrane glycoproteins previously undetected by one-dimensional gel electrophoresis were demonstrated and good evidence provided that the major platelet surface proteins are glycosylated.     

The effects of growth in human serum on an acapsular group B Streptococcus mutant

Abstract A Group B Streptococcus Type III (GBS) mutant which, when grown in Todd Hewitt broth (THB), does not produce any detectable capsule, produced a clearly visible polysaccharide capsule when grown in human serum. We isolated cytoplasmic membranes from GBS and separated the component membrane proteins by polyacrylamide gel electrophoresis. A significant change in membrane composition was found during growth in human serum. Several unique proteins were produced on serum growth and there was both up- and down-regulation of other proteins. We measured the intracellular levels of sialic acid for a variety of GBS serotype III isolates. Interestingly, while there was little difference between the intracellular sialic levels of most isolates, the sialic acid level of COH31-15 grown in THB was over 100% higher than that of any other isolate. When grown in serum this pool was reduced to a level similar to that in other strains. The concentration of bacterial cell sialic acid was directly correlated with the sialic acid content of the serum. Exogenous sialic acid content, in concert with other serum factors, plays a role in determining the capsular size in GBS.     

Topo-optical reactions on the membrane of the human red cell ghost (author's transl)]

Previous studies have proved that the thiazin dyes toluidine blue, azure A, azure B, 1.9-dimethyl methylene blue and the quinolin dyes N,N'-diethylpseudoisocyanine chloride, N,N'-6,6'-dichlorpseudoisocyanine chloride are suitable for topo-optical reaction on the membrane of the red blood cells. In the present study the applicability of the thiazin and quinolin dyes on the membrane of the human red cell ghost was examined. Optical analysis revealed that the thiazin dyes are bound in radial position to the membrane, while the quinolin dyes are bound parallel to the membrane's plane.     

The suitability of further thiazine and quinoline dyes for topo-optical reactions on the plasmalemma (author's transl)]

The present studies prove that the thiazin dyes, azure B, azure C and thionin, and the quinolin dyes pinacyanol and its hydrochloride, are suitable for topo-optical staining of the plasmalemma. On the membrane surface the orientated bound dye molecules become stabilized, and with subsequent precipitation the anisotropic effect is reinforced. On optical analysis, the thiazin dye molecules (azure B, AZURE C and Thionin) are bound radially on the membrane. The molecules of the previously studied quinolin dye, N,N'-diethylpseudoisocyanide chloride are bound parallel to the membrane, while pinacyanol and its hydrochloride, like the thiazin dyes, are bound in the radial position.     

Is the lectin binding pattern of human breast and colon cancer cells influenced by modulators of sialic acid metabolism?

Sialic acid residues are the most abundant terminal carbohydrate residues of mammalian cells. Modification of the sialic acid residues by exposure of cells in culture to sialic acid precursor analogues resulted in a modifed susceptibility to polyoma viruses. In the present study, human breast and colon cancer cell lines were exposed for 65 h to these acid precursor analogues at 5 mM and their lectin binding pattern was analysed. Use of a panel of several different lectins indicated that the pretreatment of these cell lines with the sialic acid analogues did not change their lectin binding profile. The incorporation of these precursors into membrane glycoproteins was assessed by reversed phase high-performance liquid chromatography, which clearly demonstrated that the precursors were incorporated. The results therefore indicate that these analogues are highly specific for sialic acid and do not interfere with other biosynthetic pathways of membrane glycoconjugates.     

Removal or oxidation of surface membrane sialic acid inhibits formyl-peptide-induced polymorphonuclear leukocyte chemotaxis

Polymorphonuclear leukocyte (PMN) surface membrane glycoproteins are probably involved in the phenomenon of stimulus-response coupling. Consequently, we examined the effects of either removal or oxidation of surface membrane-associated sialic acid residues on some responses of human PMN to chemotactic factors. Treatment of human PMN with either neuraminidase or sodium metaperiodate did not affect the ability of these cells to migrate randomly, but did inhibit their ability to respond chemotactically to the synthetic peptide N-formyl-methionyl-leucyl-phenylalanine (FMLP). Treated PMN responded normally, however, to the complement-derived peptide C5a, and to the lipoxygenase product leukotriene B4. Enzymatic removal or oxidation of membrane sialic acid residues did not affect either FMLP-induced PMN degranulation or FMLP-induced generation by PMN of superoxide anion radicals. Removal of sialic acid did not significantly alter specific binding of [3H]FMLP to its receptor(s) on the PMN membrane. These findings indicate that sialic acid residues on the PMN surface membrane play an important role in modulating PMN responses to FMLP.     

Two-dimensional polyacrylamide-gel electrophoresis of the proteins and glycoproteins of purified human platelet surface and intracellular membranes.

By using highly purified surface and intracellular membrane fractions prepared from human platelets by free-flow electrophoresis, the polypeptide and glycopeptides of these membranes have been characterized by high-resolution gel electrophoresis under reducing and non-reducing conditions. Silver staining and a variety of glycoprotein-staining procedures have been applied to identify the major components. The principal finding was the clear disparity between the distribution patterns for these two membrane fractions. There are proportionately more low-Mr acidic components present in the intracellular membrane than in the surface-derived membrane. Of the major platelet surface glycoproteins GPIb, IIb, IIIa and IIIb (or IV) well expressed in the surface membrane only, GPIIb and IIIa appear as trace components in the intracellular membrane. The cytoskeleton proteins, actin, myosin, tropomyosin, actin-binding protein and alpha-actinin are prominent features of the surface membrane and essentially absent from the intracellular membrane. Neuraminidase treatment at the whole-cell level, before homogenization, which is an essential requirement for good resolution of the two membrane subfractions, modifies a number of the glycoprotein subunits with respect to their pI characteristics, suggesting much molecular micro-heterogeneity with respect to sialic acid content. A comparison of the staining characteristics of the major glycoproteins with periodic acid/Schiff's reagent and concanavalin A/peroxidase detection and a combined procedure revealed significant differences in associated carbohydrate structures, and the major concanavalin A-binding component was shown to be GPIIIa. These observations are discussed in the context of functional activities of both membrane systems in the physiological behaviour of the platelet.     

One-step purification of the serotonin transporter located at the human platelet plasma membrane.

A 68-kDa glycoprotein bearing the biological activity of the plasma membrane serotonin (5-hydroxytryptamine, 5-HT) transporter has been purified from human blood platelets, a classical cell model for the study of 5-HT uptake. After treatment of the whole platelet population or its plasma membrane fraction by sulfhydryl-dependent bacterial protein toxins or by digitonin, purification was reproducibly obtained by a one-step affinity chromatography using two different columns with 5-HT or 6-fluorotryptamine as ligands and elution by 5-HT or Na(+)-free buffer. The purified fraction migrated on sodium dodecyl sulfate-polyacrylamide gel electrophoresis as a single band with an apparent molecular mass of 68 kDa and exhibited an apparent isoelectric point of 5.6-6.2. Two sialic acid residues were detected in the purified material. The purified glycoprotein bound the 5-HT uptake blocker [3H]paroxetine with a Kd (0.25 nM) similar to the one observed for intact human platelets. It also bound [3H] 5-HT but neither [3H]hydroxytetrabenazine nor [3H] ouabain, the respective markers of the granular monoamine transporter and of the Na+,K(+)-ATPase associated to the plasma membrane 5-HT transporter. 5-HT derivatives and 5-HT uptake inhibitors exhibited similar Ki values for 5-HT uptake and paroxetine binding in intact human platelets and in the purified glycoprotein. Under laser UV irradiation, 40% of this purified glycoprotein could be labeled by either [3H]paroxetine or [3H]cyanoimipramine. No labeling was detected with either [3H] gamma-aminobutyric acid or [3H]GBR 12783, the respective markers of gamma-aminobutyric acid and dopamine carriers. The purified 68-kDa protein is therefore likely to correspond at least to the binding domain of the 5-HT transporter located at the human platelet plasma membrane.     

Quinolinic acid, an endogenous metabolite with neurotoxic properties, alters the physical state of membrane proteins in human erythrocytes

Quinolinic acid (2,3-pyridinedicarboxylic acid), an endogenous, tryptophan metabolite, is neurotoxic when injected into rat striatum (1). To begin to investigate the molecular interactions of quinolinic acid with membranes, electron spin resonance studies of the effects of this neurotoxin on the physical state of lipids, proteins, and cell-surface sialic acid in human erythrocyte ghosts have been performed. Quinolinic acid induced a highly significant alteration in the physical state of membrane proteins (P less than 0.01) while that of sialic acid and membrane lipids was unaffected. These results are similar to those induced by ibotenic acid, an exogenous neurotoxin, and are discussed with reference to possible molecular characteristics of the interaction of these neurotoxins with membrane proteins.     

Change in electrophoretic mobility of human erythrocyte as the result of membrane shape change in vitro.

Shape change of human erythrocyte due to the membrane externalization induced by incorporation of excess lysolecithin or by hypertonic treatment in vitro, was accompanied by a decrease in the electrophoretic mobility of the cell. No change in sialic acid content of the membrane, mostly responsible for the cell surface charge, was observed in any of these treatments. Therefore, the membrane externalization seems to cause a redistribution of the surface charge and the resulting alteration of the electrophoretic mobility of the cell. Heating at 48 degrees C for 1 hour induced both the shape change and change in the mobility, but at the same time it reduced the membrane sialic acid content.     

Differential distribution of sialic acid in alpha2,3 and alpha2,6 linkages in the apical membrane of cultured epithelial cells and tissues.

We used lectin cytochemistry and confocal microscopy to examine the distribution of sialic acid in epithelial cells. Maackia amurensis lectin and Sambuccus nigra agglutinin were used to detect alpha2,3 and alpha2,6 sialic acid, respectively. In Caco-2, HT-29 5M12, and MCF-7 cells, which express sialic acid mainly in one type of linkage, the majority of the signal was observed in the apical membrane. In cells that bound both lectins, alpha2,3 sialic acid was distributed apically, whereas alpha2,6 sialic acid showed a broader distribution. In IMIM-PC-1 cultures, alpha2,3 sialic acid was detected mainly in the apical membrane, whereas alpha2,6 sialic acid was more abundant in the basolateral domain of polarized cells. In these cells, treatment with GalNAc-O-benzyl led to reduced alpha2,3 levels and to an increase and redistribution of alpha2,6 to the apical domain. Similarly, sialic acid was predominantly expressed apically in all epithelial tissues examined. In conclusion, (a) sialic acid is mainly distributed to the apical membrane of epithelial cells, (b) there is a hierarchy in the distribution of sialic acids in polarized epithelial cells, i.e., alpha2,3 is preferred to alpha2,6 in the apical membrane, and (c) IMIM-PC-1 cells are a good model in which to study the regulation of the levels and distribution of sialic acids.     

The effect of sialic acid on adenylate cyclase activity and thyrotropin-receptor binding in human thyroid membranes.

Exogenous sialic acid at 3 mM and higher concentrations inhibits the basal adenylate cyclase activity and the activity stimulated by thyrotropin (TSH) and fluoride in the human thyroid membrane fraction; 30 mM-sialic acid acts as an inhibitor of TSH binding. The decrease of these activities at high sialic acid concentrations might be ascribed to changes in membrane conformation caused by acidic character of this sugar.     

Higher reactivity of apolipoprotein B-100 and alpha-tocopherol compared to sialic acid moiety of low-density lipoprotein (LDL) in radical reaction

Radical reaction of low-density lipoprotein (LDL) is a key step in atherogenesis and causes both a decrease in the sialic acid moiety and modification of apolipoprotein B-100 (apoB). Although apoB modification (cross-link and fragmentation) increases in atherosclerosis, the change in apoB-bound sialic acid in atherosclerosis is controversial. To elucidate the physiological implications of desialylation of LDL by radical reaction, the reactivity of sialic acid of LDL was compared with that of apoB, which underwent facile fragmentation in radical reactions. ApoB was determined by immunoblot analysis with anti-apoB antiserum, and the sialic acid moiety was measured by blot analysis with a biotin-bound lectin [biotin-SSA from Japanese elderberry (Sambucus sieboldiana)] specific to sialic acid. When human LDL was oxidized with Cu(2+) at 37 degrees C, apoB and apoB-attached sialic acid decreased simultaneously. Comparison of the staining bands with anti-apoB and with biotin-SSA shows that sialic acid moieties still remain on fragmented apoB proteins, indicating that the decrease in sialic acid is much slower than that of apoB fragmentation. In addition, human plasma was oxidized with 400 microM of Cu(2+) at 37 degrees C. Similar analysis indicates that the decrease in sialic acid attached to apoB also results from the fragmentation of apoB. This study indicates that the fragmentation of apoB proceeds at a much faster rate than the decrease in sialic acid content when a free radical reaction is induced in isolated LDL as well as in plasma LDL exposed to Cu(2+)-induced oxidative stress. On the basis of these results, the modification of apoB is much more sensitive than the decrease in sialic acid as an indicator of oxidative stress.     

Disorders of lysosomal membrane transport--cystinosis and Salla disease

Two lysosomal storage diseases are now known to result from impaired transport of small molecules across the lysosomal membrane. In cystinosis, the disulfide amino acid, cystine, accumulates and in free sialic acid storage disorders, N-acetylneuraminic acid is stored. The lysosomal cystine carrier exhibits saturability, counter-transport, temperature dependence, and stereospecificity; it is highly specific for molecules resembling cystine. Less is known about sialic acid transport, but its temperature dependence and deficiency in certain autosomal-recessive human mutations strongly suggests that it is a carrier-mediated process. Cystine and sialic acid serve as prototypes for amino acids and sugars transported by specific lysosomal membrane carriers, whose impairment results in lysosomal storage disorders.