2.2 A resolution structure analysis of two refined N-acetylneuraminyl-lactose--wheat germ agglutinin isolectin complexes

The crystal structures of complexes of isolectins 1 and 2 of wheat germ agglutinin (WGA1 and WGA2) with N-acetylneuraminyl-lactose (NeuNAc-alpha(2-3)-Gal-beta(1-4)-Glc) have been refined on the basis of data in the 8 to 2.2 A resolution range to final crystallographic R-factors of 17.2% and 15.3% (Fo greater than 1 sigma), respectively. Specific binding interactions and water association, as well as changes in conformation and mobility of the structure upon ligand binding, were compared in the two complexes. The temperature factors (B = 16.3 A2 and 18.4 A2) were found to be much lower compared with those of their respective native structures (19 to 22 A2). Residues involved in sugar binding, dimerization and in lattice contacts exhibit the largest decreases in B-value, suggesting that sugar binding reduces the overall mobility of the protein molecules in the crystal lattice. The binding mode of this sialyl-trisaccharide, an important cell receptor analogue, has been compared in the two isolectins. Only one of the two unique binding sites (4 per dimer), located in the subunit/subunit interface, is occupied in the crystals. This site, termed the "primary" binding site, contains one of the five amino acid substitutions that differentiate WGA1 and WGA2. Superposition of the refined models in each of the independent crystallographic environments indicates a close match only of the terminal non-reducing NeuNAc residue (root-mean-square delta r of 0.5 to 0.6 A). The Gal-Glc portion was found to superimpose poorly, lack electron density, and possess high atomic thermal factors. In both complexes NeuNAc is stabilized through contact with six amino acid side-chains (Ser114 and Glu115 of subunit 1 and Ser62, Tyr64, Tyr(His)66 and Tyr73 of subunit 2), involving all NeuNAc ring substituents. Refinement has allowed accurate assessment of the contact distances for four hydrogen bonds, a strong buried non-polar contact with the acetamido CH3 group and a large number of van der Waals' interactions with the three aromatic side-chains. The higher affinity of N-acetylneuraminyl-lactose observed by nuclear magnetic resonance studies for WGA1 can be explained by the more favorable binding interactions that occur when residue 66 is a Tyr. The tyrosyl side-chain provides a larger surface for van der Waals' stacking against the NeuNAc pyranose ring than His66 and a hydrogen bond contact with Gal (C2-OH), not possible in WGA2.(ABSTRACT TRUNCATED AT 400 WORDS)     

Location of the N-acetyl-d-neuraminic acid binding site in wheat germ agglutinin: A crystallographic study at 2.8 Å resolution

The crystal structure of the non-covalent complex between wheat germ agglutinin (isolectin no. 2) and N-acetyl-d-neuraminic acid, a saccharide widely found at the termini of carbohydrate chains in membrane glycoproteins and known to interact with wheat germ agglutinin, has been determined from an electron density difference map at 2.8 Å resolution. This map exhibits two strong binding sites on the wheat germ agglutinin dimer molecule which are located in corresponding crevices at the protomer/protomer interface. Amino acid sidechains from B and C-type domains of opposite protomers contribute to the binding site. The N-acetylneuraminic acid molecule is oriented such that its acetyl group becomes essentially buried upon binding, whereas the charged carboxylate and the glycerol groups point away from the protein surface, but are also able to make contact with surface side-chains. Model building shows that substituents of the pyranoside ring which had been predicted as essential for binding from solution studies, are situated favorably to allow interactions to be made with main and side-chain atoms of the protein molecule.     

Non-crystallographic symmetry in the crystal dimer of wheat germ agglutinin

Three isomorphous heavy atom derivatives of wheat germ agglutinin crystals, KAu(CN)₂, K₂Pt(NH₃)₂(NO)₂ and mersalyl, have been examined at high resolution. Heavy atom sites were located from difference Patterson maps in three dimensions at 2.15 Å resolution for the gold and platinum derivatives and with less certainty in the centrosymmetric [010] projection for the mersalyl derivative. These sites are distributed in the crystallographic asymmetric unit such that one half of them can be related to the other half by a 180 ° rotation about an axis parallel to a, and an additional translation of about 6.35 Å along that axis. It is suggested that the two subunits of the wheat germ agglutinin dimer, which represent the asymmetric unit of the C2 unit cell, are related by the same symmetry axis, causing heterologous subunit contacts due to the 6.35 Å translation of one relative to the other subunit.     

Glycoprotein characteristics of the sodium channel saxitoxin-binding component from mammalian sarcolemma

The saxitoxin-binding component of the excitable membrane sodium channel exhibits glycoprotein characteristics as evidenced by its specific interaction with various agarose-immobilized lectins. The detergent-solubilized saxitoxin-binding component interacts quantitatively with immobilized wheat germ agglutinin and concanavalin A and fractionally with immobilized Lens culinaris hemagglutinin and Ricinus communis agglutinin. These lectins preferentially bind $\text{N-}\text{acetylglucosamine}$ and sialic acid (wheat germ agglutinin), mannose (concanavalin A and Lens cunilaris and galactose (Ricinus communis). Removal of terminal sialic acid residues by neuraminidase markedly decreases binding to immobilized wheat germ agglutinin but uncovers sites capable of interacting with lectins specific for galactose and $\text{N-}\text{acetylgalactosamine}$. $\text{β-N-}\text{acetylglucosaminidase}$, an exoglycosidase has no effect on the binding of the channel protein to wheat germ agglutinin. Similarly, phospholipase C has no effect on binding of the solubilized toxin binding component to this lectin. Neither wheat germ agglutinin nor concanavalin A free in solution alters the number of toxin binding sites or their affinity for toxin. The sodium channel saxitoxin-binding component appears to be a glycoprotein containing terminal sialic acid residues and internal mannose, galactose, $\text{N-}\text{acetylglucosamine}$, and $\text{N-}\text{acetylgalactosamine}$ residues. The toxin binding site is spatially separated from the binding sites for the lectins studied. The effect of these sugar moieties must be considered when evaluating the biophysical parameters of the sodium channel.     

Intermolecular nuclear Overhauser effect and atomic pair potential approaches to wheat germ agglutinin-sugar binding

The detailed binding mechanism of wheat germ agglutinin (WGA) with N-acetylglucosamine (GlcNAc) was investigated using intermolecular 1H-1H nuclear Overhauser effect (NOE) and atomic pair potential (APP) calculations. Negative NOE was observed on the 1H spectrum of 1-O-methyl derivative of GlcNAc in a solution containing WGA, when the aromatic region of the WGA spectrum was irradiated. Analyses of the time dependence of NOE revealed that H2 and the N-acetyl methyl protons of the sugar are in close proximity to the aromatic protons of WGA in the bound state. This was confirmed and further elucidated by the APP calculations. According to the calculation, the major binding force comes from a hydrogen-bonding between C3-OH of sugar and an acidic residue present in each of the two binding sites of WGA: Glu115 in site 1 and Asp29 in site 2. The binding is further assisted by the N-acetyl group which interacts with a few more polar amino acid residues in the binding sites. The optimized binding mode suggested by the APP calculations supports the NMR results in that H2 and a part of the N-acetyl methyl protons are within 4.5 A distance from protons of both Tyr64 and Tyr73 in site 1 and of Tyr159 in site 2.     

Site-directed mutational analysis of human tumor necrosis factor-alpha receptor binding site and structure-functional relationship.

In order to define the receptor binding site and the structure-functional relationship of tumor necrosis factor (TNF), single amino acid substitutions were made by site-directed mutagenesis at selected residues of human tumor necrosis factor, using a phagemid mutagenesis/expression vector. The recombinant TNF mutants were compared to the wild type TNF in assays using crude bacterial lysates, for protein yield, solubility, subunit trimerization, receptor binding inhibition activity, and in vitro cytotoxic activity. All mutants which did not form cross-linkable trimer also showed little cytotoxic activity or receptor binding inhibition activity, indicating that trimer formation is obligatory for TNF-alpha activity. Most mutations of internal residues yielded no cross-linkable trimer, while most mutations of surface residues yielded cross-linkable trimer. Mutations at surface residues Leu29, Arg31, and Ala35 yielded cross-linkable trimers with good activities, except proline substitutions which may cause conformational changes in the polypeptide chain. This suggested that these residues are near the receptor binding site. Mutations at other strictly conserved internal residues such as Ser60, His78, and Tyr119 form cross-linkable trimer with little activity. These mutations may indirectly affect the receptor binding site by forming trimers with undetectable abnormalities. Mutants of surface residues Tyr87, Ser95, Ser133, and Ser147 affect receptor binding and cytotoxic activity but not trimer formation, suggesting that these residues are involved directly in receptor binding. The fact that residues Arg31, Ala35, Tyr87, Ser95, and Ser147, located on the opposite sides of a monomer, are clustered at the intersubunit grooves of TNF trimer supports the current notion that TNF receptor binding sites are trivalent and are located at the three intersubunit grooves. However, our finding that Ser133, which is outside the groove, can also be involved directly in receptor binding suggested that the receptor binding sites of TNF may not be confined to the intersubunit grooves, but extended to include additional surface residues.     

Architecture of the sugar binding sites in carbohydrate binding proteins-a computer modeling study

Different sugars, Gal, GalNAc and Man were docked at the monosaccharide binding sites of Erythrina corallodenron (EcorL), peanut lectin (PNA), Lathyrus ochrus (LOLI), and pea lectin (PSL). To study the lectin-carbohydrate interactions, in the complexes, the hydroxymethyl group in Man and Gal favors, gg and gt conformations respectively, and is the dominant recognition determination. The monosaccharide binding site in lectins that are specific to Gal/GalNAc is wider due to the additional amino acid residues in loop D as compared to that in lectins specific to Man/Glc, and affects the hydrogen bonds of the sugar involving residues from loop D, but not its orientation in the binding site. The invariant amino acid residues Asp from loop A, and Asn and an aromatic residue (Phe or Tyr) in loop C provides the basic architecture to recognize the common features in C4 epimers. The invariant Gly in loop B together with one or two residues in the variable region of loop D/A holds the sugar tightly at both ends. Loss of any one of these hydrogen bonds leads to weak interaction. While the subtle variations in the sequence and conformation of peptide fragment that resulted due to the size and location of gaps present in amino acid sequence in the neighborhood of the sugar binding site of loop D/A seems to discriminate the binding of sugars which differ at C4 atom (galacto and gluco configurations). The variations at loop B are important in discriminating Gal and GalNAc binding. The present study thus provides a structural basis for the observed specificities of legume lectins which uses the same four invariant residues for binding. These studies also bring out the information that is important for the design/engineering of proteins with the desired carbohydrate specificity.     

Binding site of the rat liver specific monoclonal antibody

A rat liver-specific antigen (RLSA) lost its binding ability to the corresponding monoclonal antibody after treatment with N-glycanase or sialidase, which suggested that the specific binding site might be in a portion of the sugar chain containing sialic acid. The specific antigen reacted with wheat germ agglutinin, lentil lectin, erythroagglutinating phytohemagglutinin and Ricinus communis agglutinin, but not with concanavalin A or peanut agglutinin. These results suggest that the specific antigen has asparagine-linked complex-type sugar chains which might be the binding sites of the monoclonal antibody.     

Agglutination of Staphylococcus saprophyticus: a structural and cytochemical study

Abstract Staphylococcus saprophyticus was shown to be agglutinated by wheat germ agglutinin, wheat germ agglutinin-biotin and bovine serum albumin- p -aninophenyl- N -acetyl-β-d-glucosaminide (GlcNAc-BSA), and sheep red blood cells. In these agglutinations, filamentous or amorphous structures radiating from the surface of S. saprophyticus were demonstrated by electron microscope observation. Cytochemical analyses of the agglutination revealed the binding sites of wheat germ agglutinin in S. saprophyticus and the binding sites of GlcNAc in the sheep red blood cells and S. saprophyticus . Since GlcNAc-BSA contains N -acetylglucosamine to which wheat germ agglutinin can bind, it is most likely that an interaction between a wheat germ agglutinin-bindable substance in S. saprophyticus and an N -acetylglucosamine-bindable substance in sheep red blood cells is involved in the agglutination.     

Histidine determination in wheat germ agglutinin isolectin by X-ray diffraction analysis

Electron density maps based on 2·4 Å and 2·2 Å X-ray diffraction data for crystals of two isolectins of wheat germ agglutinin (designated isolectins 1 and 2) were compared in terms of side-chain identities. While the primary structure of wheat germ agglutinin is not available, a partial amino acid sequence for isolectin 2 has been deduced by inspection of the electron density map and through model building. The positions of the two histidines predicted from amino acid composition studies to be present in isolectin 2 but not in isolectin 1, were located by difference Fourier techniques and analysis of the heavy-atom binding properties of these two isolectins. Both histidines were found to reside in the B-domain of the multi-domain wheat germ agglutinin protomer (A, B, C, D). Histidine 57 lies in the contact region between the two subunits near the molecular dimer axis. The side-chain of histidine 64 forms part of the primary saccharide binding site at the interface where B and C-domains of opposite protomers make contact. In addition, this histidine serves as a major target for heavy-atom binding by platinum and mercury compounds.     

Evolution of the multidomain protein wheat germ agglutinin

We compared the homologous amino acid sequences of hevein and each of the four domains (A, B, C, and D) of wheat germ agglutinin and used them to construct a pseudophylogenetic tree relating these sequences to a hypothetical common ancestor sequence. In the crystal structure of the wheat germ agglutinin dimer, six pseudo-two-fold rotational symmetry axes have previously been located in addition to the true twofold axis. Four of these relate two nonidentical domains to each other in each of the four possible pairs constituting the sugar-binding sites (A1D2, A2D1, B1C2, and B2C1). The remaining two relate contiguous unique pairs of sugar-binding sites to each other (A1D2 to B1C2, and A2D1 to B2C1). These latter two sets of pairs are related to each other by the true twofold axis. Side chains that mediate sugar binding in the interfaces of each of the four pairs were found to be largely conserved. The sequence homology, taken together with these pseudo-symmetry elements in the dimer structure, suggests a pathway for the evolution of the four-domain molecule from a single-domain dimer that can be correlated with simultaneous development of the saccharide-binding sites.     

Interaction of sulfated glycosaminoglycans with lectins

The sulfated glycosaminoglycans, such as keratan sulfate and chitin sulfate having 3-hydroxy free N-acetyl-beta-D-glucosaminyl residues as constituents, reacted with wheat germ agglutinin and Solanum tuberosum agglutinin by sugar-specific interaction. The glycosaminoglycans showed different inhibitory activities to the hemagglutination reaction of these lectins and keratan sulfate and its modified products formed insoluble complexes with both of the lectins at pH 7.0 in physiological saline solutions (0.15 M NaCl). S. tuberosum agglutinin was precipitated within a particularly narrow concentration range of keratan sulfate, and the formation of a soluble complex was observed by gel chromatography. These interactions were specifically inhibited by N,N'-diacetylchitobiose but not by 2 M NaCl. The specific interactions of the glycosaminoglycans with S. tuberosum agglutinin were confirmed by their ultraviolet difference spectra with two peaks at 285 and 298 nm attributable to the tryptophan residues in the binding site of the agglutinin. It was also found that S. tuberosum agglutinin and wheat germ agglutinin have different binding specificities. The presence of sulfate groups in either keratan sulfate or chitin sulfate did not interfere with their specific interactions with S. tuberosum agglutinin as strongly as with wheat germ agglutinin. The N-acetylneuraminic acid residues in keratan sulfate were found to be receptor sites for wheat germ agglutinin but not for S. tuberosum agglutinin.     

Crystal structures of Urtica dioica agglutinin and its complex with tri-N-acetylchitotriose

Urtica dioica agglutinin is a small plant lectin that binds chitin. We purified the isolectin VI (UDA-VI) and crystal structures of the isolectin and its complex with tri-N-acetylchitotriose (NAG3) were determined by X-ray analysis. The UDA-VI consists of two domains analogous to hevein and the backbone folding of each domain is maintained by four disulfide bridges. The sequence similarity of the two domains is not high (42 %) but their backbone structures are well superimposed except some loop regions. The chitin binding sites are located on the molecular surface at both ends of the dumbbell-shape molecule. The crystal of the NAG3 complex contains two independent molecules forming a protein-sugar 2:2 complex. One NAG3 molecule is sandwiched between two independent UDA-VI molecules and the other sugar molecule is also sandwiched by one UDA-VI molecule and symmetry-related another one. The sugar binding site of N-terminal domain consists of three subsites accommodating NAG3 while two NAG residues are bound to the C-terminal domain. In each sugar-binding site, three aromatic amino acid residues and one serine residue participate to the NAG3 binding. The sugar rings bound to two subsites are stacked to the side-chain groups of tryptophan or histidine and a tyrosine residue is in face-to-face contact with an acetylamino group, to which the hydroxyl group of a serine residue is hydrogen-bonded. The third subsite of the N-terminal domain binds a NAG moiety with hydrogen bonds. The results suggest that the triad of aromatic amino acid residues is intrinsic in sugar binding of hevein-like domains.     

Mapping the agonist-binding site of GABAB type 1 subunit sheds light on the activation process of GABAB receptors

The gamma-amino-n-butyric acid type B (GABA(B)) receptor is composed of two subunits, GABA(B)1 and GABA(B)2, belonging to the family 3 heptahelix receptors. These proteins possess two domains, a seven transmembrane core and an extracellular domain containing the agonist binding site. This binding domain is likely to fold like bacterial periplasmic binding proteins that are constituted of two lobes that close upon ligand binding. Here, using molecular modeling and site-directed mutagenesis, we have identified residues in the GABA(B)1 subunit that are critical for agonist binding and activation of the heteromeric receptor. Our data suggest that two residues (Ser(246) and Asp(471)) located within lobe I form H bonds and a salt bridge with carboxylic and amino groups of GABA, respectively, demonstrating the pivotal role of lobe I in agonist binding. Interestingly, our data also suggest that a residue within lobe II (Tyr(366)) interacts with the agonists in a closed form model of the binding domain, and its mutation into Ala converts the agonist baclofen into an antagonist. These data demonstrate the pivotal role played by the GABA(B)1 subunit in the activation of the heteromeric GABA(B) receptor and are consistent with the idea that a closed state of the binding domain of family 3 receptors is required for their activation.     

Lectin binding to the porcine and human ileal receptor of intrinsic factor-cobalamin

The purified porcine recpptor for the intrinsic factor-cobalamin complex bound to concanavalin A, lentil lectin and wheat germ lectin covalently coupled to Sepharose and was eluted with the corresponding soluble sugars. In contrast, human intrinsic factor bound efficiently to concanavalin A, to some extent to lentil lectin, but only slightly to wheat germ agglutinin. The binding of IF-Cbl to the receptor was inhibited when the receptor was pre-incubated with soluble wheat germ aglutinin, with an inhibition constant estimated to be 1.9 mol/l. After transfer of the purified receptor from SDS-PAGE to Immobilon, ligand blotting of the purified receptor with iodinated lectin showed that concanavalin A and lentil lectin bound to three (75, 56 and 43 kDa) components but that wheat germ agglutinin bound only to the 75 kDa component. These results showed that the subunit of the receptor could bind to wheat germ agglutinin, resulting in an inhibition of its binding with intrinsic factor. Both binding sites of intrinsic factor and of wheat germ agglutinin could be located near to each other.     

N-Acetyl-D-glucosamine binding lectins. A model system for the study of binding specificity

Synthetic glycoconjugates prepared by the direct reductive amination of di-N-acetylchitobiose and tetra-N-acetyl-chitotetraose to poly-l-lysine with sodium cyanoborohydride have been used to explore the binding specificities of the lectins wheat germ agglutinin and Bandeiraea simplicifolia II. These conjugates are effective precipitating antigens for these lectins, and hapten inhibition experiments, employing the per-N-acetylated oligomers of chitin as inhibitors, demonstrate that wheat germ agglutinin and Bandeiraea simplicifolia II lectin have binding sites complementary to three and two contiguous β 1,4-linked N-acetyl-d-glucosamine residues, respectively, in agreement with conclusions reached using other methods. Conjugates prepared by this technique should be useful for examining the binding specificities of other lectins, and the results of a study of the effect of chain length of the hapten on the affinity of the lectin for these conjugates should provide guidance in selection of the hapten most appropriate for these studies.     

Invariant features of globin primary structure and coding of their secondary structure

Invariant features of the primary structure of 67 globins are analysed. These features may be responsible for the formation of the secondary structure of these proteins at the first stage of self-organization (in the unfolded chain). It is shown that in primary structures of globins there are 11 sites or regions of one to four residues in which at least one of the residues Asn, Asp, His, Pro, Ser or Thr is located in every globin (haem-linking His residues are excluded from these sites). An unambiguous correlation exists between the position of these regions and the secondary structure of globins: all these regions (except one) are located near the ends of helices in globins whose three-dimensional structure is known and the ends of all helices (except for the helix F) are coded by such regions. A decrease in the set of residues listed above leads to a sharp drop in the number of regions invariantly occupied by the residues, while an addition of residues such as Tyr and Gly to this set does not eventually increase the number of invariant regions. Five residues (Asn, Asp, His, Ser and Thr) of the six that code the ends of helical regions have polar side groups with a small number of degrees of freedom capable of forming hydrogen bonds with atoms of the backbone with a relatively small loss of entropy. One residue (Pro) has no NH-group and, therefore, has less chance of participating in the formation of hydrogen bonds between atoms of the backbone. This corroborates the hypothesis that competition between hydrogen bonds of short polar side groups and hydrogen bonds in the backbone is essential for the formation of the secondary structure in unfolded protein chains. Amino acid replacements in hydrophobic cores of the 67 globins are considered in the Appendix.     

Isolation of wheat germ agglutinin-resistant clones of Chinese hamster ovary cells deficient in membrane sialic acid and galactose.

Several clones of Chinese hamster ovary cells have been selected for their resistance to the toxic effects of wheat germ agglutinin. The clones do not bind wheat germ agglutinin as well as parent cells and are 5- to 250-fold more resistant to the toxic effects of the lectin. Of three clones studied in detail, all exhibit a decrease in wheat germ agglutinin binding affinity. Two have normal numbers of wheat germ agglutinin binding sites, while one (Clone 13) has a 65% decrease in binding sites. Crude membrane preparations of the clones have a decrease in sialic acid content relative to parent cells, and Clone 13 membranes are also deficient in galactose, while the mannose and hexosamine contents of all three clones are normal. The membrane sugar deficiencies affect both glycoproteins and glycolipids. Sialyl-lactosylceramide is the major glycolipid in parent cells, while Clones 1 and 1021 have lactosylceramide and Clone 13 has glucosylceramide as the predominant glycolipid. Labeling experiments with N-[G-3H]acetylmannosamine suggest that Clone 1021 cells have a block in the transfer of sialic acid from CMP-sialic acid to glycoprotein and glycolipid acceptors. Yet CMP-sialic acid:glycoprotein sialyl-transferase activity in cell lysates of Clone 1021 cells is 80% of normal. While CMP-sialic acid:lactosylceramide sialyl-transferase activity is only 25% of normal, it can be restored to normal or elevated levels by sodium butyrate induction without an associated increase in cellular sialyl-lactosylceramide content. Similarly, the galactose-deficient Clone 13 can synthesize UDP-galactose and has normal levels of UDP-galactose:glycoprotein galactosyltransferase and UDP-galactose:glucosylceramide galactosyltransferase when assayed in vitro. The glycosyltransferases of both these clones can utilize their own glycoproteins as sugar acceptors in in vitro assays. These data suggest that the variant cells fail to carry out specific glycosyltransferase reactions in vivo despite the fact that they possess the appropriate nucleotide sugars, glycoprotein and glycolipid acceptors, and glycosyltransferases.     

A quantitative analysis of lectin binding to adult rat hepatocyte cell surfaces

Summary A quantitative evaluation of lectin binding to adult rat hepatocyte cell surfaces was done using cells isolated by two different collagenase perfusion methodologies and cultured as monolayers with two different tissue culture media formulations (protocol I vs. protocol II). The presence of α-D-mannosyl and α-D-glucosyl groups was detected by the binding of Concanavalin A (Con A), Lens culinaris agglutinin (LCA), and Pisum sativum agglutinin (PSA) to freshly isolated cells. Furthermore, β-D-galactose [Ricinus communis agglutinin (RCA)] and sialic acid residues [wheat germ (WGA)] were also found. Protocols I and II served as models for evaluation of: a) the stripping effect of collagenase separation procedures, b) the restoration in culture of collagenase-stripped sugar residues, c) the effect of the culture environment on cell viability [as measured by lactic acid dehydrogenase (LDH) leakage] and the protein content of hepatocytes, and d) the presence of cell surface sugar residues as a function of culture duration. The ultrastructural morphology of freshly isolated and cultured hepatocytes was also evaluated. These studies indicated that a decline in lectin binding invariably occurred earlier than a massive leakage of LDH and a decrease in the protein content of the cells in culture. Ultrastructurally, autophagocytosis was an early phenomenon in cells isolated and cultured by protocol I, which was also inferior to protocol II regarding the preservation of hepatocyte glycocalyces. Sugar residues lost due to the collagenase-stripping effect were restored, as shown by lectin binding, within the first 24 h of culture. This stripping effect was confirmed by quantitative evaluations of lectin binding to hepatocytes in culture after an incubation with collagenase. This study shows that the binding of peroxidase-labeled lectins is a useful tool for quantitative evaluation of the sugar composition of hepatocyte cultures. This study was supported by grant I-ROI-AM 26520 from the National Institute of Arthritis, Diabetes, and Digestive and Kidney Diseases, Bethesda, MD, and by W. R. Grace Corporation.     

A survey of lectin binding in Paramecium

To better understand the general distribution of glycoproteins and the distribution of specific glycoprotein-bound sugar residues in Paramecium, a survey of the binding pattern of selected lectins was carried out in P. tetraurelia, P. caudatum, and P. multimicronucleatum. Lectins studied were concanavalin A (Con A), Griffonia simplicifolia agglutinins I and II (GS I and GS II), wheat germ agglutinin (WGA), Ulex europaeus (UEA I), peanut agglutinin (PNA), Ricinis communis toxin (RCA60) and agglutinin (RCA120), soybean agglutinin (SBA), Bauhinia purpurea agglutinin (BPA), Dolichos biflorus agglutinin (DBA), and Maclura pomifera agglutinin (MPA). Those giving the most distinctive patterns were Con A, GS II, WGA, UEA I, and PNA. No significant differences were found between the three species. Concanavalin A, a mannose/glucose-binding lectin, diffusely labeled the cell surface and cytoplasm and, unexpectedly, the nuclear envelopes. Events of nuclear division, and nuclear size and number were thus revealed. Both WGA and GS II, which are N-acetylglucosamine-binding lectins, labeled trichocyst tips, the cell surface, and the oral region, revealing stages of stomatogenesis. The lectin WGA, in addition, labeled the compartments of the phagosome-lysosome system. The lectin PNA, an N-acetyl galactosamine/galactose-binding protein, was very specific for digestive vacuoles. Finally, UEA I, a fucose-binding lectin, brightly labeled trichocysts, both their tips and body outlines. We conclude that a judicious choice of lectins can be used to localize glycoproteins and specific sugar residues as well as to study certain events of nuclear division, cellular morphogenesis, trichocyst discharge, and events in the digestive cycle of Paramecium.