Recognition roles of the carbohydrate glycotopes of human and bovine lactoferrins in lectin-N-glycan interactions.

BACKGROUND: Lactoferrin is an iron-binding protein belonging to the transferrin family. In addition to iron homeostasis, lactoferrin is also thought to have anti-microbial, anti-inflammatory, and anticancer activities. Previous studies showed that all lactoferrins are glycosylated in the human body, but the recognition roles of their carbohydrate glycotopes have not been well addressed. METHODS: The roles of human and bovine lactoferrins involved in lectin-N-glycan recognition processes were analyzed by enzyme-linked lectinosorbent assay with a panel of applied and microbial lectins. RESULTS AND CONCLUSIONS: Both native and asialo human/bovine lactoferrins reacted strongly with four Man-specific lectins - Concanavalia ensiformis agglutinin, Morniga M, Pisum sativum agglutinin, and Lens culinaris lectin. They also reacted well with PA-IIL, a LFuc>Man-specific lectin isolated from Pseudomonas aeruginosa. Both human and bovine lactoferrins also recognized a sialic acid specific lectin-Sambucus nigra agglutinin, but not their asialo products. Both native and asialo bovine lactoferrins, but not the human ones, exhibited strong binding with a GalNAc>Gal-specific lectin-Wisteria floribunda agglutinin. Human native lactoferrins and its asialo products bound well with four Gal>GalNAc-specific type-2 ribosome inactivating protein family lectins-ricin, abrin-a, Ricinus communis agglutinin 1, and Abrus precatorius agglutinin (APA), while the bovine ones reacted only with APA. GENERAL SIGNIFICANCE: This study provides essential knowledge regarding the different roles of bioactive sites of lactoferrins in lectin-N-glycan recognition processes.

Recognition intensities of submolecular structures, mammalian glyco-structural units, ligand cluster and polyvalency in abrin-a-carbohydrate interactions.

Abrin-a is the most toxic fraction of lectins isolated from Abrus precatorius seeds and belongs to the family of type 2 ribosome inactivating proteins (RIP). This toxin may act as a defense molecule in plants against viruses, fungi and insects, where attachment of abrin-a to the exposed glycans on the surface of target cells is the crucial and initial step of its cytotoxicity. Although it has been studied for over four decades, the recognition factors involved in abrin-a-carbohydrate interaction remains to be clarified. In this study, roles of mammalian glyco-structural units, ligand clusters and polyvalency in abrin-a recognition were comprehensively analyzed by enzyme-linked lectinosorbent binding and inhibition assays. The results indicate that: (i) this toxin prefers oligosaccharides having alpha-anomer of galactose (Gal) at the non-reducing terminal than the corresponding beta-anomer; (ii) Galalpha1-3Galalpha1- (B(alpha)), Galalpha1-4Gal (E), Galbeta1-3GalNAc (T) and Galbeta1-3/4GlcNAc (I/II) related oligosaccharides were the active glyco-structural units; (iii) tri-antennary II(beta), prepared from N-glycan of asialo fetuin, played a dominant role in recognition; (iv) many high-density polyvalent I(beta)/II(beta) and E(beta) glycotopes enhanced the reactivity; (v) the carbohydrate recognition domain of abrin-a is proposed to be a combination of a small cavity type of Gal as major site and a groove type of additional one to tetrasaccharides as subsites with a preference of alpha1-3/4/6Gal, beta1-3GalNAc, beta1-3/4/6GlcNAc, beta1-4/6Glc, beta1-3DAra and beta1-4Man as subterminal sugars; (vi) size of the carbohydrate recognition domain may be as large enough to accommodate a linear pentasaccharide and complementary to Galalpha1-3Galbeta1-4GlcNAc beta1-3Galbeta1-4Glc (gailipenta) sequence. A comparison of the recognition factors and combining sites of abrin-a with ricin, another highly toxic lectin, was also performed to further understand the differences in recognition factors between these two type 2 RIPs.

Identification of blood group A/A-Leb/y and B/B-Leb/y active glycotopes co-expressed on the O-glycans isolated from two distinct human ovarian cyst fluids.

Although the individual human blood group A and B determinants are well defined, their co-expression pattern on a particular glycan carrier in individuals of blood group AB status has not been delineated. To address this issue, complex O-glycans were isolated from two distinct sources of human ovarian cyst glycoproteins (HOC 89 and Cyst 19) and profiled by advanced MS analyses, in conjunction with defining their binding characteristics against a panel of lectins and monoclonal antibodies. The major O-glycans of HOC 89 were found to correspond to sialyl Tn, mono- and di-sialyl T structures, whereas those of Cyst 19 were apparently more heterogeneous and extended to larger sizes. A minimal structure that carries both A and B determinants on the same molecule was identified, in which the A epitope is attached directly to the core GalNAc, whereas the B epitope is preferentially located on the six arms of a core 2 structure. Both arms can be further extended with internal fucosylation that appears to be restricted to those non-sialylated chains already carrying the terminal ABH determinants, thus giving rise to rather prominent A/B-Le(b/y) glycotopes on larger O-glycans.

Lectins as tools in glycoconjugate research.

Lectins are ubiquitous proteins of nonimmune origin, present in plants, microorganisms, animals and humans which specifically bind defined monosugars or oligosaccharide structures. Great progress has been made in recent years in understanding crucial roles played by lectins in many biological processes. Elucidation of carbohydrate specificity of human and animal lectins is of great importance for better understanding of these processes. Long before the role of carbohydrate-protein interactions had been explored, many lectins, mostly of plant origin, were identified, characterized and applied as useful tools in studying glycoconjugates. This review focuses on the specificity-based lectin classification and the methods of measuring lectin-carbohydrate interactions, which are used for determination of lectin specificity or for identification and characterization of glycoconjugates with lectins of known specificity. The most frequently used quantitative methods are shortly reviewed and the methods elaborated and used in our laboratories, based on biotinylated lectins, are described. These include the microtiter plate enzyme-linked lectinosorbent assay, lectinoblotting and lectin-glycosphingolipid interaction on thin-layer plates. Some chemical modifications of lectin ligands on the microtiter plates and blots (desialylation, Smith degradation, beta-elimination), which extend the applicability of these methods, are also described.

Expression of sialyl Lex, sialyl Lea, Lex and Ley glycotopes in secreted human ovarian cyst glycoproteins.

Human blood group A, B, H, Ii, Le(a) and Le(b) antigens and their determinants expressed on ovarian cyst glycoproteins have been studied for over five decades. However, little is known about sialyl Le(x) and sialyl Le(a) glycotopes, which play essential roles in normal immunity, inflammation, and cancer cell metastasis. Furthermore, Le(x) and Le(y) were classified as glycotopes of unknown genes. Identification of these Lewis epitopes was hampered by the lack of specific antibodies. In this study, the occurrence of sialyl Le(x), sialyl Le(a), Le(x) and Le(y) reactivities in cyst glycoproteins was characterized by enzyme-linked immunosorbent assays. The results indicated that most human ovarian cyst glycoproteins carried Le(x) (8/25) and/or Le(y) (17/25) glycotopes. The expression (epitopes) of the new genes described in previous reports are Le(x) and Le(y) glycotopes; the reactivities of sialyl Le(x) and sialyl Le(a) glycotopes in secreted cyst glycoproteins may be affected by the conditions of purification; the relationship between Le(y) and human blood group ABH was confirmed; recognition profiles of sialyl Le(x), sialyl Le(a), Le(x) and Le(y) present in the carbohydrate chains of water-soluble cyst glycoproteins were illustrated; possible attachments of glycotopes to the internal carbohydrate complex of cyst glycoproteins have been reconstructed; proposed biosynthetic pathways for the formation of sialyl Le(a), sialyl Le(x), Le(x), Le(y), ALe(y) and BLe(y) determinant structures on Type I and Type II core structures of human ovarian cyst glycoproteins are also included in this study.

Differential contributions of recognition factors of two plant lectins -Amaranthus caudatus lectin and Arachis hypogea agglutinin, reacting with Thomsen-Friedenreich disaccharide (Galbeta1-3GalNAcalpha1-Ser/Thr).

Previous reports on the carbohydrate specificities of Amaranthus caudatus lectin (ACL) and peanut agglutinin (PNA, Arachis hypogea) indicated that they share the same specificity for the Thomsen-Friedenreich (T(alpha), Galbeta1-3GalNAcalpha1-Ser/Thr) glycotope, but differ in monosaccharide binding--GalNAc>>Gal (inactive) for ACL; Gal>>GalNAc (weak) with respect to PNA. However, knowledge of the recognition factors of these lectins was based on studies with a small number monosaccharides and T-related oligosaccharides. In this study, a wider range of interacting factors of ACL and PNA toward known mammalian structural units, natural polyvalent glycotopes and glycans were examined by enzyme-linked lectinosorbent and inhibition assays. The results indicate that the main recognition factors of ACL, GalNAc was the only monosaccharide recognized by ACL as such, its polyvalent forms (poly GalNAcalpha1-Ser/Thr, Tn in asialo OSM) were not recognized much better. Human blood group precursor disaccharides Galbeta1-3/4GlcNAcbeta (I(beta)/II(beta)) were weak ligands, while their clusters (multiantennary II(beta)) and polyvalent forms were active. The major recognition factors of PNA were a combination of alpha or beta anomers of T disaccharide and their polyvalent complexes. Although I(beta)/II(beta) were weak haptens, their polyvalent forms played a significant role in binding. From the 50% molar inhibition profile, the shape of the ACL combining site appears to be a cavity type and most complementary to a disaccharide of Galbeta1-3GalNAc (T), while the PNA binding domain is proposed to be Galbeta1-3GalNAcalpha or beta1--as the major combining site with an adjoining subsite (partial cavity type) for a disaccharide, and most complementary to the linear tetrasaccharide, Galbeta1-3GalNAcbeta1-4Galbeta1-4Glc (T(beta)1-4L, asialo GM(1) sequence). These results should help us understand the differential contributions of polyvalent ligands, glycotopes and subtopes for the interaction with these lectins to binding, and make them useful tools to study glycosciences, glycomarkers and their biological functions.

Defining the carbohydrate specificities of Erythrina corallodendron lectin (ECorL) as polyvalent Galbeta1-4GlcNAc (II) > monomeric II > monomeric Gal and GalNAc.

BACKGROUND: Erythrina corallodendron lectin (ECorL) is one of the potent applied lectins. In previous studies, the carbohydrate specificities of this lectin were limited to monosaccharides, simple oligosaccharides and several clusters. However, the polyvalent factor has not been investigated. METHODS: The binding properties at the combining sites of ECorL were characterized by sensitive enzyme-linked lectinosorbent (ELLSA) and inhibition assays, using our collection of ligands and polyvalent natural glycans with known glycotopes. RESULTS: Results of both binding and inhibition assays revealed a very high affinity between ECorL and Galbeta1-4GlcNAc (II)-containing glycoproteins. Among soluble natural glycans tested for inhibition, the high-density polyvalent II glycotopes, such as Streptococcus pneumoniae type 14 capsular polysaccharide which is composed of repeating poly-II residues, resulted in 2.4 x 10(4), 1.4 x 10(3) and 8.6 x 10(2)-fold higher affinities to ECorL than the monomeric Gal, linear II and tri-antennary II, respectively, at the non-reducing end in N-linked glycopeptides (Tri-II). The ECorL-glycan interaction was also strongly inhibited by most of the other high-density II-containing glycoproteins. Although GalNAc was as potent an inhibitor as Gal, its polyvalent structural units were poor inhibitors. CONCLUSIONS: [1] Galbeta1-4GlcNAc (II) and other Galbeta1 -related oligosaccharides are essential for binding. [2] Their polyvalent form in glycoproteins is the most important binding factor for ECorL, while II monomer and oligo-antennary II forms play only a limited role in binding. [3] Although GalNAc is more active than Gal for ECorL, its reactivity is not changed by polyvalent effects. This lectin may be used as a tool to study glycobiology in basic and medical sciences.

Glycomic mapping of O- and N-linked glycans from major rat sublingual mucin.

Carbohydrate moieties of salivary mucins play various roles in life processes, especially as a microbial trapping agent. While structural details of the salivary O-glycans from several mammalian sources are well studied, very little information is currently available for the corresponding N-glycans. The existence of N-glycans alongside O-glycans on mucin isolated from rat sublingual gland has previously been implicated by total glycosyl compositional analysis but the respective structural data are both lacking. The advent of facile glycomic mapping and sequencing methods by mass spectrometry (MS) has enabled a structural reinvestigation into many previously unsolved issues. For the first time, high energy collision induced dissociation (CID) MALDI-MS/MS as implemented on a TOF/TOF instrument was applied to permethyl derivatives of mucin type O-glycans and N-glycans, from which the linkage specific fragmentation pattern could be established. The predominant O-glycans carried on the rat sublingual mucin were defined as sialylated core 3 and 4 types whereas the N-glycans were determined to be non-bisected hybrid types similarly carrying a sialylated type II chain. The masking effect of terminal sialylation on the tight binding of rat sublingual mucin to Galbeta1-->4GlcNAc specific lectins and three oligomannose specific lectins were clearly demonstrated in this study.

Differential affinities of Erythrina cristagalli lectin (ECL) toward monosaccharides and polyvalent mammalian structural units.

Previous studies on the carbohydrate specificities of Erythrina cristagalli lectin (ECL) were mainly limited to analyzing the binding of oligo-antennary Galbeta1-->4GlcNAc (II). In this report, a wider range of recognition factors of ECL toward known mammalian ligands and glycans were examined by enzyme-linked lectinosorbent and inhibition assays, using natural polyvalent glycotopes, and a glycan array assay. From the results, it is shown that GalNAc was an active ligand, but its polyvalent structural units, in contrast to those of Gal, were poor inhibitors. Among soluble natural glycans tested for 50% molecular mass inhibition, Streptococcus pneumoniae type 14 capsular polysaccharide of polyvalent II was the most potent inhibitor; it was 2.1 x 10(4), 3.9 x 10(3) and 2.4 x 10(3) more active than Gal, tri-antennary II and monomeric II, respectively. Most type II-containing glycoproteins were also potent inhibitors, indicating that special polyvalent II and Galbeta1-related structures play critically important roles in lectin binding. Mapping all information available, it can be concluded that: [a] Galbeta1-->4GlcNAc (II) and some Galbeta1-related oligosaccharides, rather than GalNAc-related oligosaccharides, are the core structures for lectin binding; [b] their polyvalent II forms within macromolecules are a potent recognition force for ECL, while II monomer and oligo-antennary II forms play only a limited role in binding; [c] the shape of the lectin binding domains may correspond to a cavity type with Galbeta1-->4GlcNAc as the core binding site with additional one to four sugars subsites, and is most complementary to a linear trisaccharide, Galbeta1-->4GlcNAcbeta1-->6Gal. These analyses should facilitate the understanding of the binding function of ECL.

Glycomic mapping of pseudomucinous human ovarian cyst glycoproteins: identification of Lewis and sialyl Lewis glycotopes.

Expression of sialyl Lewis x (sLe(x)) and sialyl Lewis a (sLe(a)) on cell-surface glycoproteins endows cells with the ability to adhere to E-, P-, and L-selectins present on endothelia, platelets, or leukocytes. Special arrangements of these glycotopes in cancers are thought to play a key role in metastasis. Previous studies have mostly described membrane-bound sLe(x) and sLe(a) activities. In this report, the major O-glycans of the secreted human ovarian cyst sialoglycoproteins from a Le(a+) nonsecretor individual (human ovarian cyst sample 350) were characterized by MS/MS analyses and immuno-/lectin-chemical assays. The results showed that HOC 350 carries a large number of epitopes for sLe(x), sLe(a), and Le(a) reactive antibodies. Advanced MS/MS sequencing coupled with mild periodate oxidation and exoglycosidase digestions further revealed that the O-glycans from HOC 350 are mostly of core 1 and 2 structures, extended and branched on the 3-arm with both type I and type II chains, complete with variable degrees of terminal sialylation and/or fucosylation to yield the sLe(x) or sLe(a) epitopes. Thus, the underlying core and peripheral backbone structures are similar to that of a previously proposed composite structural model for nonsialylated human ovarian cysts O-glycans, but with some notable distinguishing structural features in addition to sialylation.

Recognition factors of Ricinus communis agglutinin 1 (RCA(1)).

Ricinus communis agglutinin (RCA1) is one of the most important applied lectins that has been widely used as a tool to study cell surfaces and to purify glycans. Although the carbohydrate specificity of RCA1 has been described, the information obtained was mainly focused on inhibition of simple Galbeta1-related oligosaccharides and simple clusters. Here, all possible recognition factors of RCA1 of glycan binding were examined by enzyme-linked lectinosorbent (ELLSA) and inhibition assays, using known mammalian Gal/GalNAc carbohydrate structural units and natural polyvalent glycans. Among the glycoproteins (gps) tested and expressed as 50% nanogram inhibition, the high-density polyvalent Galbeta1-4GlcNAc (II) glycotopes occurring in natural gps, such as Pneumococcus type 14 capsular polysaccharide which is composed of repeating poly II residues, resulted in 9.0 x 10(4), 1.5 x 10(5), 2.3 x 10(4) and 2.1 x 10(4)-fold higher affinities to RCA1 than the monomeric Gal, linear I/II and Tri-antennary-II (Tri-II). Of the ligands tested and expressed as nanomoles of 50% inhibition, Tri-II was the best, being about 2, 4, 25.6 and 33.3 times better inhibitor than Di-II, II, I (Galbeta1-3GlcNAc) and Gal, respectively. From the results of this study, it is concluded that: (a) Galbeta1-4GlcNAc and other Galbeta1-related oligosaccharides are essential for lectin binding and their polyvalent form in macromolecules should be the most important recognition factor for RCA1; (b) the combining site of RCA1 may be a groove type, recognizing Galbeta1-4GlcNAc (II) as the major binding site; (c) its combining size may be large enough to accommodate a tetrasaccharide of beta-anomeric Gal at the non-reducing end and most complementary to human blood group I Ma active trisaccharide (Galbeta1-4GlcNAcbeta1-6Gal) and lacto-N-neotetraose (Galbeta1-4GlcNAcbeta1-3Galbeta1-4Glc); (d) RCA1 has a preference for the beta-anomer of Gal oligosaccharides with a Galbeta1-4 linkage > Galbeta1-6 > or = Galbeta1-3; (e) configuration of carbon-2, -3 -4 and -6 in Gal are essential for binding; (f) hydrophobic interaction in the vicinity of the binding site useful for sugar accommodation increases affinity. These results should be helpful for understanding the functional role of RCA1 and for characterizing glycotopes of mammalian complex carbohydrates.