Evidence that small molecule enhancement of ß-hexosaminidase activity corrects the behavioral phenotype in Dutch APP(E693Q) mice through reduction of ganglioside-bound Aß.

Certain mutant Alzheimer's amyloid-ß (Aß) peptides (that is, Dutch mutant APP(E693Q)) form complexes with gangliosides (GAß). These mutant Aß peptides may also undergo accelerated aggregation and accumulation upon exposure to GM2 and GM3. We hypothesized that increasing ß-hexosaminidase (ß-hex) activity would lead to a reduction in GM2 levels, which in turn, would cause a reduction in Aß aggregation and accumulation. The small molecule OT1001 is a ß-hex-targeted pharmacological chaperone with good bioavailability, blood-brain barrier penetration, high selectivity for ß-hex and low cytotoxicity. Dutch APP(E693Q) transgenic mice accumulate oligomeric Aß as they age, as well as Aß oligomer-dose-dependent anxiety and impaired novel object recognition (NOR). Treatment of Dutch APP(E693Q) mice with OT1001 caused a dose-dependent increase in brain ß-hex levels up to threefold over those observed at baseline. OT1001 treatment was associated with reduced anxiety, improved learning behavior in the NOR task and dramatically reduced GAß accumulation in the subiculum and perirhinal cortex, both of which are brain regions required for normal NOR. Pharmacological chaperones that increase ß-hex activity may be useful in reducing accumulation of certain mutant species of Aß and in preventing the associated behavioral pathology.

Loss of N-glycolylneuraminic acid in human evolution. Implications for sialic acid recognition by siglecs.

The common sialic acids of mammalian cells are N-acetylneuraminic acid (Neu5Ac) and N-glycolylneuraminic acid (Neu5Gc). Humans are an exception, because of a mutation in CMP-sialic acid hydroxylase, which occurred after our common ancestor with great apes. We asked if the resulting loss of Neu5Gc and increase in Neu5Ac in humans alters the biology of the siglecs, which are Ig superfamily members that recognize sialic acids. Human siglec-1 (sialoadhesin) strongly prefers Neu5Ac over Neu5Gc. Thus, humans have a higher density of siglec-1 ligands than great apes. Siglec-1-positive macrophages in humans are found primarily in the perifollicular zone, whereas in chimpanzees they also occur in the marginal zone and surrounding the periarteriolar lymphocyte sheaths. Although only a subset of chimpanzee macrophages express siglec-1, most human macrophages are positive. A known evolutionary difference is the strong preference of mouse siglec-2 (CD22) for Neu5Gc, contrasting with human siglec-2, which binds Neu5Ac equally well. To ask when the preference for Neu5Gc was adjusted in the human lineage, we cloned the first three extracellular domains of siglec-2 from all of the great apes and examined their preference. In fact, siglec-2 had evolved a higher degree of recognition flexibility before Neu5Gc was lost in humans. Human siglec-3 (CD33) and siglec-6 (obesity-binding protein 1) also recognize both Neu5Ac and Neu5Gc, and siglec-5 may have some preference for Neu5Gc. Others showed that siglec-4a (myelin-associated glycoprotein) prefers Neu5Ac over Neu5Gc. Thus, the human loss of Neu5Gc may alter biological processes involving siglec-1, and possibly, siglec-4a or -5.

Molecular cloning of a developmentally regulated N-acetylgalactosamine alpha2,6-sialyltransferase specific for sialylated glycoconjugates.

A cDNA encoding a novel sialyltransferase has been isolated employing the polymerase chain reaction using degenerate primers to conserved regions of the sialylmotif that is present in all eukaryotic members of the sialyltransferase gene family examined to date. The cDNA sequence revealed an open reading frame coding for 305 amino acids, making it the shortest sialyltransferase cloned to date. This open reading frame predicts all the characteristic structural features of other sialyltransferases including a type II membrane protein topology and both sialylmotifs, one centrally located and the second in the carboxyl-terminal portion of the cDNA. When compared with all other sialyltransferase cDNAs, the predicted amino acid sequence displays the lowest homology in the sialyltransferase gene family. Northern analysis shows this sialyltransferase to be developmentally regulated in brain with expression persisting through adulthood in spleen, kidney, and lung. Stable transfection of the full-length cDNA in the human kidney carcinoma cell line 293 produced an active sialyltransferase with marked specificity for the sialoside, Neu5Ac-alpha2,3Gal-beta1,3GalNAc and glycoconjugates carrying the same sequence such as G(M1b) and fetuin. The disialylated tetrasaccharide formed by reacting the sialyltransferase with the aforementioned sialoside was analyzed by one- and two-dimensional 1H and 13C NMR spectroscopy and was shown to be the Neu5Ac-alpha2,3Gal-beta1,3(Neu5Ac-alpha2,6)GalNAc sialoside. This indicates that the enzyme is a GalNAc alpha-2,6-sialyltransferase. Since two other ST6GalNAc sialyltransferase cDNAs have been isolated, this sialyltransferase has been designated ST6GalNAc III. Of these three, ST6GalNAc III displays the most restricted acceptor specificity and is the only sialyltransferase cloned to date capable of forming the developmentally regulated ganglioside G(D1alpha) from G(M1b).

Expression of de-N-acetyl-gangliosides in human melanoma cells is induced by genistein or nocodazole.

Neuraminic acid is the core structure of most known sialic acids. In natural systems, the amino group at the 5 position of neuraminic acid residues is usually assumed to be acylated. Previously, synthetic de-N-acetyl-gangliosides (with free amino groups at the 5 position of neuraminic acids) have been shown to modulate cellular proliferation and tyrosine phosphokinase reactions. While indirect evidence has suggested that traces of these molecules exist naturally in certain tumor cells, further exploration has been hampered by the lack of a system showing consistent expression at an easily detectable level. Using synthetic compounds as antigens, we have developed highly specific monoclonal antibodies against de-N-acetyl-GM3 and de-N-acetyl-GD3 that require both the free amino group and the exocyclic side chain of sialic acids for recognition. Cultured human melanoma cells showed low but variably detectable levels of reactivity with these antibodies. The ability of various biologically active molecules to stimulate this reactivity was explored. Of many compounds tested, only the tyrosine kinase inhibitor genistein induced reactivity in a dose-dependent manner. Antibody reactivity with ganglioside extracts from genistein-treated cells was abolished by chemical re-N-acetylation and/or truncation of sialic acid side chains by mild periodate oxidation. High performance thin layer chromatography immuno-overlay analysis confirmed the presence of the novel compound de-N-acetyl-GD3 in these extracts. Several other tyrosine kinase inhibitors tested did not give the same increase in de-N-acetyl-ganglioside expression. However, the microtubule inhibitor nocodazole caused a similar accumulation of these molecules, particularly in non-adherent cells expected to be arrested at metaphase. Thus, genistein may induce de-N-acetyl-ganglioside expression by virtue of its known ability to arrest cells in the G2M phase, rather than as a general consequence of tyrosine kinase inhibition. These studies also provide a system in which to analyze the enzymatic basis of de-N-acetyl-ganglioside expression and their potential roles as growth regulating molecules.

Natural ligands of the B cell adhesion molecule CD22 beta can be masked by 9-O-acetylation of sialic acids.

CD22 beta is a B cell-restricted phosphoprotein expressed on the surface of mature resting B cells. It mediates interactions with other cells partly or exclusively via recognition of alpha 2-6-linked sialic acids on glycoconjugates. The sialylated N-linked oligosaccharides recognized best by CD22 beta are common to many glycoproteins, suggesting that additional regulatory mechanisms may exist. Since the exocyclic side chain of sialic acid is required for recognition, we explored the effects of a naturally occurring modification of the side chain, 9-O-acetylation. Semisynthetic N-linked oligosaccharides terminating with 9-O-acetylated, alpha 2-6-linked sialic acids showed markedly reduced binding to CD22 beta relative to their non-O-acetylated counterparts. Murine lymphoid cells were probed for natural CD22 beta ligands that might be O-acetylated using recombinant soluble forms of CD22 beta (CD22 beta Rg) and influenza C esterase (CHE-Fc, which specifically removes 9-O-acetyl esters from sialic acids). By flow cytometry analysis, CD22 beta Rg binding to splenic B cells and a subset of T cells was increased by pretreatment with CHE-Fc, indicating that some potential CD22 beta ligands are naturally "masked" by 9-O-acetylation. Unmasking of these CD22 beta ligands by removal of 9-O-acetyl esters from intact splenocytes substantially increases their CD22 beta-dependent adhesion in an in vitro adhesion assay. Probing of murine lymphoid tissue sections by CD22 beta Rg and CHE-Fc treatment demonstrates regionally restricted and differentially expressed patterns of distribution between masked and unmasked ligands. For example, lymph node-associated follicular B cells express high levels of CD22 beta ligands, none of which are masked by 9-O-acetylation. In contrast, the ligands on lymph node-associated dendritic cells are almost completely masked by 9-O-acetylation, suggesting that masking may regulate interactions between CD22 beta-positive B cells and dendritic cells. In the thymus, only medullary cells express CD22 beta ligands, and a significant portion of these are masked by 9-O-acetylation, particularly at the cortical-medullary junction. Thus, 9-O-acetylation of sialic acids on immune cells is in a position to negatively regulate CD22 beta adhesion events in a manner depending on both cell type and tissue localization.

Kinetic and spatial interrelationships between ganglioside glycosyltransferases and O-acetyltransferase(s) in human melanoma cells.

The melanoma-associated disialogangliosides 9(7)-O-acetyl-GD3 and 9(7)-O-acetyl-GD2 have been structurally well characterized. However, the compartmentalization and sequence of action of the biosynthetic activities responsible for synthesizing these molecules remain obscure. Here, we have studied the spatial and temporal interrelationships among the activities responsible for the later stages of ganglioside biosynthesis and those for O-acetylation in cultured human melanoma cells. First, brefeldin A treatment was used to separate biosynthetic steps into compartments distal or proximal to the transport block imposed by the drug. In keeping with prior reports, GM2/GD2 synthase was consistently rendered inaccessible to its acceptors GM3 and GD3. In contrast, the effect on GD3 biosynthesis was cell line-specific. Synthesis of GD3 was nearly abrogated in two lines, while it accumulated in a third line. This indicates that the spatial organization of ganglioside processing activities can vary even between similar cell lines. However, in all cell lines studied, the ratio of 9(7)-O-acetyl-GD3 to GD3 was not changed by brefeldin A, indicating that the majority of ganglioside O-acetyltransferase activity is co-localized with GD3 biosynthetic activity in the same Golgi subcompartment(s). As an alternative approach, Golgi-enriched fractions from melanoma cells were incubated with radiolabeled and nonlabeled nucleotide sugars or acetyl-CoA. In these preparations, biosynthesis is dependent upon the co-localization of appropriate sugar nucleotide transporters, glycosyltransferases, and acceptors that are endogenously present within intact topologically correct compartments. Incubations with CMP-Neu5Ac and acetyl-CoA corroborated the results with brefeldin A, co-localizing ganglioside O-acetyltransferase activity in compartments where GD3 biosynthesis takes place. Analyses with CMP-Neu5Ac and UDP-GalNAc showed that GD2 and GD3 synthesis occur in partially overlapping compartments. Labeling with acetyl-CoA and UDP-GalNAc indicated that although labeled acetate can be transferred from acetyl-CoA directly to GD2, ganglioside O-acetyltransferase activity does not substantially overlap with the biosynthetic compartment(s) for GD2. Instead, O-acetyl-GD3 appears to be co-localized with the compartment of GD2 biosynthesis and serves as an acceptor for GD2 synthase. Thus, both 9-O-acetyl-GD3 and GD2 can be precursors of 9-O-acetyl-GD2, but apparently in distinct compartments.

Natural ligands of the B cell adhesion molecule CD22 beta carry N-linked oligosaccharides with alpha-2,6-linked sialic acids that are required for recognition.

CD22 beta is a glycoprotein found on the surface of B cells during restricted stages of development. It is believed to play a role in cell-cell interactions and B cell activation. The accompanying paper (Sgroi, D., Varki, A., Braesch-Andersen, S., and Stamenkovic, I. (1993) J. Biol. Chem. 268, 7011-7018) shows that CD22 beta recognizes multiple glycoproteins on the surfaces of T and B cells and that sialylation of these ligands is essential for binding. To identify the structure(s) of the sialylated oligosaccharide(s) recognized by CD22 beta, [3H]glucosamine-labeled glycoproteins were purified from Daudi cells by adsorption onto a CD22 beta recombinant immunoglobulin (CD22 beta Rg) chimera attached to protein A-Sepharose (PAS), and the N-linked oligosaccharides were released by peptide N-glycosidase F. These released oligosaccharides failed to bind to CD22 beta Rg-PAS under the conditions used initially to adsorb the glycoproteins, but their elution from a column of CD22 beta Rg-PAS was significantly retarded. Populations of oligosaccharides with different affinities could be identified by their order of elution. Specific sialidases were used to determine the content of alpha-2,3- and alpha-2,6-linked sialic acid in these different populations and their contribution to binding. Multiantennary oligosaccharides with one alpha-2,6-linked residue bound marginally, and those with two or more bound more tightly. alpha-2,3-Linked sialic acid residues were without effect. Binding did not require divalent cations and was abrogated by mild periodate oxidation of the outer side chain of sialic acid. No marked differences in size or fucose content were found between the populations of high and low affinity oligosaccharides. However, the low affinity population could be partially converted into higher affinity by treatment with beta-galactoside alpha-2,6 sialyltransferase and CMP-sialic acid. Thus, CD22 beta is a mammalian lectin that can recognize specific N-linked oligosaccharide structures containing alpha-2,6-linked sialic acids.

Structural and immunological characterization of O-acetylated GD2. Evidence that GD2 is an acceptor for ganglioside O-acetyltransferase in human melanoma cells.

We have shown previously that Golgi-enriched vesicles from the human melanoma cell line Melur can transfer [3H]acetate from [acetyl-3H]acetyl-CoA to endogenous GD3 to form [acetyl-3H]O-acetyl-GD3 (Manzi, A. E., Sjoberg, E. R., Diaz, S., and Varki, A. (1990) J. Biol. Chem. 265, 13091-13103). Applying the same approach in the human melanoma cell line M21, label was found in [acetyl-3H]O-acetyl-GD3 and also in a species co-migrating with unsubstituted GD3 on TLC. Both were sialidase-sensitive and alkali-labile, indicating incorporation as [3H]O-acetyl esters on sialic acids. Immunological reactivity, sialidase sensitivity, chromatographic behavior, and the known ganglioside pattern of M21 cells suggested that the slower migrating species might be [acetyl-3H]O-acetyl-GD2. Sialic acids released from this labeled molecule by sialidase showed esterification with [3H]acetate at both C7 and C9 hydroxyls. Lipid extracts from cells metabolically labeled with [3H]galactose showed a corresponding ganglioside, which upon alkali treatment yielded a species migrating with GD2. Analysis of purified ganglioside by high performance thin layer chromatography immuno-overlays, fast atom bombardment-mass spectrometry in positive and negative ion modes, periodate oxidation resistance, linkage analysis by permethylation and gas chromatography-mass spectrometry, and 500 MHz 1H NMR was consistent with the following structure: 9-O Ac-Neu5Ac alpha 2-8Neu5Ac alpha 2-3(GalNAc beta 1-4) Gal beta 1-4Gluc beta 1-1' ceramide Total gangliosides from M21 were analyzed by high performance thin layer chromatography immuno-overlay with monoclonal antibodies D1.1, JONES, 27A, and 8A2, all known to, or suspected of reacting with 9-O-acetylated gangliosides. The first three bound well to 9-O-acetyl-GD3 and a slower migrating 9-O-acetylated ganglioside, which was distinct from 9-O-acetyl-GD2. Antibody 8A2 reacted weakly with purified 9-O-acetyl-GD2 and strongly with two other 9-O-acetylated gangliosides migrating slower than 9-O-acetyl-GD2. Thus, the family of O-acetylated gangliosides in melanoma cells is much more complex than previously appreciated.

Biosynthesis and turnover of O-acetyl and N-acetyl groups in the gangliosides of human melanoma cells.

We and others previously described the melanoma-associated oncofetal glycosphingolipid antigen 9-O-acetyl-GD3, a disialoganglioside O-acetylated at the 9-position of the outer sialic acid residue. We have now developed methods to examine the biosynthesis and turnover of disialogangliosides in cultured melanoma cells and in Golgi-enriched vesicles from these cells. O-Acetylation was selectively expressed on di- and trisialogangliosides, but not on monosialogangliosides, nor on glycoprotein-bound sialic acids. Double-labeling of cells with [3H]acetate and [14C]glucosamine introduced easily detectable labels into each of the components of the ganglioside molecules. Pulse-chase studies of such doubly labeled molecules indicated that the O-acetyl groups turn over faster than the parent molecule. When Golgi-enriched vesicles from these cells were incubated with [acetyl-3H]acetyl-coenzyme A, the major labeled products were disialogangliosides. [Acetyl-3H]O-acetyl groups were found at both the 7- and the 9-positions, indicating that both 7-O-acetyl GD3 and 9-O-acetyl GD3 were synthesized by the action of O-acetyltransferase(s) on endogenous GD3. Analysis of the metabolically labeled molecules confirmed the existence of both 7- and 9-O-acetylated GD3 in the intact cells. Surprisingly, the major 3H-labeled product of the in vitro labeling reaction was not O-acetyl-GD3, but GD3, with the label exclusively in the sialic acid residues. Fragmentation of the labeled sialic acids by enzymatic and chemical methods showed that the 3H-label was exclusively in [3H]N-acetyl groups. Analyses of the double-labeled sialic acids from intact cells also showed that the 3H-label from [3H]acetate was exclusively in the form of [3H]N-acetyl groups, whereas the 14C-label was at the 4-position. Pulse-chase analysis of the 3H/14C ratio showed that the N-acetyl groups of both GD3 and of the monosialoganglioside GM3 were turning over faster than the parent molecules. Selective periodate oxidation showed that both the inner and outer sialic acid residues of GD3 incorporated 3H-label in the in vitro reaction, and showed similar turnover of N-acetylation in the pulse-chase study. Taken together, these results indicate that both the O- and N-acetyl groups of the sialic acid residues of gangliosides turn over faster than the parent molecules. They also demonstrate a novel re-N-acetylation reaction that predicts the existence of de-N-acetyl gangliosides in melanoma cells.

Purification and characterization of a second form of acid lipase in human liver.

We describe here the purification and characterization of a form of acid lipase from human liver (designated ALII), which differed from the more abundant Mr-29000 form (ALI). ALII was solubilized from frozen human liver with Triton X-100 and purified 8500-fold by chromatography over concanavalin A-sepharose, CM-cellulose and finally h.p.l.c. over a Mono S column. ALII migrated as a single band on polyacrylamide-gel electrophoresis in both the presence and the absence of SDS. The Mr of ALII was estimated to be 58,500 by SDS/polyacrylamide-gel electrophoresis. Gel filtration on Sephacryl S-200 gave an apparent Mr of 69,000. 4-Methylumbelliferyl (4MU) palmitate, cholesterol oleate and triolein were substrates for ALII, with apparent Vmax values of 5000, 1100 and 2500 nmol/min per mg respectively and Km values of 1.0, 1.5 and 1.8 mM respectively. Cholesterol oleate and triolein were hydrolysed optimally by ALII at pH 4.5, whereas 4MU palmitate was hydrolysed optimally at pH 5.3. Antisera were raised against ALI and ALII and, on immunoblot analysis, no antigenic similarity was observed between ALI and ALII. Cellulose acetate electrophoresis followed by reaction with 4MU palmitate revealed two forms of lipase, corresponding to ALI and ALII. The two enzymes were also separated by hydrophobic chromatography. The activity of ALII was stimulated by several proteins and was partially inhibited by millimolar concentrations of NaCl, CaCl2 and MgSO4.

Characterization and analysis of branched-chain N-acetylglucosaminyl oligosaccharides accumulating in Sandhoff disease tissue. Evidence that biantennary bisected oligosaccharide side chains of glycoproteins are abundant substrates for lysosomes.

Branched chain N-acetylglucosaminyl oligosaccharides accumulating in visceral and neural tissues of two patients with Sandhoff disease were isolated and quantified using high performance liquid chromatography. Detailed structural analysis of the three most abundant fractions, oligosaccharides 4, 5, and 6, was carried out using 360 MHz proton magnetic resonance spectroscopy. The biantennary bisected heptasaccharide, oligosaccharide 6, was ubiquitously distributed and a major component of the stored oligosaccharides in all tissues analyzed including, liver, spleen, kidney, lung, pancreas, and brain. This analysis indicates that glycoproteins containing biantennary bisected oligosaccharide side chains are abundant substrates for lysosomes in human tissues. Moreover, oligosaccharide 6 was the predominant storage product in brain comprising 70% of the total accumulating water-soluble glycoconjugates. Oligosaccharide 5, a triantennary heptasaccharide, had a similar distribution in visceral tissues and it was the major storage product in pancreas but was at very low levels in brain. These results suggest that the biosynthetic enzymes, GlcNAc transferase III (Narasimham, S. (1982) J. Biol. Chem. 257, 10235-10242) and IV (Gleeson, P.A., and Schachter, H. (1983) J. Biol. Chem. 258, 6162-6173), which are responsible for synthesis of these structures, have a generalized distribution with varying levels of expression in human viscera, moreover, transferase IV may have limited expression in neural tissue. The proposed structures for the branched-chain compounds are as follows. (formula; see text)