SummaryThe Vibrio cholerae HA/protease gene (hap) promoter is inactive in Escherichia coli. We cloned and sequenced the 0.7 kb hap promoter fragment from strain 3083-2 and showed that hap is located immediately 3Ј of ompW, encoding a minor outer membrane protein. A clone from a genomic library of strain 3083-2 was isolated, which was required for activation of the hap promoter in E. coli. Expression from the hap promoter only occurred late in the growth phase. A single complete open reading frame (ORF) designated HapR was identified on a 1.7 kb DNA fragment that was required for activation. Allelic replacements showed that hapR was also essential for hap expression in V. cholerae. In El Tor, but not in classical biotypes of V. cholerae, hapR mutations also produced a rugose colonial phenotype. HapR was shown to encode a 203-amino-acid polypeptide with 71% identity to LuxR of V. harveyi, an essential positive regulator of the lux operon that has no previously identified homologues. The amino-terminal domain (residues 21-68) showed significant homology to the TetR family of helix-turn-helix DNA-binding domains and was 95% identical to the same domain of LuxR. HapR and LuxR activated both the hap and the lux promoters at near wild-type levels, despite only limited homology in the promoter sequences (46% identity with 12 gaps over 420 bp). DNA sequences and ORFs 5Ј (but not 3Ј) of the hapR and luxR loci were homologous, suggesting a common origin for these loci, and hapRhybridizing sequences were found in other vibrios. We conclude that HapR is absolutely required for hap expression and that HapR and LuxR form a new family of transcriptional activator proteins.
Cholera toxin (CT) travels from the plasma membrane of intestinal cells to the endoplasmic reticulum (ER) where a portion of the A-subunit, the A1 chain, crosses the membrane into the cytosol to cause disease. A related toxin, LTIIb, binds to intestinal cells but does not cause toxicity. Here, we show that the B-subunit of CT serves as a carrier for the A-subunit to the ER where disassembly occurs. The B-subunit binds to gangliosides in lipid rafts and travels with the ganglioside to the ER. In many cells, LTIIb follows a similar pathway, but in human intestinal cells it binds to a ganglioside that fails to associate with lipid rafts and it is sorted away from the retrograde pathway to the ER. Our results explain why LTIIb does not cause disease in humans and suggest that gangliosides with high affinity for lipid rafts may provide a general vehicle for the transport of toxins to the ER.
Abstract. Vibrio cholerae and Escherichia coli heat labile toxins (CT and LT) elicit a secretory response from intestinal epithelia by binding apical receptors (ganglioside GM1 ) and subsequently activating basolateral effectors (adenylate cyclase). We have recently proposed that signal transduction in polarized cells may require transcytosis of toxin-containing membranes (Lencer, W. I., G. Strohmeier, S. Moe, S. L. Carlson, C. T. Constable, and J. L. Madara. 1995. Proc. Natl. Acad. Sci. USA. 92:10094-10098). Targeting of CT into this pathway depends initially on binding of toxin B subunits to GMI at the cell surface. The anatomical compartments in which subsequent steps of CT processing occur are less clearly defined. However, the enzymatically active A subunit of CT contains the ER retention signal KDEL (RDEL in LT). Thus if the KDEL motif were required for normal CT trafficking, movement of CT from the Golgi to ER would be implied. To test this idea, recombinant wild-type (wt) and mutant CT and LT were prepared. The COOH-terminal KDEL sequence in CT was replaced by seven unrelated amino acids: LEDERAS. In LT, a single point mutation replacing leucine with valine in RDEL was made. Wt and mutant toxins displayed similar enzymatic activities and binding affinities to GM1 immobilized on plastic. Biologic activity of recombinant toxins was assessed as a C1-secretory response elicited from the polarized human epithelial cell line T84 using standard electrophysiologic techniques. Mutations in K(R)DEL of both CT and LT delayed the time course of toxin-induced C1-secretion. At T1/2, dose dependencies for K(R)DELmutant toxins were increased ~>10-fold. KDELmutants displayed differentially greater temperature sensitivity. In direct concordance with a slower rate of signal transduction, KDEL-mutants were trafficked to the basolateral membrane more slowly than wt CT (assessed by selective cell surface biotinylation as transcytosis of B subunit). Mutation in K(R)DEL had no effect on the rate of toxin endocytosis. These data provide evidence that CT and LT interact directly with endogenous KDEL-receptors and imply that both toxins may require retrograde movement through Golgi cisternae and ER for efficient and maximal biologic activity.ETROGRADE transport through Golgi cisternae has been shown to occur for soluble and membrane proteins of the ER (49) and for certain protein toxins (6, 55). Targeting of soluble ER and some type II membrane proteins in this pathway depends on the COOH-terminal sorting signal Lys-Asp-Glu-Leu (KDEL or HDEL
In polarized cells, signal transduction by cholera toxin (CT) requires apical endocytosis and retrograde transport into Golgi cisternae and perhaps ER (Lencer, W.I., C. Constable, S. Moe, M. Jobling, H.M. Webb, S. Ruston, J.L. Madara, T. Hirst, and R. Holmes. 1995. J. Cell Biol. 131:951–962). In this study, we tested whether CT's apical membrane receptor ganglioside GM1 acts specifically in toxin action. To do so, we used CT and the related Escherichia coli heat-labile type II enterotoxin LTIIb. CT and LTIIb distinguish between gangliosides GM1 and GD1a at the cell surface by virtue of their dissimilar receptor-binding B subunits. The enzymatically active A subunits, however, are homologous. While both toxins bound specifically to human intestinal T84 cells (K d ≈ 5 nM), only CT elicited a cAMP-dependent Cl− secretory response. LTIIb, however, was more potent than CT in eliciting a cAMP-dependent response from mouse Y1 adrenal cells (toxic dose 10 vs. 300 pg/well). In T84 cells, CT fractionated with caveolae-like detergent-insoluble membranes, but LTIIb did not. To investigate further the relationship between the specificity of ganglioside binding and partitioning into detergent-insoluble membranes and signal transduction, CT and LTIIb chimeric toxins were prepared. Analysis of these chimeric toxins confirmed that toxin-induced signal transduction depended critically on the specificity of ganglioside structure. The mechanism(s) by which ganglioside GM1 functions in signal transduction likely depends on coupling CT with caveolae or caveolae-related membrane domains.
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