Keiko Tadano-Aritomi

Cerebroside sulfotransferase deficiency ameliorates L-selectin-dependent monocyte infiltration in the kidney after ureteral obstruction.

Mononuclear cells infiltrating the interstitium are involved in renal tubulointerstitial injury. The unilateral ureteral obstruction (UUO) is an established experimental model of renal interstitial inflammation. In our previous study, we postulated that L-selectin on monocytes is involved in their infiltration into the interstitium by UUO and that a sulfated glycolipid, sulfatide, is the physiological L-selectin ligand in the kidney. Here we tested the above hypothesis using sulfatide- and L-selectin-deficient mice. Sulfatide-deficient mice were generated by gene targeting of the cerebroside sulfotransferase (Cst) gene. Although the L-selectin-IgG chimera protein specifically bound to sulfatide fraction in acidic lipids from wild-type kidney, it did not show such binding in fractions of Cst-/- mice kidney, indicating that sulfatide is the major L-selectin-binding glycolipid in the kidney. The distribution of L-selectin ligand in wild-type mice changed after UUO; sulfatide was relocated from the distal tubules to the peritubular capillaries where monocytes infiltrate, suggesting that sulfatide relocated to the endothelium after UUO interacted with L-selectin on monocytes. In contrast, L-selectin ligand was not detected in Cst-/- mice irrespective of UUO treatment. Compared with wild-type mice, Cst-/- mice showed a considerable reduction in the number of monocytes/macrophages that infiltrated the interstitium after UUO. The number of monocytes/macrophages was also reduced to a similar extent in L-selectin-/- mice. Our results suggest that sulfatide is a major L-selectin-binding molecule in the kidney and that the interaction between L-selectin and sulfatide plays a critical role in monocyte infiltration into the kidney interstitium.

Structural analysis of mono- and bis-sulfated glycosphingolipids by negative liquid secondary ion mass spectrometry with high- and low-energy collision-induced dissociation

Several underivatized mono- and bis-sulfated glycosphingolipids having gangliotriaose or gangliotetraose core structure were analyzed by negative liquid secondary ion mass spectrometry (LSIMS) with high- and low-energy collision-induced dissociation (CID). In the normal negative LSIMS spectra, each mono-sulfated glycolipid gave abundant [M - H]- ions and each bis-sulfated glycolipid gave abundant [M + Na - 2H]- ions as well as the hydrogen sulfate anion [OSO3H]-. In high-energy CID spectra of the deprotonated molecule, only ions containing a sulfate ester were clearly observed. When a sulfate was present on the non-reducing terminal saccharide residue, a series of ions corresponding to sulfated mono- to tetra-saccharides, resulting from sequential cleavage of glycosidic bonds, were observed. If the sulfate was attached to an internal hexose of the sugar chain, the product ions corresponding to the non-sulfated, non-reducing terminal residue were absent. In contrast, the low-energy CID resulted in extremely simple spectra that contained only one or two major product ions characteristic of each sulfated glycolipid. These results provided clear information on the overall sugar and ceramide compositions, and allowed saccharide structures differing in location and number of sulfate esters to be distinguished.

Cationic Glycosphingolipids in Neuronal Tissues and Their Possible Biological Significance

During the course of studies on natural occurrence of sphingosine base in brain, cationic glycosphingolipids bound to carboxymethyl-Sephadex and eluted with triethylamine in organic solvents were isolated and characterized. Four classes of compounds were identified: (i) plasmalopsychosine-A and -B; (ii) glyceroplasmalopsychosine; (iii) glycosphingolipids having de-N-acetyl-hexosamine, e.g., de-N-acetyl-Lc3Cer; (iv) glycosylsphingosine, i.e., lysoglycosphingolipid. Only two kinds, galactosylsphingosine (psychosine) and lactosylsphingosine, were found to occur naturally in brain. All these compounds were isolated from extract of brain white matter. Their occurrence, quantity, and distribution pattern differ from one species to another. Their quantity is much lower than that of regular acidic and neutral glycosphingolipids. They may interact with regular glycosphingolipids in glycosphingolipid-enriched microdomains to elicit signal transduction, to modify cellular phenotype, although studies along this line are highly limited at this time.

A novel mono-sulfated pentaglycosylceramide with the isoglobo-series core structure in rat kidney

A five-sugar sulfated glycosphingolipid containing an isoglobo-series carbohydrate core was isolated from rat kidney and its structure characterized by compositional analysis, FTIR spectroscopy, methylation analysis and 1H NMR spectroscopy of the intact glycolipid and its limited degradation products, and negative liquid secondary ion mass spectrometry (LSIMS). The two dimensional chemical shift correlated spectroscopy and NOE spectroscopy provided information on the sugar sequence and linkage as well as anomeric configurations, so as to establish the presence of a 3-O-sulfated galactose and a Gal alpha 1-3Gal structure within the molecule. Negative LSIMS with collision-induced dissociation defined the sugar sequence and ceramide composition, allowing to confirm the presence, and indicating the position, of the sulfate group. The glycosphingolipid was found to be a mono-sulfated derivative of the isoglobo-series core, with the following structure: HSO3(-)-3Gal beta 1-3GalNAc beta 1-3Gal alpha 1-3Gal beta 1-4Glc beta 1-1Cer (iGb5Cer V3-sulfate).

Chemical and Apoptotic Properties of Hydroxy-Ceramides Containing Long-Chain Bases with Unusual Alkyl Chain Lengths

We analysed four types of free ceramides (Cer 1, Cer 2, Cer 3 and Cer 4) from equine kidneys by electrospray ionization mass spectrometry. Cer 1 was composed of dihydroxy long-chain bases (dLCBs) of (4E)-sphingenine (d18:1), sphinganine and non-hydroxy fatty acids (NFAs); Cer 2 was composed of trihydroxy LCBs (tLCBs) of 4-hydroxysphinganine, t16:0, t18:0, t19:0 and t20:0, and NFAs; Cer 3 was composed of dLCBs, d16:1, d17:1, d18:1, d19:1 and d20:1, and hydroxy FAs (HFAs); and Cer 4 was composed of tLCBs, t16:0, t17:0, t18:0, t19:0 and t20:0, and HFAs. The results indicate all ceramide species containing LCBs with non-octadeca lengths (NOD-LCBs) can be classified into hydroxy-ceramides since these species always consist of tLCBs, and/or HFAs. Furthermore, such species tend to contain FAs with longer acyl chains but contain neither palmitate (C16:0) nor its hydroxylated form (C16:0h). The apoptosis-inducing activities of these hydroxyl-ceramides towards tumour cell lines were compared with that of non-hydroxy-ceramides, dLCB-NFA (Cer 1). Monohydroxy-ceramides, tLCB-NFA (Cer 2) and dLCB-HFA (Cer 3), exhibited stronger activities, whereas dihydroxy-ceramides, tLCB-HFA (Cer 4), exhibited similar or weaker activity than dLCB-NFA (Cer 1), depending on cell lines.

Higher expression of renal sulfoglycolipids in marine mammals

Patterns and contents of major acidic glycosphingolipids in the kidney of three marine mammalian species, the Steller sea lion (Pinnipedia), the rough-toothed dolphin and the broad-beaked dolphin (Odontoceti), were examined, and compared with those of terrestrial mesic mammals. The profile of major acidic glycosphingolipids was not significantly different between the terrestrial and marine mammals: predominant gangliosides were GM3 and GD3, and major sulfoglycolipids were SM4s and SM3. On the other hand, the total concentration (nmol/g wet tissue) of sulfoglycolipids was considerably higher in the marine mammals (2.3–3.0 times) than that in the terrestrial mesic mammals with comparable body weights. In contrast, there was no significant difference in the level of renal glycolipids-bound sialic acid between the marine and the terrestrial mammals. These results suggest that higher expression of renal sulfoglycolipids in marine mammals may contribute to the maintenance of osmotic balance of their body fluid against sea water.

STRUCTURAL CHARACTERIZATION OF A NOVEL MONO-SULFATED GANGLIOTRIAOSYLCERAMIDE CONTAINING A 3-O-SULFATED-N-ACETYLGALACTOSAMINE FROM RAT KIDNEY

A novel mono-sulfated glycosphingolipid based on the gangliotriaose core structure was isolated from rat kidney. The isolation procedure involved extraction of lipids with chloroform/methanol, mild alkaline methanolysis, column chromatographies with anion exchangers and silica beads. The structure was characterized by compositional analysis, FTIR spectroscopy, methylation analysis,1H-NMR spectroscopy and negative-ion liquid secondary ion mass spectrometry (LSIMS) using the intact glycolipid and its desulfation product. The two dimensional chemical shift correlated spectroscopy provided information on the sugar sequence as well as anomeric configurations, and indicated the presence of a 3-O-sulfatedN-acetylgalactosamine within the molecule. Negative-ion LSIMS with high- and low-energy collision-induced dissociation defined the sugar sequence and ceramide composition, confirming the presence of a sulfatedN-acetylgalactosamine at the non-reducing terminus. From these results, the complete structure was proposed to be HSO3-3GalNAcβ1-4Galβ1-4Glcβ1-1Cer (Gg3Cer III3-sulfate, SM2b).

Effect of nutritional substrate on sulfolipids metabolic turnover in isolated renal tubules from rat

Effects of a glycolytic (glucose) and a gluconeogenic renal nutritional substrate (glutamine) on metabolic turnover of sulfolipids, determined as [35S]sulfate incorporation, were compared in renal tubules prepared from well-fed rats. The results showed that the effects of glucose and glutamine, at nearly physiological serum concentration, are quite contrary to each other. Glucose increased the turnover rates of relatively long chain ganglio-series sulfoglycolipids (Gg3Cer II3-sulfate and Gg4Cer II3,IV3-bis-sulfate) (1.7 to 2.4-fold), but not of cholesterol 3-sulfate (0.9-fold). In contrast, glutamine accelerated the turnover rates of relatively short chain sulfoglycolipids (glucosyl sulfatide, galactosyl sulfatide and lactosyl sulfatide) (1.3 to 2.7-fold), as well as cholesterol 3-sulfate (2.4-fold). The possible mechanism which causes these marked differences is also discussed.