Structure-dependent pseudoreceptor intracellular traffic of adamantyl globotriaosyl ceramide mimics

The verotoxin (VT) (Shiga toxin) receptor globotriaosyl ceramide (Gb(3)), mediates VT1/VT2 retrograde transport to the endoplasmic reticulum (ER) for cytosolic A subunit access to inhibit protein synthesis. Adamantyl Gb(3) is an amphipathic competitive inhibitor of VT1/VT2 Gb(3) binding. However, Gb(3)-negative VT-resistant CHO/Jurkat cells incorporate adaGb(3) to become VT1/VT2-sensitive. CarboxyadaGb(3), urea-adaGb(3), and hydroxyethyl adaGb(3), preferentially bound by VT2, also mediate VT1/VT2 cytotoxicity. VT1/VT2 internalize to early endosomes but not to Golgi/ER. AdabisGb(3) (two deacyl Gb(3)s linked to adamantane) protects against VT1/VT2 more effectively than adaGb(3) without incorporating into Gb(3)-negative cells. AdaGb(3) (but not hydroxyethyl adaGb(3)) incorporation into Gb(3)-positive Vero cells rendered punctate cell surface VT1/VT2 binding uniform and subverted subsequent Gb(3)-dependent retrograde transport to Golgi/ER to render cytotoxicity (reduced for VT1 but not VT2) brefeldin A-resistant. VT2-induced vacuolation was maintained in adaGb(3)-treated Vero cells, but vacuolar membrane VT2 was lost. AdaGb(3) destabilized membrane cholesterol and reduced Gb(3) cholesterol stabilization in phospholipid liposomes. Cholera toxin GM1-mediated Golgi/ER targeting was unaffected by adaGb(3). We demonstrate the novel, lipid-dependent, pseudoreceptor function of Gb(3) mimics and their structure-dependent modulation of endogenous intracellular Gb(3) vesicular traffic.     

Intracellular targeting of the endoplasmic reticulum/nuclear envelope by retrograde transport may determine cell hypersensitivity to verotoxin via globotriaosyl ceramide fatty acid isoform traffic

The pentameric B subunit of verotoxin (VT) mediates the attachment to cell surface globotriaosyl ceramide (Gb3) to facilitate receptor-mediated endocytosis of the toxin. In highly toxin-sensitive tumor cells, the holotoxin and VT1 B subunit is targeted intracellularly to elements of the endoplasmic reticulum (ER)/nuclear membrane. In less sensitive cells, the toxin is targeted to components of the Golgi apparatus. We have studied two cell systems: the induced VT hypersensitivity of human astrocytoma cell lines cultured in the presence of sodium butyrate (compared to sodium propionate and capronate) and the increased VT sensitivity of multiple drug-resistant mutants as compared to parental human ovarian carcinoma cells. In both cases, a difference in the intracellular retrograde transport of the receptor-bound internalized toxin to the ER/nuclear envelope, as opposed to the Golgi, correlated with a >1,000-fold increase in cell sensitivity to VT. This change in intracellular routing may be due to sorting of Gb3 fatty acid isoforms, since nuclear targeting was found in turn to correlate with the preferential synthesis of Gb3 containing shorter chain (primarily C16) fatty acid species. We propose that the isoform-dependent traffic of Gb3 from the cell surface to the ER/nuclear membrane provides a new signal transduction pathway for Gb3 binding proteins.     

Fatty acid-dependent globotriaosyl ceramide receptor function in detergent resistant model membranes

Glycosphingolipid (GSL) fatty acid strictly regulates verotoxin 1 (VT1) and the HIV adhesin, gp120 binding to globotriaosyl ceramide within Gb(3)/cholesterol detergent resistant membrane (DRM) vesicle constructs and in Gb(3) water-air interface monolayers in a similar manner. VT2 bound Gb(3)/cholesterol vesicles irrespective of fatty acid composition, but VT1 bound neither C18 nor C20Gb(3)vesicles. C18/C20Gb(3) were dominant negative in mixed Gb(3) fatty acid isoform vesicles, but including C24:1Gb(3) gave maximal binding. VT1 bound C18Gb(3) vesicles after cholesterol removal, but C20Gb(3)vesicles required sphingomyelin in addition for binding. HIV-1gp120 also bound C16, C22, and C24, but neither C18 nor C20Gb(3) vesicles. C18 and C20Gb(3) were, in mixtures without C24:1Gb(3), dominant negative for gp120 vesicle binding. Gp120/VT1bound C18 and C24:1Gb(3) mixtures, although neither isoform bound alone. Monolayer surface pressure measurement showed VT1, but not VT2, bound Gb(3) at cellular DRM surface pressures, and confirmed loss of VT1 and gp120 (but not VT2) specific C18Gb(3) binding. We conclude fatty-acid mediated fluidity within simple model GSL/cholesterol DRM can selectively regulate GSL carbohydrate-ligand binding.     

Brefeldin A and filipin distinguish two globotriaosyl ceramide/verotoxin-1 intracellular trafficking pathways involved in Vero cell cytotoxicity

In verotoxin 1 (VT1)-sensitive cells, globotriaosyl ceramide (Gb3) bound VT1 is endocytosed and transported retrogradely to the Golgi/endoplasmic reticulum (ER). The importance of the Golgi-dependent retrograde transport of VT1 is now shown to vary as a function of both VT1 exposure time and concentration. Following 3 h exposure to < 50 ng/ml VT1, Vero cell cytotoxicity and protein synthesis inhibition is absolutely dependent on intact Golgi structure. However, after 24 h incubation with concentrations of VT1 above 50 ng/ml, a filipin-sensitive (caveolae-dependent) route for cytotoxicity becomes significant. Brefeldin A (BFA), which prevents Golgi-dependent retrograde traffic, protects cells from low VT1 concentrations but not following prolonged toxin exposure at higher VT1 concentrations. Under these conditions, only a combination of BFA and filipin is sufficient to fully protect cells. Intracellular VT1 trafficking monitored using the nontoxic B subunit showed accumulation within BFA-collapsed TGN/endosomes. Considerable VT1 B was retained at the surface of filipin-treated cells, but Golgi targeting was still apparent. Filipin-sensitive VT1 cytotoxicity does not require Golgi access and may involve direct transmembrane signaling. Although cell surface VT1 does not colocalize with caveolin 1, a small fraction of endocytosed VT1 is found within caveolin 1-containing vesicles. These studies indicate both a caveolae-dependent and independent pathway for VT1 access to the TGN/Golgi from the cell surface and two noninterconverting pools of membrane Gb3.     

Apparent cooperativity in multivalent verotoxin-globotriaosyl ceramide binding: kinetic and saturation binding studies with [(125)I]verotoxin

Verotoxin (VT) binding to the trisaccharide portion of globotriaosyl ceramide (Gb(3)) is believed to be a crucial step in the development of hemolytic uremic syndrome (HUS) commonly known as 'Hamburger disease'. This interaction is the initial step in the binding process and defines the specificity of verotoxin binding to cellular membranes. Although molecular modeling, co-crystallization and co-NMR studies with VT and the trisaccharide moiety of Gb(3) have indicated potential multiple sites for Gb(3) binding, little is known about their direct effects on kinetic and equilibrium binding. Here we describe how the binding of radiolabeled VT ([(125)I]VT1) to Gb(3) in a microtiter well format, is driven by two different association rate constants (k(+1a)=0.0075 and k(+1b)=0.275 min(-1) nM(-1)) with the high affinity site representing 15% of the total specific binding sites. Binding was reversible at room temperature, reached equilibrium after 2-3 h, and non-specific binding was less than 5%. Equilibrium binding studies defined by [(125)I]VT1 saturation binding to 15, 30, 60 and 120 ng Gb(3)/well, showed the presence of a single site with dissociation constants (K(d)s) ranging between 0.5 and 3 nM. However, the maximum density of specific [(125)I]VT1 binding sites (B(max)) did not directly correlate with the Gb(3) concentration per well: the most[(125)I]VT1 binding was observed for 60 ng Gb(3) (B(max)=1.28 nM; compared to 0. 23 nM for 30 ng Gb(3) and 0.65 nM for 120 ng Gb(3)). Furthermore, while Hill coefficients (n(H)) for 15, 30 and 120 ng Gb(3) were close to unity indicating single interactions, for the saturation isotherm for 60 ng Gb(3)/well n(H) was 1.4. Subsequent Scatchard analysis yielded a concave downward curve for [(125)I]VT1 binding to 60 ng Gb(3)/well, suggesting positive co-operativity. We present, for the first time, conclusive binding data confirming the presence of at least two discrete Gb(3) binding sites: these multivalent interactions between verotoxin VT-1 and Gb(3) were described by association reactions driven by two distinct rate constants, as well as by the positive co-operativity governing binding at a restricted receptor concentration. These results imply that the concentration of Gb(3) on the surface of target cells can have a complex, non-linear effect on verotoxin binding and thereby, on sensitivity to cytotoxicity.     

A verotoxin 1 B subunit-lambda CRO chimeric protein specifically binds both DNA and globotriaosylceramide (Gb(3)) to effect nuclear targeting of exogenous DNA in Gb(3) positive cells

Inefficient nuclear incorporation of foreign DNA remains a critical roadblock in the development of effective nonviral gene delivery systems. DNA delivered by traditional protocols remains within endosomal/lysosomal vesicles, or is rapidly degraded in the cytoplasm. Verotoxin I (VT), an AB(5) subunit toxin produced by enterohaemorrhagic Escherichia coli, binds to the cell surface glycolipid, globotriaosylceramide (Gb(3)) and is internalized into preendosomes. VT is then retrograde transported to the Golgi, endoplasmic reticulum (ER), and nucleus of highly VT-sensitive cells. We have utilized this nuclear targeting of VT to design a unique delivery system which transports exogenous DNA via vesicular traffic to the nucleus. The nontoxic VT binding subunit (VTB) was fused to the lambda Cro DNA-binding repressor, generating a 14-kDa VTB-Cro chimera. VTB-Cro binds specifically via the Cro domain to a 25-bp DNA fragment containing the consensus Cro operator. VTB-Cro demonstrates simultaneous specific binding to Gb(3). Treatment of Vero cells with fluorescent-labeled Cro operator DNA in the presence of VTB-Cro, results in DNA internalization to the Golgi, ER, and nucleus, whereas fluorescent DNA alone is incorporated poorly and randomly within the cytoplasm. VTB-Cro mediated nuclear DNA transport is prevented by brefeldin A, consistent with Golgi/ER intracellular routing. Pretreatment with filipin had no effect, indicating that caveoli are not involved. This novel VTB-Cro shuttle protein may find practical applications in the fields of intracellular targeting, gene delivery, and gene therapy.     

A mutational analysis of the globotriaosylceramide-binding sites of verotoxin VT1.

Escherichia coli verotoxin, also known as Shiga-like toxin, binds to eukaryotic cell membranes via the glycolipid Gb(3) receptors which present the P(k) trisaccharide Galalpha(1-4)Galbeta(1-4)Glcbeta. Crystallographic studies have identified three P(k) trisaccharide (P(k)-glycoside) binding sites per verotoxin 1B subunit (VT1B) monomer while NMR studies have identified binding of P(k)-glycoside only at site 2. To understand the basis for this difference, we studied binding of wild type VT1B and VT1B mutants, defective at one or more of the three sites, to P(k)-glycoside and pentavalent P(k) trisaccharide (pentaSTARFISH) in solution and Gb(3) presented on liposomal membranes using surface plasmon resonance. Site 2 was the key site in terms of free trisaccharide binding since mutants altered at sites 1 and 3 bound this ligand with wild type affinity. However, effective binding of the pentaSTARFISH molecule also required a functional site 3, suggesting that site 3 promotes pentavalent binding of linked trisaccharides at site 1 and site 2. Optimal binding to membrane-associated Gb(3) involved all three sites. Binding of all single site mutants to liposomal Gb(3) was weaker than wild type VT1B binding. Site 3 mutants behaved as if they had reduced ability to enter into high avidity interactions with Gb(3) in the membrane context. Double mutants at site 1/site 3 and site 2/site 3 were completely inactive in terms of binding to liposomal Gb(3,) even though the site 1/site 3 mutant bound trisaccharide with almost wild type affinity. Thus site 2 alone is not sufficient to confer high avidity binding to membrane-localized Gb(3). Cytotoxic activity paralleled membrane glycolipid binding. Our data show that the interaction of verotoxin with the Gb(3) trisaccharide is highly context dependent and that a membrane environment is required for biologically relevant studies of the interaction.     

Generation of receptor-active, globotriaosyl ceramide/cholesterol lipid 'rafts' in vitro : A new assay to define factors affecting glycosphingolipid receptor activity

Purified renal globotriaosyl ceramide (Gb3)/cholesterol mixtures sonicated heated in a Triton-containing buffer placed below a discontinuous sucrose gradient form glycosphingolipid (GSL)-containing dense lipid structures at the 30/5% sucrose interface after centrifugation. Inclusion of fluorescein-labeled verotoxin 1 B subunit (FITC-VT1 B) within the most dense sucrose layer results in the fluorescent labeling of this Gb3-containing raft structure. Alternatively inclusion of I-labeled VT1 fractionation allows quantitation of binding. FITC-VT1 B effectively competes for I-VT1/Gb3 raft binding. This assay will allow the definition of the optimal raft composition for VT1 (or any other ligand) binding. The effect of several potential cellular raft components are reported. Increased cholesterol content increased VT1 binding. Addition of phosphatidylethanolamine had minimal effect while phosphatidylserine was inhibitory. Although inclusion of sphingomyelin increased the Gb3 content of the "raft" reduced VT1 binding was seen. Inclusion of other glycolipids can also be inhibitory. The addition of globotetraosyl ceramide had no effect; however addition of sulfogalactosyl ceramide but not sulfogalactoglycerolipid inhibited VT1/Gb3 raft binding. These results suggest that certain GSLs can disfavor the formation of the appropriate 'raft' structure for ligand binding that this is dependent on both their carbohydrate lipid structure. Such "deceptor" GSLs may provide an as yet unappreciated mechanism for the regulation of cellular GSL receptor activity. This model is an effective tool to approach the dynamics ligand-binding specificity of GSL/cholesterol-containing lipid microdomains.     

Susceptibility to verotoxin as a function of the cell cycle.

Infection with Verotoxin producing Escherichia coli (VTEC) has been implicated in hemolytic uremic syndrome, the leading cause of pediatric renal failure. Verotoxin (VT) binds to globotriaosylceramide (Gal alpha 1-4Gal beta 1-4GlcCer Gb3) in susceptible cells. Gb3 is required for cytotoxicity and toxin-resistant cells deficient in Gb3 can be sensitized to VT cytotoxicity by incorporation of exogenous Gb3 into the cells. However, the absolute Gb3 content of cell lines does not necessarily correspond directly with the degree of sensitivity to VT. The present study demonstrates that susceptibility to VT is a function of cell growth and that stationary phase cells are resistant to VT. Using chemically synchronized Vero cells, we have also found a tenfold difference in susceptibility to VT during the cell cycle. Our experiments define a maximal sensitivity "window" of 1-2 hours from the G1/S boundary. This corresponds to increased VT binding without change in overall Gb3 content. Cell surface labelling indicated that cyclic turnover and exposure of Gb3 may be the critical parameter in determining VT sensitivity. Such changes during the cell cycle may also be of relevance in vivo in determining toxin pathology during VTEC infections and the physiology of plasma membrane Gb3.     

Localization of the binding site for modified Gb3 on verotoxin 1 using fluorescence analysis.

Verotoxins (VTs) from Escherichia coli elicit human vascular disease as a consequence of specific binding to globotriaosylceramide (Gb3) receptors on endothelial cell surfaces. Molecular models based on the VT1 crystal structure were used previously to investigate the structural basis for receptor recognition by VT1 and other verotoxins. Interestingly, these model-based predictions of glycolipid binding to VT1 differ somewhat from recently published structural data from cocrystals of the VT1 B-subunit (VT1B) and an analogue of the sugar moiety of Gb3. In this study, fluorescence spectroscopy was used to test model-based predictions of the location of Gb3 binding on the B-subunit pentamer of VT1. Resonance energy transfer was used to calculate the distance from a coumarin probe used to replace the acyl tail of Gb3 and the single tryptophan residue (Trp34) present within each VT1B monomer. The observed energy transfer efficiency (greater than 95%) suggests that these two moieties are approximately 13.3 A apart when a single distance is assumed. This distance is consistent with proposed models for the fit of Gb3 within the "cleft site" of the VT1 B-subunit. When the distances from Trp34 to the other coumarinGb3 molecules (bound to each of the four remaining monomers within the VT1B pentamer) are taken into consideration, it appears likely that the coumarin-modified Gb3 analogue used in this study associates with the previously proposed receptor binding site II of VT1. This is consistent with an observed binding preference of VT2c for coumarinGb3. To provide additional information on the association of Gb3 with the VT1 B-subunit, the influence of Gb3 glycolipid binding on the accessibility of Trp34 to different quenching agents in solution was then examined. Taken together, the data suggest that coumarin-labeled Gb3 preferentially binds to site II on VT1 in a position that is consistent with the previously described molecular models.     

Treatment of neutral glycosphingolipid lysosomal storage diseases via inhibition of the ABC drug transporter, MDR1. Cyclosporin A can lower serum and liver globotriaosyl ceramide levels in the Fabry mouse model

We have shown that the ABC transporter, multiple drug resistance protein 1 (MDR1, P-glycoprotein) translocates glucosyl ceramide from the cytosolic to the luminal Golgi surface for neutral, but not acidic, glycosphingolipid (GSL) synthesis. Here we show that the MDR1 inhibitor, cyclosporin A (CsA) can deplete Gaucher lymphoid cell lines of accumulated glucosyl ceramide and Fabry cell lines of globotriaosyl ceramide (Gb3), by preventing de novo synthesis. In the Fabry mouse model, Gb3 is increased in the heart, liver, spleen, brain and kidney. The lack of renal glomerular Gb3 is retained, but the number of verotoxin 1 (VT1)-staining renal tubules, and VT1 tubular targeting in vivo, is markedly increased in Fabry mice. Adult Fabry mice were treated with alpha-galactosidase (enzyme-replacement therapy, ERT) to eliminate serum Gb3 and lower Gb3 levels in some tissues. Serum Gb3 was monitored using a VT1 ELISA during a post-ERT recovery phase +/- biweekly intra peritoneal CsA. After 9 weeks, tissue Gb3 content and localization were determined using VT1/TLC overlay and histochemistry. Serum Gb3 recovered to lower levels after CsA treatment. Gb3 was undetected in wild-type liver, and the levels of Gb3 (but not gangliosides) in Fabry mouse liver were significantly depleted by CsA treatment. VT1 liver histochemistry showed Gb3 accumulated in Kupffer cells, endothelial cell subsets within the central and portal vein and within the portal triad. Hepatic venule endothelial and Kupffer cell VT1 staining was considerably reduced by in vivo CsA treatment. We conclude that MDR1 inhibition warrants consideration as a novel adjunct treatment for neutral GSL storage diseases.     

Dynamic measurement of the pH of the Golgi complex in living cells using retrograde transport of the verotoxin receptor

The B subunit of verotoxin (VT1B) from enterohemorrhagic Escherichia coli is responsible for the attachment of the holotoxin to the cell surface, by binding to the glycolipid, globotriaosyl ceramide. After receptor-mediated endocytosis, the toxin is targeted to the Golgi complex by a process of retrograde transport. We took advantage of this unique property of VT1B to measure the pH of the Golgi complex in intact live cells. Purified recombinant VT1B was labeled with either rhodamine or fluorescein for subcellular localization by confocal microscopy. After 1 h at 37 degrees C, VT1B accumulated in a juxtanuclear structure that colocalized with several Golgi markers, including alpha-mannosidase II, beta-COP, and NBD-ceramide. Moreover, colchicine and brefeldin A induced dispersal of the juxtanuclear staining, consistent with accumulation of VT1B in the Golgi complex. Imaging of the emission of fluorescein-labeled VT1B was used to measure intra-Golgi pH (pHG), which was calibrated in situ with ionophores. In intact Vero cells, pHG averaged 6.45 +/- 0.03 (standard error). The acidity of the Golgi lumen dissipated rapidly upon addition of bafilomycin A1, a blocker of vacuolar-type ATPases, pHG remained constant despite acidification of the cytosol by reversal of the plasmalemmal Na+/H+ antiport. Similarly, pHG was unaffected by acute changes in cytosolic calcium. Furthermore, pHG recovered quickly toward the basal level after departures imposed with weak bases. These findings suggest that pHG is actively regulated, despite the presence of a sizable H+ "leak" pathway. The ability of VT1B to target the Golgi complex should facilitate not only studies of acid-base regulation, but also analysis of other ionic species.     

Glycosphingolipid Requirements for Endosome-to-Golgi Transport of Shiga Toxin

Shiga toxin binds to globotriaosylceramide (Gb3) receptors on the target cell surface. To enter the cytosol, Shiga toxin is dependent on endocytic uptake, retrograde transport to the Golgi apparatus and further to the endoplasmic reticulum before translocation of the enzymatically active moiety to the cytosol. Here, we have investigated the importance of newly synthesized glycosphingolipids for the uptake and intracellular transport of Shiga toxin in HEp-2 cells. Inhibition of glycosphingolipid synthesis by treatment with either PDMP or Fumonisin B₁ for 24–48 h strongly reduced the transport of Gb3-bound Shiga toxin from endosomes to the Golgi apparatus. This was associated with a change in localization of sorting nexins 1 and 2, and accompanied by a protection against the toxin. In contrast, there was no effect on transport or toxicity of the plant toxin ricin. High-resolution mass spectrometry revealed a 2-fold reduction in Gb3 at conditions giving a 10-fold inhibition of Shiga toxin transport to the Golgi. Furthermore, mass spectrometry showed that the treatment with PDMP (DL-threo-1-phenyl-2-decanoylamino-3-morpholino-1-propanol) and Fumonisin B₁ among other changes of the lipidome, affected the relative content of the different glycosphingolipid species. The largest depletion was observed for the hexosylceramide species with the N -amidated fatty acid 16:0, whereas hexosylceramide species with 24:1 were less affected. Quantitative lipid profiling with mass spectrometry demonstrated that PDMP did not influence the content of sphingomyelins, phospholipids and plasmalogens. In contrast, Fumonisin B₁ affected the amount and composition of sphingomyelin and glycolipids and altered the profiles of phospholipids and plasmalogens.     

Cross-protection against challenge by intravenous Escherichia coli verocytotoxin 1 (VT1) in rabbits immunized with VT2 toxoid

Rabbits challenged intravenously with Escherichia coli verocytotoxin (VT1, Shiga toxin 1, Stx1) die after developing diarrhea and paralysis, and this outcome can be prevented by pre-immunization with VT1 toxoid. In nonimmune rabbits, intravenously administered 125I-VT1 binds to the central nervous system and gastrointestinal tract, whereas in immunized animals, these organs are spared and the toxin localizes in the liver and spleen. In rabbits immunized with either VT1 or VT2 toxoids, both the homologous or heterologous toxins are prevented from binding to target organs. This has lead to the advancement of a hypothesis that cross-protection in vivo can be induced to both toxins by immunization with a toxoid even though these toxins do not exhibit cross-neutralization in vitro. It was shown that rabbits immunized with VT2 were fully protected from the intravenous administration of 10 LD50 and 50 LD50 of VT1, and this correlated directly with the protection from binding of this toxin to target organs. These findings have important implications on the design of the vaccination strategies to prevent human VT-mediated diseases and also validate the concept of testing for immunity to VT by monitoring the inhibition of binding of the 125I-VT to target organs in preference to performing LD50 assays.     

Polyisobutylmethacrylate modifies glycolipid binding specificity of verotoxin 1 in thin-layer chromatogram overlay procedures.

Verotoxins (or Shiga-like toxins) are a family of closely related toxins elaborated by Escherichia coli. At least three toxins have been described, VT1, VT2, and SLTII, in addition to Shiga toxin itself, and all bind to globotriaosyl ceramide, Gb3. Some discrepancies exist in the literature regarding the binding of the toxins to Gb4 as monitored by TLC overlay procedures. These procedures are widely used to investigate the specificity of carbohydrate-binding ligands. Polyisobutylmethacrylate, PIBM, is generally used in TLC overlay procedures to prevent silica loss and orient carbohydrate moieties for the binding of various ligands to glycolipids. We now report that pretreatment of chromatograms with PIBM modifies binding of VT1 to include Gb4 and decreases binding to Gb3 and the P1 glycolipid. We suggest that PIBM can alter the conformation of the glycolipid oligosaccharide, and therefore caution is advised in analysis of ligand binding to glycolipids after treatment with this compound.     

Generation of receptor-active, globotriaosyl ceramide/cholesterol lipid 'rafts' in vitro: A new assay to define factors affecting glycosphingolipid receptor activity

Purified renal globotriaosyl ceramide (Gb₃)/cholesterol mixtures, sonicated and heated in a Triton-containing buffer and placed below a discontinuous sucrose gradient, form glycosphingolipid (GSL)-containing dense lipid structures at the 30/5% sucrose interface after centrifugation. Inclusion of fluorescein-labeled verotoxin 1 B subunit (FITC-VT1 B) within the most dense sucrose layer results in the fluorescent labeling of this Gb₃-containing raft structure. Alternatively, inclusion of ¹²⁵I-labeled VT1 and fractionation allows quantitation of binding. FITC-VT1 B effectively competes for ¹²⁵I-VT1/Gb₃ raft binding. This assay will allow the definition of the optimal raft composition for VT1 (or any other ligand) binding. The effect of several potential cellular raft components are reported. Increased cholesterol content increased VT1 binding. Addition of phosphatidylethanolamine had minimal effect while phosphatidylserine was inhibitory. Although inclusion of sphingomyelin increased the Gb₃ content of the 'raft', reduced VT1 binding was seen. Inclusion of other glycolipids can also be inhibitory. The addition of globotetraosyl ceramide had no effect; however, addition of sulfogalactosyl ceramide, but not sulfogalactoglycerolipid, inhibited VT1/Gb₃ raft binding. These results suggest that certain GSLs can disfavour the formation of the appropriate 'raft' structure for ligand binding and that this is dependent on both their carbohydrate and lipid structure. Such “deceptor” GSLs may provide an as yet, unappreciated mechanism for the regulation of cellular GSL receptor activity. This model is an effective tool to approach the dynamics and ligand-binding specificity of GSL/cholesterol-containing lipid microdomains. Published in 2004. This revised version was published online in August 2006 with corrections to the Cover Date.     

Two distinct Gb3/CD77 signaling pathways leading to apoptosis are triggered by anti-Gb3/CD77 mAb and verotoxin-1

Globotriasosylceramide (Gb3), a neutral glycosphingolipid, is the B-cell differentiation antigen CD77 and acts as the receptor for most Shiga toxins, including verotoxin-1 (VT-1). We have shown that both anti-Gb3/CD77 mAb and VT-1 induce apoptosis in Burkitt's lymphoma cells. We compared the apoptotic pathways induced by these two molecules by selecting cell lines sensitive to only one of these inducers or to both. In all these cell lines (including the apoptosis-resistant line), VT-1 was transported to the endoplasmic reticulum and inhibited protein synthesis similarly, suggesting that VT-1-induced apoptosis is dissociated from these processes. VT-1 triggered a caspase- and mitochondria-dependent pathway (rapid activation of caspases 8 and 3 associated with a loss of mitochondrial membrane potential (Deltapsim) and the release of cytochrome c from mitochondria). In contrast, the anti-Gb3/CD77 mAb-induced pathway was caspase-independent and only involved partial depolarization of mitochondria. Antioxidant compounds had only marginal effects on VT-1-induced apoptosis but strongly protected cells from anti-Gb3/CD77 mAb-induced apoptosis. VT-1- and anti-Gb3/CD77 mAb-treated cells displayed very different features on electron microscopy. These results clearly indicate that the binding of different ligands to Gb3/CD77 triggers completely different apoptotic pathways.     

Adamantyl globotriaosyl ceramide: a monovalent soluble mimic which inhibits verotoxin binding to its glycolipid receptor

The globotriaosylceramide (Gb3) verotoxin (VT) interaction is one of several examples of glycolipid receptors where the ceramide (or lipid) free oligosaccharides fail to show the expected binding parameters. We present a novel, yet simple strategy to synthesize monovalent, water soluble glycosphingolipid mimics which retain receptor function. Replacing the fatty acid chain with rigid, three dimensional hydrocarbon frames, such as adamantane, gives a novel class of neohydrocarbon glycoconjugates. Such adamantyl conjugates derived from Gb3 showed significantly enhanced solubility in water compared to natural Gb3. Adamantyl-Gb3 showed a thousand fold enhanced inhibitory activity (IC50 = 1 microM) for VT-Gb3 binding as compared to a lipid free Gb3 oligosaccharide derivative, alphaGal1-4betaGal1-4betaGlc1-O-CH2CH(CH2SO2C 4H9)2 (IC50 > 2 mM). This represents a new approach to the generation of antagonists of glycolipid receptors.     

Interactions of high density lipoprotein subclasses (HDL2 and HDLc) with dog adipocytes: selective effects of cholesterol and saturated fat feeding

Adipose tissue is a cholesterol storage organ and derives its cholesterol primarily from circulating lipoproteins. The present study shows that adipocytes isolated from canine omental fat tissue interact specifically with high density lipoprotein subfractions lacking or enriched in apolipoprotein E, namely canine high density lipoprotein-2 (HDL2) and HDLc, respectively. While 125I-labeled HDL2 binding was inhibited similarly by both excess unlabeled HDLc and HDL2, 125I-labeled HDLc interaction was inhibited by its homologous ligand only. Paired studies showed that the amount of HDLc associated with adipocytes was significantly higher compared to HDL2. The effect of a short-term cholesterol and saturated fat feeding on adipocyte-HDL interaction was examined using fat cells obtained from dogs before and again 3 weeks after a diet supplemented with cholesterol (1% w/w) and saturated fat (30% lard, w/w). Significant increases in body weight and omental fat cell weight occurred after fat feeding. The amount of 125I-labeled HDL2 that could be bound to adipocytes increased after the diet, whether expressed on a per cell basis (P less than 0.005) or per unit cell surface (P less than 0.025). The amount of cell-associated 125I-labeled HDLc, however, was not significantly affected by the cholesterol-rich diet. The characteristics of HDLc and HDL2 dissociation were assessed by examining the release of labeled lipoproteins from adipocytes preincubated with 125I-labeled HDLc and 125I-labeled HDL2. HDL2 dissociation from adipocytes was significantly decreased (P less than 0.05) following the diet and may explain in part the apparent increase in cell-associated 125I-labeled HDL2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Retroviral transfection of Madin-Darby canine kidney cells with human MDR1 results in a major increase in globotriaosylceramide and 10(5)- to 10(6)-fold increased cell sensitivity to verocytotoxin. Role of p-glycoprotein in glycolipid synthesis

Retroviral infection of the Madin-Darby canine kidney (MDCK) renal cell line with human MDR1 cDNA, encoding the P-glycoprotein (P-gp) multidrug resistance efflux pump, induces a major accumulation of the glycosphingolipid (GSL), globotriaosylceramide (Galalpha1-4Galbeta1-4glucosylceramide-Gb(3)), the receptor for the E. coli-derived verotoxin (VT), to effect a approximately million-fold increase in cell sensitivity to VT. The shorter chain fatty acid isoforms of Gb(3) (primarily C16 and C18) are elevated and VT is internalized to the endoplasmic reticulum/nuclear envelope as we have reported for other hypersensitive cell lines. P-gp (but not MRP) inhibitors, e.g. ketoconazole or cyclosporin A (CsA) prevented the increased Gb(3) and VT sensitivity, concomitant with increased vinblastine sensitivity. Gb(3) synthase was not significantly elevated in MDR1-MDCK cells and was not affected by CsA. In MDR1-MDCK cells, synthesis of fluorescent N-[7-(4-nitrobenzo-2-oxa-1,3-diazole)]-aminocaproyl (NBD)-lactosylceramide (LacCer) and NBD-Gb(3) via NBD-glucosylceramide (GlcCer) from exogenous NBD-C(6)-ceramide, was prevented by CsA. We therefore propose that P-gp can mediate GlcCer translocation across the bilayer, from the cytosolic face of the Golgi to the lumen, to provide increased substrate for the lumenal synthesis of LacCer and subsequently Gb(3). These results provide a molecular mechanism for the observed increased sensitivity of multidrug-resistant tumors to VT and emphasize the potential of verotoxin as an antineoplastic. Two strains (I and II) of MDCK cells, which differ in their glycolipid profile, have been described. The original MDR1-MDCK parental cell was not specified, but the MDR1-MDCK GSL phenotype and glycolipid synthase activities indicate MDCK-I cells. However, the partial drug resistance of MDCK-I cells precludes their being the parental cell. We speculate that the retroviral transfection per se, or the subsequent selection for drug resistance, selected a subpopulation of MDCK-I cells in the parental MDCK-II cell culture and that drug resistance in MDR1-MDCK cells is thus a result of both MDR1 expression and a second, previously unrecognized, component, likely the high level of GlcCer synthesis in these cells.