Wilbert Bitter

The outer membrane component, YscC, of the Yop secretion machinery of Yersinia enterocolitica forms a ring‐shaped multimeric complex

The YscC protein of Yersinia enterocolitica is essential for the secretion of anti‐host factors, called Yops, into the extracellular environment. It belongs to a family of outer membrane proteins, collectively designated secretins, that participate in a variety of transport processes. YscC has been shown to exist as a stable oligomeric complex in the outer membrane. The production of the YscC complex is regulated by temperature and is reduced in strains carrying mutations in the yscN‐U operon or in the virG gene. The VirG lipoprotein was shown to be required for efficient targeting of the complex to the outer membrane. Electron microscopy revealed that purified YscC complexes form ring‐shaped structures of ≈20u2003nm with an apparent central pore. Because of the architecture of the multimer, YscC appears to represent a novel type of channel‐forming proteins in the bacterial outer membrane.

Formation of oligomeric rings by XcpQ and PilQ, which are involved in protein transport across the outer membrane of Pseudomonas aeruginosa

Pseudomonas aeruginosa is able to translocate proteins across both membranes of the cell envelope. Many of these proteins are transported via the type II secretion pathway and adopt their tertiary conformation in the periplasm, which implies the presence of a large transport channel in the outer membrane. The outer membrane protein, XcpQ, which is involved in transport of folded proteins across the outer membrane of P. aeruginosa, was purified as a highly stable homomultimer. Insertion and deletion mutagenesis of xcpQ revealed that the C‐terminal part of XcpQ is sufficient for the formation of the multimer. However, linker insertions in the N‐terminal part can disturb complex formation completely. Furthermore, complex formation is strictly correlated with lethality, caused by overexpression of xcpQ. Electron microscopic evaluation of the XcpQ multimers revealed large, ring‐shaped structures with an apparent central cavity of 95u2003Å. Purified PilQ, a homologue of XcpQ involved in the biogenesis of type IV pili, formed similar structures. However, the apparent cavity formed by PilQ was somewhat smaller, 53u2003Å. The size of this cavity could allow for the transport of intact type IV pili.

The ferric-pseudobactin receptor PupA of Pseudomonas putida WCS358: homology to TonB-dependent Escherichia coli receptors and specificity of the protein

The initial step in the uptake of iron via ferric pseudobactin by the plant‐growth‐promoting Pseudomonas putida strain WCS358 is binding to a specific outer‐membrane protein. The nucleotide sequence of the pupA structural gene, which codes for a ferric pseudobactin receptor, was determined. It contains a single open reading frame which potentially encodes a polypeptide of 819 amino acids, including a putative N‐terminal signal sequence of 47 amino acids. Significant homology, concentrated in four boxes, was found with the TonB‐dependent receptor proteins of Escherichia coli. The pupA mutant MH100 showed a residual efficiency of 30% in the uptake of 55HFe3+ complexed to pseudobactin 358, whereas the iron uptake of four other pseudobactins was not reduced at all. Cells of strain WCS374 supplemented with the pupA gene of strain WCS358 could transport ferric pseudobactin 358 but showed no affinity for three other pseudobactins. It is concluded that PupA is a specific receptor for ferric pseudobactin 358, and that strain WCS358 produces at least one other receptor for other pseudobactins.

Protein secretion mechanisms in Gram-negative bacteria.

Gram-negative bacteria have developed a variety of secretion pathways to secrete toxins and enzymes into the extracellular medium. These pathways are very different with respect to their functional mechanism and complexity, and each system has its own advantages and limitations, regarding the number, size, folding state and fate of their substrates. Pseudomonas aeruginosa secretes many different proteins into the extracellular medium, using at least four secretion pathways. Most of the exoproteins are secreted via the type II system, composed of the 12 Xcp proteins. The only outer membrane protein of the system, XcpQ, belongs to a large family of proteins, designated secretins, which participate in a variety of different transport processes. Other Xcp proteins, XcpT-X, show homology to the subunits of the retractile type IV pili. Further analogies between the type II system and the assembly of retractile pili suggest a mechanism for type II secretion, in which a pilus-like structure, composed of XcpT-X, facilitates the transport of exoproteins through the channel formed by the secretin XcpQ.

Specificity of the lipase-specific foldases of gram-negative bacteria and the role of the membrane anchor

Abstract Folding of lipases that are secreted by Pseudomonads and other gram-negative bacteria via the type II secretion pathway is facilitated by dedicated chaperones, called lipase-specific foldases (Lifs). Lifs are membrane-anchored proteins with a large periplasmic domain. The functional interaction between the Lif and its cognate lipase is specific, since the Pseudomonas aeruginosa Lif was found not to substitute for Lifs from Burkholderia glumae or Acinetobacter calcoaceticus. However, the P. aeruginosa Lif was able to activate the lipase from the closely related species P. alcaligenes. Hybrid proteins constructed from parts of the P. aeruginosa and B. glumae Lifs revealed that the C-terminal 138 amino acids of the B. glumae Lif determine the specificity of the interaction with the cognate lipase. Furthermore, the periplasmic domain of the B. glumae Lif was functional when cloned in frame with a cleavable signal sequence, which demonstrates that the membrane anchor is not essential for Lif function in vivo. However, the recombinant Lif was released into the medium, indicating that the function of the membrane anchor is to prevent secretion of the Lif together with the lipase.

Identification and characterization of the exbB, exbD and tonB genes of Pseudomonas putida WCS358: their involvement in ferric-pseudobactin transport.

Catechol‐cephalosporins are siderophore‐like antibiotics which are taken up by cells of Pseudomonas putida WCS358 via the ferric‐siderophore transport pathway. Mutants of strain WCS358 were isolated that are resistant to high concentrations of these antibiotics. These mutants failed to grow under iron‐limiting conditions, and could not utilize different ferric‐siderophores. The mutants fall in three complementation groups. The nucleotide sequence determination identified three contiguous open reading frames, which were homologous to the exbB, exbD and tonB genes of Escherichia coli respectively. The deduced amino acid sequence of P. putida ExbB showed 58.6% homology with its E. coli homologue, but, unlike the E. coli protein, it has a N‐terminal extension of 91 amino acids. The ExbD proteins are 64.8% homologous, whereas the TonB proteins only show 27.7% homology. The P. putida exbB gene could complement an E. coli exbB mutation, but the TonB proteins were not interchangeable between the species. It is concluded that P. putida WCS358 contains an energy‐coupling system between the membranes for active transport across the outer membrane, which is comprised of a TonB‐like energy‐transducing protein and two accessory proteins. This system is similar to, but not completely compatible with, the E. coli system.

Role of the calcium ion and the disulfide bond in the Burkholderia glumae lipase

Abstract The role of the Ca 2+ ion that is present in the structure of Burkholderia glumae lipase was investigated. Previously, we demonstrated that the denatured lipase could be refolded in vitro into an active enzyme in the absence of calcium. Thus, an essential role for the ion in catalytic activity or in protein folding can be excluded. Therefore, a possible role of the Ca 2+ ion in stabilizing the enzyme was considered. Chelation of the Ca 2+ ion by EDTA severely reduced the enzyme activity and increased its protease sensitivity, however, only at elevated temperatures. Furthermore, EDTA induced unfolding of the lipase in the presence of urea. From these results, it appeared that the Ca 2+ ion in B. glumae lipase fulfils a structural role by stabilizing the enzyme under denaturing conditions. In contrast, calcium appears to play an additional role in the Pseudomonas aeruginosa lipase, since, unlike B. glumae lipase, in vitro refolding of this enzyme was strictly dependent on calcium. Besides the role of the Ca 2+ ion, also the role of the disulfide bond in B. glumae lipase was studied. Incubation of the native enzyme with dithiothreitol reduced the enzyme activity and increased its protease sensitivity at elevated temperatures. Therefore, the disulfide bond, like calcium, appears to stabilize the enzyme under detrimental conditions.

Activation of Pseudomonas aeruginosa elastase in Pseudomonas putida by triggering dissociation of the propeptide-enzyme complex

The propeptide of Pseudomonas aeruginosa elastase functions both as an intramolecular chaperone required for the folding of the enzyme and as an inhibitor that prevents activity of the enzyme before its secretion into the extracellular medium. Since expression of the lasB gene, which encodes elastase, in Pseudomonas putida did not result in extracellular elastase activity, it has been suggested that the enzyme is not recognized by the Xcp secretion machinery of the heterologous host. Here, it is demonstrated that the proenzyme is normally processed in P. putida and that it is indeed not actively secreted by the Xcp machinery. Nevertheless, substantial amounts of the enzyme were detected in the extracellular medium. Co-immunoprecipitations revealed that the extracellular enzyme was associated with the propeptide, which explains the lack of enzymic activity. Since the propeptide-enzyme complex in P. putida apparently does not dissociate spontaneously, it is concluded that a host-specific factor is required to induce this event. Mutants were selected which showed extracellular elastase activity. Two mutations, located within the lasB gene, were further characterized. These mutations, resulting in the substitution of Ala and Thr at positions -15 and -153, respectively, of the propeptide (where position +1 is defined as the first residue of the mature enzyme) destabilized the propeptide-enzyme complex. It is concluded that Ala-15 and Thr-153 are required for the inhibitor function, but not for the chaperone function of the propeptide.

Multiple Outer-membrane Receptors for Uptake of Ferric Pseudobactins in Pseudomonas-putida Wcs358

Under iron limitationPseudomonas putida WCS358 produces a fluorescent siderophore, pseudobactin 358, which, after complexing iron, is transported back into the cell via the specific outer membrane receptor PupA. In addition, this strain has the capacity to take up iron via a large variety of siderophores produced by other fluorescent pseudomonads. Putative receptor genes for such siderophores were identified in the chromosome of strain WCS358 by PCR using primers matching two domains conserved in four ferric pseudobactin receptors, including PupA. Eleven amplification products within the expected size range were obtained. Sequence analysis confirmed that the products were derived from genes encoding outer membrane receptors. Two complete receptor genes were isolated from a genomic library ofP. putida WCS358. Both protein products are involved in the transport of a limited number of specific ferric pseudobactins. These results indicate that the ability ofP. putida WCS358 to exploit many different heterologous pseudobactins is related to the presence of multiple outer membrane receptor proteins.

The role of the positively charged N-terminus of the signal sequence of E. coli outer membrane protein PhoE in export

Signal sequences of prokaryotic exported proteins have a dipolar character due to positively charged amino-acid residues at the N-terminus and to a preferentially negatively charged region around the cleavage site. The role of the two lysine residues at the N-terminus of the signal sequence of outer membrane protein PhoE of E. coli-K12 was investigated. Replacement of both of these residues by aspartic acid slightly affected the kinetics of protein translocation in vivo. This export defect, which was observed only when PhoE was overproduced, could not be suppressed by the prlA4 mutation, which has been shown to restore export defects caused by alterations in the hydrophobic core of the signal sequences of various exported proteins. In an in vitro translocation assay, the export defect was more pronounced. Replacement of both lysines by uncharged residues did not disturb the kinetics of protein export in vivo. In the in vitro assay, an extraordinarily efficient processing was detected upon incubation of this precursor with inverted cytoplasmic membrane vesicles. However, this efficient processing was not accompanied by more efficient translocation of the protein. We conclude that the positively charged residues at the N-terminus of the signal sequence are not essential for protein export, but contribute to the efficiency of the process.