Functional reconstitution of bacterial Tat translocation in vitro.

The Tat (twin-arginine translocation) pathway is a Sec-independent mechanism for translocating folded preproteins across or into the inner membrane of Escherichia coli. To study Tat translocation, we sought an in vitro translocation assay using purified inner membrane vesicles and in vitro synthesized substrate protein. While membrane vesicles derived from wild-type cells translocate the Sec-dependent substrate proOmpA, translocation of a Tat-dependent substrate, SufI, was not detected. We established that in vivo overexpression of SufI can saturate the Tat translocase, and that simultaneous overexpression of TatA, B and C relieves this SufI saturation. Using membrane vesicles derived from cells overexpressing TatABC, in vitro translocation of SufI was detected. Like translocation in vivo, translocation of SufI in vitro requires TatABC, an intact membrane potential and the twin-arginine targeting motif within the signal peptide of SUFI: In contrast to Sec translocase, we find that Tat translocase does not require ATP. The development of an in vitro translocation assay is a prerequisite for further biochemical investigations of the mechanism of translocation, substrate recognition and translocase structure.

Evaluating the oligomeric state of SecYEG in preprotein translocase.

SecA insertion and deinsertion through SecYEG drive preprotein translocation at the Escherichia coli inner membrane. We present three assessments of the theory that oligomers of SecYEG might form functional translocation sites. (i) Formaldehyde cross- linking of translocase reveals cross-links between SecY, SecE and SecG, but not higher order oligomers. (ii) Cross-linking of membranes containing unmodified SecE and hemagglutinin-tagged SecE (SecE(HA)) reveals cross-links between SecY and SecE and between SecY and SecE(HA). However, anti-HA immunoprecipitates contain neither untagged SecE nor SecY cross-linked to SecE. (iii) Membranes containing similar amounts of SecE and SecE(HA) were saturated with translocation intermediate (I(29)) and detergent solubilized. Anti-HA immunoprecipitation of I(29) required SecYE(HA)G and SecA, yet untagged SecE was not present in this translocation complex. Likewise, anti-HA immunoprecipitates of membranes containing equal amounts of SecY and SecY(HA) were found to contain SecY(HA) but not SecY. Both immunoprecipitates contain more moles of I(29) than of the untagged subunit, again suggesting that translocation intermediates are not engaged with multiple copies of SecYEG. These studies suggest that the active form of preprotein translocase is monomeric SecYEG.

Interruption of multiple cellular processes in HT-29 epithelial cells by Pseudomonas aeruginosa exoenzyme S.

Exoenzyme S (ExoS), an ADP-ribosylating enzyme produced by the opportunistic pathogen Pseudomonas aeruginosa, is directly translocated into eukaryotic cells by bacterial contact. Within the cell, ExoS ADP-ribosylates the cell signaling protein Ras and causes inhibition of DNA synthesis and alterations in cytoskeletal structure. To further understand the interrelationship of the different cellular effects of ExoS, functional analyses were performed on HT-29 epithelial cells after exposure to ExoS-producing P. aeruginosa 388 and the non-ExoS-producing strain 388DeltaS. Two different mechanisms of morphological alteration were identified: (i) a more-transient and less-severe cell rounding caused by the non-ExoS-producing strain 388DeltaS and (ii) a more-severe, long-term cell rounding caused by ExoS-producing strain 388. Long-term effects of ExoS on cell morphology occurred in conjunction with ExoS-mediated inhibition of DNA synthesis and the ADP-ribosylation of Ras. ExoS was also found to cause alterations in HT-29 cell function, leading to the loss of cell adhesion and microvillus effacement. Nonadherent ExoS-treated cells remained viable but had a high proportion of modified Ras. While microvillus effacement was detected in both 388- and 388DeltaS-treated cells, effacement was more prevalent and rapid in cells exposed to strain 388. We conclude from these studies that ExoS can have multiple effects on epithelial cell function, with more severe cellular alterations associated with the enzymatic modification of Ras. The finding that ExoS had greater effects on cell growth and adherence than on cell viability suggests that ExoS may contribute to the P. aeruginosa infectious process by rendering cells nonfunctional.

Active and passive immunization with the Pseudomonas V antigen protects against type III intoxication and lung injury.

Pseudomonas aeruginosa is an opportunistic bacterial pathogen that can cause fatal acute lung infections in critically ill individuals. Damage to the lung epithelium is associated with the expression of toxins that are directly injected into eukaryotic cells through a type Ill-mediated secretion and translocation mechanism. Here we show that the P. aeruginosa homolog of the Yersinia V antigen, PcrV, is involved in the translocation of type III toxins. Vaccination against PcrV ensured the survival of challenged mice and decreased lung inflammation and injury. Antibodies to PcrV inhibited the translocation of type III toxins.

Biological effects of Pseudomonas aeruginosa type III-secreted proteins on CHO cells.

A strain of Pseudomonas aeruginosa that fails to express known type III-secreted effector proteins was constructed as an expression host. Individual effectors were expressed in trans, and their biological effects on CHO cells were assessed in an acute cellular infection model. Intoxication with ExoS, ExoT, or ExoY resulted in alterations in cell morphology. As shown in previous genetic studies, ExoU expression was linked to acute cytotoxicity.

Regulation of ExoS production and secretion by Pseudomonas aeruginosa in response to tissue culture conditions.

This study was initiated to characterize the regulation and secretion of ExoS by Pseudomonas aeruginosa during contact with eukaryotic cells. The production of ExoS was monitored by a sensitive ADP-ribosyltransferase activity assay, and specific activities were calculated for supernatant and cell-associated fractions. Time course analysis indicated that ExoS was produced after a lag period, suggesting that induction of the regulon is necessary for the expression of detectable amounts of enzyme activity. Under tissue culture growth conditions, ExoS was induced when P. aeruginosa was in contact with Chinese hamster ovary (CHO) cells or after growth in tissue culture medium with serum. The serum induction of ExoS appeared to result in generalized type III secretion, while induction by contact with CHO cells appeared to result in polarized type III secretion. Mutants in the type III secretory system that express a null phenotype for ExoS production in bacteriological medium produced but did not secrete the enzyme when P. aeruginosa was grown under inducing conditions in tissue culture medium. These results suggest that both induction and secretion of ExoS may differ when the bacteria are exposed to different growth environments. The putative type III translocation proteins and secretion apparatus of P. aeruginosa were required for translocation of bacterial factors that mediate changes in CHO cell morphology during infection.

Identification and characterization of SpcU, a chaperone required for efficient secretion of the ExoU cytotoxin.

In recent studies, we have shown that Pseudomonas aeruginosa strains that are acutely cytotoxic in vitro damage the lung epithelium in vivo. Genetic analysis indicated that the factor responsible for acute cytotoxicity was controlled by ExsA and therefore was part of the exoenzyme S regulon. The specific virulence determinant responsible for epithelial damage in vivo and cytotoxicity in vitro was subsequently mapped to the exoU locus. The present studies are focused on a genetic characterization of the exoU locus. Northern blot analyses and complementation experiments indicated that a region downstream of exoU was expressed and that the expression of this region corresponded to increased ExoU secretion. DNA sequence analysis of a region downstream of exoU identified several potential coding regions. One of these open reading frames, SpcU (specific Pseudomonas chaperone for ExoU), encoded a small 15-kDa acidic protein (137 amino acids [pI 4.4]) that possessed a leucine-rich motif associated with the Syc family of cytosolic chaperones for the Yersinia Yops. T7 expression analysis and nickel chromatography of histidine-tagged proteins indicated that ExoU and SpcU associated as a noncovalent complex when coexpressed in Escherichia coli. The association of ExoU and SpcU required amino acids 3 to 123 of ExoU. In P. aeruginosa, ExoU and SpcU are coordinately expressed as an operon that is controlled at the transcriptional level by ExsA.

ExoY, an adenylate cyclase secreted by the Pseudomonas aeruginosa type III system.

The exoenzyme S regulon is a set of coordinately regulated virulence genes of Pseudomonas aeruginosa. Proteins encoded by the regulon include a type III secretion and translocation apparatus, regulators of gene expression, and effector proteins. The effector proteins include two enzymes with ADP-ribosyltransferase activity (ExoS and ExoT) and an acute cytotoxin (ExoU). In this study, we identified ExoY as a fourth effector protein of the regulon. ExoY is homologous to the extracellular adenylate cyclases of Bordetella pertussis (CyaA) and Bacillus anthracis (EF). The homology among the three adenylate cyclases is limited to two short regions, one of which possesses an ATP-binding motif. In assays for adenylate cyclase activity, recombinant ExoY (rExoY) catalyzed the formation of cAMP with a specific activity similar to the basal activity of CyaA. In contrast to CyaA and EF, rExoY activity was not stimulated or activated by calmodulin. A 500-fold stimulation of activity was detected following the addition of a cytosolic extract from Chinese hamster ovary (CHO) cells. These results indicate that a eukaryotic factor, distinct from calmodulin, enhances rExoY catalysis. Site-directed mutagenesis of residues within the putative active site of ExoY abolished adenylate cyclase activity. Infection of CHO cells with ExoY-producing strains of P. aeruginosa resulted in the intracellular accumulation of cAMP. cAMP accumulation within CHO cells depended on an intact type III translocation apparatus, demonstrating that ExoY is directly translocated into the eukaryotic cytosol.

Identification of type III secreted products of the Pseudomonas aeruginosa exoenzyme S regulon.

Extracellular protein profiles from wild-type and regulatory or secretory isogenic mutants of the Pseudomonas aeruginosa exoenzyme S regulon were compared to identify proteins coordinately secreted with ExoS. Data from amino-terminal sequence analysis of purified extracellular proteins were combined with data from nucleotide sequence analysis of loci linked to exoenzyme S production. We report the identification of P. aeruginosa homologs to proteins of Yersinia spp. that function as regulators of the low calcium response, regulators of secretion, and mediators of the type III translocation mechanism.

Biochemical relationships between the 53-kilodalton (Exo53) and 49-kilodalton (ExoS) forms of exoenzyme S of Pseudomonas aeruginosa.

Genetic studies have shown that the 53-kDa (Exo53) and 49-kDa (ExoS) forms of exoenzyme S of Pseudomonas aeruginosa are encoded by separate genes, termed exoT and exoS, respectively. Although ExoS and Exo53 possess 76% primary amino acid homology, Exo53 has been shown to express ADP-ribosyltransferase activity at about 0.2% of the specific activity of ExoS. The mechanism for the lower ADP-ribosyltransferase activity of Exo53 relative to ExoS was analyzed by using a recombinant deletion protein which contained the catalytic domain of Exo53, comprising its 223 carboxyl-terminal residues (termed N223-53). N223-53 was expressed in Escherichia coli as a stable, soluble fusion protein which was purified to >80% homogeneity. Under linear velocity conditions, N223-53 catalyzed the FAS (for factor activating exoenzyme S)-dependent ADP-ribosylation of soybean trypsin inhibitor (SBTI) at 0.4% and of the Ras protein at 1.0% of the rates of catalysis by N222-49. N222-49 is a protein comprising the 222 carboxyl-terminal residues of ExoS, which represent its catalytic domain. N223-53 possessed binding affinities for NAD and SBTI similar to those of N222-49 (less than fivefold differences in Kms) but showed a lower velocity rate for the ADP-ribosylation of SBTI. This indicated that the primary defect for ADP-ribosylation by Exo53 resided within its catalytic capacity. Analysis of hybrid proteins, composed of reciprocal halves of N223-53 and N222-49, localized the catalytic defect to residues between positions 235 and 349 of N223-53. E385 was also identified as a potential active site residue of Exo53.

Exoenzyme S of Pseudomonas aeruginosa is secreted by a type III pathway.

Exoenzyme S is an extracellular ADP-ribosyltransferase of Pseudomonas aeruginosa. Transposon mutagenesis of P. aeruginosa 388 was used to identify genes required for exoenzyme S production. Five Tn5Tc insertion mutants were isolated which exhibited an exoenzyme S-deficient phenotype (388::Tn5Tc 469, 550, 3453, 4885, and 5590). Mapping experiments demonstrated that 388::Tn5Tc 3453, 4885, and 5590 possessed insertions within a 5.0 kb EcoRI fragment that is not contiguous with the exoenzyme S trans-regulatory operon. 388::Tn5Tc 469 and 550 mapped to a region downstream of the trans-regulatory operon which has been previously shown to contain a promoter region that is co-ordinately regulated with exoenzyme S synthesis. Nucleotide sequence analysis of a 7.2 kb region flanking the 388::Tn5Tc 469 and 550 insertions, identified 12 contiguous open reading frames (ORFs). Database searches indicated that the first ORF, ExsD, is unique. The other 11 ORFs demonstrated high homology to the YscB-L proteins of the yersiniae Yop type III export apparatus. RNase-protection analysis of wild-type and mutant strains indicated that exsD and pscB-L form an operon. To determine whether ExoS was exported by a type III mechanism, derivatives consisting of internal deletions or lacking amino- or carboxy-terminal residues were expressed in P. aeruginosa. Deletion analyses indicated that the amino-terminal nine residues are required for ExoS export. Combined data from mutagenesis, regulatory, expression, and sequence analyses provide strong evidence that P. aeruginosa possesses a type III secretion apparatus which is required for the export of exoenzyme S and potentially other co-ordinately regulated proteins.

Genetic relationship between the 53- and 49-kilodalton forms of exoenzyme S from Pseudomonas aeruginosa.

Exoenzyme S is an ADP-ribosylating extracellular protein of Pseudomonas aeruginosa that is produced as two immunologically related forms, a 49-kDa enzymatically active form and a 53-kDa inactive form. The postulated relationship between the two proteins involves a carboxy-terminal proteolytic cleavage of the 53-kDa precursor to produce an enzymatically active 49-kDa protein. To determine the genetic relationship between the two forms of exoenzyme S, exoS (encoding the 49-kDa form) was used as a probe in Southern blot analyses of P. aeruginosa chromosomal digests. Cross-hybridizing bands were detected in chromosomal digests of a strain of P. aeruginosa in which exoS had been deleted by allelic exchange. A chromosomal bank was prepared from the exoS deletion strain, 388deltaexoS::TC, and screened with a probe internal to exoS. Thirteen clones that cross-hybridized with the exoS probe were identified. One representative clone contained the open reading frame exoT; this open reading frame encoded a protein of 457 amino acids which showed 75% amino acid identity to ExoS. The exoT open reading frame, cloned into a T7 expression system, produced a 53-kDa protein in Escherichia coli, termed Exo53, which reacted to antisera against exoenzyme S. A histidine-tagged derivative of recombinant Exo53 possessed approximately 0.2% of the ADP-ribosyltransferase activity of recombinant ExoS. Inactivation of exoT in an allelic-replacement strain resulted in an Exo53-deficient phenotype without modifying the expression of ExoS. These studies prove that the 53- and 49-kDa forms of exoenzyme S are encoded by separate genes. In addition, this is the first report of the factor-activating-exoenzyme-S-dependent ADP-ribosyltransferase activity of the 53-kDa form of exoenzyme S.

Transcriptional analysis of the Pseudomonas aeruginosa exoenzyme S structural gene.

The transcriptional regulation of the Pseudomonas aeruginosa exoS gene was investigated. Expression of exoS in P. aeruginosa PA103 was dependent upon growth in a low-cation environment and the presence of a functional exsA gene. Promoter fusion analysis indicated that a 285-bp PstI-NsiI fragment, located 5' of the exoS coding region, contained a functional promoter for exoS. Expression of the reporter gene was inducible in a low-cation growth environment and required a functional copy of exsA. Divergent promoters, coordinately regulated with exoS transcription, were identified within the PstI-NsiI fragment. A fusion derivative of ExsA, MALA3A2, was shown to bind directly to the PstI-NsiI probe. DNase I protection analysis demonstrated that MALA3A2 bound to the intergenic region between the postulated -35 boxes of each promoter region. Northern (RNA) blot analysis with probes internal to and upstream of exoS demonstrated that separate, coordinately regulated mRNAs were expressed in P. aeruginosa. These data suggested that a locus, coregulated with exoS transcription, was located upstream of exoS. DNA sequence analysis of the exoS upstream region revealed three open reading frames, ORF 1, ORF 2, and ORF 3. ORF 1 demonstrated significant homology to the SycE/YerA protein of Yersinia sp. SycE/YerA is postulated to function as a chaperone for the YopE cytotoxin. The loci encoding YopE and ExoS show similarities in genetic organization, protein composition, and regulation.

Transcriptional organization of the trans-regulatory locus which controls exoenzyme S synthesis in Pseudomonas aeruginosa.

The transcriptional organization of the exoenzyme S trans-regulatory locus was studied by using promoter fusion and transcriptional start site mapping analyses. The 5' regions flanking open reading frames encoding ExsC, ExsB, ExsA, and ExsD were cloned in both orientations into the promoter vector pQF26, which contains the chloramphenicol acetyltransferase reporter gene (cat). CAT activity from each promoter fusion transformed into Pseudomonas aeruginosa and Escherichia coli was measured. The trans-regulatory locus promoters demonstrated low to undetectable CAT activity in E. coli regardless of the orientation of the DNA fragment relative to the reporter gene. In P. aeruginosa two of the promoter clones containing DNA located 5' of exsC (pC) and exsD (pD) demonstrated significant CAT activity. Transcriptional initiation from pC and pD was dependent on the orientation of the DNA fragment, the inclusion of a chelator in the growth medium, and the presence of a functional exsA gene. Transcriptional start sites were mapped for the pC and pD promoter regions by using total RNA isolated from P. aeruginosa strains grown in medium including a chelator. Our data are consistent with an operon model for the transcriptional organization of the exoenzyme S trans-regulatory locus. In addition, ExsA appears to be involved in controlling transcriptional initiation from both the trans-regulatory locus and a region located immediately downstream of the exsA gene.

Cloning the structural gene for the 49-kDa form of exoenzyme S (exoS) from Pseudomonas aeruginosa strain 388.

We report the purification and proteolytic characterization of the 49-kDa form of exoenzyme S and the cloning of the structural gene for the 49-kDa form of exoenzyme S (exoS). The 49-kDa form of exoenzyme S was purified from SDS-polyacrylamide gels. Conditions were established that allowed efficient trypsin digestion of the 49-kDa form of exoenzyme S. Amino acid sequence determination of the amino terminus and tryptic peptides of the 49-kDa form of exoenzyme S allowed the generation of degenerate oligonucleotides, which were used to amplify DNA encoding an amino-terminal sequence and an internal sequence of the 49-kDa form of exoenzyme S. These DNA fragments were used to clone the entire structural gene for the 49-kDa form of exoenzyme S (exoS) from a cosmid library of Pseudomonas aeruginosa strain 388. The 49-kDa form of exoenzyme S (ExoS) is predicted to be a 453 amino acid protein. The predicted amino acid sequence indicates that ExoS is secreted from Pseudomonas without cleavage of an amino-terminal sequence. BESTFIT analysis identified three regions of alignment between ExoS and the active site of Escherichia coli heat-labile enterotoxin. One region of homology appears to be shared among several members of the family of bacterial ADP-ribosyltransferases.