Galactan biosynthesis in snails: a comparative study of beta-(1--> 6) galactosyltransferases from Helix pomatia and Biomphalaria glabrata.

Adult snails synthesize in their albumen glands a polysaccharide which is composed exclusively of D- or D- and L-galactose (Gal) residues which are interglycosidically linked by 1 --> 3 and 1 --> 6 bonds. It is the only carbohydrate source for embryos and freshly hatched snails. Two galactosyltransferases are described in this study which are most likely involved in the biosynthesis of this polysaccharide. One identified in Helix pomatia acts on oligosaccharides and could be used to synthesize a tetrasaccharide when the branched trisaccharide D-Gal-beta-(1 --> 3)-[D-Galbeta-(1 --> 6)]-D-Galbeta-1 --> OMe was offered as acceptor. This enzyme, requiring Mg++-and Mn++-ions for activity, introduced a linear beta-(1 --> 6) linkage at the terminal non-reducing ends and was not detected in Biomphalaria glabrata. The other enzyme, which introduced beta-(1 --> 6) linkages at subterminal D-Gal residues, thus forming branching points in the polysaccharide, was found in H. pomatia, Arianta arbustorum and B. glabrata with comparable activities. With the enzyme preparation of H. pomatia, up to four D-Gal residues were introduced into vicinal positions, forming single-membered side chains, if a hexasaccharide with five linearly beta-(1 --> 3)-linked D-Gal residues was offered as a acceptor. The multiple-branched structure formed is typical for snail galactans, making this enzyme a prime candidate for the branching enzyme in galactan synthesis. The enzyme activity could be solubilized and purified by affinity chromatography. In SDS-polyacrylamide electrophoresis, the Helix-derived eluate displayed two bands (68, 37 kDa) and that of Biomphalaria five bands (68, 63, 17.5; 15; 13 kDa). The purified material showed only 8% of the total activity of the crude extracts, but it could be shown that a phosphatase present in the crude extract can degrade UDP formed in the transfer reaction and thus drive the reaction to completion.

Amino acid sequence of the D-galactose binding lectin II from the sponge Axinella polypoides (Schmidt) and identification of the carbohydrate binding site in lectin II and related lectin I.

The sponge Axinella polypoides contains several D-galactose binding lectins. One of the main components, lectin I was sequenced earlier, the complete sequence of the other major constituent of saline extracts, lectin II has been determined by amino acid sequencing and mass spectrometry. Both lectins have a homology of 65% to each other and both possess a disulfide loop between positions 4 and 46. As long as this loop is closed in both lectins, they can be boiled in the presence of SDS or treated with 6 mol guanidine hydrochloride without losing their hemagglutinating activity. Incubation with beta-mercaptoethanol alone does not effect the carbohydrate binding capacity either. However, reduction of the disulfide bond under chaotropic conditions destroys the activity irreversibly. This disulfide loop is also an immunologically dominant epitope in both lectins, as was revealed with monospecific polyclonal antisera. Thus, sponge lectins seem to be of different origins, since three completely different structures were described: the structure of Geodia cydonium, related to the mammalian S-type lectins with one SH-group, the Axinella lectins with one disulfide loop and the Aaptos lectins I and II with 11 cysteine residues/subunit.

The specificity of an alpha-(1-->2)-L-galactosyltransferase from albumen glands of the snail Helix pomatia.

The specificity of an L-galactosyltransferase (L-Gal-T) from albumen glands of the snail Helix pomatia has been studied. This enzyme transfers L-Gal from GDP-L-Gal to various disaccharides with beta-linked D-Gal in terminal non-reducing position, forming an alpha-(1-->2) linkage. The subterminal residue and the type of interglycosidie linkage proved to be of minor importance. However, the branched trisaccharide beta-D-Gal-(1-->3)-[beta-D-Gal-(1-->6)]-beta-D-Gal-(1-->O)Me is a very poor acceptor. The specificity of the L-Gal-T correlates well with the equimolar occurrence of L-Gal and the structural element-->2)-Gal- (1-->found in the storage polysaccharide of this snail. Since L-Fuc is also transferred from its GDP-activated form, the membrane preparations of the albumen glands can be used to synthesize fucosylated oligosaccharides.

Biosynthesis of the storage polysaccharide from the snail Biomphalaria glabrata, identification and specificity of a branching beta 1-->6 galactosyltransferase.

Adult snails synthesize in their albumen glands a storage polysaccharide called galactan which is utilized by the developing embryos. With [6-3H]-uridine 5'diphosphogalactose the incorporation of labelled D-galactose into the polysaccharide can be traced in freshly removed glands maintained in a bathing buffer. After centrifugation of homogenized glands, galactosyltransferase activity is only found in the insoluble fraction. Chaps extracts of this material retain almost all of their activity and can be used for comparison of the incorporation rates into different native galactans or in various oligosaccharides. A highly efficient beta-(1-->6) galactosyltransferase was detected when methyl 3-O-(beta-D-galactopyranosyl)-beta-D-galactopyranoside was offered as acceptor. The substitution at the penultimate residue resulted in a branched trisaccharide as demonstrated by 1H-NMR-spectroscopy and permethylation analysis of the reaction product. Comparable results were obtained with various oligosaccharides containing an internal galactose unit glycosidically linked beta 1-->3. Attempts to separate and purify the various enzymes involved resulted in the isolation of a fraction which is able to transfer D-Gal exclusively to native galactan, but not to oligosaccharides. A further fraction was obtained from a different resin with activity for native galactan and 6-O-(beta-D-galactopyranosyl)-D-galactopyranose, but without any for methyl-3-O-(beta-D-galactopyranosyl)-beta-D-galactopyranose. It is thus concluded that at least three different enzymes are involved in the biosynthesis of this snail galactan.

S-type lectins occur also in invertebrates: high conservation of the carbohydrate recognition domain in the lectin genes from the marine sponge Geodia cydonium.

The marine sponge Geodia cydonium contains several lectins. The main component, called lectin-1, is composed of three to four identical subunits. The subunits of the lectins were cloned from a cDNA library; two clones were obtained. From the deduced aa sequence of one clone, LECT-1, a mol. wt of 15,313 Da is calculated; this value is in good agreement with mass spectrometric analysis of 15,453 +/- 25 Da. The sequence of another clone, LECT-2, was analysed and the aa sequence was deduced (15,433 Da). The two subunits have a framework sequence of 38 conserved aa which are characteristic for the carbohydrate-binding site of vertebrate S-type lectins. Clustering of lectin sequences of various species following their pairwise comparison establishes a dendrogram, which reveals that the sponge lectin could be considered as the ancestor for vertebrate S-type lectins.

Comparative investigations on the amino-acid sequences of different isolectins from the sponge Axinella polypoides (Schmidt).

The sponge Axinella polypoides contains four different D-galactose binding lectins and one, termed lectin IV, which is specific for hexuronic acids. Only the D-galactose binding lectins were investigated in this study. The complete amino-acid sequence of lectin I, the main component in the crude extract was determined. Lectin I is a homodimer and each subunit comprises 144 amino acids with a M(r) of 15,847 +/- 10, as calculated from the sequence data and determined by mass spectrometry. Each subunit contains one intrachain disulfide bridge between positions 4 and 46. Of lectin II, only the first 49 amino acids of the NH2-terminal end were analysed. This part has 29 amino acids in common with lectin I, including a cysteine residue at position 4, also suggesting an intrachain loop in a identical position as in lectin I. The molecular mass of its subunit is 16,235 +/- 10 Da. Only the first 15 NH2-terminal amino acids of lectins III and V could be sequenced. Lectin V was identical to lectin II in all positions, whereas lectin III showed only 5 residues identical to lectins I or II. Thus, lectins I, II and III are derived from three different genes, whereas lectin V may either be a proteolytic cleavage product, or result from different splicing events or may be derived also from a separate gene. Neither of the four lectins showed any similarity to known lectin sequences of animal or plant origin.

The galactan-degrading enzymes in the snail Biomphalaria glabrata.

1. Embryonic snails incorporate from the perivitelline fluid in which they are embedded a polysaccharide, called galactan, which is composed entirely of D-, or D- and L-galactose. In this investigation the p-nitrophenyl-beta-D-galactoside degrading enzyme of Biomphalaria glabrata which was assumed to be involved in the degradation of the galactans was purified almost to homogeneity and its specificity was studied. 2. It has a mol. wt of 135,000 and is composed of two identical subunits. 3. It could be shown that p-nitrophenyl-beta-D-fucoside was hydrolysed eight times faster, but native galactan was neither decomposed nor was it inhibitory for the hydrolysis of p-nitrophenyl-glycosides. 4. Thus, it is most likely that this galactosidase is not involved in the galactan metabolism. 5. However, a membrane-bound enzyme complex was revealed which was able to metabolize the native galactan of Biomphalaria glabrata completely and which showed graded reactivity towards galactans of other species. 6. Since no intermediate degradation products were found it must be assumed that they were metabolized further in the mitochondria.

Allergens of horse epithelium. I. Physicochemical and immunochemical characterization of five different horse epithelium raw materials used for allergen extract preparation.

We investigated five horse epithelial allergen extracts prepared from different qualities of raw material by several biochemical and immunochemical methods. Horse serum albumin and horse serum were used to identify serum-related antigens. We found high similarities as well as marked differences between the extracts. There were strong differences in the protein contents, the protein patterns obtained by isoelectric focusing and sodium dodecyl sulfate polyacrylamide gel electrophoresis, the total allergenic activities obtained by radioallergosorbent test inhibition assays and the amounts and numbers of serum-related proteins. The patterns of dander-related allergens in crossed radioimmunoelectrophoresis were similar but showed partly strong differences in allergen concentrations. Allergen compositions determined by blotting methods showed only minor differences between the investigated epithelial extracts. It appears that some of the differences, e.g. the content of serum-related proteins, depend on the way the different raw materials are prepared. Because serum-related extract components are not considered as major allergens, their content should be low in horse epithelial allergen extracts. For this reason whole skin cannot be recommended as starting material for horse epithelium allergen extract preparation.

Structural studies on the galactan from the snail Helix pomatia.

1. The galactan of the snail Helix pomatia was subjected to two cycles of Smith-degradation and the resulting products were isolated by gel filtration and thin layer chromatography. 2. The structures of the low molecular weight oligosaccharides were elucidated being identical to those obtained from Lymnaea stagnalis galactan. However, the quantities released differed significantly between the two species. The high molecular fractions comprising about 66% of the material were not obtained in a similar degradation of the Lymnaea stagnalis galactan. 4. Thus the observed structural differences can explain easily the species-specific reactivity among the two polysaccharides seen earlier with lectins, enzymes and antibodies.

The reactivity of galactose oxidase with snail galactans, galactosides and D-galactose-composed oligosaccharides.

The enzymic oxidation of snail galactans, of their first and second Smith degradation products and of some structurally related polysaccharides was studied. Lymnaea stagnalis galactan after one cycle of Smith degradation reacted best and native Helix pomatia galactan was almost inactive. Investigations on the structural requirements for oligosaccharides to bind to galactose oxidase showed that the branched tetrasaccharide, Gal-beta-1----6-[Gal-beta-1----3]-Gal-beta-1----1 L-Gro, in the terminal nonreducing position was the most complementary structure in the native galactan to associate with the enzyme. All nitrophenyl alpha-galactosides reacted better, and the ortho-form was 10-times more potent compared with this tetrasaccharide, indicative of the involvement of a hydrophobic region in binding. However, the beta-linked isomers were only equally or less reactive than galactose. The enzymic oxidation determined colorimetrically by transferring the peroxide formed to o-dianisidine ceased at a maximum typical for each substrate and independent of the reaction time. When the absolute turn-over rates for ortho- and para-nitrophenyl alpha-galactoside and for the beta-isomer were determined by HPLC, it could be demonstrated that the oxidation had not finished at the maximum of the colour reaction, but proceeded until the substrate was consumed. The initial speed of the colour reaction paralleled the absolute oxidation rate.

Isolation and characterization of a lectin from the snail Biomphalaria glabrata and a study of its combining site.

The hemagglutinins from the spawn of the water snail Biomphalaria glabrata were isolated by affinity chromatography on hog gastric mucin coupled to Sepharose 4B. The N-acetyl-D-glucosamine eluate (0.1 M) was fractionated further on Bio-Gel P-300, yielding two fractions. Fraction 1 had an Mr of 350 000 and displayed one band in immunoelectrophoresis, but was heterogeneous in discontinuous electrophoresis. It agglutinated human red blood cells with A1 and B specificity at concentrations of 12 and 72 micrograms nitrogen/ml, respectively. Fraction 2 had an Mr on gel filtration of 67 000 and was homogeneous in immuno- and polyacrylamide electrophoresis, and in isoelectrofocusing. It is composed of three subunits with Mr of 17 000 and one smaller subunit of 15 000. This fraction (lectin I) is a glycoprotein containing 6% hexoses and 2.5% hexosamines. For minimal agglutination of human A1 and B red blood cells 2.4 and 72.0 micrograms nitrogen/ml, respectively, of lectin I were required. O red blood cells were not agglutinated. Lectin I precipitated well with a human blood group substance of A1 specificity, moderately with a B- and poorly with an H-substance. Precipitin-inhibition studies revealed that among other sugars N-acetylneuraminic acid was the most potent inhibitor. Immunofluorescence studies confirmed the good interaction of lectin I with receptors of A1 and B erythrocytes and the failure of lectin I to attach to O-erythrocytes. Since N-acetylneuraminic acid is present on the cell surface of all human erythrocytes, it cannot be the dominant part of the receptor for the B. glabrata lectin I, despite its effectiveness as an inhibitor.

Immunohistochemical studies on the distribution and the function of the D-galactose-specific lectins in the sponge Axinella polypoides (Schmidt).

The distribution of the two D-galactose-specific lectins within the sponge tissue of Axinella polypoides was studied by autoradiography and by an immunohistochemical method on paraplast- and cryosections. Both techniques revealed that the lectins are stored inside the vesicles of the spherulous cells. All spherulous cells, regardless of their appearance in the different types of tissue contained the lectins. Antibodies were purified from an antiserum that reacted with both lectin I and lectin II and from the same antiserum rendered monospecific for lectin I. The purified antibodies were used to demonstrate that lectin II is predominantly present in spherulous cells with small vesicles, and lectin I in those with large vesicles. Electron-microscopic studies revealed that the spherulous cells with small vesicles are derived from archaeocytes and transformed into spherulous cells with large vesicles, a process accompanied by the conversion of lectin II to lectin I. Histological investigations showed that the tips of the bush-like, branched sponge lack the central axis, a spongin fiber network that provides support and stability to the sponge tissue. However, the missing spongin network is already preformed by cell bundles that ultimately produce the numerous fiber strands of the central axis. These bundles are composed exclusively of spindle-shaped cells and the spherulous cells. Other areas where production of spongin fibers is expected are also enriched with spherulous cells. These findings and the reaction of lectin-specific antibodies with the spongin fibers indicate that spherulous cells, and thus the lectins, are involved in synthesis of spongin fiber. Sponges lacking spongin fibers, e.g. Aaptos aaptos and Geodia cydonium, produce lectins with different carbohydrate specificity and possess large numbers of spherulous cells.

A mitogenic lactose-binding lectin from the sponge Geodia cydonium.

Two lectins with affinity for hog A + H blood group substance were extracted from the Mediterranean sponge Geodia cydonium. One, termed Geodia lectin I, was purified to near homogeneity by lactose elution from a column of hog A + H coupled to Sepharose 4B. Geodia lectin I was a glycoprotein (carbohydrate content about 14%) with m.w. of about 60,000 and an isoelectric point of pH 4.4. Subunits of about 15,000 daltons were linked by disulfide bonds. The lectin precipitated with various snail galactans composed entirely of DGal and LGal, to a slight degree with guaran, which has DGal alpha 1 leads to 6 in a terminal nonreducing position, and with blood group substances. Of 42 sugars tested, only lactose, dGal beta 1 leads to 4 DGlcNAc, DGal beta 1 leads to 3DGlcNAc, DGalNAc, inhibited precipitation. In view of the relatively high concentration of those disaccharides that inhibited relative to other lectins, the specificity of interaction is thought to be via beta-linked DGal residues that are part of a more complex combining site. Geodia lectin I was mitogenic for human peripheral blood lymphocytes with an optimal concentration of about 5.6 micrograms/ml if serum was omitted for the first 24 hr of culture to allow "triggering." Fetal calf serum apparently contained a high concentration of substances that inhibited mitogenicity and hemagglutination by Geodia lectin I, presumably by specifically interacting with the binding site.

Human monoclonal macroglobulins with specificity for Klebsiella K polysaccharides that contain 3,4-pyruvylated-D-galactose and 4,6-pyruvylated-D-galactose.

Two human IgM myeloma proteins, IgMWEA and IgMMAY, were found to react with agar and Klebsiella polysaccharides that contain pyruvylated D-galactose (DGal). Quantitative precipitin data and precipitin inhibition studies with methyl alpha- and beta-glycosides of 4,6-pyruvylated-D-galactose showed their combining sites to be different, although each was directed against the pyruvylated-D-Gal, one reacting most specifically with Klebsiella polysaccharides with terminal nonreducing beta-linked 2,4 pyruvylated-D-Gal, whereas the other reacted equally well with Klebsiella polysaccharides that contain 3,4 beta-linked and 4,6 alpha-linked terminal nonreducing pyruvylated-DGal. Inhibition studies showed that both sites are directed toward one of the two space isomers of 3,4- or 4,6-pyruvylated DGal, the form in which the methyl group of the pyruvate is equatorial, or endo, and its carboxyl group axial, or exo, to the plane of the acetal ring. Coprecipitation studies showed the combining site of IgMWEA to be located on an (Fab')2 fragment and not on the (Fc)5mu fragment. The monoclonal peak in the serum of IgMMAY was specifically precipitated by Klebsiella polysaccharide. Myeloma proteins with specificities of this type may occur with reasonable frequency in humans and may be a consequence of clonal expansion from inapparent infection, carrier states, or disease produced by various Klebsiella organisms.

Investigations on the lectin-producing cells in the sponge Axinella polypoides (Schmidt).

The localization of two carohydrate binding proteins, so-called lectins, was studied in the sponge tissue of Axinella polypoides by light and immunofluorescence microscopy. They do not occur at the cellular surface of any cell type, but they are stored in vesicles of the "spherulous cells". After short formaldehyde fixation spherulous cells can be isolated and they release the active lectins upon lysis in distilled water. Electron microscopical studies of spherulous cells show that they contain almost nothing else but a small nucleus and vesicles of different size and number. Small vesicles are full of an electron dense material, whereas the content of large vesicles has a fluffy and fibrillar structure. Spherulous cells are large and tightly packed in the outer layer of the ectosome and in the meshwork of the spongin fibres of the central axis. The are small and scattered in the inner layer of the ectosome, and they are found throughout the choanosome. The function of the lectins is not clearly defined, and different alternatives such as participation in glycoprotein synthesis, immunological defense, or carbohydrate transport are possible.

[Determination of the association constant K0 and the number of combining sites n of the mitogenic lectin I and its structural relationship to the nonmitogenic lectin II from the sponge Axinella polypoides (Schmidt) (author's transl)]. / Die Bestimmung der Bindungskonstanten K0 und der Zahl der Bindungsstellen n für das mitogene Lektin I und dessen strukturelle Beziehungen zu dem amitogenen Kektin II aus dem Schwamm Axinella polypoides (Schmidt).

The association constant K0 and the number of combining-sites n for the mitogenic lectin I from the sponge Axinella polypoides was determined. K0 was found to be 2,8 . 10(2) 1/mol and n = 1. Immunoelectrophoretic investigations demonstrated, that lectin I and the nonmitogenic lectin II of Axinella polypoides have structural relationships but have also domains which are unique to them. The correlation between these findings, their carbohydrate specificity and mitogenicity is discussed.

[Differentiation by microimmunofluorescence of T. cruzi and T. cruzi-like strains from T. conorhini and T. rangeli, using protection from the sponge Aaptos papillata (author's transl)]. / Immunfluoreszenzmikroskopische Unterscheidung zwischen T. cruzi-, T. cruzi-like Stämmen, T. conorhini und T. rangeli mit dem Protektin des Schwammes Aaptos papillata.

Carbohydrates containing terminal nonreducting D N-acetylgalactosamin or D N-acetylglucosamin were identified at the cell surface of Trypanosoma cruzi by an indirect immunofluorescence test using the lectin of the sponge Aaptos papillata. With the method described in this study T. cruzi and T. cruzi-like strains are easy to distinguish from T. rangeli, but not from T. conorhini. The immunofluorescence test presented here may be very helpful for certain diagnostic problems.

Purification and characterization of the agglutinins from the sponge Aaptos papillata and a study of their combining sites.

The lectins from the sponge Aaptos papillata were isolated by affinity chromatography using polyleucyl blood group A + H substances from hog stomach linings as an absorbent and eluting with 3 M MgCl2. Further separation on diethylaminoethylcellulose and preparative disc electrophoresis on polyacrylamide gave the three fractions, Aaptos lectins I, II, and III. They were essentially homogenous in polyacrylamide electrophoresis and sedimentation analysis: a small second component was seen in lectins I and II in immunoelectrophoresis at high concentration. The S20,W0 values for Aaptos lectins I, II, and III were 3.5, 6.0, and 5.5. By electrophoresis in sodium dodecyl sulfate with an without beta-mercaptoethanol Aaptos lectin I showed two bands corresponding to molecular weights of 12 000 and 21 000; Aaptos lectins II and III gave only one band of molecular weight of 16 000. In isoelectric focusing, Aaptos lectin I showed bands at pH 4.7 and 5.4 and in the range between 6.8 and 7.6, while Aaptos lectins II and III were almost identical with bands at pH 3.8, 4.7 to 4.9, and 5.3. Aaptos lectin I differed from II and III in amino acid composition but the latter two were very similar. They contained no significant carbohydrate. Aaptos lectin I reacted best with blood group substances with terminal nonreducing N-acetyl-D-glucosamine residues precipitating about two-thirds of the lectin N added while blood group substances with terminal nonreducing DGalNAc were almost inactive. However, Aaptos lectin II was completely precipitated by blood group substances and glycoproteins containing terminal DGalNAc, DGlcNAc, or sialic acid residues. Aaptos lectin III had a precipitation pattern similar to Aaptos lectin II. DGlcNAc but not DGalNAc inhibited precipitation of Aaptos lectin I by blood group substances and N, N', N'', N'''-tetraacetylchitotetraose was the best inhibitor and was 2000 times more active than DGlcNAc. Precipitin reactions with Aaptos lectin II were inhibited by equal amounts of DGlcNAc and by sialic acid which were four times more potent than DGalNAc. N,N',N''-triacetylchiotriose was the best inhibitor and was 13 times better than DGlcNAc. At 37 degrees C three to four times higher amounts of inhibitor were necessary to inhibit precipitation of Aaptos lectin II than were needed at 4 degrees C, indicating higher affinity of blood group substances for Aaptos lectin II with increasing temperature. Aaptos lectin I was precipitated by the monofunctional hapten p-nitrophenyl-alphaDGalNAc, while p-nitrophenyl-betaDGalNAc did not precipitate and was a good inhibitor. Both phenomena indicate involvement of hydrophobic bonds.

A galactose-inhibitable mitogen for human lymphocytes from the sponge axinella polypoides.

Of two galactose-binding hemagglutinins isolated from the sponge Axinella polypoides, axinella I was strongly mitogenic for human peripheral blood lymphocytes, and axinella II was not. Purified T cells responded strongly and B cells weakly to axinella I. Mitogenic response, as monitored by rate of 3H-thymidine incorporation on the third day of culture, was specifically inhibited by Dgalactose, Dfucose, raffinose, or 2-deoxy-D-galactose added within 5 hr of the mitogen. Mitogenic response was correlated with degree of lymphocyte agglutination. The effectiveness of a given sugar in inhibiting mitogenic response to axinella I paralleled its potency in inhibiting precipitation of lectin by blood group substances. If an inhibitory concentration of Dgalactose was add 24 to 40 hr after mitogenic activation, rate of 3H-thymadine uptake at 72 hr was two to twenty times above the rate induced in cultures to which no galactose was added. Dgalactose at a subinhibitory concentration (10mug/ml) enhanced 3H-thymidine incorportion incorporation induced by phytohemagglutinin or Con A, an effect reversible by Dgalactose. These findings suggest that axinella I has tow antagonistic effects on human lymphocytes: a) mitogenic activation and b) depressive activity resulting from depletion of essential galactose moieties.