Specificity of the Type II Secretion Systems of Enterotoxigenic Escherichia coli and Vibrio cholerae for Heat-Labile Enterotoxin and Cholera Toxin

The Gram-negative type II secretion (T2S) system is a multiprotein complex mediating the release of virulence factors from a number of pathogens. While an understanding of the function of T2S components is emerging, little is known about what identifies substrates for export. To investigate T2S substrate recognition, we compared mutations affecting the secretion of two highly homologous substrates: heat-labile enterotoxin (LT) from enterotoxigenic Escherichia coli (ETEC) and cholera toxin (CT) from Vibrio cholerae. Each toxin consists of one enzymatic A subunit and a ring of five B subunits mediating the toxin''s secretion. Here, we report two mutations in LT''s B subunit (LTB) that reduce its secretion from ETEC without global effects on the toxin. The Q3K mutation reduced levels of secreted LT by half, and as with CT (T. D. Connell, D. J. Metzger, M. Wang, M. G. Jobling, and R. K. Holmes, Infect. Immun. 63:4091-4098, 1995), the E11K mutation impaired LT secretion. Results in vitro and in vivo show that these mutants are not degraded more readily than wild-type LT. The Q3K mutation did not significantly affect CT B subunit (CTB) secretion from V. cholerae, and the E11A mutation altered LT and CTB secretion to various extents, indicating that these toxins are identified as secretion substrates in different ways. The levels of mutant LTB expressed in V. cholerae were low or undetectable, but each CTB mutant expressed and secreted at wild-type levels in ETEC. Therefore, ETEC''s T2S system seems to accommodate mutations in CTB that impair the secretion of LTB. Our results highlight the exquisitely fine-tuned relationship between T2S substrates and their coordinate secretion machineries in different bacterial species.Gram-negative bacteria have evolved a number of methods to secrete proteins into the extracellular milieu, with at least six specific secretion systems currently described (14, 30). Type II secretion (T2S), or the main terminal branch of the general secretory pathway, is a feature of a number of proteobacteria and has been shown to be required for pathogenesis and maintenance of environmental niches in a large number of species (5). The T2S system is a multiprotein complex of 12 to 15 components that spans the inner and outer membranes, allowing for the controlled release of certain folded proteins that have been directed to the periplasm through the Sec or Tat machinery (21). Aside from providing a means of exporting freely released virulence factors from plant, animal, and human pathogens (5), the T2S system has been shown to export surface-associated virulence factors (18), fimbrial components (46), outer membrane cytochromes (36), and a surfactant required for sliding motility in Legionella pneumophila (39), among other substrates.While an increasing number of studies have focused on understanding the structure and function of the components of the T2S system itself, little is known about what identifies a periplasmic protein as a substrate for secretion (21, 32). Because proteins secreted from the same bacterial species need not share any obvious structural homology, it is not even clear how much of a T2S substrate interacts with the secretion machinery (32). Analysis of two similar substrates that can each be secreted by the T2S systems of two distinct species would provide information about species-specific identification of T2S substrates and, by extension, the nature of the “secretion motif” identifying those substrates. Heat-labile enterotoxin (LT) from enterotoxigenic Escherichia coli (ETEC) and cholera toxin (CT) from Vibrio cholerae represent one such pair of substrates.ETEC and V. cholerae are enteric pathogens causing significant morbidity and mortality worldwide (33). The causative agents of traveler''s diarrhea and cholera, respectively, these two pathogens share a number of similarities, including the nature of their disease symptoms (38). Each pathogen secretes an AB₅ toxin important for colonization and the induction of water and electrolyte efflux from intestinal epithelial cells (1, 29). These toxins, LT and CT, are both encoded by two-gene operons. After sec-dependent transport to the periplasm, holotoxin formation occurs spontaneously (13), with one catalytic A subunit (LTA or CTA) assembling with five B subunits (LTB or CTB), which are responsible for the binding properties of the toxins. Export of fully folded and assembled LT or CT is then accomplished by the T2S system (34, 40). In ETEC, this system is encoded by gspC to -M (40), while in V. cholerae, these genes are found in the eps operon (34).LT and CT are very similar in structure, sharing approximately 80% sequence homology and 83% identity in the mature B subunit (16, 24). ETEC is thought to have acquired the genes for CT through horizontal transfer, with the toxins evolving over time to possess slight differences (45). As such, these toxins share the same primary host receptor, the monosialoganglioside G_M1, and catalyze the same ADP-ribosylation reaction within host cells (38). However, LT is able to bind other host sphingolipids in addition to G_M1 and to interact with sugar residues from the A-type blood antigen, which CT cannot bind (16, 41). Both LT and CT are able to associate with sugar residues in lipopolysaccharide (LPS) on the surface of E. coli cells (17). Binding to each of these substrates can be impaired by point mutation (26, 43).In this study, we report point mutations impairing the release of LT from ETEC and CT from V. cholerae. We analyzed the specificity of the defects in substrate recognition by comparing the effects of substituting charged and neutral residues in key regions of LTB and CTB. To confirm that the identified mutations resulted specifically in a secretion defect, we tested the effect of the mutations on (i) ligand binding by each toxin, (ii) toxin stability, and (iii) formation of secretion-competent B-subunit pentamers. By introducing comparable mutations into both toxins, including one previously reported to impair the secretion of CT (6), and exchanging toxin substrates between the two species, we have revealed species-dependent differences in T2S substrate recognition. Although wild-type LT and CT can be heterologously expressed and secreted from V. cholerae and ETEC, respectively, the substrate residues identified by the secretion machinery in each species are distinct. Together, our results demonstrate that highly homologous T2S substrates are recognized in different ways when secreted by two distinct systems.