Pseudomonas aeruginosa 1244 pilin glycosylation: glycan substrate recognition

The pilin of Pseudomonas aeruginosa 1244 is glycosylated with an oligosaccharide that is structurally identical to the O-antigen repeating unit of this organism. Concordantly, the metabolic source of the pilin glycan is the O-antigen biosynthetic pathway. The present study was conducted to investigate glycan substrate recognition in the 1244 pilin glycosylation reaction. Comparative structural analysis of O subunits that had been previously shown to be compatible with the 1244 glycosylation machinery revealed similarities among sugars at the presumed reducing termini of these oligosaccharides. We therefore hypothesized that the glycosylation substrate was within the sugar at the reducing end of the glycan precursor. Since much is known of PA103 O-antigen genetics and because the sugars at the reducing termini of the O7 (strain 1244) and O11 (strain PA103) are identical (beta-N-acetyl fucosamine), we utilized PA103 and strains that express lipopolysaccharide (LPS) with a truncated O-antigen subunit to test our hypothesis. LPS from a strain mutated in the wbjE gene produced an incomplete O subunit, consisting only of the monosaccharide at the reducing end (beta-d-N-acetyl fucosamine), indicating that this moiety contained substrate recognition elements for WaaL. Expression of pilAO(1244) in PA103 wbjE::aacC1, followed by Western blotting of extracts of these cells, indicated that pilin produced has been modified by the addition of material consistent with a single N-acetyl fucosamine. This was confirmed by analyzing endopeptidase-treated pilin by mass spectrometry. These data suggest that the pilin glycosylation substrate recognition features lie within the reducing-end moiety of the O repeat and that structures of the remaining sugars are irrelevant.     

Glycosylation of Pseudomonas aeruginosa 1244 pilin: glycan substrate specificity

The structural similarity between the pilin glycan and the O-antigen of Pseudomonas aeruginosa 1244 suggested that they have a common metabolic origin. Mutants of this organism lacking functional wbpM or wbpL genes synthesized no O-antigen and produced only non-glycosylated pilin. Complementation with plasmids containing functional wbpM or wbpL genes fully restored the ability to produce both O-antigen and glycosylated pilin. Expression of a cosmid clone containing the O-antigen biosynthetic gene cluster from P. aeruginosa PA103 (LPS serotype O11) in P. aeruginosa 1244 (LPS serotype O7) resulted in the production of strain 1244 pili that contained both O7 and O11 antigens. The presence of the O11 repeating unit was confirmed by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry. Expression of the O-antigen biosynthesis cluster from Escherichia coli O157:H7 in strain 1244 resulted in the production of pilin that contained both the endogenous Pseudomonas as well as the Escherichia O157 O-antigens. A role for pilO in the glycosylation of pilin in P. aeruginosa is evident as the cloned pilAO operon produced glycosylated strain 1244 pilin in eight heterologous P. aeruginosa strains. Removal of the pilO gene resulted in the production of unmodified strain 1244 pilin. These results show that the pilin glycan of P. aeruginosa 1244 is a product of the O-antigen biosynthetic pathway. In addition, the structural diversity of the O-antigens used by the 1244 pilin glycosylation apparatus indicates that the glycan substrate specificity of this reaction is extremely low.     

Glycosylation substrate specificity of Pseudomonas aeruginosa 1244 pilin

The beta-carbon of the Pseudomonas aeruginosa 1244 pilin C-terminal Ser is a site of glycosylation. The present study was conducted to determine the pilin structures necessary for glycosylation. It was found that although Thr could be tolerated at the pilin C terminus, the blocking of the Ser carboxyl group with the addition of an Ala prevented glycosylation. Pilin from strain PA103 was not glycosylated by P. aeruginosa 1244, even when the C-terminal residue was converted to Ser. Substituting the disulfide loop region of strain PA103 pilin with that of strain 1244 allowed glycosylation to take place. Neither conversion of 1244 pilin disulfide loop Cys residues to Ala nor the deletion of segments of this structure prevented glycosylation. It was noted that the PA103 pilin disulfide loop environment was electronegative, whereas that of strain 1244 pilin had an overall positive charge. Insertion of a positive charge into the PA103 pilin disulfide loop of a mutant containing Ser at the C terminus allowed glycosylation to take place. Extending the "tail" region of the PA103 mutant pilin containing Ser at its terminus resulted in robust glycosylation. These results suggest that the terminal Ser is the major pilin glycosylation recognition feature and that this residue cannot be substituted at its carboxyl group. Although no other specific recognition features are present, the pilin surface must be compatible with the reaction apparatus for glycosylation to occur.     

Structural characterization of the Pseudomonas aeruginosa 1244 pilin glycan

An antigenic similarity between lipopolysaccharide (LPS) and glycosylated pilin of Pseudomonas aeruginosa 1244 was noted. We purified a glycan-containing molecule from proteolytically digested pili and showed it to be composed of three sugars and serine. This glycan competed with pure pili and LPS for reaction with an LPS-specific monoclonal antibody, which also inhibited twitching motility by P. aeruginosa bearing glycosylated pili. One-dimensional NMR analysis of the glycan indicated the sugars to be 5N beta OHC(4)7NfmPse, Xyl, and FucNAc. The complete proton assignments of these sugars as well as the serine residue were determined by COSY and TOCSY. Electrospray ionization mass spectrometry (MS) determined the mass of this molecule to be 771.5. The ROESY NMR spectrum, tandem MS/MS analysis, and methylation analysis provided information on linkage and the sequence of oligosaccharide components. These data indicated that the molecule had the following structure: alpha-5N beta OHC(4)7NFmPse-(2-->4)beta-Xyl-(1-->3)-beta-FucNAc-(1-->3)-beta-Ser.     

Glycosylation of Pilin and Nonpilin Protein Constructs by Pseudomonas aeruginosa 1244

PilO is an oligosaccharyl transferase (OTase) that catalyzes the O-glycosylation of Pseudomonas aeruginosa 1244 pilin by adding a single O-antigen repeating unit to the β carbon of the C-terminal residue (a serine). While PilO has an absolute requirement for Ser/Thr at this position, it is unclear if this enzyme must recognize other pilin features. To test this, pilin constructs containing peptide extensions terminating with serine were tested for the ability to support glycosylation. It was found that a 15-residue peptide, which had been modeled on the C-proximal region of strain 1244 pilin, served as a PilO substrate when it was expressed on either group II or group III pilins. In addition, adding a 3-residue extension culminating in serine to the C terminus of a group III pilin supported PilO activity. A protein fusion composed of strain 1244 pilin linked at its C terminus with Escherichia coli alkaline phosphatase (which, in turn, contained the above-mentioned 15 amino acids at its C terminus) was glycosylated by PilO. E. coli alkaline phosphatase lacking the pilin membrane anchor and containing the 15-residue peptide was also glycosylated by PilO. Addition of the 3-residue extension did not allow glycosylation of either of these constructs. Site-directed mutagenesis of strain 1244 pilin residues of the C-proximal region common to the group I proteins showed that this structure was not required for glycosylation. These experiments indicate that pilin common sequence is not required for glycosylation and show that nonpilin protein can be engineered to be a PilO substrate.Colonization and dissemination of the opportunistic pathogen Pseudomonas aeruginosa rely to a large extent on the ability of this organism to produce functional type IV pili (26). These protein fibers, which radiate from the cell pole, are adhesion factors (51), mediate a form of surface translocation referred to as twitching motility (10, 37), and are important in biofilm formation (39). The pili of this organism are primarily composed of a monomeric subunit called pilin (PilA). Type IV pili can be differentiated into two classes (a or b) on the basis of the PilA sequence and structure (23). Although they display considerable sequence variation, the majority of the type IVa pilins of P. aeruginosa can be placed into one of three groups on the basis of primary structure and antigenicity, as well as by the presence of auxiliary pilin genes found immediately downstream from pilA (8, 33). We previously determined that pilin from P. aeruginosa 1244, which belongs to group I (8), contained an O-antigen repeating unit covalently attached to the β-hydroxyl group of a serine residing at the C terminus of this protein (7). While the specific physiological role of the pilin glycan in this organism is not clear, the presence of this saccharide influences pilus hydrophobicity and has a pronounced effect on virulence, as determined in a mouse respiratory model (47). The metabolic origin of the pilin saccharide is the O-antigen biosynthetic pathway (14), and its attachment is catalyzed by an oligosaccharyl transferase (OTase) called PilO (6). Specific regions of this cytoplasmic membrane protein necessary for glycosylation activity have been identified (42). Topological studies of PilO have shown that these regions face the periplasm, suggesting that pilin glycosylation takes place in this chamber (42). Here the glycan substrate is the O-antigen repeating unit covalently linked to the undecaprenol carrier lipid.PilO has a very relaxed glycan substrate specificity, as indicated by the evidence that it is able to utilize a number of structurally dissimilar O-antigen repeating units as substrate (14), and requires only features of the reducing end sugar to carry out pilin glycosylation (28). WaaL, the enzyme that transfers polymerized O antigen to core lipid A, from Escherichia coli also has a similar broad glycan specificity (19). Recent studies (18) provided evidence that PglL, an OTase of Neisseria meningitidis, recognized only the carrier lipid and was able to attach a variety of saccharides to the pilin of this organism. Although the glycan specificity of PilO is relaxed, this enzyme will not attach other carrier lipid-bound saccharides, such as the peptidoglycan subunit or polymerized O-antigen repeating unit, to pilin. This is indicated by the absence of pilins with increased mass in O-antigen-negative mutants or the production of multiple pilin sizes in the wild-type strain (6).In vivo analysis of mutagenized P. aeruginosa 1244 pilin showed that the C-terminal serine of this protein was a major pilin glycosylation recognition feature of PilO (27). In addition, modification (substitution of the C-terminal amino acid with a 3-residue sequence terminating in serine) of a group II pilin allowed PilO-dependent attachment of the O-antigen repeating unit (27). While these results suggested that the preponderance of pilin structural information was not required for glycosylation, it was not clear whether regions common among the P. aeruginosa pilins were needed. In the present study three types of experiments were carried out in order to answer this question. First, the glycosylation site was extended away from the pilin surface with the addition of a 15-residue peptide which terminates with serine. Second, an engineered periplasmic protein containing the glycosylation residue at its C terminus was fused with pilin and tested for PilO activity. Finally, this periplasmic protein containing no pilin common region was constructed and tested. Evidence presented in this paper suggests that PilO requires only the glycosylation target residue.The work presented also indicated that, in addition to pilins, nonpilin protein free in the periplasm or anchored to the cytoplasmic membrane could be engineered so as to serve as a PilO substrate. These results suggest that a wide range of pilins and nonpilin proteins can be engineered to serve as substrate for glycosylation, a finding that would potentially have practical value, particularly in the area of vaccine construction. In addition to elucidating the protein specificity of the PilO system, the present work determined that the peptide extension used can supply functional epitope information to the modified protein, in addition to providing a site for glycosylation. Altogether, the results presented suggest that engineering of pilins and nonpilin proteins for the biological generation of protein-peptide-saccharide constructs is a potentially important strategy in vaccine design.     

The subcellular localization of a C-terminal processing protease in Pseudomonas aeruginosa

Carboxy (C)-terminal processing proteases (CTP) are a relatively new group of serine proteases. Found in a broad range of organisms - bacteria, archaea, algae, plants and animals - these proteases are involved in the C-terminal processing of proteins. In comparison with amino-terminal processing of bacterial proteins, less is known about C-terminal processing and its physiological function. Bacterial CTPs appear to influence different basal cellular processes. Although CTPs of Gram-negative bacteria are generally referred to as being localized in the periplasm, there is little experimental evidence for this. We show for the first time the subcellular localization of a CTP-3 family protein from Pseudomonas aeruginosa, named CtpA, in the periplasm by a carefully designed fractionation study. Our results provide experimental evidence for the generally accepted hypothesis that CTPs are located in the periplasmic space of Gram-negative bacteria.     

Chromosomal location and function of genes affecting Pseudomonas aeruginosa nitrate assimilation

Seven known genes control Pseudomonas aeruginosa nitrate assimilation. Three of the genes, designated nas, are required for the synthesis of assimilatory nitrate reductase: nasC encodes a structural component of the enzyme; nasA and nasB encode products that participate in the biosynthesis of the molybdenum cofactor of the enzyme. A fourth gene (nis) is required for the synthesis of assimilatory nitrite reductase. The remaining three genes (ntmA, ntmB, and ntmC) control the assimilation of a number of nitrogen sources. The nas genes and two ntm genes have been located on the chromosome and are well separated from the known nar genes which encode synthesis of dissimilatory nitrate reductase. Our data support the previous conclusion that P. aeruginosa has two distinct nitrate reductase systems, one for the assimilation of nitrate and one for its dissimilation.     

Alteration of protein subcellular location and domain formation by alternative translational initiation

Alternative translation is an important cellular mechanism contributing to the generation of proteins and the diversity of protein functions. Instead of studying individual cases, we systematically analyzed the alteration of protein subcellular location and domain formation by alternative translational initiation in eukaryotes. The results revealed that 85.7% of alternative translation events generated biological diversity, attributed to different subcellular localizations and distinct domain contents in alternative isoforms. Analysis of isoelectric point values revealed that most N-terminal truncated isoforms significantly lowered their isoelectric point values targeted at different subcellular localizations, whereas they had conserved domain contents the same as the full-length isoforms. Furthermore, Fisher's exact test indicated that the two ways-targeting at different cellular compartments and changing domain contents-were negatively associated. The N-term truncated isoforms should have only one way to diversify their functions distinct from the full-length ones. The peculiar consequence of subcellular relocation as well as change of domain contents reflected the very high level of biological complexity as alternative usage of initiation codons.     

HD-GYP domain proteins regulate biofilm formation and virulence in Pseudomonas aeruginosa

HD-GYP is a protein domain involved in the hydrolysis of the bacterial second messenger cyclic-di-GMP. The genome of the human pathogen Pseudomonas aeruginosa PAO1 encodes two proteins (PA4108, PA4781) with an HD-GYP domain and a third protein, PA2572, which contains a domain with variant key residues (YN-GYP). Here we have investigated the role of these proteins in biofilm formation, virulence factor synthesis and virulence of P. aeruginosa . Mutation of PA4108 and PA4781 led to an increase in the level of cyclic-di-GMP in P. aeruginosa , consistent with the predicted activity of the encoded proteins as cyclic-di-GMP phosphodiesterases. Mutation of both genes led to reduced swarming motility but had differing effects on production of the virulence factors pyocyanin, pyoverdin and ExoS. Mutation of PA2572 had no effect on cyclic-di-GMP levels and did not influence swarming motility. However, PA2572 had a negative influence on swarming that was cryptic and was revealed only after removal of an uncharacterized C-terminal domain. Mutation of PA4108 , PA4781 and PA2572 had distinct effects on biofilm formation and architecture of P. aeruginosa. All three proteins contributed to virulence of P. aeruginosa to larvae of the Greater Wax moth Galleria mellonella.     

Ribonucleotide reductase modularity: Atypical duplication of the ATP-cone domain in Pseudomonas aeruginosa

The opportunistic pathogen Pseudomonas aeruginosa, which causes serious nosocomial infections, is a gamma-proteobacterium that can live in many different environments. Interestingly P. aeruginosa encodes three ribonucleotide reductases (RNRs) that all differ from other well known RNRs. The RNR enzymes are central for de novo synthesis of deoxyribonucleotides and essential to all living cells. The RNR of this study (class Ia) is a complex of the NrdA protein harboring the active site and the allosteric sites and the NrdB protein harboring a tyrosyl radical necessary to initiate catalysis. P. aeruginosa NrdA contains an atypical duplication of the N-terminal ATP-cone, an allosteric domain that can bind either ATP or dATP and regulates the overall enzyme activity. Here we characterized the wild type NrdA and two truncated NrdA variants with precise N-terminal deletions. The N-terminal ATP-cone (ATP-c1) is allosterically functional, whereas the internal ATP-cone lacks allosteric activity. The P. aeruginosa NrdB is also atypical with an unusually short lived tyrosyl radical, which is efficiently regenerated in presence of oxygen as the iron ions remain tightly bound to the protein. The P. aeruginosa wild type NrdA and NrdB proteins form an extraordinarily tight complex with a suggested alpha4beta4 composition. An alpha2beta2 composition is suggested for the complex of truncated NrdA (lacking ATP-c1) and wild type NrdB. Duplication or triplication of the ATP-cone is found in some other bacterial class Ia RNRs. We suggest that protein modularity built on the common catalytic core of all RNRs plays an important role in class diversification within the RNR family.     

Organic solvent-selective domain of the resistance-nodulation-division-type xenobiotic-antibiotic transporters of Pseudomonas aeruginosa

The hydrophobic substrate-selective domain of the resistance-nodulation-division-type xenobiotic transporter of Pseudomonas aeruginosa was assigned based on the different organic-solvent selectivities of MexB and MexY. The MexB-MexY hybrid protein consisting of two large periplasmic domains of MexB and the transmembrane domains of MexY showed MexB-type organic solvent selectivity. The results imply that the resistance-nodulation-division-type xenobiotic transporters recognize hydrophobic substrates such as organic solvents by their periplasmic domains and expel them to the external milieu. This is an elegant way to protect the cytoplasmic membrane from membrane-deteriorating agents.     

Using functional domain composition and support vector machines for prediction of protein subcellular location

Proteins are generally classified into the following 12 subcellular locations: 1) chloroplast, 2) cytoplasm, 3) cytoskeleton, 4) endoplasmic reticulum, 5) extracellular, 6) Golgi apparatus, 7) lysosome, 8) mitochondria, 9) nucleus, 10) peroxisome, 11) plasma membrane, and 12) vacuole. Because the function of a protein is closely correlated with its subcellular location, with the rapid increase in new protein sequences entering into databanks, it is vitally important for both basic research and pharmaceutical industry to establish a high throughput tool for predicting protein subcellular location. In this paper, a new concept, the so-called "functional domain composition" is introduced. Based on the novel concept, the representation for a protein can be defined as a vector in a high-dimensional space, where each of the clustered functional domains derived from the protein universe serves as a vector base. With such a novel representation for a protein, the support vector machine (SVM) algorithm is introduced for predicting protein subcellular location. High success rates are obtained by the self-consistency test, jackknife test, and independent dataset test, respectively. The current approach not only can play an important complementary role to the powerful covariant discriminant algorithm based on the pseudo amino acid composition representation (Chou, K. C. (2001) Proteins Struct. Funct. Genet. 43, 246-255; Correction (2001) Proteins Struct. Funct. Genet. 44, 60), but also may greatly stimulate the development of this area.     

Evidence for the location of OprM in the Pseudomonas aeruginosa outer membrane

Abstract OprM with a M _r of 49 K is associated with the multidrug resistance of Pseudomonas aeruginosa . Detergent fractionation of bacterial cells has demonstrated that OprM is located in the outer membrane from which it sediments with the other major outer membrane proteins. In this study we have determined the location of OprM as the P. aeruginosa outer membrane. Western immunoblots of cell fractions, obtained by sucrose density gradient centrifugation of whole cell lysates, were probed with an OprM-specific murine polyclonal antiserum.     

Exotoxin A of Pseudomonas aeruginosa: evidence that domain I functions in receptor binding

We have constructed defined deletions in the structural gene of Pseudomonas aeruginosa exotoxin A (ETA) in order to probe the function of Domain I of this protein. Three forms of the gene containing specific deletions were expressed in a strain of Escherichia coli K12 with lesions in the htpR and Ion genes; extracts containing the gene products were tested for ADP-ribosylation activity, cytotoxicity, and ability to protect sensitive cells from the cytotoxic action of authentic ETA. Two of the mutant ETAs gave concentration-dependent protection against authentic ETA, and protection correlated with the presence of the bulk of Domain I. The results support the notion that Domain I functions in binding the toxin to specific cell-surface receptors.     

Ferrisiderophore reductases of Pseudomonas. Purification, properties and cellular location of the Pseudomonas aeruginosa ferripyoverdine reductase.

Purification of the ferripyoverdine reductase from Pseudomonas aeruginosa, strain PAO1, lead to the isolation of a soluble protein of M(r) 27,000-28,000, as determined by HPLC sieving filtration and by denaturating gel electrophoresis. In the presence of NADH as the reductant, ferripyoverdine as the iron substrate, ferrozine as an iron(II)-trapping agent and FMN, this protein displayed an iron-reductase activity which resulted in the formation of ferrozine-iron(II) complex, providing that the enzymic assay was run under strict anaerobiosis. FMN was absolutely required for the activity to occur, but the lack of a visible spectrum and the lack of fluorescence for the protein in solution suggested that ferripyoverdine reductase is not a flavin-containing protein and that covalently bound FMN is not a prerequisite for the enzymatic reaction. A search of ferripyoverdine reductase by immunological detection amongst the different cellular compartments of P. aeruginosa lead to the conclusion that the soluble enzyme, which represented more than 95% of the total cellular enzyme, is not located in the periplasm but specifically in the cytoplasm. A strongly immunoreacting material, corresponding to a protein with identical M(r) as the ferripyoverdine reductase of P. aeruginosa PAO1, was detected in all the eighteen fluorescent pseudomonad strains belonging to the P. aeruginosa, P. fluorescens, P. putida and P. chlororaphis species, as well as in P. stutzeri, a non-fluorescent species, suggesting that the enzyme acting as a ferripyoverdine reductase in P. aeruginosa PAO1 is ubiquitous among the Pseudomonas.     

Translocon-independent intracellular replication by Pseudomonas aeruginosa requires the ADP-ribosylation domain of ExoS

Pseudomonas aeruginosa, a significant cause of human morbidity and mortality, uses a type 3 secretion system (T3SS) to inject effector toxins into host cells. We previously reported that P. aeruginosa uses ADP-ribosyltransferase (ADPr) activity of the T3SS effector ExoS for intracellular replication. T3SS translocon (ΔpopB)-mutants, which can export, but not translocate effectors across host membranes, retained intracellular replication. We hypothesized that secreted effectors mediate translocon-independent intracellular replication. Translocon mutants of PAO1 lacking one or more of its three known effectors (ExoS, ExoT and ExoY) were used. All translocon mutants, irrespective of effectors expressed, localized to intracellular vacuoles. Translocon-effector null mutants and translocon-exoS mutants showed defective intracellular replication. Mutants in exoT, exoY or both replicated as efficiently as translocon mutants expressing all effectors. Complementation of translocon-effector null mutants with native exoS or a membrane localization domain mutant of exoS, but not the ADPr mutant exoS (pUCPexoSE381D), restored intracellular replication, correlating with increased bacteria per vacuole. Thus, P. aeruginosa is capable of intravacuolar replication that requires ExoS ADPr activity, but not the translocon. These data suggest that T3SS effectors can participate in pathogenesis without translocon-mediated translocation across host membranes, and that intracellular bacteria can contribute to P. aeruginosa pathogenesis within epithelial cells.