Sonja K. Gross

Quantitation of the rabbit intestinal glycolipid receptor for Shiga toxin

Shiga toxin, produced by Shigella dysenteriae 1, causes enterotoxic, cytotoxic, and neurotoxic effects, which may be mediated by a glycolipid receptor, globotriaosylceramide, Gb3. To study the relationship of this receptor and toxin effects, globotriaosylceramide was quantitated and further characterized in rabbit small intestinal microvillus membranes at various ages. Glycolipids were extracted from rabbit microvillus membranes, purified on Unisil columns, and quantitated by high-performance liquid chromatography. The major glycolipid peaks were hydroxylated fatty acid-containing glucosylceramide, lactosylceramide, and globotriaosylceramide. There was a marked increase of globotriaosylceramide levels with age, ranging from 0.02 to 16.2 pmol/micrograms microvillus membrane protein in neonates and adults, respectively. The globotriaosylceramide peak was susceptible to alpha-galactosidase treatment, which produced an elevation in the lactosylceramide peak, but markedly reduced globotriaosylceramide content in 34-day-old rabbits. Binding of iodinated Shiga toxin to globotriaosylceramide was documented on high-performance thin-layer chromatography plates by autoradiography. The glycolipid receptor for Shiga toxin in rabbit microvillus membranes is thus a hydroxylated fatty acid-containing globotriaosylceramide. This moiety is virtually absent in neonates and gradually increases with age. Quantitative differences in globotriaosylceramide may be the underlying basis for the age-specific differences in functional responsiveness of rabbit intestinal tissue to Shiga toxin.

The accumulation and metabolism of glycosphingolipids in primary kidney cell cultures from beige mice

In the normal C57BL/6J male mouse a specific subset of the kidney glycosphingolipids which is associated with multilamellar bodies of lysosomal origin and represents about 10% of the total kidney glycolipids, is excreted into the urine each day. This excretion is blocked and glycosphingolipids accumulate in the kidney of bgJ/bgJ mutants of this strain. To examine this process in vitro, glycosphingolipid metabolism and excretion were studied in beige mouse kidney cell cultures. Primary kidney cell cultures from male C57BL/6J control and bgJ/bgJ beige mutants were grown in D-valine medium and glycosphingolipids labeled with [3H]palmitate. As we have shown previously, the giant lysosomes of altered morphology were maintained in cultures of the beige kidney cells. Beige-J and control cells synthesized the same types of glycosphingolipids, but the mutant cells had quantitatively higher levels of these compounds than control cells, as determined by high performance liquid chromatography. Beige-J cells incorporated more [3H]palmitate into glycospingholipids than control cells on a cpm/mg protein basis and the specific activity (cpm/pmole glycosphingolipid) was lower in beige cells. Medium from beige-J cells accumulated more glycosphingolipids than that from control cells in a 24 h period. The glycosphingolipids released into the medium as determined by HPLC were primarily non-lysosomal types and both control and mutant cells retained the glycosphingolipids associated with lysosomal multilamellar bodies excreted in vivo. The elevated levels of lysosomal glycosphingolipids and the dysmorphic lysosomes in primary cultures of beige cells, then, are not caused by a mutant block in secretion of lysosomes. (Mol Cell Biochem 118: 61–66, 1992)

EXPRESSION OF GLYCOSPHINGOLIPIDS IN SERUM-FREE PRIMARY CULTURES OF MOUSE KIDNEY CELLS : MALE-FEMALE DIFFERENCES AND ANDROGEN SENSITIVITY

The expression of neutral glycosphingolipids was examined in primary kidney cell cultures derived from adult male and female beige mutant mice (C57BL/6J;bgj/bgj) with enrichment for proximal tubule cells during preparation of explants and using defined serum-free medium for the culture conditions. Cell proliferated for 7 daysin vitro to provide confluent or nearly confluent monolayers of epithelial-type growth indicative of proximal tubule cells. The malevs female differences in neutral glycosphingolipids seen in the kidneyin vivo were retained in these 7 day cultures. Cultures derived from males contained galacto- and digalactosylceramides whereas those from females did not express these types of glycolipids. Also, male cells had higher ratios of sphingosine: phytosphingosine containing species in Nfa (non-hydroxy fatty acid) globotriaosylceramide and in glucosylceramide than females. The shift in sphingosine: phytosphingosine to male ratios in Nfa globotriaosylceramide and in glucosylceramide could be stimulated in female kidney cells by treatment with 10−5 M testosterone or 5α-dihydrotestosterone. The male-specific expression of neutral glycosphingolipids, then, appears to be stable character of male-type differentiation in mouse kidney that is passed on during proliferation in culture. Female kidney cells retain an ability to respond to androgens with specific changes in neutral glycosphingolipid expression during 7 days of growthin vitro in serum-free conditions, but do not respond with the induction of the male-specific glycolipids galacto-and digalactosylceramides as seenin vivo.

Biochemical and morphological characterization of primary kidney cell cultures from beige mutant mice.

SummaryPrimary kidney cultures from adult beige-J (bgJ/ bgJ) mice were selected for epithelial cell growth using D-valine medium. After 2 weeks of attachment and proliferation in vitro, the cells form a confluent or nearly confluent monolayer that retains several phenotypic characteristics of the beige-J mutant. These include large, multilamellar inclusion bodies that are apparently dysmorphic lysosomes, and higher concentrations of neutral glycosphingolipids and dolichols than control cells. β-Glucuronidase activity, used as a lysosomal enzyme marker, is not elevated in beige-J-cultured kidney cells compared with controls, as it is in the intact kidney. The high levels of β-glucuronidase activity in both control and mutant cells may mask expression of this difference in vitro. The action of the beige-J mutation in kidney cells is thought to be due to a block in exocytosis that results in the accumulation of abnormal lysosomes and their components. The maintenance of the beige phenotype in vitro indicates that the mutation is not suppressed in primary kidney cell cultures. The expression of the beige phenotype in vitro should be useful for studies concerning the primary lesion of this mutation.