Glycoconjugate distribution in gastric fundic mucosa of Umbrina cirrosa L. revealed by lectin histochemistry

The stomach of adult shi drum Umbrina cirrosa was investigated using a battery of nine horseradish peroxidase‐conjugated lectins combined with enzymatic treatment, in order to distinguish glycoconjugate sugar residues. Epithelial cells showed the presence of galactosyl(β1→4)N‐acetylglucosamine, mannose, N‐acetylgalactosamine, N‐acetylglucosamine, fucose and sialic acid‐galactosyl(β1→3)N‐acetylgalactosamine residues. Gastric pits had similar sugar residues with the exception of N‐acetylgalactosamine which was less diffused. Gastric glands were characterized by the presence of glycoconjugates containing galactosyl(β1→3)N‐acetylgalactosamine, N‐acetylglucosamine, galactosyl(β1→4) N‐acetylglucosamine, N‐acetylgalactosamine and a small amount of sialic acid linked to N‐acetylgalactosamine.     

A lectin histochemical study of the oesophagus of shi drum

The saccharide composition of surface and secretion glycoconjugates in the oesophagus of Umbrina cirrosa was examined by means of lectin histochemistry. Mucous cells showed the presence of N‐acetylgalactosamine, N‐acetylglucosamine and sialic acid linked to the dimer galactosyl(β1→3) N‐acetylgalactosamine. Columnar epithelial cells had a positive reaction with almost all the lectins employed, located in the supranuclear region and in the cell coat. The presence of abundant and various glycoconjugates in the secretions of shi drum oesophagus was correlated to the absence of salivary glands in fishes in general.     

Biosynthesis of the major brain gangliosides GD1a and GT1b

Gangliosides-sialylated glycosphingolipids-are the major glycoconjugates of nerve cells. The same four structures-GM1, GD1a, GD1b and GT1b-comprise the great majority of gangliosides in mammalian brains. They share a common tetrasaccharide core (Galβ1-3GalNAcβ1-4Galβ1-4Glcβ1-1'Cer) with one or two sialic acids on the internal galactose and zero (GM1 and GD1b) or one (GD1a and GT1b) α2-3-linked sialic acid on the terminal galactose. Whereas the genes responsible for the sialylation of the internal galactose are known, those responsible for terminal sialylation have not been established in vivo. We report that St3gal2 and St3gal3 are responsible for nearly all the terminal sialylation of brain gangliosides in the mouse. When brain ganglioside expression was analyzed in adult St3gal1-, St3gal2-, St3gal3- and St3gal4-null mice, only St3gal2-null mice differed significantly from wild type, expressing half the normal amount of GD1a and GT1b. St3gal1/2-double-null mice were no different than St3gal2-single-null mice; however, St3gal2/3-double-null mice were >95% depleted in gangliosides GD1a and GT1b. Total ganglioside expression (lipid-bound sialic acid) in the brains of St3gal2/3-double-null mice was equivalent to that in wild-type mice, whereas total protein sialylation was reduced by half. St3gal2/3-double-null mice were small, weak and short lived. They were half the weight of wild-type mice at weaning and displayed early hindlimb dysreflexia. We conclude that the St3gal2 and St3gal3 gene products (ST3Gal-II and ST3Gal-III sialyltransferases) are largely responsible for ganglioside terminal α2-3 sialylation in the brain, synthesizing the major brain gangliosides GD1a and GT1b.     

Distribution of Carbohydrates Recognized by the Lectins Euonymus europaeus and Concanavalin A in Monoxenic and Heteroxenic Trypanosomatids

We observed a wide distribution of the carbohydrate epitopes galactosylα(1–3) galactose (galα1–3 gal), α-glucoside, and α-mannoside in mono- and heteroxenic trypanosomatids by using fluorescein-labelled lectins of Euonymus europaeus (EE) and Concanavalin A (Con A) as well as sera from acute chagasic patients who have very high levels of anti-galα(1–3) gal antibodies. The direct fluorescence test for galα1–3 gal with EE was positive at minimum concentrations of 6 μg/ml for heteroxenic trypanosomatids and 0.7 μg/ml for monoxenic ones and for the plant parasite, Phytomonas. On the other hand, heteroxenic trypanosomatids that infect vertebrates bound ten-fold more Con A than monoxenic flagellates and Phytomonas. These data were confirmed in ELISA and Western Blot assays carried out with peroxidase-labelled EE and Con A. Euonymus europaeus recognized several glycoproteins in all trypanosomatids that we tested. Con A, however, recognized a glycoprotein cluster in heteroxenic protozoa, which ranging from 60–120 kDa, seemed to lack monoxenic parasites and Phytomonas. These findings suggest that α-D-mannose and α-D-glucose might play an important role in the interaction between trypanosomatids and vertebrate hosts.     

Localization of penultimate carbohydrate residues in zona pellucida and acrosomes by means of lectin cytochemistry and enzymatic treatments

Lectins from peanuts (PNA) and soy beans (SBA) bind terminal residues of galactose (Gal) and N-acetyl-galactosamine (GalNAc) respectively. Galactose oxidase oxidizes the hydroxyl group at C-6 of terminal Gal and GalNAc blocking the binding of PNA and SBA. Binding of these lectins to sugar residues is also severely limited by the existence of terminal residues of sialic acid. In the present study, lectin cytochemistry in combination with enzymatic treatments and quantitative analysis has been applied at light and electron microscopical levels to develop a simple methodology allowing the in situ discrimination between penultimate and terminal Gal/GalNAc residues. The areas selected for the demonstration of the method included rat zona pellucida and acrosomes of rat spermatids, which contain abundant glycoproteins with terminal Gal/GalNAc residues. Zona pellucida was labelled by LFA, PNA and SBA. After galactose oxidase treatment, terminal Gal/GalNAc residues are oxidized, and reactivity to PNA/SBA is abolished. The sequential application of galactose oxidase, neuraminidase and PNA/ SBA has the following effects: (i) oxidation of terminal Gal/GalNAc residues; (ii) elimination of terminal sialic acid residues rendering accessible to the lectins preterminal Gal/GalNAc residues; and (iii) binding of the lectins to the sugar residues. Acrosomes were reactive to PNA and SBA. No LFA reactivity was detected, thus indicating the absence of terminal sialic acid residues. Therefore, no labelling was observed after both galactose oxidase--PNA/SBA and galactose oxidase--neuraminidase--PNA/SBA sequences. In conclusion, the combined application of galactose oxidase, neuraminidase and PNA/SBA cytochemistry is a useful technique for the demonstration of penultimate carbohydrate residues with affinity for these lectins. This revised version was published online in November 2006 with corrections to the Cover Date.     

Glycoconjugate histochemistry of the digestive tract of <Emphasis Type="Italic">Triturus carnifex</Emphasis> (Amphibia,Caudata)

Summary In this study, the variety of sugar residues in the gut glycoconjugates of Triturus carnifex (Amphibia, Caudata) are investigated by carbohydrate conventional histochemistry and lectin histochemistry. The oesophageal surface mucous cells contained acidic glycoconjugates, with residues of GalNAc, Gal β1,3 GalNAc and (GlcNAc β1,4) _n oligomers. The gastric surface cells mainly produced neutral glycoproteins with residues of fucose, Gal β1-3 GalNAc, Gal-αGal, and (GlcNAc β1,4) _n oligomers in N- and O-linked glycans, as the glandular mucous neck cells, with residues of mannose/glucose, GalNAc, Gal β1,3 GalNAc, (GlcNAc β1,4) _n oligomers and fucose linked α1,6 or terminal α1,3 or α1,4 in O-linked glycans. The oxynticopeptic tubulo-vesicular system contained neutral glycoproteins with N- and O-linked glycans with residues of Gal-αGal, Gal β1-3 GalNAc and (GlcNAc β1,4) _n oligomers; Fuc linked α1,2 to Gal, α1,3 to GlcNAc in (poly)lactosamine chains and α1,6 to GlcNAc in N-linked glycans. Most of these glycoproteins probably corresponds to the H⁺K⁺-ATPase β-subunit. The intestinal goblet cells contained acidic glycoconjugates, with residues of GalNAc, mannose/ glucose, (GlcNAc β1,4) _n oligomers and fucose linked α1,2 to Gal in O-linked oligosaccharides. The different composition of the mucus in the digestive tracts may be correlated with its different functions. In fact the presence of abundant sulphation of glycoconjugates, mainly in the oesophagus and intestine, probably confers resistance to bacterial enzymatic degradation of the mucus barrier.     

The Arabidopsis thaliana putative sialyltransferase resides in the Golgi apparatus but lacks the ability to transfer sialic acid

A common feature of the animal sialyltransferases (STs) is the presence of four conserved motifs, namely large (L), small (S), very small (VS) and motif III. Although sialic acid (SA) has not been detected in plants, three orthologues containing sequences similar to the ST motifs have been identified in the Arabidopsis thaliana L. database. In this study, we report that the At3g48820 gene (Gene ID: 824043) codes for a Golgi resident protein lacking the ability to transfer SA to asialofetuin or Galβ1,3GalNAc and Galβ1,4GlcNAc oligosaccharide acceptors. Restoration of deteriorated motifs S, VS and motif III by constructing chimeric proteins consisting of the 28–308 amino acid region of the A. thaliana At3g48820 ST-like protein and the 264–393 amino acid region of the Oryza sativa L. AK107493 ST-like protein, or of the 28–240 amino acid region of the At3g48820 protein and the 204–350 amino acid region of the Homo sapiens L. α2,3-ST ( NP_008858 ) was not able to recover sialyltransferase activity. Altering the appropriate amino acid regions of the A. thaliana At3g48820 ST-like protein to those typical for the mammalian motif III (HHYWE) and VS motif (HDADFE) also did not have any effect. Our data, together with previous results, indicate that A. thaliana in particular, and plants in general, do not have transferases for SA. Substrates for the plant ST-like proteins might be compounds involved in secondary metabolism.     

Histochemical and ultrastructural analysis of the epidermal gland cells of Branchiomma luctuosum (Polychaeta, Sabellidae)

Abstract. This histochemical and ultrastructural study describes the epidermal gland cells of a tubicolous polychaete, Branchiomma luctuosum . The histochemistry was carried out using standard techniques and FITC-labelled lectins. Four types of secretory cells were identified in two categories: orthochromatic cells (Type 1) and metachromatic cells (Types 2, 3, and 4). The secretory product of the Type-1 orthochromatic cells contains neutral glycoproteins with Galβ1,3GalNAc residues. Metachromatic cells produce acidic, mainly sulfated, glycoconjugates with Galβ1,3GalNAc residues (Type 2) or glucosidic and/or mannosidic residues (Types 3 and 4). In sialylated chains, terminal sialic acid is bound to the penultimate GalNAc and Galβ1,3GalNAc residues. The complex composition of the mucus produced by epidermal gland cells of B. luctuosum may be correlated with its different functions. Ultrastructural studies of the epidermal gland cells showed differing morphology, and the presence in the gland cells of Types 3 and 4 of a funnel-shaped structure for the extrusion of the secretory material.     

Qualitative Analysis of the Carbohydrate Composition of Apolipoprotein H

The specific binding of digoxigenin-labeled lectins to carbohydrate moieties is used to characterize the carbohydrate chains bound to apolipoprotein H. Our results show that apolipoprotein H is rich in sialic acid linked (2–6) to galactose or N-acetylgalactosamine. Sialic acid is not (2–3)-linked to galactose. Galactose is (1–4)-linked to N-acetylglucosamine and (1–3)-linked to N-acetylgalactosamine. High-mannose N-glycan chains are barely detectable. After N-glycosidase F treatment the molecular weight is substantially reduced. The main band is 32,500 daltons. Carbohydrate O-linked chains, which are mainly represented by sialic acid, are (2–6)-linked to galactose or N-acetylgalactosamine. Galactose is also organized in O-linked chains and it is (1–4)-linked to N-acetylglucosamine and (1–3)-linked to acetylgalactosamine. Biochemical analysis of carbohydrate structures reveals that no specific carbohydrate complex is bound to a single isoform.     

Oligosaccharide structural specificity of the soluble agglutinin released from guinea pig colonic epithelial cells

Abstract Guinea pig colonic epithelial cells release a soluble lectin capable of agglutinating numerous strains of Shigella and Escherichia coli as well as other bacteria. Using pure oligosaccharides and glycopeptides with well-defined structures to inhibit the agglutination of Shigella flexneri 1b by the soluble intestinal lectin, we have been able to demonstrate that the latter recognises different structural types. Inhibition by human milk glucoprotein glycopeptides with biantennary glycans of the N -acetyllactosamine type was dependent on the simultaneous presence of unsubstituted terminal non-reducing galactose residues and of a fucose residue α-1,6-linked to the asparagine-conjugated N -acetylglucosamine residue. Unsubstituted terminal non-reducing galactose was also determinant for inhibition by human milk oligosaccharides. Finally oligosaccharides possessing the Man (α1–2) Man structure inhibited more effectively than those with a Man(α1–3)Man sequence. The fact that these different structural motifs were all inhibitory raises the problem of the possible existence of a multispecific lectin or of several different lectins in the guinea pig colonic mucosa mediating bacterial adherence.     

Chemotaxis of Entamoeba histolytica towards the pro-inflammatory cytokine TNF is based on PI3K signalling, cytoskeleton reorganization and the Galactose/N-acetylgalactosamine lectin activity

Entamoeba histolytica is the protozoan parasite responsible for human amoebiasis. During invasive amoebiasis, migration is an essential process and it has previously been shown that the pro-inflammatory compound tumour necrosis factor (TNF) is produced and that it has a migratory effect on E. histolytica . This paper focuses on the analysis of parasite signalling and cytoskeleton changes leading to directional motility. TNF-induced signalling was PI3K-dependent and could lead to modifications in the polarization of certain cytoskeleton-related proteins. To analyse the effect of TNF signalling on gene expression, we used microarray analysis to screen for genes encoding proteins that were potentially important during chemotaxis towards TNF. Interestingly, we found that elements of the galactose/N-acetylgalactosamine lectin (Gal/GalNAc lectin) were upregulated during chemotaxis as well as genes encoding proteins involved in cytoskeleton dynamics. The α-actinin protein appeared to be an important candidate to link the Gal/GalNAc lectin to the cytoskeleton during chemotaxis signalling. Dominant negative parasites blocked for Gal/GalNAc lectin signalling were no longer able to chemotax towards TNF. These results have given us an insight on how E. histolytica changes its cytoskeleton dynamics during chemotaxis and revealed the capital role of PI3K and Gal/GalNAc lectin signalling in chemotaxis.     

ON THE STRUCTURE OF TWO NEW GANGLIOSIDES FROM BEEF BRAIN

Abstract— Two new gangliosides were isolated in pure form from beef brain. They were provisionally named ganglioside G5a and G5b. Ganglioside GSa is a monosialoganglioside containing fucose. Its basic neutral glycosphingolipid core is the gangliotetraose ceramide: Gal (1 —> 3) GalNac (1—> 4) Gal (1 —> 4) Glc (1—>) ceramide, most likely with β-linkages. Fucose is linked to the 2-position of external galactose, N -acetylneuraminic acid to the 3- position of internal galactose. Ganglioside G5b is a mixture of at least two isomeric disialogangliosides containing N -acetylneuraminic acid and N -glycolylneura-minic acid. The major isomer has the following structure: NeuNac (α,2—>3) Gal (β,1—>3) GalNac (β, 1 —> 4) (NeuNglα, 2 —> 3) gal (β,1—>4) Glc (β,1 —>)-ceramide. The minor isomer contains N -acetylneur-aminic acid and N -glycolylneuraminic acid in an inverted linkage position.     

Growth characteristics of skeletal muscle tissue in Oreochromis niloticus larvae fed on a lysine supplemented diet

The effect of lysine amino acid supplementation on the growth characteristics and morphological pattern of skeletal muscle tissue in Nile tilapia Oreochromis niloticus larvae was evaluated. There were four treatments (T) with increasing levels of lysine supplement (T1 = 0·0%; T2 = 1·1%; T3 = 1·7%; T4 = 4·0%) and one treatment with a commercial diet (T5). In all treatments, morphological and histochemical muscle tissue analyses were similar. Two distinct layers were identified: a superficial red layer, more developed in the lateral line region, formed by fibres with intense to moderate NADH‐TR reaction and strong acid‐stable mATPase activity, and a deep white one, most of the muscle mass, formed by fibres with weak NADH‐TR reaction and strong alkali‐stable mATPase activity. There was an intermediate layer between these two layers with fibres exhibiting either weak acid‐stable or acid‐labile mATPase activity. Body mass increase was significantly higher in T5 than in the lysine treatments (T1–T4). There was no difference in number and diameters of muscle fibres between lysine treatments. In T5, muscle fibre diameter and number were higher. The frequency of red fibres with diameters ≤8 μm was higher in the lysine treatments, and with diameters between 16 and 24 μm, was higher in T5. Most white fibre diameters in T5 were significantly larger than 24 μm and in T1–T4 were between 8 and 16 μm. Cell proliferation was higher in the lysine treatments and muscle growth in T5 was mainly by fibre hypertrophy.     

Release of sex steroids into the water by roach

Electro‐olfactogram (EOG) recordings of the olfactory epithelium of both male and female roach Rutilus rutilus demonstrated that both sexes were able to detect free and glucuronidated 17,20β‐dihydroxy‐4‐pregnen‐3‐one (17,20β‐P) with high sensitivity. Male, but not female, roach were also sensitive to androstenedione. Sexually mature female roach were shown to release free 17,20β‐P, glucuronidated 17,20β‐P and androstenedione into the water; for all three steroids, the rate of release was significantly enhanced by injection of carp pituitary extract (CPE). A series of trials was also carried out which showed that mature males, and to a lesser extent immature males and females, were able also to release free and glucuronidated 17,20β‐P, both before and after CPE treatment. Water extracts from containers that had held CPE‐treated mature male and female roach were examined for the presence of other steroids. This revealed that free and glucuronidated 17,20β‐P plus free and glucuronidated 17,20β,21‐trihydroxy‐4‐pregnen‐3‐one (17,20β, 21‐P) predominated in water extracts from both sexes. The free moieties of 17,20α‐dihydroxy‐4‐pregnen‐3‐one, 17‐hydroxyprogesterone and 11‐deoxycortisol were found at concentrations which were between four and 20 times lower than those of free 17,20β‐P. Androstenedione was found at concentrations which were 25‐fold lower than those of 17,20β‐P. Despite its apparent high rate of release by sexually mature male and female roach, free 17,20β,21‐P was found not to exhibit any EOG activity at the highest dose tested (10⁻⁷ M).     

The substrate specificity of the enzyme Endo-α-N-acetyl-D-galactosaminidase from Diplococcus pneumonia

The substrate specificity of the enzyme endo-α-N-acetyl-D-galactosaminidase from Diplococcus pneumonia was re-examined using bovine submaxillary mucin and remodelled antifreeze glycoprotein as substrates. Incubation with desialylated bovine submaxillary mucin, which contains six O-linked core types, indicated that the disaccharide Galβ1-3GalNAc, which is present in very small amount, was the only glycan released, while the disaccharide GlcNAcβ1-3GalNAc, which is the major structure present, and other disaccharides, were not released. To test whether the core disaccharide Galβ1-3GalNAc with sialic acid linked α2-3 to the Gal or linked α2-6 to the GalNAc was released, the enzyme was incubated with remodelled antifreeze glycoprotein containing (1) [3H]NeuAcα2-3Galβ1-3GalNAc and (2) Galβ1-3[[14C]NeuAcα2-6]GalNAc as substrates. No NeuAc-containing trisaccharide was released. These results serve to clarify the doubts of many researchers regarding the activity of this enzyme on some newly-described core types and on sialylated substrates. This revised version was published online in November 2006 with corrections to the Cover Date.     

Evidence of regional differences in the lectin histochemistry along the ductus epididymis of the lizard,Podarcis sicula Raf

The regional difference in the carbohydrate components of the ductus epididymis epithelium of a lizard was delineated by means of 13 lectins. Basal cells expressed only N-acetylglucosamine (GlcNAc). Throughout the ductus, the secretory cells showed oligosaccharides with terminal N-acetylneuraminic acid (Neu5Ac)(2,6)galactose (Gal)/N-acetylgalactosamine (GalNAc) and internal mannose (Man) and/or glucose (Glc) in the whole cytoplasm, oligosaccharides terminating in Neu5Ac(2,6)Gal(1,3)GalNAc, Neu5Ac(2,6)Gal (1,4)GlcNAc, GalNAc, GlcNAc, and fucose (Fuc) in the supra-nuclear zone, and also glycans terminating in Neu5Ac(2,3)Gal (1,4)GlcNAc, Neu5Ac(2,6)Gal(1,3)GalNAc, Gal (1,4)GlcNAc on the luminal surface. In the caput and corpus regions, the supra-nuclear cytoplasm was characterized by terminal Gal(1,4)GlcNAc and GalNAc, the luminal surface by GalNAc and Gal. The Golgi zone, showing oligosaccharides with terminal Neu5Ac(2,3)Gal (1,4)GlcNAc, Neu5Ac(2,6)Gal (1,3)GalNAc, Neu5Ac(2,6)Gal (1,4)GlcNAc, and internal GlcNAc, expressed terminal Gal (1,4)GlcNAc and GalNAc in the caput, and terminal GalNAc in the corpus. The granules showed all the investigated carbohydrates in their peripheral zone except terminal GalNAc and Fuc, whereas internal Man/Glc and terminal Gal were expressed in the central core, and Fuc throughout the ductus, terminal GlcNAc in the caput and corpus, and terminal GalNAc only in the corpus.     

The evolution of galactose α2,3-sialyltransferase: <Emphasis Type="Italic">Cionaintestinalis</Emphasis> ST3GAL I/II and <Emphasis Type="Italic">Takifugu rubripes</Emphasis> ST3GAL II sialylate Galβ1,3GalNAc structures on glycoproteins but not glycolipids

Sialyltransferases are a family of enzymes catalyzing the transfer of sialic acid residues to terminal non-reducing positions of oligosaccharide chains of glycoproteins and glycolipids. Although expression of sialic acid is well documented in animals of the deuterostomian lineage, sialyltransferases have been predominantly described for relatively recent vertebrate lineages such as birds and mammals. This study outlines the characterization of the only sialyltransferase gene found in the tunicate Ciona intestinalis, the first such report of a non-vertebrate deuterostomian sialyltransferase, which has been discussed as a possible orthologue of the common ancestor of galactose α2,3-sialyltransferases. We also report for the first time the characterization of a ST3Gal II gene from the bony fish Takifugu rubripes. We demonstrate that both genes encode functional α2,3-sialyltransferases that are structurally and functionally related to the ST3Gal family of mammalian sialyltransferases. However, characterization of the recombinant, purified forms of both enzymes reveal novel acceptor substrate specificities, with sialylation of the disaccharide Galβ1-3GalNAc and asialofetuin, but not GM1 or GD1b observed. This is in contrast to the mammalian ST3Gal II that predominantly sialylates gangliosides. Taken together the ceramide binding/recognition site previously proposed for the mouse ST3Gal II might represent a unique feature of mammalian ST3Gal II that is missing in the evolutionary more distant fish and tunicate species reported here. This suggests that during the evolution of the ST3Gal II, probably following the separation of the teleosts, a significant shift in substrate specificity enabling the sialylation of gangliosides took place.     

Unusual glycoconjugates in the oesophagus of a tilapine polyhybrid

The aim of this work is to elucidate the glycoconjugate composition of the secretory products of the oesophageal mucous cells in a tilapine polyhybrid. Lectin histochemistry gave evidence of the presence of β-galactose, α-N-acetylgalactosamine and sialic acid residues in the terminal position. The majority of sialic acid belongs to short side chains; a few sialic acid residues are acetylated at the C₇ and/or C₈ and/or C₉ level. The heterogeneity of the carbohydrate chains may mask potential receptor sites for micro-organisms and hamper the formation of multiple bonds.     

The Structural Basis for the Susceptibility of Gangliosides to Enzymatic Degradation

The conformational properties of GM2, GalNac-4(Neu5Ac-3) Gal-4Glc-1Cer have been compared to those of 6-GM2, in which the linkage between the GalNAc and Gal was altered from GalNac-4Gal- to GalNac-6Gal-, and to those of GD1a, Neu5Ac-3Gal-3GalNAc-4(Neu5Ac-3)Gal-4Glc-1Cer, and GalNAc-GD1a.Our results revealed that unlike the compact and rigid oligosaccharide head group found in GM2, where the Neu5Ac and the GalNAc residues interact, the sugar chain of 6-GM2 is in an open spatial arrangement, with the Neu5Ac no longer interacting with GalNAc, freely accessible to external interactions.The structure of GD1a can be regarded as that of GM2 with an extension of the terminal Neu5Ac-3Gal-disaccharide. The inner portion of GD1a is that of GM2 comprising the very rigid GalNAc-[Neu5Ac-]Gal trisaccharide. The terminal Neu5Ac-Gal linkage is flexible and fluctuates between two limiting conformations. In GalNAc-GD1a the outer sialic acid gains conformational rigidity due to the presence of the outer GalNAc in position 4 of galactose. This ganglioside has two core GalNAc-[Neu5Ac-]Gal trisaccharide linked in tandem.     

Scanning mutagenesis of regions in the Gα protein Gpa1 that are predicted to interact with yeast mating pheromone receptors

The mechanism by which receptors activate heterotrimeric G proteins was examined by scanning mutagenesis of the Saccharomyces cerevisiae pheromone-responsive Gα protein (Gpa1). The juxtaposition of high-resolution structures for rhodopsin and its cognate G protein transducin predicted that at least six regions of Gα are in close proximity to the receptor. Mutagenesis was targeted to residues in these domains in Gpa1, which included four loop regions (β2–β3, α2–β4, α3–β5, and α4–β6) as well as the N and C termini. The mutants displayed a range of phenotypes from nonsignaling to constitutive activation of the pheromone pathway. The constitutive activity of some mutants could be explained by decreased production of Gpa1, which permits unregulated signaling by Gβγ. However, the constitutive activity caused by the F344C and E335C mutations in the α2–β4 loop and F378C in the α3–β5 loop was not due to decreased protein levels, and was apparently due to defects in sequestering Gβγ. The strongest loss of the function mutant, which was not detectably induced by a pheromone, was caused by a K314C substitution in the β2–β3 loop. Several other mutations caused weak signaling phenotypes. Altogether, these results suggest that residues in different interface regions of Gα contribute to activation of signaling.