Alginate synthesis in Pseudomonas aeruginosa: the role of AlgL (alginate lyase) and AlgX.

Previous studies localized an alginate lyase gene (algL) within the alginate biosynthetic gene cluster at 34 min on the Pseudomonas aeruginosa chromosome. Insertion of a Tn501 polar transposon in a gene (algX) directly upstream of algL in mucoid P. aeruginosa FRD1 inactivated expression of algX, algL, and other downstream genes, including algA. This strain is phenotypically nonmucoid; however, alginate production could be restored by complementation in trans with a plasmid carrying all of the genes inactivated by the insertion, including algL and algX. Alginate production was also recovered when a merodiploid that generated a complete alginate gene cluster on the chromosome was constructed. However, alginate production by merodiploids formed in the algX::Tn501 mutant using an alginate cluster with an algL deletion was not restored to wild-type levels unless algL was provided on a plasmid in trans. In addition, complementation studies of Tn501 mutants using plasmids containing specific deletions in either algL or algX revealed that both genes were required to restore the mucoid phenotype. Escherichia coli strains which expressed algX produced a unique protein of approximately 53 kDa, consistent with the gene product predicted from the DNA sequencing data. These studies demonstrate that AlgX, whose biochemical function remains to be defined, and AlgL, which has alginate lyase activity, are both involved in alginate production by P. aeruginosa.     

Alginate production by an <Emphasis Type="Italic">Azotobacter vinelandii</Emphasis> mutant unable to produce alginate lyase

Alginate is an industrially relevant linear copolymer composed of beta-1,4-linked D-mannuronic acid and its C-5 epimer L-guluronic acid. The rheological and gel-forming properties of alginates depend on the molecular weight and the relative content of the two monomers. Alginate produced by Azotobacter vinelandii was shown to be degraded towards the end of the culture, an undesirable situation in terms of potential alginate applications. A gene ( algL) encoding the alginate lyase activity AlgL is present within the alginate biosynthetic gene cluster of A. vinelandii. We constructed strain SML2, an A. vinelandii strain carrying a non-polar mutation within algL. No alginate lyase activity was detected in SML2. Under 3% dissolved oxygen tension, higher values of maximum mean molecular weight alginate were obtained (1240 kDa) with strain SML2, compared to those from the parental strain ATCC 9046 (680 kDa). These data indicate that AlgL activity causes the drop in the molecular weight of alginate produced by A. vinelandii.     

Alginate lyase (AlgL) activity is required for alginate biosynthesis in Pseudomonas aeruginosa

To determine whether AlgL's lyase activity is required for alginate production in Pseudomonas aeruginosa, an algLdelta::Gm(r) mutant (FRD-MA7) was created. algL complementation of FRD-MA7 restored alginate production, but algL constructs containing mutations inactivating lyase activity did not, demonstrating that the enzymatic activity of AlgL is required for alginate production.     

Cloning and expression of the algL gene, encoding the Azotobacter chroococcum alginate lyase: purification and characterization of the enzyme

The alginate lyase-encoding gene (algL) of Azotobacter chroococcum was localized to a 3.1-kb EcoRI DNA fragment that revealed an open reading frame of 1,116 bp. This open reading frame encodes a protein of 42.98 kDa, in agreement with the value previously reported by us for this protein. The deduced protein has a potential N-terminal signal peptide that is consistent with its proposed periplasmic location. The analysis of the deduced amino acid sequence indicated that the gene sequence has a high homology (90% identity) to the Azotobacter vinelandii gene sequence, which has very recently been deposited in the GenBank database, and that it has 64% identity to the Pseudomonas aeruginosa gene sequence but that it has rather low homology (15 to 22% identity) to the gene sequences encoding alginate lyase in other bacteria. The A. chroococcum AlgL protein was overproduced in Escherichia coli and purified to electrophoretic homogeneity in a two-step chromatography procedure on hydroxyapatite and phenyl-Sepharose. The kinetic and molecular parameters of the recombinant alginate lyase are similar to those found for the native enzyme.     

Identification of algF in the alginate biosynthetic gene cluster of Pseudomonas aeruginosa which is required for alginate acetylation.

Mucoid strains of Pseudomonas aeruginosa produce a high-molecular-weight exopolysaccharide called alginate that is modified by the addition of O-acetyl groups. To better understand the acetylation process, a gene involved in alginate acetylation called algF was identified in this study. We hypothesized that a gene involved in alginate acetylation would be located within the alginate biosynthetic gene cluster at 34 min on the P. aeruginosa chromosome. To isolate algF mutants, a procedure for localized mutagenesis was developed to introduce random chemical mutations into the P. aeruginosa alginate biosynthetic operon on the chromosome. For this, a DNA fragment containing the alginate biosynthetic operon and adjacent argF gene in a gene replacement cosmid vector was utilized. The plasmid was packaged in vivo into lambda phage particles, mutagenized in vitro with hydroxylamine, transduced into Escherichia coli, and mobilized to an argF auxotroph of P. aeruginosa FRD. Arg+ recombinants coinherited the mutagenized alginate gene cluster and were screened for defects in alginate acetylation by testing for increased sensitivity to an alginate lyase produced by Klebsiella aerogenes. Alginates from recombinants which showed increased sensitivity to alginate lyase were tested for acetylation by a colorimetric assay and infrared spectroscopy. Two algF mutants that produced alginates reduced more than sixfold in acetyl groups were obtained. The acetylation defect was complemented in trans by a 3.8-kb XbaI-BamHI fragment from the alginate gene cluster when placed in the correct orientation under a trc promoter. By a merodiploid analysis, the algF gene was further mapped to a region directly upstream of algA by examining the polar effect of Tn501 insertions. By gene replacement, DNA with a Tn501 insertion directly upstream of algA was recombined with the chromosome of mucoid strain FRD1. The resulting strain, FRD1003, was nonmucoid because of the polar effect of the transposon on the downstream algA gene. By providing algA in trans under the tac promoter, FRD1003 produced nonacetylated alginate, indicating that the transposon was within or just upstream of algF. These results demonstrated that algF, a gene involved in alginate acetylation, is located directly upstream of algA.     

Characterization of alginate lyase from Pseudomonas syringae pv. syringae

The gene encoding alginate lyase (algL) in Pseudomonas syringae pv. syringae was cloned, sequenced, and overexpressed in Escherichia coli. Alginate lyase activity was optimal when the pH was 7.0 and when assays were conducted at 42 degrees C in the presence of 0.2 M NaCl. In substrate specificity studies, AlgL from P. syringae showed a preference for deacetylated polymannuronic acid. Sequence alignment with other alginate lyases revealed conserved regions within AlgL likely to be important for the structure and/or function of the enzyme. Site-directed mutagenesis of histidine and tryptophan residues at positions 204 and 207, respectively, indicated that these amino acids are critical for lyase activity.     

Cloning of Pseudomonas aeruginosa algG, which controls alginate structure.

The biochemical mechanism by which alpha-L-guluronate (G) residues are incorporated into alginate by Pseudomonas aeruginosa is not understood. P. aeruginosa first synthesizes GDP-mannuronate, which is used to incorporate beta-D-mannuronate residues into the polymer. It is likely that the conversion of some beta-D-mannuronate residues to G occurs by the action of a C-5 epimerase at either the monomer (e.g., sugar-nucleotide) or the polymer level. This study describes the results of a molecular genetic approach to identify a gene involved in the formation or incorporation of G residues into alginate by P. aeruginosa. Mucoid P. aeruginosa FRD1 was chemically mutagenized, and mutants FRD462 and FRD465, which were incapable of incorporating G residues into alginate, were independently isolated. Assays using a G-specific alginate lyase from Klebsiella aerogenes and 1H-nuclear magnetic resonance analyses showed that G residues were absent in the alginates secreted by these mutants. 1H-nuclear magnetic resonance analyses also showed that alginate from wild-type P. aeruginosa contained no detectable blocks of G. The mutations responsible for defective incorporation of G residues into alginate in the mutants FRD462 and FRD465 were designated algG4 and algG7, respectively. Genetic mapping experiments revealed that algG was closely linked (greater than 90%) to argF, which lies at 34 min on the P. aeruginosa chromosome and is adjacent to a cluster of genes required for alginate biosynthesis. The clone pALG2, which contained 35 kilobases of P. aeruginosa DNA that included the algG and argF wild-type alleles, was identified from a P. aeruginosa gene bank by a screening method that involved gene replacement. A DNA fragment carrying algG was shown to complement algG4 and algG7 in trans. The algG gene was physically mapped on the alginate gene cluster by subcloning and Tn501 mutagenesis.     

Role of alginate lyase in cell detachment of Pseudomonas aeruginosa.

The exopolysaccharide alginate of Pseudomonas aeruginosa was shown to be important in determining the degree of cell detachment from an agar surface. Nonmucoid strain 8822 gave rise to 50-fold more sloughed cells than mucoid strains 8821 and 8830. Alginate anchors the bacteria to the agar surface, thereby influencing the extent of detachment. The role of the P. aeruginosa alginate lyase in the process of cell sloughing was investigated. Increased expression of the alginate lyase in mucoid strain 8830 led to alginate degradation and increased cell detachment. Similar effects were seen both when the alginate lyase was induced at the initial stage of cell inoculation and when it was induced at a later stage of growth. It appears that high-molecular-weight alginate polymers are required to efficiently retain the bacteria within the growth film. When expressed from a regulated promoter, the alginate lyase can induce enhanced sloughing of cells because of degradation of the alginate. This suggests a possible role for the lyase in the development of bacterial growth films.     

Genetic analysis of the transcriptional arrangement of Azotobacter vinelandii alginate biosynthetic genes: identification of two independent promoters

The study of alginate biosynthesis, the exopolysac charide produced by Azotobacter vinelandii and Pseudomonas aeruginosa, might lead to different bio-technological applications. Here we report the cloning of A. vinelandii algA, the gene coding for the bifunctional enzyme phosphomannose isomerase-guano-sine diphospho-D-mannose pyrophosphorylase (PMI-GMP). This gene was selected by the complementation for xanthan gum production of Xanthomonas campestris pv. campestris xanB mutants, which lack this enzymatic activity. The complementing cosmid clones selected, besides containing algA, presented a gene coding for an alginate lyase activity (algL), and some of them also contained algD which codes for GDP-mannose dehydrogenase. We present here the characterization of the A. vinelandii chromosomal region comprising algD and its promoter region, algA and algL, showing that, as previously reported for P. aeruginosa, A. vinelandii has a cluster of the biosynthetic alginate genes. We provide evidence for the presence of an algD-independent promoter in this region which transcribes at least algL and algA, and which is regulated in a manner that differs from that of the algD promoter.     

Alg44, a unique protein required for alginate biosynthesis in Pseudomonas aeruginosa

Here the putative alginate biosynthesis gene alg44 of Pseudomonas aeruginosa was functionally assigned. Non-polar isogenic alg44 deletion mutants of P. aeruginosa were generated and did neither produce alginate nor released free uronic acids. No evidence for alginate enrichment in the periplasm was obtained. Alginate production was restored by introducing only the gene alg44. PhoA fusion protein analyses suggested that Alg44 is a soluble protein localized in the periplasm. Hexahistidine-tagged Alg44 was detected by immunoblotting. The corresponding 42.6 kDa protein was purified and identified by MALDI/TOF-MS analysis. Alg44 might be directly involved in alginate polymerization presumably by exerting a regulatory function.     

Adaptations of Pseudomonas aeruginosa to the cystic fibrosis lung environment can include deregulation of zwf, encoding glucose-6-phosphate dehydrogenase

Cystic fibrosis (CF) patients are highly susceptible to chronic pulmonary disease caused by mucoid Pseudomonas aeruginosa strains that overproduce the exopolysaccharide alginate. We showed here that a mutation in zwf, encoding glucose-6-phosphate dehydrogenase (G6PDH), leads to a approximately 90% reduction in alginate production in the mucoid, CF isolate, P. aeruginosa FRD1. The main regulator of alginate, sigma-22 encoded by algT (algU), plays a small but demonstrable role in the induction of zwf expression in P. aeruginosa. However, G6PDH activity and zwf expression were higher in FRD1 strains than in PAO1 strains. In PAO1, zwf expression and G6PDH activity are known to be subject to catabolite repression by succinate. In contrast, FRD1 zwf expression and G6PDH activity were shown to be refractory to such catabolite repression. This was apparently not due to a defect in the catabolite repression control (Crc) protein. Such relaxed control of zwf was found to be common among several examined CF isolates but was not seen in other strains of clinical and environmental origin. Two sets of clonal isolates from individual CF patient indicated that the resident P. aeruginosa strain underwent an adaptive change that deregulated zwf expression. We hypothesized that high-level, unregulated G6PDH activity provided a survival advantage to P. aeruginosa within the lung environment. Interestingly, zwf expression in P. aeruginosa was shown to be required for its resistance to human sputum. This study illustrates that adaptation to the CF pulmonary environment by P. aeruginosa can include altered regulation of basic metabolic activities, including carbon catabolism.     

AlgX is a periplasmic protein required for alginate biosynthesis in Pseudomonas aeruginosa

Alginate, an exopolysaccharide produced by Pseudomonas aeruginosa, provides the bacterium with a selective advantage that makes it difficult to eradicate from the lungs of cystic fibrosis (CF) patients. Previous studies identified a gene, algX, within the alginate biosynthetic gene cluster on the P. aeruginosa chromosome. By probing cell fractions with anti-AlgX antibodies in a Western blot, AlgX was localized within the periplasm. Consistent with these results is the presence of a 26-amino-acid signal sequence. To examine the requirement for AlgX in alginate biosynthesis, part of algX in P. aeruginosa strain FRD1::pJLS3 was replaced with a nonpolar gentamicin resistance cassette. The resulting algXDelta::Gm mutant was verified by PCR and Western blot analysis and was phenotypically nonmucoid (non-alginate producing). The algXDelta::Gm mutant was restored to the mucoid phenotype with wild-type P. aeruginosa algX provided on a plasmid. The algXDelta::Gm mutant was found to secrete dialyzable oligouronic acids of various lengths. Mass spectroscopy and Dionex chromatography indicated that the dialyzable uronic acids are mainly mannuronic acid dimers resulting from alginate lyase (AlgL) degradation of polymannuronic acid. These studies suggest that AlgX is part of a protein scaffold that surrounds and protects newly formed polymers from AlgL degradation as they are transported within the periplasm for further modification and eventual transport out of the cell.     

Specific recognition of the major capsid protein of Acanthamoeba polyphaga mimivirus by sera of patients infected by Francisella tularensis

The enzymes involved in the catabolism of leucine are encoded by the liu gene cluster in Pseudomonas aeruginosa PAO1. A mutant in the liuE gene (ORF PA2011) of P. aeruginosa was unable to utilize both leucine/isovalerate and acyclic terpenes as the carbon source. The liuE mutant grown in culture medium with citronellol accumulated metabolites of the acyclic terpene pathway, suggesting an involvement of liuE in both leucine/isovalerate and acyclic terpene catabolic pathways. The LiuE protein was expressed as a His-tagged recombinant polypeptide purified by affinity chromatography in Escherichia coli . LiuE showed a mass of 33 kDa under denaturing and 79 kDa under nondenaturing conditions. Protein sequence alignment and fingerprint sequencing suggested that liuE encodes 3-hydroxy-3-methylglutaryl-coenzyme A lyase (HMG-CoA lyase), which catalyzes the cleavage of HMG-CoA to acetyl-CoA and acetoacetate. LiuE showed HMG-CoA lyase optimal activity at a pH of 7.0 and 37 °C, an apparent K _m of 100 μM for HMG-CoA and a V _max of 21 μmol min⁻¹ mg⁻¹. These results demonstrate that the liuE gene of P. aeruginosa encodes for the HMG-CoA lyase, an essential enzyme for growth in both leucine and acyclic terpenes.     

Characterization of AlgMsp,an Alginate Lyase from Microbulbifer sp. 6532A

Alginate is a polysaccharide produced by certain seaweeds and bacteria that consists of mannuronic acid and guluronic acid residues. Seaweed alginate is used in food and industrial chemical processes, while the biosynthesis of bacterial alginate is associated with pathogenic Pseudomonas aeruginosa. Alginate lyases cleave this polysaccharide into short oligo-uronates and thus have the potential to be utilized for both industrial and medicinal applications. An alginate lyase gene, algMsp, from Microbulbifer sp. 6532A, was synthesized as an E.coli codon-optimized clone. The resulting 37 kDa recombinant protein, AlgMsp, was expressed, purified and characterized. The alginate lyase displayed highest activity at pH 8 and 0.2 M NaCl. Activity of the alginate lyase was greatest at 50°C; however the enzyme was not stable over time when incubated at 50°C. The alginate lyase was still highly active at 25°C and displayed little or no loss of activity after 24 hours at 25°C. The activity of AlgMsp was not dependent on the presence of divalent cations. Comparing activity of the lyase against polymannuronic acid and polyguluronic acid substrates showed a higher turnover rate for polymannuronic acid. However, AlgMSP exhibited greater catalytic efficiency with the polyguluronic acid substrate. Prolonged AlgMsp-mediated degradation of alginate produced dimer, trimer, tetramer, and pentamer oligo-uronates.     

Cloning, sequence analysis and expression of Pseudoalteromonas elyakovii IAM 14594 gene (alyPEEC) encoding the extracellular alginate lyase.

A gene (alyPEEC) encoding an alginate lyase of Pseudoalteromonas elyakovii IAM 14594 was cloned using the plasmid vector pUC118 and expressed in Escherichia coli. Sequencing of a 3.0kb fragment revealed a 1,197bp open reading frame encoding 398 amino acid residues. The calculated molecular mass and isoelectric point of the alyPEEC gene product are 43.2 kDa and pI 5.29. A region G(165) to V(194) in the AlyPEEC internal sequence is identical to the N-terminal amino acid sequence of the previously purified extracellular alginate lyase of P. elyakovii, and the calculated molecular mass (25.4 kDa) and isoelectric point (pI 4.78) of the region resembled those of the purified enzyme. Expression of enzymically-active alginate lyase from alyPEEC required growth of recombinant E. coli in LB broth containing 50% (v/v) artificial seawater (ASW). Alginate lyase activity with broad substrate specificity was detected in both 42 and 30 kDa products. Subcloning of the region G(165) to N(398) of AlyPEEC corresponding to the 30 kDa protein confirmed that this region of the alyPEEC gene encoded the active site of the enzyme. A region A(32) to G(164) corresponding to about 13 kDa of the N-terminal region of AlyPEEC showed about 30% identity to a putative chitin binding domain of Streptomyces chitinases, but did not exhibit any catalytic activity.     

A novel type II secretion system in Pseudomonas aeruginosa

The genome sequence of Pseudomonas aeruginosa strain PAO1 has been determined to facilitate postgenomic studies aimed at understanding the capacity of adaptation of this ubiquitous opportunistic pathogen. P. aeruginosa produces toxins and hydrolytic enzymes that are secreted via the type II secretory pathway using the Xcp machinery or 'secreton'. In this study, we characterized a novel gene cluster, called hxc for homologous to xcp. Characterization of an hxcR mutant, grown in phosphate-limiting medium, revealed the absence of a 40 kDa protein found in the culture supernatant of wild-type or xcp derivative mutant strains. The protein corresponded to the alkaline phosphatase L-AP, renamed LapA, which is secreted in an xcp-independent but hxc-dependent manner. Finally, we showed that expression of the hxc gene cluster is under phosphate regulation. This is the first report of the existence of two functional type II secretory pathways within the same organism, which could be related to the high adaptation potential of P. aeruginosa.     

Cloning and sequencing of a Deleya marina gene encoding for alginate lyase

A bacterial strain N-1 was isolated as a decomposer of alginate and identified as Deleya marina. The alyA encoding for alginate lyase was cloned into Escherichia coli. The structural gene, located on a 1.9-kb SalI fragment, revealed 1,122 bp encoding a mature protein of 348 amino acids and a signal peptide of 26 amino acids. The deduced amino acid sequence of the D. marina alginate lyase showed high homology to AlgL of Pseudomonas aeruginosa with 63% identity and belonging to class 1 by hydrophobic cluster analysis.