Design of a photoreactive analogue of the Escherichia coli heat-stable enterotoxin STIb: use in identifying its receptor on rat brush border membranes

A comparative molecular field analysis (COMFA) of the structural determinants of heat-stable enterotoxins mediating activation of guanylyl cyclase C

The heat-stable enterotoxin binds to and activates guanylyl cyclase C (GC-C), regulating fluid and electrolyte secretion in intestinal epithelial cells. A COMFA model was developed to predict the primary interactions between GC-C agonists and their receptor. This model predicts that the amide backbone of Cys(5)-Cys(6)-Glu(7)-Leu(8), the beta carbon atoms of Cys(5)-Cys(6), and the side chains of Pro(12), Ala(13), and Ala(15) comprise the primary interactions of GC-C agonists with the receptor surface.

The relevance of N-linked glycosylation to the binding of a ligand to guanylate cyclase C

The role of carbohydrate moieties at the N-linked glycosylation sites of guanylate cyclase C (GC-C), a receptor protein for guanylin, uroguanylin and heat-stable enterotoxin, in ligand binding and structural stability was examined using site-directed mutagenesis of the putative N-linked glycosylation sites in the extracellular domain (ECD) of porcine GC-C. For this purpose, eight mutant proteins of ECD (N9A, N20A, N56A, N172A, N261A, N284A, N334A and N379A) and six mutant proteins of the complete GC-C (N9A, S11A, N172A, T174A, N379A and T381A) were prepared, in which Ala replaced Asn, Ser and Thr at the N-linked glycosylation consensus sites. All the mutant proteins showed a ligand-binding affinity (K(d)) similar to those of the wild-type proteins, although the deletion of a carbohydrate moiety at each of the N-linked glycosylation sites affected the ligand-binding ability of ECD or GC-C to some degree. However, the mutant proteins of ECD (N379A) and GC-C (N379A and T381A) showed considerably decreased binding ability in the context of maximum capacity (B(max)) to a ligand, despite the fact that the expression levels of these mutant proteins were nearly the same as the wild-type proteins. Moreover, the mutant protein of ECD (N379A) was considerably less stable to a denaturant. These results clearly indicate a crucial role for the carbohydrate moiety at N379, which is located near the transmembrane region, in structural stability, the ability to bind to a ligand and the cyclase catalytic activity of GC-C, and provide a route for the elucidation of the mechanism of the interaction between GC-C and a ligand.

Interaction of Escherichia coli heat-stable enterotoxin B with cultured human intestinal epithelial cells

Binding of Escherichia coli heat-stable enterotoxin B (STb) to the human intestinal epithelial cell lines T84 and HT29 and to polarized T84 cells was studied to define the initial interaction of this peptide toxin with target cells. Equilibrium and competitive binding isotherms showed that 125I-STb bound specifically to T84 and HT29 cells; however, the toxin-epithelial cell interactions could be characterized by low-affinity binding (< or = 10(5) M(-1)) to a high number of binding sites (> or = 10(6) per cell). STb binding to T84 and HT29 cells as a function of 125I-STb concentration did not approach saturation at levels well above the effective biological concentration of STb for fluid secretion. Treatment of the 125I-STb-bound T84 and HT29 cells with an acidic saline solution to remove surface-bound toxin revealed that only approximately 55% +/- 10% of 125I-STb could be removed by this treatment at 4 degrees C, suggesting that approximately half of the bound STb was stably associated with the plasma membrane and/or internalized into the cytoplasm. Similar results were obtained when binding and internalization experiments were conducted at 22 and 37 degrees C. Immunofluorescence studies demonstrated that the strongest signal for STb appeared in the plasma membrane even after acid treatment. Toxin-treated cells also displayed diffuse cytoplasmic staining, indicating that once cell bound, STb did not appear to preferentially associate with membrane vesicles or cellular organelles. Binding and subsequent internalization of 125I-STb were not affected by treatment of the cells with trypsin, endoglycosidase F/peptide N-glycosidase F, Vibrio cholerae neuraminidase, tunicamycin, or 5 mM sodium chlorate, which blocks sulfation of surface proteoglycans. In addition, the internalization process was not altered by preincubation of the cells with the cytoskeleton inhibitors cytochalasin D and colchicine or cellular perturbants (i.e., 0.45 M sucrose and 5 mM sodium azide), indicating that cell surface proteins or carbohydrates did not function as STb receptors. The binding of 125I-STb to polarized T84 cells was also examined, and the total and nonspecific binding isotherms were found to overlap, indicating that the apical surface of polarized T84 cells did not contain a specific receptor for STb. In comparison to undifferentiated cells, twice the amount of bound STb (approximately 80% +/- 10%) was removable from polarized T84 cells after treatment with acidic solution. The percentage of surface-bound STb to polarized T84 cells did not vary significantly with the transepithelial electrical resistance of the cells or when STb was applied basolaterally. Together, our results indicate that STb binds with relatively low affinity to the plasma membrane of cultured intestinal epithelial cells and polarized T84 cells, probably to membrane lipids, and becomes stably associated with the lipid bilayer. The fact that a significant portion of the bound STb becomes free in the cytoplasm, even at a low temperature, suggests that the bound toxin may directly traverse the membrane bilayer.

Binding protein for Escherichia coli heat-stable enterotoxin II in mouse intestinal membrane

The protein binding Escherichia coli heat-stable enterotoxin II (STII) was isolated from cell membranes of mouse intestine. The binding of 125I-labeled STII to the proteins was inhibited by unlabeled STII, showing that it is specific. Proteins cross-linked with 125I-STII were purified by column chromatography on hydroxyapatite and TSK gel. Analyses of the purified protein by SDS-polyacrylamide gel electrophoresis and gel filtration showed that the molecular mass was 25 kDa.

The Escherichia coli heat-stable enterotoxin is a long-lived superagonist of guanylin

The mechanism by which bacterial heat-stable enterotoxins (ST I STA) cause diarrhea in humans and animals has been linked to the activation of an intestinal membrane-bound guanylate cyclase. Guanylin, a recently discovered rat intestinal peptide, is homologous in structure to ST I and can activate guanylate cyclase present on the human colonic carcinoma cell line T84. To directly test the mechanistic association of guanylate cyclase activation with diarrhea, we synthesized guanylin and a guanylin analog termed N9P10 guanylin and compared their biological activities with those of a synthetic ST I analog, termed ST Ib(6-18). We report that guanylin is able to inhibit the binding of a radiolabeled ST I analog to rat intestinal cells but causes diarrhea in infant mice only at doses at least 4 orders of magnitude higher than that of ST Ib(6-18). In contrast, N9P10 guanylin was enterotoxic in mice at much lower doses than guanylin but proved to be a weaker inhibitor of radiolabeled ST I than guanylin in the receptor binding assay. The pattern of guanylate cyclase activation observed for ST Ib(6-18) and the two guanylin analogs parallels the results observed in the receptor binding assay rather than those observed in the diarrheal assay. Treatment of guanylin with chymotrypsin or lumenal fluid derived from newborn mouse intestines resulted in a rapid loss of binding activity. Together, these results suggest that ST I enterotoxins may represent a class of long-lived superagonists of guanylin.

Receptors for Escherichia coli heat stable enterotoxin in human intestine and in a human intestinal cell line (Caco-2)

Escherichia coli heat stable enterotoxin (STa) and the newly identified endogenous ligand guanylin bind to an intestinal receptor and activate membrane bound guanylate cyclase. We compared STa binding and affinity crosslinking of STa receptors in human small intestine to those in the Caco-2 human colon carcinoma cell line. STa had similar kinetics of binding in human intestinal and Caco-2 brush border membranes. In both human intestine and Caco-2 brush border membranes, multiple specifically radiolabeled bands, including a 140-165 kDa band, were identified by affinity crosslinking. However, in human intestine the most prominent autoradiographic species was a 60 kDa band. A 60 kDa protein was also specifically immunoprecipitated from solubilized human brush border membranes using antisera raised against a cloned STa receptor fusion protein. Our observations of multiple crosslinked proteins in human intestine and Caco-2 cells could be explained by the existence of several members of a family of STa receptors and/or the existence of smaller STa binding proteins generated by the protease cleavage of a larger complete STa receptor.

Ligand-based histochemical localization and capture of cells expressing heat-stable enterotoxin receptors

The heat stable enterotoxins (ST) of enterotoxigenic Escherichia coli (ETEC) cause diarrhoea by binding specific intestinal receptors. Precise histochemical localization of ST receptors could provide more information about the pathophysiology of secretory diarrhoea and the role of ST receptors in normal biology. To accomplish this, we quantitatively coupled biotin to the N-terminus of ST1b using biotin-X-X-N-hydroxysuccinimide ester. The derivatized toxin (BST) has an apparent Kd of 11.7 +/- 10 nM for rat brush border receptors. We used BST in an affinity panning cell-capture system, to validate its ability to discriminate between receptor-positive and receptor-negative cells. Cell lines expressing ST receptors (human colon carcinoma T84, and COS cells transfected with guanylyl cyclase-C (GC-C) ST receptor cDNA) were captured to streptavidin and anti-biotin-coated plates with high efficiency and specificity. This system provides a novel approach to screening cells for the presence of unique ST-binding proteins. BST was then used with streptavidin-gold to demonstrate the cellular topography of ST receptors at the light microscopic level. Villus enterocytes were intensely stained, but only a faint signal was observed in upper crypts of rat small intestine. Thus, a gradient of increasing receptor density was seen as upper crypt cells matured into villus enterocytes. Higher magnification revealed that ST receptors are concentrated at the apical aspect of villus enterocytes. Recently, guanylin, a putative endogenous ligand for ST receptors, has been localized to Paneth cells, at the base of intestinal crypts. Thus, ST receptors are concentrated in villus enterocytes, while guanylin appears to be produced at the base of the crypts.(ABSTRACT TRUNCATED AT 250 WORDS)

Glycoprotein receptors for a heat-stable enterotoxin (STh) produced by enterotoxigenic Escherichia coli

Glycoprotein receptors for heat-stable enterotoxin STh of enterotoxigenic Escherichia coli in the rat intestinal cell membrane were identified and characterized. Incubation of rat intestinal cell membranes with radioiodinated N-5-azidonitrobenzoyl-STh[5-19] (125I-ANB-STh[5-19]) followed by photolysis resulted in specific radiolabeling of two distinct proteins with M(r)s of 200,000 (designated STR-200A and STR-200B). STR-200A was found to be composed of two molecules of a protein with an M(r) of 70,000 (70-kDa protein), whereas STR-200B was composed of two different protein molecules with M(r)s of 53,000 (53-kDa protein) and 77,000 (77-kDa protein). These proteins showed no guanylate cyclase activity. The 70-kDa protein was labeled most with 125I-ANB-STh[5-19], suggesting that STR-200A is the main receptor protein in the rat intestinal cell membrane. The carbohydrate moieties of STR-200A and STR-200B were examined by enzymatic deglycosylation. The 70-kDa protein of STR-200A was found to contain N-linked high-mannose-type and/or hybrid-type oligosaccharides, and results suggested that it possesses at least three N glycosylation sites. The 53-kDa protein of STR-200B was found to have an N-linked complex-type oligosaccharide side chain. The deglycosylated 70-kDa protein retained activity for binding to STh, suggesting that the carbohydrate moieties of these receptor proteins are not important for binding with STh.

Age-dependent changes in affinity-labeled receptors for Escherichia coli heat-stable enterotoxin in the swine intestine

Intestinal brush border membranes from 1-day-old and 4-week-old (day of weaning) pigs were affinity labeled with an Escherichia coli heat-stable enterotoxin (STa) by cross-linking 125I-STa to receptor proteins with disuccinimidyl suberate. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography revealed that a radioactive protein with a relative molecular weight of 137,000 to 145,000 was present in both age groups. A strongly radioactive protein with an apparent Mr of 90,000 was present in the 1-day-old animals but not in those that were 4 weeks old. The major radioactive protein present in the older pigs had an Mr of 64,000 to 67,000, but this protein was missing or very weakly radioactive in the younger pigs. There was no significant difference between the groups in receptor affinity for STa, although the receptor density in the older animals was marginally significantly greater. STa-stimulated guanylate cyclase activity in membranes from 1-day-old pigs was only one-sixth that in 4-week-old pigs, although the basal and Lubrol PX-stimulated activities were similar.

Heterogeneity of intestinal receptors for Escherichia coli heat-stable enterotoxin

The structure of rat intestinal cell receptors for Escherichia coli heat-stable enterotoxin (ST) was investigated by affinity cross-linking to 125I-ST and analysis by denaturing gel electrophoresis. Cross-linking of labeled toxin to intestinal membranes and analysis by nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) revealed five specifically labeled proteins with molecular masses of 160, 136, 78, 71, and 56 (kilodaltons) kDa. Exhaustive reduction of these samples resulted in a similar pattern of labeling. Affinity-labeled proteins were further analyzed by nonreducing SDS-PAGE, reduction of the resulting separated proteins, and further separation by SDS-PAGE in the presence of beta-mercaptoethanol. Thus, the 160-kDa band on nonreducing gels consisted of two different receptors: a 160-kDa polypeptide not further reducible and one composed of at least two subunits, one of which was the 78-kDa subunit. Similarly, the 136-kDa band on nonreducing gels consisted of a 136-kDa polypeptide not further reducible and one composed of at least two subunits, one of which was the 71-kDa subunit. The 78-, 71-, and 56-kDa subunits were not further reducible. These data suggest heterogeneity of the ST receptor subunit structure and organization in rat intestinal epithelia.

Different crosslinking agents identify distinctly different putative Escherichia coli heat-stable enterotoxin rat intestinal cell receptor proteins

The receptor for heat-stable enterotoxins (ST) produced by Escherichia coli and related organisms is located in the brush border region of intestinal villus cells. Heterobifunctional and homobifunctional crosslinkers were used to covalently couple 125I-ST to rat intestinal cell brush border membrane proteins. Experimental conditions during ligand binding and subsequent crosslinking significantly influence the efficiency of crosslinking, and the number of peptides specifically crosslinked to the 125I-ST. Multiple proteins efficiently coupled to 125I-ST with agents that can couple through the ST amino terminus. The crosslinker 1-ethyl-3-(dimethylaminopropyl)carbodiimide (EDC), which can react with the carboxy terminus of the ST, covalently crosslinked 125I-ST to a single protein with an apparent Mr of 125,000-130,000, larger than the proteins identified using longer crosslinkers. Each of the proteins identified by crosslinking migrate with the same retention time on gel filtration after solubilization, with an approximate molecular size of 150,000-200,000.

Reduction of enterotoxic activity of Escherichia coli heat-stable enterotoxin by substitution for an asparagine residue

The Escherichia coli heat-stable enterotoxins (STs) are small peptide toxins consisting of 18 (STp) or 19 (STh) amino acids. STp and STh share biologically active sequences which reside in the C-terminal 13 amino acid residues, but the role of each amino acid in the active sequences is not clear. We substituted in vivo Asp, Tyr, His, Gln, Lys, and Arg for the Asn residue at position 11 of STp by oligonucleotide-directed site-specific mutagenesis and examined the biological activities of the resulting mutants. All mutant STs reacted with both monoclonal and polyclonal antibodies, demonstrating that the amino acid substitutions at position 11 did not cause a significant change in the conformation of STp. However, the substitutions invariably caused a significant decrease in enterotoxic activities. The most remarkable decrease was observed with Asn-11----Lys-11 and Asn-11----Arg-11 mutations; that is, enterotoxic activity could not be detected in the culture supernatant of either of these mutant strains. These results indicate that Asn-11 of STp plays an essential role in the enterotoxic activity. The amide group and the length of side chain of Asn-11 seem to be especially important for enterotoxic activity.

Importance of disulfide bridges in the structure and activity of Escherichia coli enterotoxin ST1b

A 13-amino acid sequence of the Escherichia coli heat-stable enterotoxin ST1b encodes its receptor-binding and diarrheal functions. This sequence includes six cysteines involved in three intramolecular disulfide bridges. To determine the importance of disulfide bridges to the biological activity of ST1b, we synthesized 15 analogues of the tridecapeptide representing all possible replacements of two of the six cysteines by alanines. Only 2 analogues--namely, A6,11ST1b-(6-18) and A10,18ST1b(6-18)--could inhibit the binding of a radiolabeled analogue of ST1b to rat intestinal cells. The purified peptides were, respectively, 4200 and 130 times less effective as inhibitors than ST1b(6-18), the sequence that includes all six cysteines. In addition, both peptides produce diarrhea when given orally to suckling mice. These analogues share in common only two cysteines (Cys-7 and Cys-15), suggesting that four cysteines, two of which are Cys-7 and Cys-15, are necessary for activity. A pattern of disulfide linkages is proposed where Cys-7 is paired to Cys-15, Cys-6 to Cys-11, and Cys-10 to Cys-18, the preceding disulfide bridges being ranked in descending order of importance in terms of their respective contribution to the activity of the enterotoxin. Using this disulfide bridge arrangement and constraints derived from NMR spectroscopy, we propose a folding pattern for the toxic domain of ST1b.

Substitutions of cysteine residues of Escherichia coli heat-stable enterotoxin by oligonucleotide-directed mutagenesis

The Escherichia coli 18-amino-acid, heat-stable enterotoxin STp has six cysteine residues linked intramolecularly by three disulfide bonds. These disulfide bonds are important for toxic activity, but the precise role of each bond is not clear. We substituted cysteine residues of STp in vivo by oligonucleotide-directed site-specific mutagenesis to dissociate each disulfide bond and examined the biological activities of the resulting mutants. The Cys-6----Ala and Cys-17----Ala mutations caused a complete loss of toxic activity. The Cys-5----Ala, Cys-10----Ser, and Gly-16, Cys-17----Cys-16, Gly-17 mutations caused a large decrease in toxic activity. These results mean that all three disulfide bonds formed at fixed positions are required for full expression of the biological activity of STp. However, a weak but significant toxicity still remained after three mutations, Cys-5----Ala, Cys-10----Ser, and Gly-16, Cys-17----Cys-16, Gly-17. This indicates that STp has some flexibilities in its conformation to exert toxic activity and that the role of each disulfide bond exerting toxic activity is not quite the same.

Immunoactive chimeric ST-LT enterotoxins of Escherichia coli generated by in vitro gene fusion

Two different lengths of the gene encoding Escherichia coli heat-stable toxin (STa) were fused to the carboxy end of the gene coding for the E. coli heat-labile toxin A-subunit (LTA). The hybrid genes directed expression of chimeric LTA-STa proteins. Association of these chimeras with native heat-labile toxin B-subunit (LTB) resulted in protein complexes that bound to GM1 ganglioside and thereby could be assayed in a GM1 ELISA. The complexes reacted with monoclonal antibodies against either LTA, LTB or STa indicating that the STa and LT epitopes remained immunologically intact after fusion. Genetically constructed chimeric proteins exhibiting LT and STa antigens on the same molecule may represent a promising approach to development of broadly protective immunoprophylactic agents and/or useful immunodiagnostic reagents for diarrhoeal diseases caused by enterotoxinogenic E. coli.