Nitrobenzoates and aminobenzoates are chemoattractants for Pseudomonas strains

Three Pseudomonas strains were tested for the ability to sense and respond to nitrobenzoate and aminobenzoate isomers in chemotaxis assays. Pseudomonas putida PRS2000, a strain that grows on benzoate and 4-hydroxybenzoate by using the beta-ketoadipate pathway, has a well-characterized beta-ketoadipate-inducible chemotactic response to aromatic acids. PRS2000 was chemotactic to 3- and 4-nitrobenzoate and all three isomers of aminobenzoate when grown under conditions that induce the benzoate chemotactic response. P. putida TW3 and Pseudomonas sp. strain 4NT grow on 4-nitrotoluene and 4-nitrobenzoate by using the ortho (beta-ketoadipate) and meta pathways, respectively, to complete the degradation of protocatechuate derived from 4-nitrotoluene and 4-nitrobenzoate. However, based on results of catechol 1,2-dioxygenase and catechol 2,3-dioxygenase assays, both strains were found to use the beta-ketoadipate pathway for the degradation of benzoate. Both strains were chemotactic to benzoate, 3- and 4-nitrobenzoate, and all three aminobenzoate isomers after growth with benzoate but not succinate. Strain TW3 was chemotactic to the same set of aromatic compounds after growth with 4-nitrotoluene or 4-nitrobenzoate. In contrast, strain 4NT did not respond to any aromatic acids when grown with 4-nitrotoluene or 4-nitrobenzoate, apparently because these substrates are not metabolized to the inducer (beta-ketoadipate) of the chemotaxis system. The results suggest that strains TW3 and 4NT have a beta-ketoadipate-inducible chemotaxis system that responds to a wide range of aromatic acids and is quite similar to that present in PRS2000. The broad specificity of this chemotaxis system works as an advantage in strains TW3 and 4NT because it functions to detect diverse carbon sources, including 4-nitrobenzoate.     

Neural Development: Chemoattractants for navigating axons

Newly identified proteins that seem to act as diffusible attractants for circumferentially growing axons in the vertebrate embryonic spinal cord are related to a protein that directs circumferential axon growth in the nematode.     

Pseudomonas syringae Catalases Are Collectively Required for Plant Pathogenesis

The bacterial pathogen Pseudomonas syringae pv. tomato DC3000 must detoxify plant-produced hydrogen peroxide (H(2)O(2)) in order to survive in its host plant. Candidate enzymes for this detoxification include the monofunctional catalases KatB and KatE and the bifunctional catalase-peroxidase KatG of DC3000. This study shows that KatG is the major housekeeping catalase of DC3000 and provides protection against menadione-generated endogenous H(2)O(2). In contrast, KatB rapidly and substantially accumulates in response to exogenous H(2)O(2). Furthermore, KatB and KatG have nonredundant roles in detoxifying exogenous H(2)O(2) and are required for full virulence of DC3000 in Arabidopsis thaliana. Therefore, the nonredundant ability of KatB and KatG to detoxify plant-produced H(2)O(2) is essential for the bacteria to survive in plants. Indeed, a DC3000 catalase triple mutant is severely compromised in its ability to grow in planta, and its growth can be partially rescued by the expression of katB, katE, or katG. Interestingly, our data demonstrate that although KatB and KatG are the major catalases involved in the virulence of DC3000, KatE can also provide some protection in planta. Thus, our results indicate that these catalases are virulence factors for DC3000 and are collectively required for pathogenesis.     

Environment and Colonisation Sequence Are Key Parameters Driving Cooperation and Competition between Pseudomonas aeruginosa Cystic Fibrosis Strains and Oral Commensal Streptococci

Cystic fibrosis (CF) patient airways harbour diverse microbial consortia that, in addition to the recognized principal pathogen Pseudomonas aeruginosa, include other bacteria commonly regarded as commensals. The latter include the oral (viridans) streptococci, which recent evidence indicates play an active role during infection of this environmentally diverse niche. As the interactions between inhabitants of the CF airway can potentially alter disease progression, it is important to identify key cooperators/competitors and environmental influences if therapeutic intervention is to be improved and pulmonary decline arrested. Importantly, we recently showed that virulence of the P. aeruginosa Liverpool Epidemic Strain (LES) could be potentiated by the Anginosus-group of streptococci (AGS). In the present study we explored the relationships between other viridans streptococci (Streptococcus oralis, Streptococcus mitis, Streptococcus gordonii and Streptococcus sanguinis) and the LES and observed that co-culture outcome was dependent upon inoculation sequence and environment. All four streptococcal species were shown to potentiate LES virulence factor production in co-culture biofilms. However, in the case of S. oralis interactions were environmentally determined; in air cooperation within a high cell density co-culture biofilm occurred together with stimulation of LES virulence factor production, while in an atmosphere containing added CO₂ this species became a competitor antagonising LES growth through hydrogen peroxide (H₂O₂) production, significantly altering biofilm population dynamics and appearance. Streptococcus mitis, S. gordonii and S. sanguinis were also capable of H2O2 mediated inhibition of P. aeruginosa growth, but this was only visible when inoculated as a primary coloniser prior to introduction of the LES. Therefore, these observations, which are made in conditions relevant to the biology of CF disease pathogenesis, show that the pathogenic and colonisation potential of P. aeruginosa isolates can be modulated positively and negatively by the presence of oral commensal streptococci.     

Effective Isolation and Identification of Toluene-tolerant Pseudomonas Strains

A total of 1752 strains of osmophilic yeasts were isolated from honey and pollens. Forty-three strains of osmophilic yeasts produced polyols, among which 6 strains produced erythritol in good yields. On the other hand, 52 osmophilic yeasts converted sucrose to fructooligosaccharides, among which 8 strains produced both extra and intracellular β-fructofuranosidase, which converted sucrose to fructooligosaccharides. This investigation concluded that osmophilic yeasts converted sucrose not only to polyols, but also to fructooligosaccharides in good yields.     

Selected Schizosaccharomyces pombe Strains Have Characteristics That Are Beneficial for Winemaking

At present, wine is generally produced using Saccharomyces yeast followed by Oenococus bacteria to complete malolactic fermentation. This method has some unsolved problems, such as the management of highly acidic musts and the production of potentially toxic products including biogenic amines and ethyl carbamate. Here we explore the potential of the fission yeast Schizosaccharomyces pombe to solve these problems. We characterise an extensive worldwide collection of S. pombe strains according to classic biochemical parameters of oenological interest. We identify three genetically different S. pombe strains that appear suitable for winemaking. These strains compare favourably to standard Saccharomyces cerevisiae winemaking strains, in that they perform effective malic acid deacidification and significantly reduce levels of biogenic amines and ethyl carbamate precursors without the need for any secondary bacterial malolactic fermentation. These findings indicate that the use of certain S. pombe strains could be advantageous for winemaking in regions where malic acid is problematic, and these strains also show superior performance with respect to food safety.     

Specificity of Octopine Uptake by Rhizobium and Pseudomonas Strains

The octopine-utilizing strain Agrobacterium tumefaciens B6S3 and three nonagrobacteria which had the capacity to utilize this opine were compared for octopine uptake. The characteristics of uptake by Rhizobium meliloti A3 and strain B6S3 were similar. In both bacteria, uptake activity was inducible by octopine and by the related opine octopinic acid, and competition assays showed that these two opine substrates were accepted by the same uptake system with an equivalent affinity. Cells of Pseudomonas putida 203 accumulated octopine against a concentration gradient, and this activity was induced specifically by octopine. While strain 203 did not utilize octopinic acid, a spontaneous mutant with a combined capacity for octopine and octopinic acid utilization was obtained. Both opines induced octopine uptake by this mutant, but octopinic acid was not a substrate for the induced system. Thus, the Pseudomonas uptake system exhibited a different specificity for octopine than the corresponding Agrobacterium system. The nonfluorescent pseudomonad GU187j, which utilized the three related opines octopine, octopinic acid, and nopaline, was constitutive for octopine uptake. Strain GU187j possessed a system which accepted these three opines, but not arginine or ornithine, with a similar affinity.     

The MG1363 and IL1403 Laboratory Strains of Lactococcus lactis and Several Dairy Strains Are Diploid

Bacteria are normally haploid, maintaining one copy of their genome in one circular chromosome. We have examined the cell cycle of laboratory strains of Lactococcus lactis, and, to our surprise, we found that some of these strains were born with two complete nonreplicating chromosomes. We determined the cellular content of DNA by flow cytometry and by radioactive labeling of the DNA. These strains thus fulfill the criterion of being diploid. Several dairy strains were also found to be diploid while a nondairy strain and several other dairy strains were haploid in slow-growing culture. The diploid and haploid strains differed in their sensitivity toward UV light, in their cell size, and in their D period, the period between termination of DNA replication and cell division.In contrast to higher eukaryotes, bacteria are haploid (6, 19); i.e., they store their genetic information in a single chromosome, which is then duplicated during the cell cycle. If the growth rate is sufficiently low, bacteria are born with a single copy of the chromosome, which will then be duplicated before the bacterium divides.There are a few reports about bacteria that have more than one genome per cell, i.e., that are polyploid. Deinococcus radiodurans has been shown to have 4 to 10 copies of its genome (13, 14). The diplococcal bacterium Neisseria gonorrhoeae was found to be diploid per coccal unit (31). Azotobacter vinelandii bacteria amplify the genome during growth in rich medium more than 40 times (20, 24, 27). The giant bacterium Epulopiscium fishelsoni has been shown to amplify its genome into a polytene chromosome of 3,000-fold ploidy (2). In addition, noncomplementing diploid bacteria have been isolated from protoplast fusions in Bacillus subtilis (11) and, as a result of zygogenesis, in Escherichia coli (10). A few other bacteria with two to six different chromosomes have been reported (15, 30).The normal cell cycle is divided into three periods: (i) the B period from cell division until initiation of replication, (ii) the C period in which the cell replicates its DNA, and (iii) the D period from termination of productive replication until cell division. The D period thus includes processes such as proofreading and deconcatenation. The B period is found only in cells whose generation times exceed the length of the combined C and D periods. If the generation times become shorter than the combined lengths of the C and D periods, then the initiations of replication move into previous cell cycles (16). Fast-growing bacteria will therefore have more than one ongoing round of DNA replication at the same time; they might have 4, 8, or even 16 origins of replication (4). Normal haploid cells are born with one chromosome, either replicating or nonreplicating, and always with one terminus of replication. Not until the replication has ended do the cells have two termini. If the D period becomes longer than the generation time, which happens at high growth rates, the cells will be born with two termini as a result of the overlapping cell cycles. Long D periods are discussed further in the Discussion.We have examined the cell cycle of Lactococcus lactis subsp. cremoris MG1363 in order to determine the cell cycle periods. To our surprise, we found that slow-growing cultures of these bacteria were born with two complete chromosomes, which were replicated into four chromosomes during the C period. This strain thus fulfills the criterion of being diploid without overlapping chromosomal replication cycles. Comparison with other L. lactis strains showed that both of the subspecies, L. lactis subsp. cremoris and L. lactis subsp. lactis, had members that were either diploid, like MG1363, or haploid, like most bacteria.     

Pyocine Typing of Clinical Strains of Pseudomonas aeruginosa

A total of 954 clinical isolates of Pseudomonas aeruginosa were typed by their ability to produce pyocines. The strains of Pseudomonas were isolated from urines, bloods, sputa, stools, and miscellaneous infectious exudates or tissue of patients of the Mayo Clinic and four associated hospitals. About 80% of the typable strains could be grouped into three major pyocine types: A (30.9%), B (34.8%), and D (14.1%). These large groups could be divided into subtypes by using additional indicator strains. There was no significant difference in the distribution of types by either institutional or specimen source, except that urine specimens yielded the highest percentage of one type. By this procedure, 93% of all isolates could be typed. Repeated typing of serially transferred strains indicated that the procedure has a high degree of reliability. Several strains exhibited extreme fluctuation in inhibition pattern. The procedure is a simple and reliable method to monitor the patterns of nosocomial infections due to P. aeruginosa.     

Invasion and Exclusion among Coexisting Pseudomonas syringae Strains on Leaves

The invasion and exclusion abilities of coexisting Pseudomonas syringae strains were quantified on leaves. Twenty-nine P. syringae strains were inoculated onto plants in 107 pairwise combinations. All pairs were duplicated so that each strain was inoculated both first as an antagonist strain (day 0) and second as a challenge strain (day 3). The population size of each strain in a mixture was quantified on day 6 following incubation under moist conditions. For P. syringae strains, the presence of an established population often significantly reduced the growth of subsequently arriving challenge strains on the leaf surface. Invasion and exclusion abilities, quantified by contrasting population sizes of challenge strains in the presence and in the absence of another strain, varied significantly among P. syringae strains and were partly a function of the particular strain pair. The population size of a strain when present alone on a leaf was not predictive of invasion or exclusion ability. Successful invaders were significantly less likely to exclude challenge populations than were nonsuccessful invaders. Population sizes of successful excluders were negatively correlated with population sizes of coexisting challenge strains, while population sizes of successful invaders were positively correlated with those of coexisting antagonist strains. The patterns of interaction among coexisting strains suggest mechanisms for successful invasion and exclusion among P. syringae strains on leaves.     

Degradation of 1,2,4-Trichloro- and 1,2,4,5-Tetrachlorobenzene by Pseudomonas Strains

Two Pseudomonas sp. strains, capable of growth on chlorinated benzenes as the sole source of carbon and energy, were isolated by selective enrichment from soil samples of an industrial waste deposit. Strain PS12 grew on monochlorobenzene, all three isomeric dichlorobenzenes, and 1,2,4-trichlorobenzene (1,2,4-TCB). Strain PS14 additionally used 1,2,4,5-tetrachlorobenzene (1,2,4,5-TeCB). During growth on these compounds both strains released stoichiometric amounts of chloride ions. The first steps of the catabolism of 1,2,4-TCB and 1,2,4,5-TeCB proceeded via dioxygenation of the aromatic nuclei and furnished 3,4,6-trichlorocatechol. The intermediary cis-3,4,6-trichloro-1,2-dihydroxycyclohexa-3,5-diene (TCB dihydrodiol) formed from 1,2,4-TCB was rearomatized by an NAD⁺-dependent dihydrodiol dehydrogenase activity, while in the case of 1,2,4,5-TeCB oxidation the catechol was obviously produced by spontaneous elimination of hydrogen chloride from the initially formed 1,3,4,6-tetrachloro-1,2-dihydroxycyclohexa-3,5-diene. Subsequent ortho cleavage was catalyzed by a type II catechol 1,2-dioxygenase producing the corresponding 2,3,5-trichloromuconate which was channeled into the tricarboxylic acid pathway via an ordinary degradation sequence, which in the present case included 2-chloro-3-oxoadipate. From the structure-related compound 2,4,5-trichloronitrobenzene the nitro group was released as nitrite, leaving the above metabolite as 3,4,6-trichlorocatechol. Enzyme activities for the oxidation of chlorobenzenes and halogenated metabolites were induced by both strains during growth on these haloaromatics and, to a considerable extent, during growth of strain PS12 on acetate.     

FolX and FolM Are Essential for Tetrahydromonapterin Synthesis in Escherichia coli and Pseudomonas aeruginosa

Tetrahydromonapterin is a major pterin in Escherichia coli and is hypothesized to be the cofactor for phenylalanine hydroxylase (PhhA) in Pseudomonas aeruginosa, but neither its biosynthetic origin nor its cofactor role has been clearly demonstrated. A comparative genomics analysis implicated the enigmatic folX and folM genes in tetrahydromonapterin synthesis via their phyletic distribution and chromosomal clustering patterns. folX encodes dihydroneopterin triphosphate epimerase, which interconverts dihydroneopterin triphosphate and dihydromonapterin triphosphate. folM encodes an unusual short-chain dehydrogenase/reductase known to have dihydrofolate and dihydrobiopterin reductase activity. The roles of FolX and FolM were tested experimentally first in E. coli, which lacks PhhA and in which the expression of P. aeruginosa PhhA plus the recycling enzyme pterin 4a-carbinolamine dehydratase, PhhB, rescues tyrosine auxotrophy. This rescue was abrogated by deleting folX or folM and restored by expressing the deleted gene from a plasmid. The folX deletion selectively eliminated tetrahydromonapterin production, which far exceeded folate production. Purified FolM showed high, NADPH-dependent dihydromonapterin reductase activity. These results were substantiated in P. aeruginosa by deleting tyrA (making PhhA the sole source of tyrosine) and folX. The ΔtyrA strain was, as expected, prototrophic for tyrosine, whereas the ΔtyrA ΔfolX strain was auxotrophic. As in E. coli, the folX deletant lacked tetrahydromonapterin. Collectively, these data establish that tetrahydromonapterin formation requires both FolX and FolM, that tetrahydromonapterin is the physiological cofactor for PhhA, and that tetrahydromonapterin can outrank folate as an end product of pterin biosynthesis.Pterins contain the bicyclic pteridine ring with an amino group in the 2-position and an oxo group in the 4-position; they can be reduced through the dihydro forms to the tetrahydro forms, which are active as cofactors (Fig. ​(Fig.1A).1A). Tetrahydropterins are known to be the cofactors for phenylalanine hydroxylases from Pseudomonas and Chromatium species as well as for mammalian aromatic amino acid hydroxylases and other mammalian enzymes (13, 17, 38, 41) (Fig. ​(Fig.1B).1B). Although the identity of the mammalian tetrahydropterin cofactor, tetrahydrobiopterin (H₄-BPt), is firmly established (38), the same is not true for bacteria, and the biosynthesis of bacterial tetrahydropterins is not well understood.Open in a separate windowFIG. 1.Tetrahydropterin structure, cofactor role, and biosynthesis. (A) The pterin nucleus, its levels of reduction, and the structures of compounds relevant to this study. (B) The requirement for a tetrahydropterin (H₄-pterin) cofactor for phenylalanine hydroxylase (PAH) and the cofactor regeneration cycle involving pterin-4a-carbinolamine dehydratase (PCD) and quinonoid dihydropterin (q-H₂-pterin) reductase (q-DHPR; EC 1.5.1.34). (C) The established steps in tetrahydrobiopterin (H₄-BPt) biosynthesis and possible routes for tetrahydromonapterin (H₄-MPt) biosynthesis in relation to the folate pathway. H₄-BPt is formed by the sequential action of 6-pyruvoyltetrahydropterin (P-H₄-Pt) synthase (PTPS-II) and sepiapterin reductase (SR). H₄-MPt could originate via the FolX-catalyzed epimerization of dihydroneopterin triphosphate (H₂-NPt-P₃) to dihydromonapterin triphosphate (H₂-MPt-P₃), followed by dephosphorylation to dihydromonapterin (H₂-MPt) and reduction by a dihydropterin reductase (EC 1.5.1.33), putatively FolM. H₄-MPt also could come from the FolB-mediated epimerization of dihydroneopterin (H₂-NPt) followed by reduction. FolB also mediates the side chain cleavage of H₂-NPt or H₂-MPt to give 6-hydroxymethyldihydropterin (H₂-HMPt); the H₂-MPt cleavage is omitted for simplicity. Other abbreviations: P-ase, phosphatase; H₂-HMPt-P₂, 6-hydroxymethyldihydropterin diphosphate; pABA, p-aminobenzoate; H₂-pteroate, dihydropteroate; H₂-folate, dihydrofolate; H₄-folate, tetrahydrofolate.While a few bacterial taxa, such as Cyanobacteria and Chlorobia, produce H₄-BPt, most do not, as judged directly from pterin analysis and indirectly from the rarity of H₄-BPt biosynthesis genes 6-pyruvoyltetrahydropterin synthase II (PTPS-II) and sepiapterin reductase (SR) (Fig. ​(Fig.1C)1C) among sequenced genomes (12, 25). As bacteria lacking H₄-BPt include Pseudomonas and many others with phenylalanine hydroxylase genes, it is clear that bacterial phenylalanine hydroxylases generally must use a cofactor other than H₄-BPt. The most prominent candidate is tetrahydromonapterin (H₄-MPt), which occurs in Escherichia coli (21) and almost certainly also in Pseudomonas species (11, 17). H₄-MPt could be derived from the dihydropterin intermediates of folate biosynthesis via two different routes (Fig. ​(Fig.1C).1C). These are (i) the conversion of dihydroneopterin triphosphate (H₂-NPt-P₃) to dihydromonapterin triphosphate (H₂-MPt-P₃) by H₂-NPt-P₃ epimerase (FolX) followed by dephosphorylation and reduction to the tetrahydro level, and (ii) the conversion of dihydroneopterin (H₂-NPt) to dihydromonapterin (H₂-MPt) by the epimerase action of dihydroneopterin aldolase (FolB) and then reduction. FolB is a fairly well-understood enzyme of folate synthesis (9), but FolX has no known biological role and a folX deletant has no obvious phenotype (19). folX genes apparently are confined to Gammaproteobacteria (9).Although the epimerase activities of FolX and FolB have been demonstrated amply in vitro (1, 5, 19), no genetic evidence links either enzyme to H₄-MPt formation in vivo. The situation with the reduction of H₂-MPt to H₄-MPt is even less clear, because this activity has not been investigated experimentally. A candidate enzyme for this step nevertheless can be proposed on bioinformatic grounds: the somewhat mysterious FolM protein (9). FolM belongs to a subset of the short-chain dehydrogenase/reductase (SDR) family having the characteristic motif TGX₃RXG (in place of TGX₃GXG, which typifies other SDRs). The archetype of this subset is Leishmania pteridine reductase 1 (PTR1), which reduces various dihydropterins to the tetrahydro state (15). E. coli FolM has low dihydrofolate (H₂-folate) and dihydrobiopterin (H₂-BPt) reductase activities in vitro (14), but neither of these is likely to be its physiological function, since H₂-folate reduction normally is mediated by FolA and E. coli lacks H₄-BPt. folM genes occur in many Gram-negative organisms, including Chlamdiae, Chloroflexi, Cyanobacteria, Acidobacteria, Planctomycetes, Alphaproteobacteria, Betaproteobacteria, Gammaproteobacteria, and Deltaproteobacteria (9).We report here comparative genomic and genetic evidence that FolX and FolM are required for H₄-MPt synthesis in E. coli and P. aeruginosa, the bacteria in which H₄-MPt has been most studied, and biochemical evidence that FolM has high H₂-MPt reductase activity. We also point out gaps in the understanding of pterin metabolism that our data bring sharply into focus.     

Multiple Domains Are Required for the Toxic Activity of Pseudomonas aeruginosa ExoU

Expression of ExoU by Pseudomonas aeruginosa is correlated with acute cytotoxicity in a number of epithelial and macrophage cell lines. In vivo, ExoU is responsible for epithelial injury. The absence of a known motif or significant homology with other proteins suggests that ExoU may possess a new mechanism of toxicity. To study the intracellular effects of ExoU, we developed a transient-transfection system in Chinese hamster ovary cells. Transfection with full-length but not truncated forms of ExoU inhibited reporter gene expression. Inhibition of reporter activity after cotransfection with ExoU-encoding constructs was correlated with cellular permeability and death. The toxicity of truncated versions of ExoU could be restored by coexpression of the remainder of the molecule from separate plasmids in trans. This strategy was used to map N- and C-terminal regions of ExoU that are necessary but not sufficient for toxicity. Disruption of a middle region of the protein reduces toxicity. This portion of the molecule is postulated to allow the N- and C-terminal regions to functionally complement one another. In contrast to ExoS and ExoT, native and recombinant ExoU molecules do not oligomerize or form aggregates. The complex domain structure of ExoU suggests that, like other P. aeruginosa-encoded type III effectors (ExoS and ExoT), ExoU toxicity may result from a molecule that possesses more than one activity.     

New Pseudomonas spp. Are Pathogenic to Citrus

Five putative novel Pseudomonas species shown to be pathogenic to citrus have been characterized in a screening of 126 Pseudomonas strains isolated from diseased citrus leaves and stems in northern Iran. The 126 strains were studied using a polyphasic approach that included phenotypic characterizations and phylogenetic multilocus sequence analysis. The pathogenicity of these strains against 3 cultivars of citrus is demonstrated in greenhouse and field studies. The strains were initially grouped phenotypically and by their partial rpoD gene sequences into 11 coherent groups in the Pseudomonas fluorescens phylogenetic lineage. Fifty-three strains that are representatives of the 11 groups were selected and analyzed by partial sequencing of their 16S rRNA and gyrB genes. The individual and concatenated partial sequences of the three genes were used to construct the corresponding phylogenetic trees. The majority of the strains were identified at the species level: P. lurida (5 strains), P. monteilii (2 strains), P. moraviensis (1 strain), P. orientalis (16 strains), P. simiae (7 strains), P. syringae (46 strains, distributed phylogenetically in at least 5 pathovars), and P. viridiflava (2 strains). This is the first report of pathogenicity on citrus of P. orientalis, P. simiae, P. lurida, P. moraviensis and P. monteilii strains. The remaining 47 strains that could not be identified at the species level are considered representatives of at least 5 putative novel Pseudomonas species that are not yet described.     

Serological Typing of 31 Achromogenic and 40 Melanogenic Pseudomonas aeruginosa Strains

Thirty-one achromogenic and 40 melanogenic Pseudomonas aeruginosa strains were studied with 10 monovalent typing sera (3). Twenty-one of the achromogenic (67.7%) and seven of the melanogenic (17.5%) strains were agglutinated by one of the 10 typing sera. Ten achromogenic and 33 melanogenic strains were not agglutinated by any of the 10 typing sera. As far as this set of antisera is concerned, the typability of achromogenic and melanogenic P. aeruginosa strains appears to be much lower than that of the chromogenic, nonmelanogenic strains of the species reported previously.     

Degradation of Phenanthrene by Mutant Naphthalene-Degrading Pseudomonas putida Strains

Five naphthalene- and salicylate-utilizing Pseudomonas putida strains cultivated for a long time on phenanthrene produced mutants capable of growing on this substrate and 1-hydroxy-2-naphthoate as the sole sources of carbon and energy. The mutants catabolize phenanthrene with the formation of 1-hydroxy-2-naphthoate, 2-hydroxy-1-naphthoate, salicylate, and catechol. The latter products are further metabolized by the meta- and ortho-cleavage pathways. In all five mutants, naphthalene and phenanthrene are utilized with the involvement of plasmid-born genes. The acquired ability of naphthalene-degrading strains to grow on phenanthrene is explained by the fact that the inducible character of the synthesis of naphthalene dioxygenase, the key enzyme of naphthalene and phenanthrene degradation, becomes constitutive.     

Biogeography and Degree of Endemicity of Fluorescent Pseudomonas Strains in Soil

Fluorescent Pseudomonas strains were isolated from 38 undisturbed pristine soil samples from 10 sites on four continents. A total of 248 isolates were confirmed as Pseudomonas sensu stricto by fluorescent pigment production and group-specific 16S ribosomal DNA (rDNA) primers. These isolates were analyzed by three molecular typing methods with different levels of resolution: 16S rDNA restriction analysis (ARDRA), 16S-23S rDNA intergenic spacer-restriction fragment length polymorphism (ITS-RFLP) analysis, and repetitive extragenic palindromic PCR genomic fingerprinting with a BOX primer set (BOX-PCR). All isolates showed very similar ARDRA patterns, as expected. Some ITS-RFLP types were also found at every geographic scale, although some ITS-RFLP types were unique to the site of origin, indicating weak endemicity at this level of resolution. Using a similarity value of 0.8 or more after cluster analysis of BOX-PCR fingerprinting patterns to define the same genotypes, we identified 85 unique fluorescent Pseudomonas genotypes in our collection. There were no overlapping genotypes between sites as well as continental regions, indicating strict site endemism. The genetic distance between isolates as determined by degree of dissimilarity in BOX-PCR patterns was meaningfully correlated to the geographic distance between the isolates' sites of origin. Also, a significant positive spatial autocorrelation of the distribution of the genotypes was observed among distances of <197 km, and significant negative autocorrelation was observed between regions. Hence, strong endemicity of fluorescent Pseudomonas genotypes was observed, suggesting that these heterotrophic soil bacteria are not globally mixed.