Project description:The neutral sphingomyelinase (N-SMase) is considered a major candidate for mediating the stress-induced production of ceramide, and it plays an important role in cell-cycle arrest, apoptosis, inflammation, and eukaryotic stress responses. Recent studies have identified a small region at the very N-terminus of the 55 kDa tumour necrosis factor receptor (TNF-R55), designated the neutral sphingomyelinase activating domain (NSD) that is responsible for the TNF-induced activation of N-SMase. There is no direct association between TNF-R55 NSD and N-SMase; instead, a protein named factor associated with N-SMase activation (FAN) has been reported to couple the TNF-R55 NSD to N-SMase. Since the three-dimensional fold of N-SMase is still unknown, we have modeled the structure using the protein fold recognition and threading method. Moreover, we propose models for the TNF-R55 NSD as well as the FAN protein in order to study the structural basis of N-SMase activation and regulation. Protein-protein interaction studies suggest that FAN is crucially involved in mediating TNF-induced activation of the N-SMase pathway, which in turn regulates mitogenic and proinflammatory responses. Inhibition of N-SMase may lead to reduction of ceramide levels and hence may provide a novel therapeutic strategy for inflammation and autoimmune diseases. Molecular dynamics (MD) simulations were performed to check the stability of the predicted model and protein-protein complex; indeed, stable RMS deviations were obtained throughout the simulation. Furthermore, in silico docking of low molecular mass ligands into the active site of N-SMase suggests that His135, Glu48, Asp177, and Asn179 residues play crucial roles in this interaction. Based on our results, these ligands are proposed to be potent and selective N-SMase inhibitors, which may ultimately prove useful as lead compounds for drug development.

Project description:Absorption of dietary sphingomyelin (SM) requires its initial degradation into ceramide, a process catalyzed by the intestinal enzyme alkaline sphingomyelinase (alk-SMase, NPP7, ENPP7). alk-SMase belongs to the nucleotide pyrophosphatase/phosphodiesterase (NPP) family, the members of which hydrolyze nucleoside phosphates, phospholipids, and other related molecules. NPP7 is the only paralog that can cleave SM, and its activity requires the presence of bile salts, a class of physiological anionic detergents. To elucidate the mechanism of substrate recognition, we determined the crystal structure of human alk-SMase in complex with phosphocholine, a reaction product. Although the overall fold and catalytic center are conserved relative to other NPPs, alk-SMase recognizes the choline moiety of its substrates via an NPP7-specific aromatic box composed of tyrosine residues. Mutational analysis and enzymatic activity assays identified features on the surface of the protein-a cationic patch and a unique hydrophobic loop-that are essential for accessing SM in bile salt micelles. These results shed new light on substrate specificity determinants within the NPP enzyme family.

Project description:Alkaline sphingomyelinase (alk-SMase) is expressed in the intestine and human liver. It may inhibit colonic tumorigenesis, and loss of function mutations have been identified in human colon cancer. The present study investigates its expression in human liver cancer. In HepG2 liver cancer cells, RT-PCR identified three transcripts with 1.4, 1.2 and 0.4 kb, respectively. The 1.4 kb form is the wild-type cDNA with five translated exons, the 1.2 kb product lacks exon 4 and the 0.4 kb form is a combination of exons 1 and 5. Genomic sequence showed that these aberrant transcripts were products of alternative splicing. Transient expression of the 1.2 kb form showed no alk-SMase activity. In HepG2 cells, the alk-SMase activity is low in monolayer condition and increased with cell polarisation. Coexistence of 1.4 and 1.2 kb forms was also identified in one hepatoma biopsy. GenBank search identified a cDNA clone from human liver tumour, which codes a protein containing full length of alk-SMase plus a 73-amino-acid tag at the N terminus. The aberrant form was translated by an alternative starting codon upstream of the wild-type mRNA. Expression study showed that linking the tag markedly reduced the enzyme activity. We also analysed human liver biopsy samples and found relatively low alk-SMase activity in diseases with increased risk of liver tumorigenesis. In conclusion, expression of alk-SMase is changed in hepatic tumorigenesis, resulting in loss or marked reduction of the enzyme function.

Project description:Intestinal alkaline sphingomyelinase (alk-SMase) generates ceramide and inactivates platelet-activating factor and associated with digestion and inhibition of cancer. There is few study to analyze the correlated function and characterize the genes related to alk-SMase comprehensively. In this work, deep RNA sequencing was performed to investigate the function of alk-SMase. Our RNA-seq data found 239 differentially expressed mRNAs between the wild type (WT) mice and alk-SMase (gene NPP7) knockout (KO) mice, in which 73 were significantly up-regulated and 166 were down-regulated, including protein coding genes, non-coding RNAs. Notably, the results of gene ontology functional enrichment analysis indicated that differentially expressed genes were functionally associated with the immune response, regulation of cell proliferation and development related terms using DAVID. Additionally, an integrated PPI and KEGG network was chose to study the relationship of differentially expressed genes, it was shown that some modules was significantly related to alk-SMase and with accordance of previously results. We chose 6 of these genes randomly were validated the accuracy of RNA-seq technology using quantitative real-time polymerase chain reaction (qPCR) and 2 genes showed difference significantly (P<0.05).

Project description:Intestinal alk-SMase (alkaline sphingomyelinase) is an ectoenzyme related to the NPP (nucleotide phosphodiesterase) family. It has five potential N-glycosylation sites and predicated transmembrane domains at both the N- and C-termini. The amino acid residues forming the two metal-binding sites in NPP are conserved, and those of the active core are modified. We examined the functional changes of the enzyme induced by deglycosylation and mutagenesis. Treating alk-SMase cDNA-transfected COS-7 cells with tunicamycin rendered the expressed enzyme completely inactive. Mutations of the five potential N-glycosylation sites individually and in combination showed that these sites were all glycosylated and deficient glycosylation decreased the enzyme activity. Immunogold labelling showed that the wild-type enzyme was mainly located in the plasma membrane, whereas the C-terminal domain-truncated enzyme was released into the medium. Deglycosylation blocked the release of the enzyme that accumulated in endosome-like structures. The enzyme activity was also decreased by mutations of the residues forming the putative metal-binding sites and the active core. Substitution of the active core sequence with that of NPP or mutation of T75 in the core abolished the enzyme activity against sphingomyelin but failed to render the enzyme NPP active. Our results indicate that alk-SMase activity is severely affected by defective N-glycosylation and structural alterations of the putative metal-binding sites and the predicted active core.

Project description:Intestinal alkaline sphingomyelinase (alk-SMase) generates ceramide and inactivates platelet-activating factor and associated with digestion and inhibition of cancer. There is few study to analyze the correlated function and characterize the genes related to alk-SMase comprehensively. In this work, deep RNA sequencing was performed to investigate the function of alk-SMase. Our RNA-seq data found 239 differentially expressed mRNAs between the wild type (WT) mice and alk-SMase (gene NPP7) knockout (KO) mice, in which 73 were significantly up-regulated and 166 were down-regulated, including protein coding genes, non-coding RNAs. Notably, the results of gene ontology functional enrichment analysis indicated that differentially expressed genes were functionally associated with the immune response, regulation of cell proliferation and development related terms using DAVID. Additionally, an integrated PPI and KEGG network was chose to study the relationship of differentially expressed genes, it was shown that some modules was significantly related to alk-SMase and with accordance of previously results. We chose 6 of these genes randomly were validated the accuracy of RNA-seq technology using quantitative real-time polymerase chain reaction (qPCR) and 2 genes showed difference significantly (P<0.05).

Project description:A cold-adapted marine alkaline protease (MP, accession no. ACY25898) was produced by a marine bacterium strain, which was isolated from Yellow Sea sediment in China. Many previous researches showed that this protease had potential application as a detergent additive. It was therefore crucial to determine the tertiary structure of MP. In this study, a homology model of MP was constructed using the multiple templates alignment method. The tools PROCHECK, ERRAT, and Verify_3D were used to check the effectiveness of the model. The result showed that 94% of residues were found in the most favored allowed regions, 6% were in the additional allowed region, and 96.50% of the residues had average 3D-1D scores of no less than 0.2. Meanwhile, the overall quality factor (ERRAT) of our model was 80.657. In this study, we also focused on elucidating the molecular mechanism of the two "flap" motions. Based on the optimized model, molecular-dynamics simulations in explicit solvent environments were carried out by using the AMBER11 package, for the entire protein, in order to characterize the dynamical behavior of the two flaps. Our results showed an open motion of the two flaps in the water solvent. This research may facilitate inhibitor virtual screening for MP and may also lay the foundation knowledge of mechanism of the inhibitors.

Project description:Human acid sphingomyelinase (ASM) hydrolyses sphingomyelin to ceramide and phosphocholine. Metabolic studies on COS-1 cells transfected with ASM cDNA revealed the occurrence of an enzymically inactive precursor which is differentially processed to two predominant native glycoprotein forms: a 70 kDa polypeptide corresponding to human urinary protein and a 57 kDa form. Formation of these potentially active forms was shown to be restricted to distinct compartments. Maturation of the ASM precursor to a predominant 70 kDa form occurs exclusively inside acidic organelles, whereas variable amounts of 57 kDa ASM are detectable immediately after biosynthesis. Metabolic labelling of transfected COS-1 cells with [32P]Pi further suggests that this form obviously does not carry oligomannosylphosphate residues, in contrast with the mature lysosomal ASM. In order to verify that this early form of active ASM results from co-post-translational proteolysis of the ASM precursor and not from the use of different translation-initiation sites on the ASM mRNA, appropriate 5'-mutagenized cDNA constructs were transiently expressed. These results clearly indicate that the first potential in-frame AUG is exclusively used for translation initiation in vivo and that deletion of the proposed signal sequence for endoplasmic reticulum import completely eliminates the ability of the translation product to enter the vacuolar apparatus. As there are two different subcellular sites of maturation of the ASM precursor, and intracellular targeting of the two processed forms appears to be different, the two ASM proteins may contribute to distinct physiological functions.

Project description:Alkaline sphingomyelinase (alk-SMase) hydrolyses sphingomyelin (SM) to ceramide in the gut. To evaluate the physiological importance of the enzyme, we generated alk-SMase knockout (KO) mice by the Cre-recombinase-Locus of X-over P1(Cre-LoxP) system and studied SM digestion. Both wild-type (WT) and KO mice were fed ³H-palmitic acid labeled SM together with milk SM by gavage. The lipids in intestinal content, intestinal tissues, serum, and liver were analyzed by TLC. In KO mice, nondigested ³H-SM in the intestinal content increased by 6-fold and the formation of ³H-ceramide decreased markedly, resulting in 98% reduction of ³H-ceramide/³H-SM ratio 1 h after gavage. The absorbed ³H-palmitic acid portion was decreased by 95%. After 3 h, a small increase in ³H-ceramide was identified in distal intestine in KO mice. In feces, ³H-SM was increased by 243% and ceramide decreased by 74% in the KO mice. The KO mice also showed significantly decreased radioactivity in liver and serum. Furthermore, alkaline phosphatase activity in the mucosa was reduced by 50% and histological comparison of two female littermates preliminarily suggested mucosal hypertrophy in KO mice. This study provides definite proof for crucial roles of alk-SMase in SM digestion and points to possible roles in regulating mucosal growth and alkaline phosphatase function.

Project description:Alkaline sphingomyelinase (alk-SMase) is phospholipase that creates ceramides and inactivates platelet activating factors during metabolism, and is linked to digestion and cancer prevention. There have been few studies that completely investigate the linked function and identify the genes related to alk-SMase. In this work, RNA sequencing was performed to investigate the function of alk-SMase. Using RNA-seq data, we discovered 95 differentially expressed genes in the liver of wild type (WT) mice and alk-SMase (gene NPP7) knockout (KO) mice. Differentially expressed genes were functionally associated with the inflammatory response, steroid metabolic process and TNF signaling pathway related terms, regulation of carbohydrate biosynthetic process, and Cytochrome P450-arranged by substrate type using Metascape, according to the results of gene ontology functional enrichment analysis. In addition, an integrated PPI and KEGG network was used to investigate the relationship of differentially expressed genes, It was discovered that one module, which contained 21 nodes and 23 interactions, was significantly related to Cytochrome P450 family, which as mediator of phospholipase. To corroborate the RNAseq results, we identified 12 important genes with high expression levels and significant differences in RNAseq for quantitative real-time polymerase chain reaction (qPCR) verification; 7 genes showed difference significantly (P < 0.05). Our research is the first to conduct a comprehensive genome-wide analysis of the alk-SMase knockout model. Alk-SMase is involved in sphingomyelin hydrolysis. In liver tissues lacking alk-SMase expression, the expression levels of seven genes, including Cyp4a14 and Cyp4a10, were altered.