An established light ear mutant (C57BL/6J-Pdeb(rd1) le) mouse cell line exhibits a block to secretion of lysosomal enzymes.

The hypopigment mutant mice, light ear, pallid, and beige, possess defects in melanosomes, lysosomes, and platelet dense granules, suggesting that these organelles share a common biogenesis and processing. Light ear and pallid mutants are animal models for Hermansky Pudlak syndrome, whereas the beige mouse is an animal model for Chediak Higashi syndrome. An established skin cell line from the light ear mouse was tested along with pallid and beige cell lines for mutant effects on secretion of lysosomal hydrolase activities of six different lysosomal glycosidases and the trafficking of N-[5-(5,7-dimethyl BODIPY)-1-pentanoyl]-D-erythrosphingosine (C(5)-DMB-ceramide). There were no consistently significant differences between the pallid and the beige mutant cell lines or between these two mutant lines and the control cell line in the percentage secretion of lysosomal hydrolase activities. The light ear mutant cell line, however, displayed a significantly lower percentage secretion of lysosomal hydrolase activities than all other cell lines tested. The light ear mutant cells processed C(5)-DMB-ceramide completely, as seen in the control cell line, whereas pallid and beige cell lines retained fluorescent material and exhibited a block in the complete processing of C(5)-DMB-ceramide 20 h after labeling. The block to secretion of lyososomal hydrolase activities in the light ear mutant cell line will be useful for further studies on this mutant's lysosomal defect.

The effect of lysosomotropic amines on beige mouse cells.

The beige mutant in the mouse is characterized by enlarged lysosomes in many cell types due to increased fluidity of cellular membranes and organelle fusion. In this study, mutant fibroblasts derived from C57BL/ 6J;bgJ/bgJ animals were compared with control fibroblasts (C57BL/6J;+/+) for vacuolation when treated with lysosomotropic weak bases including ammonium chloride, trimethylamine, and methylamine. These amines produce vacuolation by their accumulation in cellular acidic compartments, which causes osmotic swelling and fusion of organelles due to the increase in pH. Beige cells exhibited greater vacuolation than control cells for all treatments, which was indicative of the mutant's effect on organelle fusion and membrane fluidity. Trimethylamine caused the most pronounced difference in vacuolation between mutant and control cells. This method allows for a simple morphological distinction between beige and control cells that also utilizes a physiological difference in the expression of the beige gene.

Correction of the galactocerebrosidase deficiency in globoid cell leukodystrophy-cultured cells by SL3-3 retroviral-mediated gene transfer.

Globoid cell leukodystrophy (GCL) or Krabbe disease is an autosomal recessive inherited disease caused by the deficiency of galactocerebrosidase, the lysosomal enzyme responsible for the degradation of galactocerebroside, a major component of myelin. An animal model homologue of GCL is the twitcher mouse. In the present work, using novel recombinant retroviruses harboring the SL3-3 LTR, we have been able to stably correct the galactocerebrosidase deficiency in twitcher mouse TM-2 cells and in primary human fibroblasts from a patient with globoid cell leukodystrophy. These results show the possibility of retroviral-mediated gene therapy for the treatment of GCL.

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. Cells proliferated for 7 days in vitro to provide confluent or nearly confluent monolayers of epithelial-type growth indicative of proximal tubule cells. The male vs female differences in neutral glycosphingolipids seen in the kidney in 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 5 alpha-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 growth in vitro in serum-free conditions, but do not respond with the induction of the male-specific glycolipids galacto- and digalactosylceramides as seen in vivo.

Cellular expression of the beige mouse mutation and its correction in hybrids with control human fibroblasts.

Fibroblasts from a beige mouse (C57BL/6J; bgJ bgJ) have been established and maintained in culture for more than 3 yr. At early passages, the mutant cells were distinguishable from C57BL/6J control mouse fibroblasts at the ultrastructural level by the presence of enlarged cytoplasmic granules. After continuous passaging, this distinguishing feature was lost from the mutant cells, correlated with their increased growth rate. Clustered, perinuclear distribution of lysosomes was retained, however, and was quantitatively different at any passage number of the beige cell line from the dispersed distribution of these organelles in control mouse fibroblasts, as analyzed by computer-aided, video-enhanced light microscopy. In somatic cell hybrids between the established beige cell line and a control human diploid fibroblast cell strain, seven uncorrected hybrid lines retained a lysosomal dispersion pattern statistically indistinguishable from that of the beige mouse cell lines. Three corrected hybrid lines had lysosomal dispersion patterns that were significantly different from the beige parent line and indistinguishable from that of the control mouse fibroblast line. Thus, lysosomal dispersion can be used objectively and quantitatively to distinguish mutant beige and control mouse fibroblasts and corrected vs. uncorrected cell hybrids made from the beige/control human somatic cell crosses.

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 glycosphingholipids 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.

Somatic cell genetic analysis of the galactocerebrosidase gene: lack of complementation in human Krabbe disease/twitcher mouse cell hybrids.

The inherited deficiency of galactosylceramide beta-galactosidase (E.C. 3.2.1.46: galactocerebrosidase) activity results in globoid cell leukodystrophy in humans (Krabbe disease) and in mice (twitcher mutant). To determine whether Krabbe patients' cells complement twitcher cells to produce, in hybrid combination, greater than deficient levels of galactocerebrosidase activity, five separate crosses were made between an established twitcher mouse cell line and five cell strains from unrelated Krabbe disease patients. A total of 57 twitcher mouse/Krabbe somatic cell hybrid lines developed from all of these crosses were deficient in galactocerebrosidase activity despite the presence of human chromosomes 14 or 17, which have been previously implicated as bearing the galactocerebrosidase gene. A control cross between twitcher mouse/positive control human fibroblasts resulted in 14 of 21 independent hybrid lines that expressed higher than deficient levels of galactocerebrosidase activity. The lack of complementation between Krabbe disease patient and twitcher mutant mouse cells provides further evidence that the twitcher mouse is an authentic murine model for Krabbe disease and supports the hypothesis that the mutations in both species are within the structural gene for the galactocerebrosidase enzyme.

Characterization of the yellow pigment in the axanthic mutant of the Mexican axolotl, Ambystoma mexicanum.

The yellow pigment observed in older axanthic (ax/ax) mutant Mexican axolotls (Ambystoma mexicanum) was analyzed by thin layer chromatography and by spectrofluorometry of its acetyl derivative. Ethanol extracts from the skin of axanthic animals were acetylated and the chloroform-soluble portion of the product mixture was compared with a chloroform solution of an authentic riboflavin tetraacetate standard prepared in the same manner. The pigment in these two solutions behaved identically on thin layer chromatograms and in fluorescent emission spectroscopy. This confirms that the yellow pigment seen in these genetically axanthic animals is riboflavin and, since it cannot be synthesized by the animal, must be derived from the diet.

Galactocerebrosidase activity in somatic cell hybrids derived from twitcher mouse/control human fibroblasts is associated with human chromosome 17.

Somatic cell hybrids derived from twitcher mouse cells and from control human fibroblasts were selected by two different methods. One method utilized 6-thioguanine-resistant twitcher cells as a parental line and the other used neomycin-resistant control human fibroblasts as a parental line so that hybrid lines could be selected in either HAT or in G-418 medium, respectively. The hybrid lines were analyzed for galactocerebrosidase activity. Since the twitcher cell lines are deficient in galactocerebrosidase activity, the presence of this activity in these hybrid lines depends upon the presence of human chromosome contents. Both galactocerebrosidase-positive and -deficient hybrid lines were analyzed for their human chromosome contents by the use of isozyme markers. In hybrids derived from both selection methods the expression of galactocerebrosidase activity was associated with the presence of human chromosome 17 marker isozymes. This was confirmed cytogenetically by means of trypsin-banded Giemsa staining of intact human chromosome 17 in three galactocerebrosidase-positive hybrid lines.

Establishment of a galactocerebrosidase-deficient twitcher mouse cell line that expresses galactocerebrosidase activity in hybrids with control human fibroblasts.

Primary cell cultures from twitcher (galactocerebrosidase deficient) mice were made by enzymatic dispersion and explantation of skin obtained from 3-d-old littermates of a twi+/twi X twi+/twi mating. Galactocerebrosidase activity remained deficient for two twitcher cell lines, TM-1 and TM-2, and both lines demonstrated an initial period of growth decline, followed by accelerated growth. The TM-2 line has been subcultured for more than 3.5 yr, has a modal chromosome number of 63, a doubling time of approximately 16 h, and has remained galactocerebrosidase deficient throughout its life span. These data indicate this to be an established twitcher cell line that can be continuously maintained in culture as a transformed galactocerebrosidase-deficient mouse cell line. This established line was rendered 6-thioguanine resistant so that the cells could be fused with control human fibroblasts and selected for hybrid lines in hypoxanthine-aminopterin-thymidine medium. Also, the established twitcher cells were crossed with neomycin-resistant control human fibroblasts and selected in G418 medium. Several of the hybrid lines from both crosses had higher than deficient levels of galactocerebrosidase activity initially, followed by a decrease to twitcher levels during subculture, whereas other lines retained high levels of activity. These results indicate that twitcher-human somatic cell hybrids will express galactocerebrosidase activity and thus may be useful for determining the human chromosome or chromosomes associated with this expression.

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

Primary 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. beta-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 beta-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.

Metabolic activities in human skin fibroblasts preloaded with labeled GM2-ganglioside.

Confluent cultures of human skin fibroblasts were maintained for 10 days with sphingosine labeled [3H]GM2. Labeled medium was then replaced with normal medium and the cells maintained for 42 days with weekly medium changes. Cells were harvested at regular intervals and cells, medium, and trypsin digest supernatant analyzed for [3H]GM2 and its metabolic products. The ganglioside can be membrane associated and removed by trypsin, or membrane incorporated and trypsin insensitive. The membrane incorporated material is apparently transported to the lysosomes slowly by membrane flow, where 80% of the cellular GM2 can be metabolized by day 42. [3H]GM2 as well as its metabolic products in control cells is continuously released into the medium, during which it can also become associated with the cell surface membrane. There is no detectable metabolism of the [3H]GM2 in GM2 gangliosidosis cell lines over the extended post-labeling period, indicating that there is no residual enzyme activity in these cells. Undegraded GM2 is continuously released into the medium and remains associated with the cell surface membrane as well.

Glycosphingolipid patterns in primary mouse kidney cultures.

Primary kidney cultures from C57BL/6J mice, 6 weeks of age or older, were produced using D-valine medium to select for epithelial cell growth. After allowing the cells to attach and proliferate for 1 week following plating, medium was changed once per week. Cells formed nearly confluent monolayers during the second week of culture. The cultured cells contained all of the glycosphingolipids seen in the adult kidney, analyzed by high performance liquid chromatography as their perbenzoyl derivatives. Glucosylceramide, however, was highly predominant in the cultured cells, whereas dihexosyl- and trihexosylceramides predominate in the intact kidney. Sex differences in glycolipid contents found in the intact kidney were also apparent in these cultured cells: The concentration of neutral glycolipids, in general, was higher in male cells than in those derived from females, and the male-specific glycolipid nonhydroxy fatty acid digalactosylceramide was high in male cells but very low in female cells. Neutral glycosphingolipids were labeled in 2-week-old cultures using [3H]palmitate. The [3H]palmitate was incorporated into all of the glycolipids within 2 hr of labeling. Hence, adult mouse kidney cells in D-valine medium retain their differentiated characteristics for a sufficient period of time to allow investigation of glycolipid syntheses in monolayer cultures of epithelial cells derived from this organ.

GM2-ganglioside metabolism in hexosaminidase A deficiency states: determination in situ using labeled GM2 added to fibroblast cultures.

To clarify the relationship between hexosaminidase A (HEX A) activity and GM2-ganglioside hydrolysis in atypical clinical situations of HEX A deficiency, we have developed a simple method to assess GM2-ganglioside metabolism in cultured fibroblasts utilizing GM2 labeled with tritium in the sphingosine portion of the molecule. The radioactive lipid is added to the media of cultured skin fibroblasts, and after 10 days the cells are thoroughly washed, then harvested, and their lipid composition analyzed by HPLC. The degree of hydrolysis of the ingested GM2 is determined by comparing the amount of radioactive counts recovered in undegraded substrate with total cellular radioactivity. A deficiency in GM2-ganglioside hydrolysis was demonstrated in seven HEX A-deficient adults with neurological signs and in two healthy-appearing adolescents with older affected siblings. In each case, an analysis of endogenous monosialoganglioside composition revealed an increase in GM2-ganglioside, confirming the presence of a block in the metabolism of GM2. No defect in GM2-catabolism was found in four other healthy individuals with HEX A deficiency. This method of assay is especially helpful in the evaluation of atypical cases of HEX A deficiency for the definitive diagnosis of GM2-gangliosidosis.

GM2-ganglioside metabolism in cultured human skin fibroblasts: unambiguous diagnosis of GM2-gangliosidosis.

The metabolism of GM2-ganglioside was studied in situ using cultured skin fibroblasts from normal individuals and patients with different forms of GM2-gangliosidosis. [3H]Sphingosine-labeled GM2 was provided in the culture medium to confluent cells in 6-cm petri dishes. After 10 days, the cells were washed free of radioactivity and harvested by trypsinization. The cellular lipids were extracted and analyzed for radioactivity in GM2 and its metabolic products. In fibroblasts from healthy subjects, 50-60% of the total cellular radioactivity was found in the neutral glycosphingolipids, ceramide, sphingomyelin and fatty acids. Degradation of the labeled GM2 progressed rapidly via GM3, ceramide dihexoside and ceramide monohexoside with a build-up of radioactivity mainly in the ceramide pool of the cell. The labeled ceramide is also reutilized for the synthesis of ceramide trihexoside, globoside and sphingomyelin or is converted to fatty acid and incorporated in ester linkages. In contrast, cells from patients with GM2-gangliosidosis representing Tay-Sachs, Sandhoff and AB variant forms of the disease did not metabolize the ingested labeled GM2-like controls. Nearly all of the radioactivity was present in the ganglioside fraction in the lipid extracts from these cells and consisted of unhydrolyzed GM2. High-performance liquid chromatographic analysis of monosialogangliosides from cells grown without added labeled GM2 in the medium indicated accumulation of endogenously synthesized GM2 in cell lines from all patients with GM2 gangliosidosis compared to healthy controls. This approach provides a reliable tool for pre- and post-natal diagnosis of all forms of GM2-gangliosidosis without ambiguity.

Alcohol dehydrogenase isozymes in the clawed frog, Xenopus laevis.

Alcohol dehydrogenase (ADH; EC 1.1.1.1) activity in Xenopus laevis was highest in liver tissue, with decreasing activities in kidney, heart, and gut tissues, respectively. Essentially no activity was found among other tissues screened, including lung, ovary, eye, and testes. Also, there was no apparent sexual dimorphism of ADH activity in either liver or kidney tissue. All ADH isozymes were inhibited by 10 mM pyrazole, and no eye-specific retinol dehydrogenase activity was detected on starch gel electropherograms. Isozyme patterns from 418 offspring from 11 different crosses could be explained genetically assuming the presence of two structural genes coding for ADH production: one carrying two electrophoretically separable variants and the other showing quantitative variation in its expression. The ADH system in X. laevis should be useful for studies concerning the molecular mechanisms governing the expression of ADH activity in vertebrate development.

Xanthine dehydrogenase activity in the clawed frog, Xenopus laevis.

Xanthine dehydrogenase (XDH; EC 1.2.1.37) activity in the clawed frog, Xenopus laevis, was detected in kidney tissue homogenates, but not in skin, liver, ovaries or gut tissues. The enzyme migrated as a single band of activity on both polyacrylamide and starch gel electropherograms, exhibited substrate inhibition, and did not appear developmentally until feeding larval stages. The tissue specificity, post-fertilization stage of appearance and single isozymic form make this a useful enzyme marker for further study concerning its developmental appearance and maintenance as a kidney-specific protein.

Flavonoid genetics of the 28-chromosome "Siberian" Iris.

A Chromatographic survey of flavonoids in the various flower color mutants of the 28-chromosome "Siberian" Iris (series Sibiricae subseries Sibiricae) was conducted using mutants of known genotype (Vaughn 1974). Mutants at the C locus contain the malvidin glycoside ensatin, indicating that this gene locus may control methylation of delphinidin. Clear white, a mutation at the W locus, results in the production of flavones in excess.