Binding of disaccharides by peanut agglutinin as studied by ultraviolet difference spectroscopy

Exosomal Thomsen-Friedenreich Glycoantigen: A New Liquid Biopsy Biomarker for Lung and Breast Cancer Diagnoses

Exosomes are nanosized extracellular vesicles released by cells to transport biomolecules such as proteins and RNAs for intercellular communication. Exosomes play important roles in cancer development and metastasis; therefore, they have emerged as potential liquid biopsy biomarkers for cancer screening, diagnosis, and management. Many exosome cargos, including proteins, RNAs, and lipids, have been extensively investigated as biomarkers for cancer liquid biopsy. However, carbohydrates, an important type of biomolecule, have not yet been explored for this purpose. In this study, we reported a new exosomal carbohydrate biomarker, α-linked Thomsen-Friedenreich glycoantigen (TF-Ag-α; Galβ1-3GalNAc-α). To translate our discovery into clinical settings, we developed a surface plasmon resonance-based assay which utilized a unique mAb, JAA-F11, with high specificity to measure the levels of exosomal TF-Ag-α in blood. To the best of our knowledge, we are the first to demonstrate that exosomes carry TF-Ag-α. We detected exosomal TF-Ag-α in as low as 10 μL serum samples from patients with cancer, but in contrast, levels were negligible in those from normal controls. With a total of 233 patients with cancer and normal controls, we showed that exosomal TF-Ag-α detected lung cancer (n = 60) and breast cancer (n = 95) from normal controls (n = 78) with ≥95% and ≥97% accuracy, respectively. These results demonstrated that exosomal TF-Ag-α is a potential liquid biopsy biomarker for cancer diagnosis.

SIGNIFICANCE

Exosomes or small extracellular vesicles have emerged as potent biomarkers of cancer liquid biopsy. We discovered a new exosomal carbohydrate marker, TF-Ag-α (Galβ1-3GalNAc-α), and showed that exosomal TF-Ag-α detected both lung and breast cancers with >95% accuracy. Our findings demonstrated that exosomal TF-Ag-α is a promising liquid biopsy biomarker for cancer screening and early detection.

Catalyst-proximity protein chemical labelling on affinity beads targeting endogenous lectins

Catalyst-proximity labelling on affinity beads enables the identification of ligand-binding proteins such as lectins, which cannot be analyzed by conventional techniques. 1-Methyl-4-arylurazole (MAUra) efficiently labels proteins bound to the beads.

Preclinical Analysis of JAA-F11, a Specific Anti-Thomsen-Friedenreich Antibody via Immunohistochemistry and In Vivo Imaging

The tumor specificity of JAA-F11, a novel monoclonal antibody specific for the Thomsen-Friedenreich cancer antigen (TF-Ag-alpha linked), has been comprehensively studied by in vitro immunohistochemical (IHC) staining of human tumor and normal tissue microarrays and in vivo biodistribution and imaging by micro-positron emission tomography imaging in breast and lung tumor models in mice. The IHC analysis detailed herein is the comprehensive biological analysis of the tumor specificity of JAA-F11 antibody performed as JAA-F11 is progressing towards preclinical safety testing and clinical trials. Wide tumor reactivity of JAA-F11, relative to the matched mouse IgG3 (control), was observed in 85% of 1269 cases of breast, lung, prostate, colon, bladder, and ovarian cancer. Staining on tissues from breast cancer cases was similar regardless of hormonal or Her2 status, and this is particularly important in finding a target on the currently untargetable triple-negative breast cancer subtype. Humanization of JAA-F11 was recently carried out as explained in a companion paper "Humanization of JAA-F11, a Highly Specific Anti-Thomsen-Friedenreich Pancarcinoma Antibody and In Vitro Efficacy Analysis" (Neoplasia 19: 716-733, 2017), and it was confirmed that humanization did not affect chemical specificity. IHC studies with humanized JAA-F11 showed similar binding to human breast tumor tissues. In vivo imaging and biodistribution studies in a mouse syngeneic breast cancer model and in a mouse-human xenograft lung cancer model with humanized 124I- JAA-F11 construct confirmed in vitro tumor reactivity and specificity. In conclusion, the tumor reactivity of JAA-F11 supports the continued development of JAA-F11 as a targeted cancer therapeutic for multiple cancers, including those with unmet need.

Organic modification and subsequent biofunctionalization of porous anodic alumina using terminal alkynes

Porous anodic alumina (PAA) is a well-defined material that has found many applications. The range of applications toward sensing and recognition can be greatly expanded if the alumina surface is covalently modified with an organic monolayer. Here, we present a new method for the organic modification of PAA based on the reaction of terminal alkynes with the alumina surface. The reaction results in the the formation of a monolayer within several hours at 80 °C and is dependent on both oxygen and light. Characterization with X-ray photoelectron spectroscopy and infrared spectroscopy indicates formation of a well-defined monolayer in which the adsorbed species is an oxidation product of the 1-alkyne, namely, its α-hydroxy carboxylate. The obtained monolayers are fairly stable in water and at elevated temperatures, as was shown by monitoring the water contact angle. Modification with 1,15-hexadecadiyne resulted in a surface that has alkyne end groups available for further reaction, as was demonstrated by the subsequent reaction of N-(11-azido-3,6,9-trioxaundecyl)trifluoroacetamide with the modified surface. Biofunctionalization was explored by coupling 11-azidoundecyl lactoside to the surface and studying the subsequent adsorption of the lectin peanut agglutinin (PNA) and the yeast Candida albicans, respectively. Selective and reversible binding of PNA to the lactosylated surfaces was demonstrated. Moreover, PNA adsorption was higher on surfaces that exposed the β-lactoside than on those that displayed the α anomer, which was attributed to surface-associated steric hindrance. Likewise, the lactosylated surfaces showed increased colonization of C. albicans compared to unmodified surfaces, presumably due to interactions involving the cell wall β-glucan. Thus, this study provides a new modification method for PAA surfaces and shows that it can be used to induce selective adsorption of proteins and microorganisms.

Detection of carbohydrate-binding proteins by oligosaccharide-modified polypyrrole interfaces using electrochemical surface plasmon resonance

This paper reports on the use of electrochemical surface plasmon resonance (E-SPR) for the detection of carbohydrate-binding proteins. The generation of an SPR sensor specific to lectins Arachis hypogaea (PNA) and Maackia amurensis (MAA) is based on the electrochemical polymerization of oligosaccharide derivatives functionalized by pyrrole groups. The resulting thin conducting polymer films were characterized using E-SPR and atomic force microscopy (AFM). The specific binding of PNA to polypyrrole-lactosyl and of MAA to polypyrrole-3'-sialyllactosyl films was investigated using SPR. The detection limit was 41 nM for PNA and 83 nM for MAA. Through Scatchard analysis and linear transformation of the SPR sensorgram data, association (k(ass)) and dissociation rate constants (k(diss)) could be determined.

Investigation of the interaction between peanut agglutinin and synthetic glycopolymeric multivalent ligands

The interaction between synthetic glycoplymers bearing beta-D-galactose side groups and the lectin peanut agglutinin (PNA) was investigated by UV-difference spectroscopy and isothermal titration calorimetry (ITC). UV-difference spectroscopy indicated that the polymer-lectin interaction was stronger than that between PNA and either the corresponding monomer, D-galactose or D-lactose. The thermodynamics of binding (K, DeltaG, DeltaH, DeltaS and n) were determined from ITC data by fitting with a two-site, non-cooperative binding model. It was found that the glycopolymer displayed around a 50 times greater affinity for the lectin than the parent carbohydrate, and around 10 times greater than the monomer, on a valency-corrected basis. Binding was found to be entropically driven, and was accompanied by aggregation and precipitation of protein molecules. Furthermore, interesting differences between polymers prepared either from deacetylated monomers, or by deacetylation of pre-formed polymers, were found.

Binding specificity of mannose-specific carbohydrate-binding protein from the cell surface of Trypanosoma cruzi

The sugar binding specificity of the recently described mannose-specific carbohydrate-binding proteins (CBP) isolated to homogeneity from both the epimastigote and trypomastigote stages of the pathogenic protozoa Trypanosoma cruzi has been studied by quantitative hapten inhibition of the biotinylated CBPs to immobilized thyroglobulin using model oligosaccharides. The results clearly show a differential specificity toward high-mannose glycans between the CBPs from the two developmental stages. Thus, the isolated CBP from epimastigotes exhibited stronger affinity for higher mannose oligomers containing the Manalpha1-2Manalpha1-6Manalpha1-6 structure. Its affinity decreased, as did the number of mannose residues on the oligomer or removal of the terminal Manalpha1-2-linked mannose. By contrast the CBP isolated from the trypomastigote stage showed about 400-fold lower avidity than the epimastigote form, and contrary to it, it was slightly more specific toward Man5GlcNAc than Man9GlcNAc. Analysis of the interaction of epimastigote-Man-CBP with its ligands by UV difference spectroscopy indicates the existence of an extended binding site in that protein with a large enthalpic contribution to the binding. The thermodynamic parameters of binding were obtained by isothermal titration calorimetry and been found that the DeltaH values to be in good agreement with the van't Hoff values. The binding reactions are mainly enthalpically driven and exhibit enthalpy-enthropy compensation. In addition, analysis of the high-mannose glycans from different parts of the digestive tract of the reduviid insect vector of T. cruzi suggest a role of the CBP in the retention of the epimastigote stage in the anterior portion of the gut.

Coexpression of MUC1 mucin peptide core and the Thomsen-Friedenreich antigen in colorectal neoplasms

BACKGROUND

Controversial findings have been reported regarding the expression of the Thomsen-Friedenreich (TF) antigen in colorectal neoplasms when different monoclonal antibodies (MoAbs) have been used. Moreover, there is no information available regarding the carrier protein(s) of this antigen.

METHODS

Forty-five colorectal adenomas and 48 carcinomas were studied by avidin-biotin complex-peroxidase immunohistochemistry. The immunohistochemistry employed the MoAb BW835, which was reactive to a carrier specific and site specific TF antigen on MUC1 mucin, as well as reference antibodies directed to MUC1 (HMFG2) or MUC2 core peptides (4F1) and directed to TF antigen irrespective of its carrier (A78-G/A7, peanut agglutinin). To evaluate the coexpression of different epitopes by the same antigen, sandwich enzyme-linked immunoadsorbent assays were performed.

RESULTS

Although MUC1 peptide antigen and MUC1-bound TF antigen were not detectable in normal or transitional mucosa surrounding colorectal neoplasms, expression of these antigens in adenomas accompanied the development of high grade dysplasia. By contrast, MUC2 expression detected by the MoAb 4F1 was inversely correlated with the progression of the adenoma-carcinoma sequence. In well- and moderately differentiated colorectal carcinomas, the neo-expressed TF antigen is predominantly bound to MUC1. This feature could be demonstrated by antigen coexpression using peptide and the TF antigen specific MoAbs. However, in mucinous carcinomas exhibiting a weak MUC1 peptide expression in most specimens, the presence of TF antigen on the MUC2 peptide core cannot be ruled out.

CONCLUSIONS

TF antigen is strongly coexpressed with MUC1 mucin peptide core in the colorectal adenoma-carcinoma sequence, resulting in well- and moderately differentiated carcinomas. Only in mucinous carcinomas may it be coexpressed with MUC2 antigen.

Cloning by genomic PCR and production of peanut agglutinin in Escherichia coli

Using the polymerase chain reaction, the coding sequence for peanut agglutinin (PNA) was cloned and expressed in Escherichia coli. Amplified PNA is identical to previously reported cDNA, suggesting the absence of any introns in PNA gene. Recombinant (re-) PNA forms inclusion bodies in E. coli. Production of PNA was confirmed by probing Western blots with polyclonal anti-PNA immunoglobulin G. Inclusion bodies were solubilized with 6 M guanidine-HCl and renatured by rapid dilution in the presence of metal ions. The renatured lectin was then purified by affinity chromatography. The re-lectin shows carbohydrate-binding properties similar to the natural PNA. This expression system provides a model for future mutagenesis studies of the carbohydrate-binding site and thus facilitates ongoing efforts to explore the molecular basis for the specificity of lectin-carbohydrate interaction.

Further characterization of the saccharide specificity of peanut (Arachis hypogaea) agglutinin

2-Dansylamino-2-deoxy-D-galactose (GalNDns) has been shown to bind to peanut (Arachis hypogaea) agglutinin (PNA) in a saccharide-specific manner. This binding was accompanied by a five-fold increase in the fluorescence of GalNDns. The interaction was characterized by an association constant of 0.15 mM at 15 degrees and delta H and delta S values of -57.04 kJ.mol-1 and -118.1J.mol-1.K-1, respectively. Binding of a variety of other mono-, di- and oligo-saccharides to PNA, studied by monitoring their ability to dissociate the PNA GalNDns complex, revealed that PNA interacts with several T-antigen-related structures, such as beta-D-Galp-(1----3)-D-GalNAc, beta-D-Galp-(1----3)-alpha-D-GalpNAcOMe, and beta-D-Galp-(1----3)-alpha-D-GalpNAc-(1----3)-Ser, as well as the asialo-GM1 tetrasaccharide, with comparable affinity, thus showing that this lectin does not discriminate between saccharides in which the penultimate sugar of the beta-D-Galp-(1----3)-D-GalNAc unit is the alpha or beta anomer, in contrast to jacalin (Artocarpus integrifolia agglutinin), another anti T-lectin which preferentially binds to beta-D-Galp-(1----3)-alpha-D-GalNAc and does not recognize beta-D-Galp-(1----3)-beta-D-GalNAc or the related asialo-GM1 oligosaccharide. These studies also indicated that, in the extended combining region of PNA which accommodates a disaccharide, the primary subsite (subsite A) is highly specific for D-galactose, whereas the secondary subsite (subsite B) is less specific and can accommodate various structures, such as D-galactose, 2-acetamido-2-deoxy-D-galactose, D-glucose, and 2-acetamido-2-deoxy-D-glucose.

The amino acid sequence of peanut agglutinin

The amino acid sequence of peanut (Arachis hypogaea) agglutinin was determined from three major fragments obtained by mild acid cleavage at Asp-Pro peptide bonds. The sequence of 236 amino acids has residues identical to those that form the metal-binding site and the hydrophobic pocket in concanavalin A and other lectins, although the overall similarity is only 42%. In the segments of peanut agglutinin that correspond to the four loops that form the carbohydrate-binding site in concanavalin A and favin, several central residues are homologous, while others show changes to smaller side chains, such as Tyr----Gly. The carbohydrate-binding site of peanut agglutinin may therefore have a similar peptide-backbone architecture, but form a considerably more open cleft.

Topography of the combining region of a Thomsen-Friedenreich-antigen-specific lectin jacalin (Artocarpus integrifolia agglutinin). A thermodynamic and circular-dichroism spectroscopic study

Thermodynamic analysis of carbohydrate binding by Artocarpus integrifolia (jackfruit) agglutinin (jacalin) shows that, among monosaccharides, Me alpha GalNAc (methyl-alpha-N-acetylgalactosamine) is the strongest binding ligand. Despite its strong affinity for Me alpha GalNAc and Me alpha Gal, the lectin binds very poorly when Gal and GalNAc are in alpha-linkage with other sugars such as in A- and B-blood-group trisaccharides, Gal alpha 1-3Gal and Gal alpha 1-4Gal. These binding properties are explained by considering the thermodynamic parameters in conjunction with the minimum energy conformations of these sugars. It binds to Gal beta 1-3GalNAc alpha Me with 2800-fold stronger affinity over Gal beta 1-3GalNAc beta Me. It does not bind to asialo-GM1 (monosialoganglioside) oligosaccharide. Moreover, it binds to Gal beta 1-3GalNAc alpha Ser, the authentic T (Thomsen-Friedenreich)-antigen, with about 2.5-fold greater affinity as compared with Gal beta 1-3GalNAc. Asialoglycophorin A was found to be about 169,333 times stronger an inhibitor than Gal beta 1-3GalNAc. The present study thus reveals the exquisite specificity of A. integrifolia lectin for the T-antigen. Appreciable binding of disaccharides Glc beta 1-3GalNAc and GlcNAc beta 1-3Gal and the very poor binding of beta-linked disaccharides, which instead of Gal and GalNAc contain other sugars at the reducing end, underscore the important contribution made by Gal and GalNAc at the reducing end for recognition by the lectin. The ligand-structure-dependent alterations of the c.d. spectrum in the tertiary structural region of the protein allows the placement of various sugar units in the combining region of the lectin. These studies suggest that the primary subsite (subsite A) can accommodate only Gal or GalNAc or alpha-linked Gal or GalNAc, whereas the secondary subsite (subsite B) can associate either with GalNAc beta Me or Gal beta Me. Considering these factors a likely arrangement for various disaccharides in the binding site of the lectin is proposed. Its exquisite specificity for the authentic T-antigen, Gal beta 1-3GalNAc alpha Ser, together with its virtual non-binding to A- and B-blood-group antigens, Gal beta 1-3GalNAc beta Me and asialo-GM1 should make A. integrifolia lectin a valuable probe for monitoring the expression of T-antigen on cell surfaces.

Erythrocyte-binding studies on an acidic lectin from winged bean (Psophocarpus tetragonolobus)

An acidic lectin (WBA II) was isolated to homogeneity from the crude seed extract of the winged bean (Psophocarpus tetragonolobus) by affinity chromatography on lactosylaminoethyl-Bio-Gel. Binding of WBA II to human erythrocytes of type-A, -B and -O blood groups showed the presence of 10(5) receptors/cell, with high association constants (10(6)-10(8) M-1). Competitive binding studies with blood-group-specific lectins reveal that WBA II binds to H- and T-antigenic determinants on human erythrocytes. Affinity-chromatographic studies using A-, B-, H- and T-antigenic determinants coupled to an insoluble matrix confirm the specificity of WBA II towards H- and T-antigenic determinants. Inhibition of the binding of WBA II by various sugars show that N-acetylgalactosamine and T-antigenic disaccharide (Thomsen-Friedenreich antigen, Gal beta 1-3GalNAc) are the most potent mono- and di-saccharide inhibitors respectively. In addition, inhibition of the binding of WBA II to erythrocytes by dog intestine H-fucolipid prove that the lectin binds to H-antigenic determinant.

Intrinsic fluorescence studies on saccharide binding to Artocarpus integrifolia lectin

The combining region of Artocarpus integrifolia lectin has been studied by using the ligand-induced changes in the fluorescence of the lectin. The saccharide binding properties of the lectin show that C-1, C-2, C-4, and C-6 hydroxyl groups of D-galactose are important loci for sugar binding. The alpha-anomer of galactose binds more strongly than its beta-counterpart. Inversion in the configuration at C-4 as in glucose results in a loss of binding to the lectin. The C-6 hydroxyl group is also presumably involved in binding as D-fucose does not bind to the lectin. The lectin binds to the Thomsen-Friedenreich antigen (Gal beta(1----3)GalNAc) more strongly than the other disaccharides studied, viz. Gal beta (1----4) Gal and Gal beta (1----3) GlcNAc, which are topographically similar to T-antigen. This observation suggests that the combining region of Artocarpus lectin is complementary to that of T-antigen. Solvent accessibility of the protein fluorophores have been probed by the quenching of protein fluorescence by Iodide ion in the absence and presence of sugar. In the presence of sugar a slight inaccessibility of the fluorophores to the solvent has been observed.

Interaction of rice (Oryza sativa) lectin with N-acetylglucosaminides. Fluorescence studies

The interaction of lectin isolated from rice (Oryza sativa) embryos with N-acetylglucosaminides was studied by equilibrium dialysis and fluorescence. Equilibrium dialysis with 4-methylumbelliferyl-(GlcNac)2 showed that rice lectin (Mr 38000) contains four equivalent saccharide-binding sites. Addition of the N-acetylglucosaminides GlcNac, (GlcNac)2 and (GlcNac)3 enhanced the intrinsic fluorescence of rice lectin and this was accompanied by a 10nm blue-shift of its maximum fluorescence with (GlcNac)2 and (GlcNac)3. These changes in intensity allowed determination of the association constants, which increased with the number of saccharide units: at 20 degrees C, Ka = (1.3 +/- 0.1) X 10(3), (5.1 +/- 0.4) X 10(4) and (2.6 +/- 0.1) X 10(5) M-1 for GlcNac, (GlcNac)2 and (GlcNac)3 respectively. The binding enthalpy, delta H0, for the three glucosaminides were very low and ranged from -12.1 to -20.6 kJ X mol-1. The results are compared with those obtained with wheat-germ agglutinin, another GlcNac-specific gramineaous lectin.

Effect of pH on oligomeric equilibrium and saccharide-binding properties of peanut agglutinin

The conformation and saccharide-binding properties of peanut agglutinin (PNA) depend on pH as studied by analytical ultracentrifugation, fluorescence, circular dichroism, equilibrium dialysis, and absorption spectroscopy. PNA is tetrameric in neutral solution and dissociates reversibly into dimers below pH 5.1. Below pH 3.4, the lectin is totally dimeric. Lowering of the pH induces reversible changes in the tertiary and secondary structures of PNA. Binding of saturating amounts of lactose to tetrameric (pH 6.9) or dimeric (pH 3.2) PNA resulted in identical ultraviolet difference spectra. Fluorescence studies of PNA as a function of pH in the presence of lactose indicated that tryptophanyl residues, present at or near the saccharide binding site, are more accessible to the ligand in dimeric than in tetrameric PNA. For solutions of dimeric PNA, containing only minor amounts of tetramers (pH 3.6), equilibrium dialysis with MeUmb-beta Gal beta(1----3)GalNac showed that the binding capacity of PNA was the same as for tetrameric PNA (one binding site per protomer) but the apparent association constant was one order of magnitude lower than for tetrameric PNA. The enhancement of MeUmb-beta Gal beta(1----3)GalNac fluorescence upon binding to PNA was pH dependent: 50% at neutrality, 16% at pH 3.7, and unobservable at pH 3.0, suggesting that the microenvironment of this PNA-bound chromophore changed progressively with pH and was dependent on ionization of an acidic amino acid residue.

Ultraviolet difference spectroscopic analysis of the saccharide-binding properties of Ricinus communis agglutinin

The nature of the binding of saccharides to Ricinus communis agglutinin was studied by ultraviolet difference spectroscopy. Upon binding of galactose and galactose-containing saccharides, R. communis agglutinin displayed difference spectra with an extreme maximum at 291-293 nm and a smaller maximum at 284-285 nm. Such difference spectra suggest that the environment of a tryptophan residue located at or near the saccharide-binding site of R. communis agglutinin is being changed by an interaction between a tryptophan residue and the bound saccharides. The value of the difference spectra (delta epsilon) increased upon progressive addition of saccharide until the saccharide binding site was saturated with ligand. From the increase in delta epsilon at 291-293 nm, the association constants were obtained for the R. communis agglutinin-saccharide interaction over the temperature range 5-35 degrees C and various pH values. The results clearly demonstrate that the association constants are nearly equal in the range of pH 5-8, but decrease beyond the above pH range and with elevation of temperature. From the thermodynamic parameters for the binding of various saccharides to R. communis agglutinin, we suggest that there exists a subsite structure in the saccharide-binding site of the R. communis agglutinin molecule.

Binding of simple carbohydrates and some N-acetyllactosamine-containing oligosaccharides to Erythrina cristagalli agglutinin as followed with a fluorescent indicator ligand

Erythrina cristagalli agglutinin, a dimeric lectin [J.L. Iglesias, et al. (1982) Eur. J. Biochem. 123, 247-252] was shown by equilibrium dialysis to be bivalent for 4-methylumbelliferyl-beta-D-galactoside. Upon binding to the lectin, this ligand showed a difference absorption spectrum with two maxima (at 322 and 336 nm) of equal intensity (delta epsilon = 1.2 X 10(3) M-1 cm-1). A similar spectrum with a comparable value of delta epsilon was obtained with 4-methylumbelliferyl-N-acetyl-beta-D-galactosaminide. Binding of methyl-alpha-D-galactoside, lactose, and N-acetyllactosamine all produced small but equally intense protein difference spectra with a maximum (delta epsilon = 2.8 X 10(2) M-1 cm-1) at 291.6 nm. Upon binding of N-dansyl-D-galactosamine to the lectin, there was a fivefold increase in fluorescence intensity of this ligand. The association constant for N-dansyl-D-galactosamine was caused by a very favorable delta S degree of the dansyl group without affecting the strictly carbohydrate-specific character of binding. N-Dansyl-D-galactosamine was employed as a fluorescent indicator ligand in substitution titrations. This involved the use of simple carbohydrates, N-acetyllactosamine, and oligosaccharides which occur in the carbohydrate units of N-glycoproteins; the latter were Gal(beta 1----4)GlcNAc(beta 1----2)Man, Gal(beta 1----4)GlcNAc(beta 1----6)Man, and Gal(beta 1----4)GlcNAc(beta 1----6)[Gal(beta 1----4)GlcNAc(beta 1----2)]Man. The titrations were performed at two temperatures to determine the thermodynamic parameters. In the series N-acetyl-D-galactosamine, methyl-alpha-D-galactoside, and lactose, -delta H degrees increased from 24 to 41 kJ mol-1; it increased further for N-acetyllactosamine and then remained unchanged for the N-acetyllactosamine-containing oligosaccharides (55 +/- 1 kJ mol-1. This indicated that the site specifically accommodated the disaccharide structure with an important contribution of the 2-acetamido group in the penultimate sugar. Beyond this, no additional contacts seemed to be formed. This conclusion also followed from considerations of delta S degrees values which became more unfavorable in the above series (-23 to -101 +/- 4 J mol-1 K-1); the most negative value of delta S degrees was observed with N-acetyllactosamine and the three N-acetyllactosamine-containing oligosaccharides.

Temperature-induced ultraviolet difference absorption spectrometry for determination of enthalpy changes. Binding of 4-methylumbelliferyl glycosides to four lectins

Raising the temperature in a single mixture of a lectin and a chromophoric glycoside allows determination of the binding enthalpy. This is made possible by continuously monitoring the displacement of the complex from its equilibrium concentration with a sensitive difference absorption spectrophotometer. The method is illustrated with the following lectins: concanavalin A, soybean agglutinin, peanut agglutinin and Erythrina cristagalli agglutinin. The ligands are 4-methylumbelliferyl glycosides. The binding enthalpies found range from -60 kJ X mol-1 for the Gal beta 1----3GalNAc-beta glycoside and peanut agglutinin to -30 kJ X mol-1 for a monosaccharide glycoside and the other lectins.

Relationship between mouse lymphocyte receptors for peanut agglutinin (PNA) and Helix pomatia agglutinin (HPA)

The relationship between mouse lymphocyte receptors for peanut agglutinin (PNA) and Helix pomatia agglutinin (HPA) has been investigated by immunofluorescence (cocapping) and radiolabeling. In neuraminidase-treated and untreated thymocytes there are two groups of glycoproteins which bind roughly equivalent amounts of PNA. One group also carries all the detectable receptors for HPA, the other binds only PNA. Binding inhibition experiments suggest that PNA and HPA receptors are in close proximity on the shared glycoproteins. The same two groups of receptors are present on 35-40% of neuraminidase-treated spleen lymphoid cells, mainly immunoglobulin (Ig)-negative lymphocytes. Almost all B cells have only PNA-specific receptors. Five-12% of the untreated spleen cells appreciably bind PNA and only a few bind HPA. Solubilized glycoproteins specific for PNA or HPA were compared by sodium dodecyl sulfate polyacrylamide gel electrophoresis and autoradiography. The major PNA-specific radioiodinated glycoproteins of neuraminidase-treated thymocytes, as isolated by affinity chromatography, consist of the 185-kDa and 195-kDa components of the T200 antigen and of two (diffuse) components of about 140 and 120-125 kDa. All these molecules also bind to HPA-Sepharose, with the exception of the 185 kDa component, which is probably the main constituent of the "pure" PNA receptors on the intact thymocytes. In gels directly labeled with radioactive lectins, the only band strongly labeled by PNA and HPA is the diffuse 140-kDa band. The band at 120 kDa is well labeled by PNA, but all the other components are weakly labeled. The mobility of the 140- and 120-kDa bands depends strongly on neuraminidase-treatment. These bands cannot be detected in gels of untreated thymocytes, but a major HPA-and PNA-specific band of lower molecular weight can be labeled after treating the gels with neuraminidase. The factors determining the differences in labeling pattern obtained by different methods as well as the nature of PNA and HPA binding sites are discussed. The same major PNA- and HPA-binding glycoproteins (apart from minor differences) are present on neuraminidase-treated Ig-negative spleen lymphocytes. The major PNA-binding protein of B lymphocytes appears to correspond to the 225-kDa ("B220") antigen specific for these cells.

Immunochemistry of O-glycosidically-linked Gal(beta 1 leads to 3) GalNAc on fragments of human glycophorin A

N-terminal and internal fragments of human glycophorin A with chemically defined carbohydrate moieties have been used as immunogens after conjugation to BSA or polymerization to produce carbohydrate-directed antibodies with the desired specificity against O-glycosidically linked D-galactopyranosyl-beta-(1 leads to 3)-N-acetyl-D-galactopyranosamine, a possible marker on transformed T-lymphocytes and mammary tissue of humans. Antisera from rabbits have been characterized by inhibition studies using 125I-labelled peptides in radioimmunoassay and by haemagglutination inhibition. The inhibition caused by natural and synthetic glycoconjugates, which have no structural correspondence with the antigen except its carbohydrates, clearly indicated the formation of antibodies specific for Gal-beta(1 leads to 3)-GalNAc in serum A3.

Binding of 4-methylumbelliferyl beta-D-galactosyl-(1 leads to 3)-N-acetyl-beta-D-galactosaminide to peanut agglutinin. Characterisation and application in substitution titrations

Binding of 4-methylumbelliferyl-2-acetamido-2-deoxy-3-O-(beta-D-galactopyranosyl) beta-D-galactopyranoside [MeUmb beta Gal(beta 1 leads to 3)GalNAc] to peanut agglutinin was characterized by equilibrium dialysis and by measurement of the increase in ultraviolet absorption or fluorescence of the chromophoric glycoside upon continuous titration with excess of the lectin. All data in the 4-30 degrees C range correspond to delta G = -(26.5 +/- 0.1) kJ mol-1, delta H = -(58.4 +/- 2) kJ mol-1 and delta S = -(107 +/- 8)J mol-1 K-1. Values of the association constants are e.g. K = 2.5 X 10(5) M-1 at 4 degrees C and K = 4.5 X 10(4) M-1 at 25 degrees C. MeUmb beta Gal(beta 1 leads to 3)GalNAc was used as an indicator ligand to determine K values for nonchromophoric carbohydrates by continuous displacement titrations, measuring either fluorescence or difference in absorption of the indicator. The data were analyzed in terms of the general expression for a non-ideal indicator system (as detailed in the appendix). Thus, the values of K are not underestimated. They are K = 4.8 X 10(3) M-1 for methyl alpha-D-galactopyranoside [Me alpha Gal], 2.0 X 10(3) M-1 for methyl beta-D-galactopyranoside [Me beta Gal] and 4.7 X 10(3) M-1 for lactose [Gal(beta 1 leads to 4)Glc], all at 14.5 degrees C. The MeUmb difference absorption spectra resulting from binding of the lectin with MeUmb beta Gal(beta 1 leads to 3)GalNAc and MeUmb beta Gal(beta 1 leads to 4)Glc are larger than for MeUmb beta Gal and MeUmb alpha Gal. These observations are consistent with the extended nature of the combining site of peanut agglutinin.