Involvement of the exopolysaccharide alginate in the virulence and epiphytic fitness of Pseudomonas syringae pv. syringae

Alginate, a co-polymer of O-acetylated beta-1,4-linked D-mannuronic acid and L-guluronic acid, has been reported to function in the virulence of Pseudomonas syringae, although genetic studies to test this hypothesis have not been undertaken previously. In the present study, we used a genetic approach to evaluate the role of alginate in the pathogenicity of P. syringae pv. syringae 3525, which causes bacterial brown spot on beans. Alginate biosynthesis in strain 3525 was disrupted by recombining Tn5 into algL, which encodes alginate lyase, resulting in 3525.L. Alginate production in 3525.L was restored by the introduction of pSK2 or pAD4033, which contain the alginate biosynthetic gene cluster from P. syringae pv. syringae FF5 or the algA gene from P. aeruginosa respectively. The role of alginate in the epiphytic fitness of strain 3525 was assessed by monitoring the populations of 3525 and 3525.L on tomato, which is not a host for this pathogen. The mutant 3525.L was significantly impaired in its ability to colonize tomato leaves compared with 3525, indicating that alginate functions in the survival of strain 3525 on leaf surfaces. The contribution of alginate to the virulence of strain 3525 was evaluated by comparing the population dynamics and symptom development of 3525 and 3525.L in bean leaves. Although 3525. L retained the ability to form lesions on bean leaves, symptoms were less severe, and the population was significantly reduced in comparison with 3525. These results indicate that alginate contributes to the virulence of P. syringae pv. syringae 3525, perhaps by facilitating colonization or dissemination of the bacterium in planta.     

Uronic acid sequence in alginate from different sources

Alginate may be considered as a block co-polymer of D-mannuronic and L-guluronic acids, and consists of three types of blocks: homopolymeric blocks of mannuronic acid (MM) and of guluronic acid (GG), and blocks with an alternating sequence (MG). The block composition of alginates has been characterized by a simple chemical method involving partial hydrolysis with acid, followed by fractional precipitation of the acid-resistant part of the alginate. Alginates from eleven different species of brown algae have been examined and, for five species, alginates from different tissues have been compared. The results indicate that young tissue is rich in MM blocks, and that the difference between the alginates from different species is mainly due to the alginates from the older parts of the plants. Extracellular alginates from two types of bacteria have been examined.     

Regulation of nucleoside diphosphate kinase and secretable virulence factors in Pseudomonas aeruginosa: roles of algR2 and algH.

Alginate is an important virulence factor for Pseudomonas aeruginosa during infection of the lungs of cystic fibrosis patients. The genes encoding enzymes for alginate production by P. aeruginosa are normally silent. They are activated in response to several environmental conditions, including high osmolarity, exposure to ethanol, or long-term growth under conditions of nutrient deprivation. Several genes which participate in the activation of alginate gene promoters have been identified; among these is the algR2 (algQ) gene. AlgR2 is an 18-kDa protein which has been shown to regulate the critical algD gene encoding GDP-mannose dehydrogenase as well as to regulate the levels of a tricarboxylic acid cycle enzyme, i.e., succinyl coenzyme A synthetase, and nucleoside diphosphate kinase (Ndk), an enzyme involved in nucleoside triphosphate synthesis. Succinyl coenzyme A synthetase and Ndk form a complex in P. aeruginosa. While algR2 is required for alginate synthesis at 37 degrees C, an algR2 insertion mutant was still able to make alginate slowly at 37 or at 30 degrees C. We used this observation to identify and clone a gene, termed algH. A strain with mutations in both algR2 and algH is unable to produce alginate at either 37 or 30 degrees C, and it is fully defective in Ndk production.     

The use of 13C-n.m.r. spectroscopy to monitor alginate biosynthesis in mucoid Pseudomonas aeruginosa.

The biosynthesis of alginate by a mucoid strain of Pseudomonas aeruginosa, isolated from a cystic-fibrosis patient, was monitored by using 13C-n.m.r. spectroscopy of bacterial cultures incubated with 1-13C- or 2-13C-enriched fructose. When 1-13C- or 2-13C-enriched fructose was used as the precursor of alginate, enrichment with 13C in the constituent uronic acid monomers of the polysaccharide could only be detected in C-1 or C-2 respectively, indicating that alginate is synthesized in Ps. aeruginosa directly from fructose, with the hexose molecule being retained intact; this rules out the involvement of C3 intermediates, which occurs when glucose is the alginate precursor. The absence of detectable poly-L-gluluronate block sequences from the alginate of Ps. aeruginosa was confirmed, and it was shown that there is no modification of the arrangement of the constituent uronic acids between polymerization to form alginate and the appearance of the mature alginate in the extracellular medium. The 13C-n.m.r. data also provided independent evidence for acetylation on D-mannuronate residues and for the ratio of D-mannuronate to L-guluronate residues in newly synthesized alginate, which had previously been determined only for material secreted from bacteria into the extracellular medium.     

Cloning of genes controlling alginate biosynthesis from a mucoid cystic fibrosis isolate of Pseudomonas aeruginosa.

Mucoid strains of Pseudomonas aeruginosa isolated from the sputum of cystic fibrosis patients produce copious quantities of an exopolysaccharide known as alginic acid. Since clinical isolates of the mucoid variants are unstable with respect to alginate synthesis and revert spontaneously to the more typical nonmucoid phenotype, it has been difficult to isolate individual structural gene mutants defective in alginate synthesis. The cloning of the genes controlling alginate synthesis has been facilitated by the isolation of a stable alginate-producing strain, 8830. The stable mucoid strain was mutagenized with ethyl methanesulfonate to obtain various mutants defective in alginate biosynthesis. Several nonmucoid (Alg-) mutants were isolated. A mucoid P. aeruginosa gene library was then constructed, using a cosmid cloning vector. DNA isolated from the stable mucoid strain 8830 was partially digested with the restriction endonuclease HindIII and ligated to the HindIII site of the broad host range cosmid vector, pCP13. After packaging in lambda particles, the recombinant DNA was introduced via transfection into Escherichia coli AC80. The clone bank was mated (en masse) from E. coli into various P. aeruginosa 8830 nonmucoid mutants with the help of pRK2013, which provided donor functions in trans, and tetracycline-resistant exconjugants were screened for the ability to form mucoid colonies. Three recombinant plasmids, pAD1, pAD2, and pAD3, containing DNA inserts of 20, 9.5, and 6.2 kilobases, respectively, were isolated based on their ability to restore alginate synthesis in various strain 8830 nonmucoid (Alg-) mutants. Mutants have been assigned to at least four complementation groups, based on complementation by pAD1, pAD2, or pAD3 or by none of them. Introduction of pAD1 into the spontaneous nonmucoid strain 8822, as well as into other nonmucoid laboratory strains of P. aeruginosa such as PAO and SB1, was found to slowly induce alginate synthesis. This alginate-inducing ability was found to reside on a 7.5-kilobase EcoRI fragment that complemented the alg-22 mutation of strain 8852. The pAD1 chromosomal insert which complements the alg-22 mutation was subsequently mapped at ca. 19 min of the P. aeruginosa PAO chromosome.     

Isolation and Characterization of the algD gene of Pseudomonas syringae pv. phaseolicola and its distribution among other Pseudomonads and related Organisms

The gene coding for GDP-mannose dehydrogenase ( algD ) was isolated from a Pseudomonas syringae pv. phaseolicola genomic library using a polymerase chain reaction-generated heterologous DNA-probe from Pseudomonas aeruginosa . A total of 2123 base pairs were sequenced (accession number AF001555) and analysed for homologies to the alginate gene cluster of P. aeruginosa . Downstream from algD an alg8 homologue was found suggesting a similar arrangement of the alginate gene cluster in P. syringae pv. phaseolicola to that in P. aeruginosa . Also, the deduced amino acid sequence of algD shows high similarity to that of P. aeruginosa (0.9) and Azotobacter vinelandii (0.88). Southern hybridization experiments revealed that algD is widely distributed among members of the Pseudomonas rRNA homology group I. Among others, sequences homologous to algD were detected in the P. syringae pathovars lachrymans , mori , morsprunorum, pisi , savastanoi, tabaci and tomato as well as in Pseudomonas amygdali . For most of the algD positive organisms synthesis of alginate has been reported by other studies. However, algD homologues were also detected for the species Pseudomonas corrugata , Pseudomonas marginalis and Pseudomonas avenae ( Acidovorax avenae ), for which alginate biosynthesis has not yet been reported.     

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.     

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.     

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.     

In vitro alginate polymerization and the functional role of Alg8 in alginate production by Pseudomonas aeruginosa

An enzymatic in vitro alginate polymerization assay was developed by using 14C-labeled GDP-mannuronic acid as a substrate and subcellular fractions of alginate overproducing Pseudomonas aeruginosa FRD1 as a polymerase source. The highest specific alginate polymerase activity was detected in the envelope fraction, suggesting that cytoplasmic and outer membrane proteins constitute the functional alginate polymerase complex. Accordingly, no alginate polymerase activity was detected using cytoplasmic membrane or outer membrane proteins, respectively. To determine the requirement of Alg8, which has been proposed as catalytic subunit of alginate polymerase, nonpolar isogenic alg8 knockout mutants of alginate-overproducing P. aeruginosa FRD1 and P. aeruginosa PDO300 were constructed, respectively. These mutants were deficient in alginate biosynthesis, and alginate production was restored by introducing only the alg8 gene. Surprisingly, this resulted in significant alginate overproduction of the complemented P. aeruginosa Deltaalg8 mutants compared to nonmutated strains, suggesting that Alg8 is the bottleneck in alginate biosynthesis. (1)H-NMR analysis of alginate isolated from these complemented mutants showed that the degree of acetylation increased from 4.7 to 9.3% and the guluronic acid content was reduced from 38 to 19%. Protein topology prediction indicated that Alg8 is a membrane protein. Fusion protein analysis provided evidence that Alg8 is located in the cytoplasmic membrane with a periplasmic C terminus. Subcellular fractionation suggested that the highest specific PhoA activity of Alg8-PhoA is present in the cytoplasmic membrane. A structural model of Alg8 based on the structure of SpsA from Bacillus subtilis was developed.     

Immunochemical examination of the Pseudomonas aeruginosa glycocalyx: a monoclonal antibody which recognizes L-guluronic acid residues of alginic acid

Mice immunized with Formalin-fixed mucoid Pseudomonas aeruginosa cells developed an immune response directed, in part, towards the P. aeruginosa glycocalyx. The polyclonal mouse sera produced good immunofluorescent staining of the P. aeruginosa glycocalyx and cell surface. A library of 250 hybridoma cell lines which produced monoclonal antibodies directed against P. aeruginosa was established. Twelve clones (4.8%) produced antibody which reacted with alginate in an enzyme-linked immunosorbent assay (ELISA). Clone Ps 53 was chosen for further study, cloned, and an ascites tumor established. Clone Ps 53 was chosen for further study because the antibody produced demonstrated a specificity similar to that of a recently isolated heparin--rat-lung lectin which recognizes alginates of the Homma nontypable P. aeruginosa strains. The Ps 53 clone produced an immunoglobulin M which reacted with P. aeruginosa alginate and produced good immunofluorescent staining of the P. aeruginosa glycocalyx. The Ps 53 monoclonal antibody has an apparent specificity for L-guluronic residues in ELISA. Competitive binding studies with various alginates and monosaccharides suggest that the C6 carboxyl group of uronic acids are recognized by the antibody and that the antigen-binding site is fairly large and may recognize a particular sequence or epitope of alginic acid which is rich in L-guluronic acid. The Ps 53 monoclonal antibody did not react uniformily with all P. aeruginosa alginates but did react with all of the alginates of the Homma nontypable strains tested, suggesting that acetylation or various modifications found in P. aeruginosa alginates may interfere with antibody binding and define specific epitopes. The Ps 53 antibody also reacted with purified outer membrane, indicating that some alginate or L-guluronic acid is intimately associated with outer membrane.     

Copper as a signal for alginate synthesis in Pseudomonas syringae pv. syringae.

Plant-associated pseudomonads are commonly exposed to copper bactericides, which are applied to reduce the disease incidence caused by these bacteria. Consequently, many of these bacteria have acquired resistance or tolerance to copper salts. We recently conducted a survey of 37 copper-resistant (Cur) Pseudomonas spp., including P. cepacia, P. fluorescens, P. syringae, and P. viridiflava, and found that a subset of the P. syringae strains showed a dramatic increase in exopolysaccharide (EPS) production on mannitol-glutamate medium containing CuSO4 at 250 micrograms/ml. A modified carbazole assay indicated that the EPS produced on copper-amended media contained high levels of uronic acids, suggesting that the EPS was primarily alginic acid. Uronic acids extracted from selected strains were further confirmed to be alginate by demonstrating their sensitivity to alginate lyase and by descending paper chromatography following acid hydrolysis. Subinhibitory levels of arsenate, cobalt, lithium, rubidium, molybdenum, and mercury did not induce EPS production, indicating that alginate biosynthesis is not induced in P. syringae cells exposed to these heavy metals. A 200-kb plasmid designated pPSR12 conferred a stably mucoid phenotype to several P. syringae recipients and also increased their resistance to cobalt and arsenate. A cosmid clone constructed from pPSR12 which conferred a stably mucoid phenotype to several P. syringae strains but not to Pseudomonas aeruginosa was obtained. Results obtained in this study indicate that some of the signals and regulatory genes for alginate production in P. syringae differ from those described for alginate production in P. aeruginosa.     

A study of the reaction catalysed by alginate lyase VI from the sea mollusc, Littorina sp.

The molecular weight of polymeric alginic acid digested by alginate lyase (poly(1,4-beta-D-mannuronide) lyase, EC 4.2.2.3) was determined at various stages of the lysis. Low molecular weigh fragments were detected only after 60-100% lysis. Some high molecular weight fragments remained intact even after addition of a fresh aliquot of enzyme to the digest. The enzyme showed maximal activity at pH 5.6 in 0.05 M salt. Enzyme activity was stimulated by addition of 7.5 mM CaCl2 and 0.2 M NaCl, when the pH optimum was between 8 and 8.5. Only mannuronic acid was detected at the reducing end of fragments after exhausive enzymolysis, reduction and hydrolysis. On studying the reaction products by NMR, a double-bound signal (sigma = 5.98 ppm) was observed. A considerable decrease in intensity of the D-mannuronic acid residue signal was detected after hydrolysis of alginate lyase VI on poly-(ManUA-GulUA), but not poly(GulUA). The results suggest that alginate lyase VI may be an endoalginate lyase that splits glycoside bonds only between two mannuronic acid residues.     

Alginate inhibition of the uptake of Pseudomonas aeruginosa by macrophages

Pseudomonas aeruginosa alginate was purified and characterized in terms of uronic acid, carbohydrate and protein content, as well as by infra-red spectroscopy and gel electrophoresis. Added exogenous bacterial alginate inhibited the uptake and degradation of both viable and non-viable radiolabelled non-mucoid P. aeruginosa by resident mouse peritoneal macrophages. Alginic acid (from seaweed) inhibited the same parameters to almost the same degree. Bacterial alginate also inhibited the uptake of fluorescent-labelled zymosan and latex particles. Starch, at equivalent viscosity to the alginate, inhibited the uptake and degradation of radiolabelled nonviable P. aeruginosa to a greater extent, but Dextran T500 had no effect. This suggests that the viscous nature of alginate exerts a non-specific inhibitory effect on the uptake and subsequent degradation of phagocytosible particles.     

Understanding the control of Pseudomonas aeruginosa alginate synthesis and the prospects for management of chronic infections in cystic fibrosis

Decades of research have been dedicated to the study of the opportunistic pathogen Pseudomonas aeruginosa, a Gram-negative, environmental bacterium that secretes the exopolysaccharide alginate during chronic lung infection of cystic fibrosis (CF) patients. Although P. aeruginosa utilizes a variety of factors to establish a successful infection in the lungs of CF patients, alginate has stood out as one of the best-studied prognostic indicators of chronic lung infection. While the genetics, biosynthesis and regulation of alginate are well understood, questions still remain concerning its role in biofilm development and its potential as a therapeutic target. The purpose of this review is to provide a brief summary of alginate biosynthesis and regulation, and to highlight recent discoveries in the areas of alginate production, biofilm formation and vaccine design. This information is placed in context with a proposed P. aeruginosa infectious pathway, highlighting avenues for the use of existing therapies as well as the potential for novel agents to reduce or eliminate chronic infections in CF patients.     

Alginate lyase from Pseudomonas aeruginosa CF1/M1 prefers the hexameric oligomannuronate as substrate

In order to investigate the catalytic properties of alginate lyase from Pseudomonas aeruginosa CF1/M1, a clinical isolate, regarding the capability to perform β-elimination on oligomannuronates of defined length (2–9), the alginate lyase was purified from periplasmic extracts. A purification method for unsaturated and saturated oligomannuronates applying anionic exchange chromatography on a FPLC apparatus was established. The alginate lyase showed the highest activity, when hexamers were provided as substrate. This indicated that the alginate lyase best accommodates a chain of six alginate residues in the active center. As a minimum chain length, the pentameric oligomannuronate was still accepted as substrate. Mannuronate oligomers shorter than the pentamer were not accepted as substrate for alginate lyase. Furthermore, oligomer pattern analysis of polymannuronate which was subjected to β-elimination by alginate lyase revealed that the trimer is the most abundant oligomer. These data indicated that β-elimination and cleavage occurred at mannuronic acid residue no. 3 of the accommodated hexameric alginate chain.     

Cloning and expression of an Azotobacter vinelandii mannuronan C-5-epimerase gene.

An Azotobacter vinelandii mannuronan C-5-epimerase gene was cloned in Escherichia coli. This enzyme catalyzes the Ca(2+)-dependent epimerization of D-mannuronic acid residues in alginate to the corresponding epimer L-guluronic acid. The epimerase gene was identified by screening a bacteriophage EMBL3 gene library of A. vinelandii DNA with a synthetic oligonucleotide probe. The sequence of this probe was deduced after determination of the N-terminal amino acid sequence of a previously reported extracellular mannuronan C-5-epimerase from A. vinelandii. A DNA fragment hybridizing against the probe was subcloned in a plasmid vector in E. coli, and the corresponding recombinant plasmid expressed intracellular mannuronan C-5-epimerase in this host. The nucleotide sequence of the gene encoding the epimerase was determined, and the sequence data showed that the molecular mass of the deduced protein is 103 kDa. A module consisting of about 150 amino acids was repeated tandemly four times in the C-terminal part of the deduced protein. Each of the four repeats contained four to six tandemly oriented nonameric repeats. The sequences in these motifs are similar to the Ca(2+)-binding domains of functionally unrelated secreted proteins reported previously in other bacteria. The reaction product of the recombinant epimerase was analyzed by nuclear magnetic resonance spectroscopy, and the results showed that the guluronic acid residues were distributed in blocks along the polysaccharide chain. Such a nonrandom distribution pattern, which is important for the commercial use of alginate, has previously also been identified in the reaction product of the corresponding enzyme isolated from A. vinelandii.     

The structure of O-specific polysaccharide of Pseudomonas aeruginosa immunotype 3; revision of the structure of acetoamidine derivative of 2,3-diamino-2,3-dideoxy-D-mannuronic acid

O-Specific side chain of P. aeruginosa immunotype 3 lipopolysaccharide is composed of N-acetyl-D-fucosamine (FucNAc), 2,3-diacetamido-2,3-dideoxy-L-guluronic acid (GulN2Ac2A) and 3-acetamidino = 2-acetamido = 2,3 = dideoxy = D-mannuronic acid (ManNAcAmA). The latter sugar is identified on the basis of solvolysis with anhydrous hydrogen fluoride, 13C NMR spectroscopy and fast-atom bombardment mass spectrometry analysis, as well as of reactions of acetamidino function (alkaline hydrolysis to acetamido group and reductive deamination to ethylamino group). Earlier, in the course of investigation of P. aeruginosa O3 lipopolysaccharides, the structure of 1-methyl-2-imidazoline was erroneously ascribed to the acetamidino group. The following structure was established for the repeating unit of immunotype 3 polysaccharide which is identical to P. aeruginosa O3(a),3c polysaccharide: ----4)-beta-D-ManNAcAmA-(1----4)-alpha-L-GulN2Ac2A-(1----3)- beta-D-FucNac-(1----.     

Cloning of Escherichia coli and Pseudomonas aeruginosa phosphomannose isomerase genes and their expression in alginate-negative mutants of Pseudomonas aeruginosa.

The phosphomannose isomerase (pmi) gene of Escherichia coli was cloned on a broad-host-range cosmid vector and expressed in Pseudomonas aeruginosa at a low level. Plasmid pAD3, which harbors the E. coli pmi gene, contains a 6.2-kilobase-pair HindIII fragment derived from the chromosome of E. coli. Subcloning produced plasmids carrying the 1.5-kilobase-pair HindIII-HpaI subfragment of pAD3 that restored alginic acid production in a nonmucoid, alginate-negative mutant of P. aeruginosa. This fragment also complemented mannose-negative, phosphomannose isomerase-negative mutants of E. coli and showed no homology by DNA-DNA hybridization to P. aeruginosa chromosomal DNA. By using a BamHI constructed cosmid clone bank of the stable alginate producing strain 8830, we have been able to isolate a recombinant plasmid of P. aeruginosa origin that also restores alginate production in the alginate-negative mutant. This new recombinant plasmid, designated pAD4, contained a 9.9-kilobase-pair EcoRI-BamHI fragment with the ability to restore alginate synthesis in the alginate-negative P. aeruginosa. This fragment showed no homology to E. coli chromosomal DNA or to plasmid pAD3. Both mucoid and nonmucoid strains of P. aeruginosa had no detectable levels of phosphomannose isomerase activity as measured by mannose 6-phosphate-to-fructose 6-phosphate conversion. However, P. aeruginosa strains harboring the cloned pmi gene of E. coli contained measurable levels of phosphomannose isomerase activity as evidenced by examining the conversion of mannose 6-phosphate to fructose 6-phosphate.