Cytotoxic property of Streptococcus mitis strain producing two different types of cholesterol-dependent cytolysins.

Streptococcus mitis strain Nm-65 secretes an atypical 5-domain-type cholesterol-dependent cytolysin (CDC) called S. mitis-derived human platelet aggregation factor (Sm-hPAF) originally described as a platelet aggregation factor. Sm-hPAF belongs to Group III CDC that recognize both membrane cholesterol and human CD59 as the receptors, and shows preferential activity towards human cells. Draft genome analyses have shown that the Nm-65 strain also harbors a gene encoding another CDC called mitilysin (MLY). This CDC belongs to Group I CDC that recognizes only membrane cholesterol as a receptor, and it is a homolog of the pneumococcal CDC, pneumolysin. The genes encoding each CDC are located about 20 kb apart on the Nm-65 genome. Analysis of the genomic locus of these CDC-encoding genes in silico showed that the gene encoding Sm-hPAF and the region including the gene encoding MLY were both inserted into a specific locus of the S. mitis genome. The results obtained using deletion mutants of the gene(s) encoding CDC in Nm-65 indicated that each CDC contributes to both hemolysis and cytotoxicity, and that MLY is the major hemolysin/cytolysin in Nm-65. The present study aimed to determine the potential pathogenicity of an S. mitis strain that produces two CDC with different receptor recognition properties and secretion modes.

Differential mobility separation of leukotrienes and protectins.

Differential mobility spectrometry (DMS) is capable of separating stereoisomeric molecular ions based on their mobility in an oscillating electrical field with an asymmetric waveform. Thus, it is an "orthogonal" technique to chromatography and (tandem) mass spectrometry. Bioactive lipids, particularly of the eicosanoid and docosanoid class feature numerous stereoisomers, which exhibit a highly specific structure-activity relationship. Moreover, the geometry of these compounds also reflects their biochemical origin. Therefore, the unambiguous characterization of related isomers of the eicosanoid and docosanoid classes is of fundamental importance to the understanding of their origin and function in many biological processes. Here we show, that SelexION DMS technology coupled to µLC-MS/MS is capable of differentiating at least five closely related leukotrienes partially coeluting and (almost) unresolvable using LC-MS/MS only. We applied the developed method to the separation of LTB4 and its coeluting isomer 5S,12S-diHETE in murine peritoneal exudate cells, showing that LTB4 is present only after zymosan A injection while its isomer 5S,12S-diHETE is produced after saline (PBS) administration. Additionally, we show that the SelexION technology can also be applied to the separation of PD1 and PDX (10S,17S-diHDHA), two isomeric protectins.

Gecko CD59 is implicated in proximodistal identity during tail regeneration.

Several adult reptiles, such as Gekko japonicus, have the ability to precisely re-create a missing tail after amputation. To ascertain the associated acquisition of positional information from blastemal cells and the underlying molecular mechanism of tail regeneration, a candidate molecule CD59 was isolated from gecko. CD59 transcripts displayed a graded expression in the adult gecko spinal cord with the highest level in the anterior segment, with a stable expression along the normal tail. After tail amputation, CD59 transcripts in the spinal cord proximal to the injury sites increased markedly at 1 day and 2 weeks; whereas in the regenerating blastema, strong CD59 positive signals were detected in the blastemal cells anterior to the blastema, with a gradual decrease along the proximodistal (PD) axis. When treated with RA following amputation, CD59 transcripts in the blastema were up-regulated. PD confrontation assays revealed that the proximal blastema engulfed the distal one after in vitro culture, and rabbit-anti human CD59 antibody was able to block this PD engulfment. Overexpression of the CD59 during tail regeneration causes distal blastemal cells to translocate to a more proximal location. Our results suggest that position identity is not restricted to amphibian limb regeneration, but has already been established in tail blastema of reptiles. The CD59, a cell surface molecule, acted as a determinant of proximal-distal cell identity.

[Clone, prokaryotic expression and preparation of polyclonal antibody of hCD59].

AIM: To construct full length hCD59 eukaryotic and extracellular domain of hCD59 (hsCD59)prokaryotic expression vectors and prepare polyclonal antibody of hCD59. METHODS: cDNA fragments encoding hCD59 and hsCD59 were amplified from human PBMCs by RT-PCR and cloned into the eukaryotic vector pVAX-1 and prokaryotic vector pGEX-KG, respectively. The recombinant fusion protein GST-hsCD59 was expressed in E.coil BL21 induced by IPTG. Then the fusion protein was purified and identified. Polyclonal antibody against hCD59 was prepared by immunizing rabbit with pVAX-1-hCD59 and boosting with GST-hsCD59 fusion protein, and the titer was identified. RESULTS: The recombinant eukaryotic vector pVAX-1-hCD59 and prokaryotic vector pGEX-KG-hsCD59 were successfully constructed. The GST-hsCD59 fusion protein was over-expressed in E.coli BL21 and the relative molecular mass (M(r)) of the expression product was identical with predicted size. The titer of the anti-hCD59 serum was 1:3 200. CONCLUSION: We got the recombinant eukaryotic vector pVAX-1-hCD59, prokaryotic vector pGEX-KG-hsCD59 and rabbit anti-hCD59 polyclonal antibody successfully.These work would be helpful for the further study of the biological function of human CD59.

The ceramide structure of GM1 ganglioside differently affects its recovery in low-density membrane fractions prepared from HL-60 cells with or without triton-X100.

Gangliosides are characteristically enriched in various membrane domains that can be isolated as low density membrane fraction insoluble in detergents (detergent-resistant membranes, DRMs) or obtained after homogenization and sonication in 0.5 M sodium carbonate (low-density membranes, LDMs). We assessed the effect of the ceramide structure of four [(3)H]-labeled GM1 ganglioside molecular species (GM1s) taken up by HL-60 cells on their occurrence in LDMs, and compared it with our previous observations for DRMs. All GM1s contained C18 sphingosine, which was acetylated in GM1(18:1/2) or acylated with C(14), C(18) or C(18:1) fatty acids (Fas).

Ly-6 superfamily members Ly-6A/E, Ly-6C, and Ly-6I recognize two potential ligands expressed by B lymphocytes.

Most hemopoietic cells express one or more members of the Ly-6 supergene family of small glycosylphosphatidylinositol-linked proteins. Although levels of Ly-6 proteins vary with stages of differentiation and activation, their function largely remains unknown. To ascertain whether ligands for Ly-6 proteins exist, chimeric proteins were constructed in which Ly-6E, Ly-6C, and Ly-6I were fused to the murine IgM heavy chain. These chimeras specifically stained both developing and mature B lymphocytes, as assessed by flow cytometry. Analysis of variants of the CH27 B cell lymphoma revealed that Ly-6A/E and Ly-6I recognized different molecules. CH27 cells with low levels of Ly-6A/E ligand activity also lost expression of CD22, and cells transfected with CD22 gained the ability to bind the Ly-6A/E chimera and, to a lesser extent, the Ly-6C and Ly-6I chimeric proteins. As many mature B cells coexpress Ly-6A/E and CD22, the function of Ly-6 molecules may be to associate with other membrane proteins, possibly concentrating these ligands in lipid rafts, rather than acting directly as cell:cell adhesion molecules.

Isolation and functional assay of the membrane complement inhibitors CD55 (DAF) and CD59 (MIRL).

The complement system is the primary effector of humoral immunity. Because of its enormous destructive capacity, mechanisms for confining the activity of the system to the desired target and elaborate safeguards for protecting self against complement-mediated injury have evolved. Human cells, particularly those found at sites of inflammation (e.g., hematopoietic and endothelial cells), express highly specialized membrane constituents that act independently or in concert with plasma regulatory proteins to inhibit the functional activity of complement. Decay-accelerating factor (DAF), or CD55, directly inhibits the formation and stability of the amplification C3 and C5 convertases of both the classical and the alternative pathways. Failure of a cell to regulate the amplification C3 and C5 convertases allows the generation of the potentially cytolytic membrane attack complex (MAC), or C5b-9 (consisting of the complement components C5b, C6, C7, C8, and C9). The primary cellular regulator of the MAC is the membrane inhibitor of reactive lysis (MIRL), or CD59, which restricts complement-mediated lysis by blocking assembly of the MAC (primarily at the stage of C9 binding and polymerization). This unit provides a basic protocol for isolating CD55 and CD59, along with two support protocols describing separate functional assays for CD59 and CD55.

Production and functional characterization of a soluble recombinant form of mouse CD59.

This report describes the engineering, expression, purification and functional characterization of a soluble recombinant form of murine CD59 (srMoCD59). We report the expression in Chinese hamster ovary (CHO) cells of a modified mouse CD59 cDNA that had been truncated at D-74, resulting in the loss of the glycosylphosphatidyl inositol (GPI) anchor, and containing six additional C-terminal histidines. The expressed srMoCD59 was purified from tissue culture supernatant by means of its poly-histidine tag using immobilized metal affinity chromatography. In comparison with CD59 on mouse erythrocytes, the srMoCD59 had a reduced molecular weight (18-20 000 as compared with 20-28 000 for GPI-anchored srMoCD59). The terminal complement inhibitory capacity of this soluble recombinant protein was assessed using two methods: a cobra venom factor (CVF)-triggered 'reactive-lysis' system and a C5b-7 site assay. In both assays, srMoCD59 inhibited lysis by the sera from all three species tested in the rank order mouse > rat >> human. The amount of srMoCD59 required to produce 50% inhibition of lysis in the C5b-7 site assay, using purified terminal components to develop lysis, was 10-fold less than that required in the same assay when EDTA serum was used as a source of C8 and C9, or in the CVF reactive lysis system. These data indicate that the presence of serum markedly interfered with the activity of srMoCD59 and have important implications for the use of recombinant soluble CD59 analogues as therapeutic agents in complement-mediated diseases.

Determination of the non-ionic detergent insolubility and phosphoprotein associations of glycosylphosphatidylinositol-anchored proteins expressed on T cells.

Glycosylphosphatidylinositol (GPI)-anchored proteins are poorly solublized in non-ionic detergents such as Triton X-100 and Nonidet P40, but are easily solublized by detergents with high critical micelle concentrations such as octylglucoside. This solubility profile has been suggested to be due to the localization of GPI-anchored proteins to lipid microdomains rich in cholesterol and sphingolipids. Additionally, GPI-anchored proteins expressed on haemopoietic cells have been shown to associate with src-family tyrosine kinases and heterotrimeric G proteins. Despite these observations, the non-ionic detergent insolubility of GPI-anchored proteins on haemopoietic cells has not been quantified nor has a relationship between the non-ionic detergent insolubility of these proteins and their association with signal-transduction molecules been identified. Here we show that GPI-anchored proteins found on T-cell tumours and activated T cells, although significantly more insoluble then transmembrane proteins, are not uniform in their detergent insolubility. Whereas CD59 was between 4% and 13% soluble, CD48 was between 13% and 25% soluble, CD55 was between 20% and 30% soluble, and CD109 was between 34% and 75% soluble. The ability of these GPI-anchored proteins to associate with phosphoproteins was correlated with their detergent insolubility: the more detergent-insoluble that a GPI-anchored protein was, the greater the level of phosphoprotein associations. These experiments reveal a relationship between non-ionic detergent insolubility and association with signal-transduction molecules and suggest a cause-and-effect relationship between these two properties. In total, these experiments support the hypothesis that the association of GPI-anchored proteins with signalling molecules is due to their sorting to lipid microdomains.

Molecular cloning, chromosomal localization, expression, and functional characterization of the mouse analogue of human CD59.

We have previously described the isolation and cloning of the rat analogue of the human complement inhibitor CD59 (hCD59). Using the rat CD59 (rCD59) coding region as probe, we have isolated positive cDNAs from a mouse kidney cDNA library. Sequence analysis of these clones indicated that they contained an open reading frame encoding a 124 amino acid protein. Comparisons with the known sequences of hCD59 and rCD59 suggested that the clones contained a full-length cDNA encoding the mouse analogue of CD59 (mCD59). The cDNA encoded a 81-bp 5'-flanking region, a 23 amino acid NH2-signal peptide, a 101 amino acid coding region including putative N-glycosylation sites and a glycosyl phosphatidylinositol (GPI) anchoring signal, and approximately 0.8 kb 3'-untranslated flanking region. Reverse transcriptase PCR revealed the presence of mCD59 mRNA in all mouse tissues examined. The gene for mCD59 was mapped by fluorescence in situ hybridization to the E2-E4 region of mouse chromosome 2, a region that includes areas syntenous with the location of the human CD59 gene on chromosome 11p13. Expression of mCD59 in a CD59-negative human cell line conferred protection against lysis by complement from rodent, human, and several other species, confirming that mCD59 was the functional analogue of hCD59 and that function was not species restricted. The expressed protein was glycosyl phosphatidylinositol anchored as demonstrated by its partial removal from U937 cells on treatment with phosphatidylinositol-specific phospholipase C. Abs raised against the expressed protein demonstrated the presence of mCD59 on all mouse blood cell types and on several mouse cell lines and neutralized function of mCD59 on mouse E and expressed on U937. Western blot analysis revealed that both expressed and endogenous mCD59 had a molecular mass of 22 to 24 kDa.

Shedding and enrichment of the glycolipid-anchored complement lysis inhibitor protectin (CD59) into milk fat globules.

Protectin (CD59) is a glycolipid-anchored inhibitor of the membrane attack complex (MAC) of human complement (C) that protects blood cells, endothelial cells and various epithelial cells from C-mediated lysis. Because of its activities protectin is a candidate molecule for use in the treatment of paroxysmal nocturnal haemoglobinuria or conditions where MAC causes tissue damage. Soluble, phospholipid-free forms of protectin have been isolated from human urine and produced in recombinant form, but they have only a relatively weak C lysis-inhibiting activity. In the present study we have looked for functionally active protectin in human breast milk. Milk is rich in fat droplets, milk fat globules (MFG), that are enveloped in a plasma membrane derived from secretory cells of the mammary gland. The membranes of MFG contain a variety of glycoproteins expressed by the mammary epithelial cells. Both immunofluorescence and immunoblotting analysis demonstrated that protectin was strongly expressed on human MFG. In sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis, MFG protectin (CD59M) appeared as distinct bands with apparent molecular weights of 19,000-23,000 MW, similar to protectin extracted from MCF7 breast carcinoma cells. CD59M in breast milk was functionally active and had a glycophospholipid anchor, as judged by its ability to incorporate into guinea-pig erythrocytes and inhibit their lysis by human complement. These results indicate that functionally active protectin becomes enriched in MFG and imply that secretion of glycophospholipid-anchored molecules, e.g. into cow milk and colostrum, could be exploited as a means of producing bioactive molecules that need to be targeted into cell membranes.