Utilization of membranous lipid substrates by membranous enzymes: activation of the latent sphingomyelinase of hen erythrocyte membrane

Accumulated bending energy elicits neutral sphingomyelinase activity in human red blood cells

We propose that accumulated membrane bending energy elicits a neutral sphingomyelinase (SMase) activity in human erythrocytes. Membrane bending was achieved by osmotic or chemical processes, and SMase activity was assessed by quantitative thin-layer chromatography, high-performance liquid chromatography, and electrospray ionization-mass spectrometry. The activity induced by hypotonic stress in erythrocyte membranes had the pH dependence, ion dependence, and inhibitor sensitivity of mammalian neutral SMases. The activity caused a decrease in SM contents, with a minimum at 6 min after onset of the hypotonic conditions, and then the SM contents were recovered. We also elicited SMase activity by adding lysophosphatidylcholine externally or by generating it with phospholipase A(2). The same effect was observed upon addition of chlorpromazine or sodium deoxycholate at concentrations below the critical micellar concentration, and even under hypertonic conditions. A unifying factor of the various agents that elicit this SMase activity is the accumulated membrane bending energy. Both hypo-and hypertonic conditions impose an increased curvature, whereas the addition of surfactants or phospholipase A(2) activation increases the outer monolayer area, thus leading to an increased bending energy. The fact that this latent SMase activity is tightly coupled to the membrane bending properties suggests that it may be related to the general phenomenon of stress-induced ceramide synthesis and apoptosis.

Sphingomyelinases: enzymology and membrane activity

This paper reviews our present knowledge of sphingomyelinases as enzymes, and as enzymes acting on a membrane constituent lipid, sphingomyelin. Six types of sphingomyelinases are considered, namely acidic, secretory, Mg(2+)-dependent neutral, Mg(2+)-independent neutral, alkaline, and bacterial enzymes with both phospholipase C and sphingomyelinase activity. Sphingomyelinase assay methods and specific inhibitors are reviewed. Kinetic and mechanistic studies are summarized, a kinetic model and a general-base catalytic mechanism are proposed. Sphingomyelinase-membrane interactions are considered from the point of view of the influence of lipids on the enzyme activity. Moreover, effects of sphingomyelinase activity on membrane architecture (increased membrane permeability, membrane aggregation and fusion) are described. Finally, a number of open questions on the above topics are enunciated.

A fluorescence-based, high-throughput sphingomyelin assay for the analysis of Niemann-Pick disease and other disorders of sphingomyelin metabolism

Sphingomyelin is an important lipid component of cell membranes and lipoproteins that can be hydrolyzed by sphingomyelinases into ceramide and phosphorylcholine. The Type A and B forms of Niemann-Pick disease (NPD) are lipid storage disorders due to the deficient activity of the enzyme acid sphingomyelinase and the resultant accumulation of sphingomyelin in cells, tissues, and fluids. In this paper we report a new, enzymatic method to quantify the levels of sphingomyelin in plasma, urine, or tissues from NPD patients and mice. In this assay, bacterial sphingomyelinase is first used to hydrolyze sphingomyelin to phosphorylcholine and ceramide. Alkaline phosphatase then generates choline from the phosphorylcholine, and the newly formed choline is then used to generate hydrogen peroxide in a reaction catalyzed by choline oxidase. Finally, with peroxidase as a catalyst, hydrogen peroxide reacts with the Amplex Red reagent to generate a highly fluorescent product, resorufin. These enzymatic reactions are carried out simultaneously in a single 100-microl reaction mixture for 20 min. Use of a 96-well microtiter plate permits automated and sensitive quantification using a plate reader and fluorescence detector. This procedure allowed quantification of sphingomyelin over a broad range from 0.02 to 10 nmol, similar in sensitivity to a recently described radioactive method using diacylglycerol kinase and 50 times more sensitive than a colorimetric, aminoantipyrine/phenol-based assay. To validate this new assay method, we quantified sphingomyelin in plasma, urine, and tissues from normal individuals and from NPD mice and patients. The sphingomyelin content in adult homozygous or heterozygous NPD mouse plasma and urine was significantly elevated compared to that of normal mice. Moreover, the accumulated sphingomyelin in the tissues of NPD mice was 4 to 15 times higher than that in normal mice depending on the tissue analyzed. The sphingomyelin levels in plasma from several Type B NPD patients also was significantly elevated compared to normal individuals of the same age. Based on these results, we propose that this new, fluorescence-based procedure can provide simple, fast, sensitive, and reproducible sphingomyelin quantification in tissues and fluids from normal individuals and NPD patients. It could also be a useful tool for the study of other sphingomyelin-related diseases and in a variety of research settings where sphingomyelin quantification is required.

Insertional mutagenesis of the mouse acid ceramidase gene leads to early embryonic lethality in homozygotes and progressive lipid storage disease in heterozygotes

Ceramide is an important cellular lipid involved in signal transduction and the biosynthesis of complex sphingolipids. It can be hydrolyzed into sphingosine, another important signaling lipid, by the activity of ceramidases. Point mutations in the gene (Asah1) encoding one ceramidase, acid ceramidase (AC), lead to the lysosomal storage disorder Farber disease (FD). To investigate the role of AC in mammalian development, we disrupted the mouse gene Asah1 in embryonic stem cells by homologous recombination mediated insertion of an AC targeting vector into the wild-type sequence. Genotype analysis of over 150 offspring or embryos from heterozygous intercrosses revealed an absence of Asah1(-/-) individuals at embryonic day (E) 8.5 or later, although the ratio of wild-type to Asah1(+/-) individuals from these intercrosses was 1:2. Northern blot analysis showed that AC expression was turned on early in development, by E7.0, and continued through at least E17. In contrast, expression of the related lipid hydrolase, acid sphingomyelinase, was shut down by E11. Asah1(+/-) mice survived and lived a normal lifespan, but developed a progressive lipid storage disease in several of their organs, particularly the liver. These histopathological findings in Asah1(+/-) animals correlated with an up to twofold increase in the ceramide content of these tissues and a reduction n AC activity, confirming that the gene insertion event disrupted AC activity and ceramide metabolism. These results provide direct in vivo evidence that normal ceramide metabolism, and AC activity in particular, is essential for mammalian development. The animals and embryos described here should be a valuable resource for investigators studying the role of ceramide in cell growth and development, as well as those interested in the pathogenesis of FD and other sphingolipid storage disorders.

An enzymatic assay for quantifying sphingomyelin in tissues and plasma from humans and mice with Niemann-Pick disease

Sphingomyelin is an important lipid component of cell membranes and lipoproteins which can be hydrolyzed by sphingomyelinases into ceramide and phosphorylcholine. The type A and B forms of Niemann-Pick disease (NPD) are lipid storage disorders due to the deficient activity of the enzyme acid sphingomyelinase, and the resultant accumulation of sphingomyelin in cells and tissues. In this paper we report a new, enzyme-based method to quantify the levels of sphingomyelin in tissues and plasma of normal individuals and NPD patients. The method utilizes sphingomyelinase from Bacillus cereus to completely hydrolyze the sphingomyelin into ceramide. Quantification of the sphingomyelin-derived ceramide is accomplished using Escherichia coli diacylglycerol (DAG) kinase and [gamma-(32)P]ATP. The resulting [(32)P]ceramide is quantified using a phosphor-imager system following TLC separation. This procedure allowed quantification of sphingomyelin over a broad range from 10 pmol to 1 nmol. To validate this assay we quantified sphingomyelin in plasma and tissues obtained from normal and NPD mice and humans. The sphingomyelin content in adult homozygous (-/-) or heterozygous (+/-) NPD mouse plasma was significantly elevated compared to that of normal mice (up to twofold). Moreover, the accumulated sphingomyelin in the tissues of NPD mice was 4 to 40 times higher than that in normal mice depending on the tissue analyzed. The sphingomyelin levels in plasma from several type B NPD patients also were significantly elevated compared to normal individuals of the same age. Based on these results we propose that this new, enzyme-based procedure can provide sensitive and reproducible sphingomyelin quantification in tissues and fluids from normal individuals and NPD patients. It could be a useful tool for the diagnosis of NPD and the evaluation of NPD treatment protocols, as well as for the study of ceramide-mediated apoptosis since the method provides the simultaneous determination of sphingomyelin and ceramide in the same lipid extract.

Hematopoietic stem cell gene therapy leads to marked visceral organ improvements and a delayed onset of neurological abnormalities in the acid sphingomyelinase deficient mouse model of Niemann-Pick disease

Types A and B Niemann-Pick disease (NPD) result from the deficient activity of acid sphingomyelinase (ASM). Currently, no treatment is available for either form of NPD. Using the ASM knockout (ASMKO) mouse model, we evaluated the effects of ex vivo hematopoietic stem cell gene therapy on the NPD phenotype. Thirty-two newborn ASMKO mice were preconditioned with low dose radiation (200 cGy) and transplanted with ASMKO bone marrow cells which had been transduced with an ecotropic retroviral vector encoding human ASM. Engraftment of donor-derived cells ranged from 15 to 60% based on Y-chromosome in situ hybridization analysis of peripheral white blood cells, and was achieved in 92% of the transplanted animals. High levels of ASM activity (up to five-fold above normal) were found in the engrafted animals for up to 10 months after transplantation, and their life-span was extended from a mean of 5 to 9 months by the gene therapy procedure. Biochemical and histological analysis of tissues obtained 4-5 months after transplantation indicated that the ASM activities were increased and the sphingomyelin storage was significantly reduced in the spleens, livers and lungs of the treated mice, major sites of pathology in type B NPD. The presence of Purkinje cell neurons was also markedly increased in the treatment group as compared with non-treated animals at 5 months after transplantation, and a reduction of storage in spinal cord neurons was observed. However, all of the transplanted mice eventually developed ataxia and died earlier than normal mice. Overall, these results indicated that hematopoietic stem cell gene therapy should be effective for the treatment of non-neurological type B NPD, but improved techniques for targeting the transplanted cells and/or expressed enzyme to specific sites of pathology in the central nervous system must be developed in order to achieve effective treatment for type A NPD.

Infusion of recombinant human acid sphingomyelinase into niemann-pick disease mice leads to visceral, but not neurological, correction of the pathophysiology

An inherited deficiency of acid sphingomyelinase (ASM) activity results in the Type A and B forms of Niemann-Pick disease (NPD). Using the ASM-deficient mouse model (ASMKO) of NPD, we evaluated the efficacy of enzyme replacement therapy (ERT) for the treatment of this disorder. Recombinant human ASM (rhASM) was purified from the media of overexpressing Chinese Hamster ovary cells and i.v. injected into 16 five-month-old ASMKO mice at doses of 0.3, 1, 3, or 10 mg/kg every other day for 14 days (7 injections). On day 16, the animals were killed and the tissues were analyzed for their sphingomyelin (SPM) content. Notably, the SPM levels were markedly reduced in the hearts, livers, and spleens of these animals, and to a lesser degree in the lungs. Little or no substrate depletion was found in the kidneys or brains. Based on these results, three additional 5-month-old ASMKO animals were injected every other day with 5 mg/kg for 8 days (4 injections) and killed on day 10 for histological analysis. Consistent with the biochemical results, marked histological improvements were observed in the livers, spleens, and lungs, indicating a reversal of the disease pathology. A group of 10 ASMKO mice were then i.v. injected once a week with 1 mg/kg rhASM for 15 wk, starting at 3 wk of age. Although anti-rhASM antibodies were produced in these mice, the antibodies were not neutralizing and no adverse effects were observed from this treatment. Weight gain and rota-rod performance were slightly improved in the treated animals as compared with ASMKO control animals, but significant neurological deficits were still observed and their life span was not extended by ERT. In contrast with these CNS results, striking histological and biochemical improvements were found in the reticuloendothelial system organs (livers, spleens, and lungs). These studies indicate that ERT should be an effective therapeutic approach for Type B NPD, but is unlikely to prevent the severe neurodegeneration associated with Type A NPD.

Biochemical, pathological, and clinical response to transplantation of normal bone marrow cells into acid sphingomyelinase-deficient mice

BACKGROUND

Acid sphingomyelinase knock-out (ASMKO) mice are a model of types A and B Niemann-Pick disease. In the present study, we evaluated whether bone marrow transplantation (BMT) carried out on newborn ASMKO mice could prevent or alter the Niemann-Pick disease phenotype.

METHODS

Previous work from our laboratory had shown that ASMKO mice were highly susceptible to irradiation-induced death. Therefore, we preconditioned 1-day-old ASMKO (n=35) mice with a "sublethal" dose of 200 cGy of total body irradiation before BMT. The transplantation effects were then analyzed by biochemical, pathological, and clinical approaches.

RESULTS

Engraftment ranging from 7% to 100% was achieved in 97% of the transplanted animals. Growth of the engrafted animals was improved, and their survival was increased (from a mean of 5 months to 9 months). The onset of ataxia also was delayed in most of the engrafted animals. In accordance with these observations, biochemical and pathological analysis revealed significant changes in the transplanted group as compared with nontransplanted animals. Lipid storage was reduced in several organs, and there was evidence of histologic improvement seen throughout the reticuloendothelial system, even in animals that were engrafted as low as 14%. In the central nervous system, lipid storage also was reduced, and the Purkinje cells, which are almost absent in ASMKO mice, were present in certain areas of the transplanted animals cerebella.

CONCLUSIONS

These results demonstrated that BMT could alter the pathologic phenotype in ASMKO mice, but that this procedure alone was not sufficient to elicit a complete therapeutic effect.

Response of SCC-12F, a human squamous cell carcinoma cell line, to complement attack

We studied the response of a human squamous cell carcinoma cell line, SCC-12F, to human complement attack and found that the cells were completely resistant to complement lysis. In the absence of lysis, there was significant C3 deposition and C5b-9 deposition on the cells. Removal of the lipid-linked complement regulatory proteins CD59 and decay-accelerating factor (DAF) by treatment of the cells with phosphatidylinositol-specific phospholipase C (PIPLC) resulted in increased C3b and C5b-9 deposition on the cells and a slight increase in cell death. Treatment of the cells with complement caused them to release membrane vesicles containing the terminal complement proteins. In addition, complement induced SCC-12F to produce significant amounts of prostaglandin F2alpha (PGF2alpha). We conclude that CD59 and DAF are important in the resistance of SCC-12F to complement and that these cells produce membrane vesicles and PGF2alpha in response to complement attack. These responses, in the absence of cell death, may be important in the pathogenesis of inflammatory skin disease in which complement is deposited.

Purified rat brain microvessels exhibit both acid and neutral sphingomyelinase activities

Purified rat brain microvessels have been shown to hydrolyze radiolabeled sphingomyelin by means of two different enzyme systems. Enzymatic activity was detected at pH 7.4 and was strongly stimulated by magnesium or manganese and inhibited by calcium. Activity at pH 5.1 could also be found and was not dependent on any of these cations. At neutral pH and in the presence of magnesium, the rate of sphingomyelin hydrolysis did not exhibit a linear relationship with protein concentration. In contrast, increasing the protein concentration from 0.05 to 0.5 mg/ml resulted in a constant increase of sphingomyelin hydrolysis at pH 5.1. Kinetic parameters of both neutral and acid activities have been determined and were similar in magnitude to values reported previously for neural sphingomyelinases. This work demonstrates the occurrence of a neutral sphingomyelinase activity in purified rat brain microvessels, an observation raising the question of its role at the level of the blood-brain interface.

A sphingomyelinase-resistant pool of sphingomyelin in the nuclear membrane of hen erythrocytes

Experiments in which hen erythrocytes were exposed to the action of exogenous sphingomyelinase (Staphylococcus aureus) or to their endogenous plasma membrane sphingomyelinase showed that about 15% of the total sphingomyelin was resistant to breakdown either in intact or lysed cells. This resistant pool of sphingomyelin seems likely to reside in the nuclear membranes of the cells, so that essentially all the plasma membrane sphingomyelin can be broken down by exogenous sphingomyelinase acting on intact cells, suggesting that plasma membrane sphingomyelin is exclusively localised in the outer lipid leaflet. Paradoxically, introduction of Ca2+ into the intact cells using A23187 causes the breakdown of up to 30% of total cell sphingomyelin inside the cells but without apparently affecting the putative nuclear pool of sphingomyelin and this suggests that Ca2+ may alter the original disposition of sphingomyelin in the membrane so that originally outer leaflet sphingomyelin becomes accessible to the endogenous sphingomyelinase inside the cells. No differences were seen in the fatty acid compositions of sphingomyelin degradable by exogenous sphingomyelinase, sphingomyelin degradable in the presence of A23187/Ca2+ or the enzyme-resistant pool of sphingomyelin.