Acid sphingomyelinase is a water-soluble, lysosomal glycoprotein that catalyzes the degradation of membrane-bound sphingomyelin into phosphorylcholine and ceramide. Sphingomyelin itself is an important component of the extracellular leaflet of various cellular membranes. The aim of the present investigation was to study sphingomyelin hydrolysis as a membrane-bound process. We analyzed the degradation of sphingomyelin by recombinant, highly purified acid sphingomyelinase in a detergent-free, liposomal assay system. In order to mimic the in vivo intralysosomal conditions as closely as possible a number of negatively charged, lysosomally occuring lipids including bis(monoacylglycero)phosphate and phosphatidylinositol were incorporated into substrate-carrying liposomes. Dolichol and its phosphate ester dolicholphosphate were also included in this study. Bis(monoacylglycero)phosphate and phosphatidylinositol were both effective stimulators of sphingomyelin hydrolysis. Dolichol and dolicholphosphate also significantly increased sphingomyelin hydrolysis. The influence of membrane curvature was investigated by incorporating the substrate into small (SUVs) and large unilamellar vesicles (LUVs) with varying mean diameter. Degradation rates were substantially higher in SUVs than in LUVs. Surface plasmon resonance experiments demonstrated that acid sphingomyelinase binds strongly to lipid bilayers. This interaction is significantly enhanced by anionic lipids such as bis(monoacylglycero)phosphate. Under detergent-free conditions only the sphingolipid activator protein SAP-C had a pronounced influence on sphingomyelin degradation in both neutral and negatively charged liposomes, catalyzed by highly purified acid sphingomyelinase, while SAP-A, -B and -D had no noticeable effect on sphingomyelin degradation.
An Arxula adeninivorans-AHSB4 gene, encoding histone H4, was isolated and characterized. The gene includes a coding sequence of 363 bp disrupted by a 51-bp intron, similar to the situation in other fungal H4 genes. The identity of the gene was confirmed by the high degree of homology of the derived amino acid sequence with that of other H4 histones. The gene is strongly and constitutively expressed, maintaining this expression profile under salt-stress conditions. The AHSB4 promoter was tested for suitability in heterologous gene expression using genes encoding the intracellular green fluorescent protein and the secreted human serum albumin (HSA) for assessment. Plasmids incorporating respective expression cassettes were used to transform the host strain A. adeninivorans LS3, which forms budding cells at 30 degrees C, and strain 135, which forms mycelia under these conditions. Transformants of both types were found to harbor a single copy of the heterologous DNA. Strong constitutive expression was observed during culture in salt-containing and salt-free media, as expected from the expression profile of AHSB4. In 200-ml shake-flask cultures, maximal HSA levels of 20 mg l(-1) culture medium were achieved. This productivity could be increased to 50 mg l(-1 )in strains harboring two copies of the expression cassette. The AHSB4 promoter thus provides an attractive component for constitutive heterologous gene expression under salt-free and salt-stress conditions.
The non-conventional dimorphic thermo- and salt-resistant yeast Arxula adeninivorans has been developed as a host for heterologous gene expression. For assessment of the system two model genes have been selected: the GFP gene encoding the intracellular green fluorescent protein, and the HSA gene encoding the secreted human serum albumin. The expression system includes two host strains, namely A. adeninivorans LS3, which forms budding cells at 30 degrees C and mycelia at >42 degrees C, and the strain A. adeninivorans 135, which forms mycelia at temperatures as low as 30 degrees C. For expression control the constitutive A. adeninivorans-derived TEF1-promoter and S. cerevisiae-derived PHO5-terminator were selected. The basic A. adeninivorans transformation/expression vector pAL-HPH1 is further equipped with the Escherichia coli-derived hph gene conferring hygromycin B resistance and the 25S rDNA from A. adeninivorans for rDNA targeting. Transformants were obtained for both budding cells and mycelia. In both cell types similar expression levels were achieved and the GFP was localised in the cytoplasm while more than 95% of the HSA accumulated in the culture medium. In initial fermentation trials on a 200-ml shake flask scale maximal HSA product levels were observed after 96 h of cultivation.
Differential scanning calorimetry (DSC) and film balance measurements were performed to study the interactions of the GalNAcb134(NeuAca233)Galb134Glc131 H Cer (GM2)-activator protein with phospholipid/ganglioside vesicles and monolayers. The nonglycosylated form of the GM2-activator protein, added to unilamellar lipid vesicles of different composition, causes differential effects on the gel to liquid±crystalline phase transition peaks. The phase transition temperature (T m ) of pure dimyristoylglycerophosphocholine (DMPC) bilayer is slightly decreased. When lipids which specifically bind the GM2-activator protein are incorporated into the vesicles (e.g. a sulfatide or gangliosides) a shoulder in the thermograms at higher temperatures is observed, indicating an increase of the stability of the gel phase in relation to the liquid-crystalline phase. We also studied the surface activity of a glycosylated and a nonglycosylated GM2-activator protein at the air±water interface. The glycosylated form showed a slightly lower surface activity than the GM2-activator protein without oligosaccharide moiety. When the GM2-activator protein is added to the sub-phase of a surface covered with a lipid monolayer, it can only insert into the monolayer and reach the air±water interface below a monolayer pressure of 25 mN´m 21 , depending on the lipid composition, and not when the monolayers are at the bilayer equivalence pressure of 30±35 mN´m 21 . Particularly for Galb133GalNAcb134(NeuAca233)Galb134Glc131 H Cer (GM1) and GM2 containing films, the critical pressures (p crit ) when no additional increase in surface pressure is observed after addition of the protein into the subphase, are much lower. This leads to the conclusion that binding of the GM2 activator protein to the ganglioside headgroups prevents the protein from reaching the air±water interface. The protein is then located preferentially at the lipid±water interface and cannot penetrate into the chain region.
Al~stract Human placental acid sphingomyelinase (ASM) was purified by sequential chromatography on Con A-Sepharose, octyI-Sepharose and Matrex gel red A. Final purification to apparent homogeneity was achieved by immunoaff'mity chromatography employing polyclonal anti-ASM antibodies. The antibodies also allowed specific detection of ASM by Western blotting at various stages of purification. The ASM activity was enriched about ll0000-fold over that of the crude extract, yielding an enzyme preparation with a specific activity of about 1 mmol/h per mg protein in a detergent-containing assay system. Analysis of the final preparation by SDS-PAGE resulted in a single protein band with a molecular mass of ~ 75 kDa, which was reduced to ,-~60 kDa after complete deglycosylation. Microsequencing of the purified ASM revealed the N-terminal amino acid sequence of the mature placental enzyme.
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