Crystal structure of a bicupin protein HutD involved in histidine utilization in Pseudomonas

Cupins form one of the most functionally diverse superfamilies of proteins, with members performing a wide range of catalytic, non-catalytic, and regulatory functions. HutD is a predicted bicupin protein that is involved in histidine utilization (Hut) in Pseudomonas species. Previous genetic analyses have suggested that it limits the upper level of Hut pathway expression, but its mechanism of action is unknown. Here, we have determined the structure of PfluHutD at 1.74 Å resolution in several crystallization conditions, and identified N-formyl-l-glutamate (FG, a Hut pathway intermediate) as a potential ligand in vivo. Proteins 2017; 85:1580-1588. © 2017 Wiley Periodicals, Inc.

Testing temperature-induced proteomic changes in the plant-associated bacterium Pseudomonas fluorescens SBW25

Traits used by bacteria to enhance ecological performance in natural environments are not well understood. Recognizing that the saprophytic plant-colonizing bacterium Pseudomonas fluorescens SBW25 experiences temperatures in its natural environment significantly cooler than the 28°C routinely used in the laboratory, we identified proteins differentially expressed between 28°C and the more environmentally relevant temperature of 14°C. Of 2102 protein isoforms, 32 were temperature responsive and identified by mass spectrometry. Seven of these (OmpR, MucD, GuaD, OsmY and three of unknown function, Tee1, Tee2 and Tee3) were selected for genetic and ecological analyses. In each instance, changes in protein expression with temperature were mirrored by parallel transcriptional changes. The fitness contribution of the genes encoding each of the seven proteins was larger at 14°C than 28°C and included two cases of trade-offs (enhanced fitness at one temperature and reduced fitness at the other -mucD and tee2 deletions). The relationship between the fitness effects of genes in vitro and in vivo was variable, but two temperature-responsive genes -osmY and mucD- contribute substantially to the ability of P. fluorescens to colonize the plant environment.

The structure-function relationship of WspR, a Pseudomonas fluorescens response regulator with a GGDEF output domain

The GGDEF response regulator WspR couples the chemosensory Wsp pathway to the overproduction of acetylated cellulose and cell attachment in the Pseudomonas fluorescens SBW25 wrinkly spreader (WS) genotype. Here, it is shown that WspR is a diguanylate cyclase (DGC), and that DGC activity is elevated in the WS genotype compared to that in the ancestral smooth (SM) genotype. A structure-function analysis of 120 wspR mutant alleles was employed to gain insight into the regulation and activity of WspR. Firstly, 44 random and defined pentapeptide insertions were produced in WspR, and the effects determined using assays based on colony morphology, attachment to surfaces and cellulose production. The effects of mutations within WspR were interpreted using a homology model, based on the crystal structure of Caulobacter crescentus PleD. Mutational analyses indicated that WspR activation occurs as a result of disruption of the interdomain interface, leading to the release of effector-domain repression by the N-terminal receiver domain. Quantification of attachment and cellulose production raised significant questions concerning the mechanisms of WspR function. The conserved RYGGEEF motif of WspR was also subjected to mutational analysis, and 76 single amino acid residue substitutions were tested for their effects on WspR function. The RYGGEEF motif of WspR is functionally conserved, with almost every mutation abolishing function.

Experimental adaptation to high and low quality environments under different scales of temporal variation

We investigated the role of the scale of temporal variation in the evolution of generalism in populations of the bacterium Pseudomonas fluorescens. Replicate populations were propagated as batch cultures for approximately 1400 generations (192 days), in either high quality media only, low quality media only, or were alternated between the two at a range of temporal scales (between 1 and 48 days). Populations evolved in alternating media showed fitness increases in both media and the rate of alternation during selection had no effect on average fitness in either media. Moreover, the fitness of these populations in high quality media was the same as for populations evolved only in high quality media and likewise for low quality media. Populations evolved only in high or low quality media did not show fitness improvements in their nonselective media. These results indicate that cost-free generalists can evolve under a wide range of temporal variation.

Spatial heterogeneity and the stability of host-parasite coexistence

Spatially heterogeneous environments can theoretically promote more stable coexistence of hosts and parasites by reducing the risk of parasite attack either through providing permanent spatial refuges or through providing ephemeral refuges by reducing dispersal. In experimental populations of Pseudomonas aeruginosa and the bacteriophage PP7, spatial heterogeneity promoted stable coexistence of host and parasite, while coexistence was significantly less stable in the homogeneous environment. Phage populations were found to be persisting on subpopulations of sensitive bacteria. Transferring populations to fresh microcosms every 24 h prevented the development of permanent spatial refuges. However, the lower dispersal rates in the heterogeneous environment were found to reduce parasite transmission thereby creating ephemeral refuges from phage attack. These results suggest that spatial heterogeneity can stabilize an otherwise unstable host-parasite interaction even in the absence of permanent spatial refuges.

Type III secretion in plant growth-promoting Pseudomonas fluorescens SBW25

In vivo expression technology (IVET) analysis of rhizosphere-induced genes in the plant growth-promoting rhizobacterium (PGPR) Pseudomonas fluorescens SBW25 identified a homologue of the type III secretion system (TTSS) gene hrcC. The hrcC homologue resides within a 20-kb gene cluster that resembles the type III (Hrp) gene cluster of Pseudomonas syringae. The type III (Rsp) gene cluster in P. fluorescens SBW25 is flanked by a homologue of the P. syringae TTSS-secreted protein AvrE. P. fluorescens SBW25 is non-pathogenic and does not elicit the hypersensitive response (HR) in any host plant tested. However, strains constitutively expressing the rsp-specific sigma factor RspL elicit an AvrB-dependent HR in Arabidopsis thaliana ecotype Col-0, and a host-specific HR in Nicotiana clevelandii. The inability of wild-type P. fluorescens SBW25 to elicit a visible HR is therefore partly attributable to low expression of rsp genes in the leaf apoplast. DNA hybridization analysis indicates that rsp genes are present in many plant-colonizing Pseudomonas and PGPR, suggesting that TTSSs may have a significant role in the biology of PGPR. However, rsp and rsc mutants retain the ability to reach high population levels in the rhizosphere. While functionality of the TTSS has been demonstrated, the ecological significance of the rhizosphere-expressed TTSS of P. fluorescens SBW25 remains unclear.

Disturbance and diversity in experimental microcosms

External agents of mortality (disturbances) occur over a wide range of scales of space and time, and are believed to have large effects on species diversity. The "intermediate disturbance hypothesis", which proposes maximum diversity at intermediate frequencies of disturbance, has received support from both field and laboratory studies. Coexistence of species at intermediate frequencies of disturbance is thought to require trade-offs between competitive ability and disturbance tolerance, and a metapopulation structure, with disturbance affecting only a few patches at any given time. However, a unimodal relationship can also be generated by global disturbances that affect all patches simultaneously, provided that the environment contains spatial niches to which different species are adapted. Here we report the results of tests of this model using both isogenic and diverse populations of the bacterium Pseudomonas fluorescens. In both cases, a unimodal relationship between diversity and disturbance frequency was generated in heterogeneous, but not in homogeneous, environments. The cause of this relationship is competition among niche-specialist genotypes, which maintains diversity at intermediate disturbance, but not at high or low disturbance. Our results show that disturbance can modulate the effect of spatial heterogeneity on biological diversity in natural environments.

In vivo expression technology strategies: valuable tools for biotechnology

Whole genome sequences have shown that bacteria possess a significant number of genes that have no known function. It is probable that many of these are required for survival in environments other than the agar plate. In vivo selection strategies provide a means of obtaining genes active in complex natural environments. Direct access to these genes is essential for understanding ecological performance and provides novel opportunities for biotechnology.

Diversity peaks at intermediate productivity in a laboratory microcosm

The species diversity of natural communities is often strongly related to their productivity. The pattern of this relationship seems to vary: diversity is known to increase monotonically with productivity, to decrease monotonically with productivity, and to be unimodally related to productivity, with maximum diversity occurring at intermediate levels of productivity. The mechanism underlying these patterns remains obscure, although many possibilities have been suggested. Here we outline a simple mechanism--involving selection in a heterogeneous environment--to explain these patterns, and test it using laboratory cultures of the bacterium Pseudomonas fluorescens. We grew diverse cultures over a wide range of nutrient concentrations, and found a strongly unimodal relationship between diversity and productivity in heterogeneous, but not in homogeneous, environments. Our result provides experimental evidence that the unimodal relationship often observed in natural communities can be caused by selection for specialized types in a heterogeneous environment.

The emergence and maintenance of diversity: insights from experimental bacterial populations

Mechanisms maintaining genetic and phenotypic variation in natural populations are central issues in ecology and evolution. However, the long generation times of most organisms and the complexity of natural environments have made elucidation of ecological and evolutionary mechanisms difficult. Experiments using bacterial populations propagated in controlled environments reduce ecosystem complexity to the point where understanding simple processes in isolation becomes possible. Recent studies reveal the circumstances and mechanisms that promote the emergence of stable polymorphisms.

Environmentally constrained mutation and adaptive evolution in Salmonella

The relationship between environment and mutation is complex [1]. Claims of Lamarkian mutation [2] have proved unfounded [3-5]; it is apparent, however, that the external environment can influence the generation of heritable variation, through either direct effects on DNA sequence [6] or DNA maintenance and copying mechanisms [7-10], or as a consequence of evolutionary processes [11-16]. The spectrum of mutational events subject to environmental influence is unknown [6] and precisely how environmental signals modulate mutation is unclear. Evidence from bacteria suggests that a transient recombination-dependent hypermutational state can be induced by starvation [5]. It is also apparent that changes in the mutability of specific loci can be influenced by alterations in DNA topology [10,17]. Here we describe a remarkable instance of adaptive evolution in Salmonella which is caused by a mutation that occurs in intermediate-strength osmotic environments. We show that the mutation is not 'directed' and describe its genetic basis. We also present compelling evidence in support of the hypothesis that the mutational event is constrained by signals transmitted from the external environment via changes in the activity of DNA gyrase.

Adaptation of Pseudomonas fluorescens to the plant rhizosphere

Saprophytic Pseudomonas are common root-colonizing bacteria that can improve plant health. Efficient exploitation of these bacteria in agriculture requires knowledge of traits that enhance ecological performance in the rhizosphere. Here, I describe the development and application of a promoter-trapping technology (IVET) that enables the isolation of Pseudomonas fluorescens genes that show elevated levels of expression in the rhizosphere. Using IVET, 20 P. fluorescens genes were identified that are induced during rhizosphere colonization, and their patterns of expression were analysed in laboratory media and in the rhizosphere. Fourteen genes showed significant homology to sequences in GenBank that are involved in nutrient acquisition, stress response, or secretion; six showed no homology. Seven of the rhizosphere-induced (rhi) genes have homology to known non-Pseudomonas genes. One of the rhi genes (hrcC) is a component of a type III secretion pathway, not previously known in non-parasitic bacteria. Together, these genes provide a view of the rhizosphere environment as perceived by a rhizosphere colonist, and suggest that the nature of the association between P. fluorescens and the plant root may be more complex and intimate than previously thought.

Evolutionary genetics: The economics of mutation

The presence of mutator genotypes in populations of bacteria may be favoured by selection because they produce rare beneficial mutations and thereby increase the rate of adaptive evolution. Recent work, however, shows that the relationship between mutation rates and adaptive evolution is more complicated.

Detecting linkage disequilibrium in bacterial populations

The distribution of the number of pairwise differences calculated from comparisons between n haploid genomes has frequently been used as a starting point for testing the hypothesis of linkage equilibrium. For this purpose the variance of the pairwise differences, VD, is used as a test statistic to evaluate the null hypothesis that all loci are in linkage equilibrium. The problem is to determine the critical value of the distribution of VD. This critical value can be estimated either by Monte Carlo simulation or by assuming that VD is distributed normally and calculating a one-tailed 95% critical value for VD, L, L = EVD + 1.645 sqrt(VarVD), where E(VD) is the expectation of VD, and Var(VD) is the variance of VD. If VD (observed) > L, the null hypothesis of linkage equilibrium is rejected. Using Monte Carlo simulation we show that the formula currently available for Var(VD) is incorrect, especially for genetically highly diverse data. This has implications for hypothesis testing in bacterial populations, which are often genetically highly diverse. For this reason we derive a new, exact formula for Var(VD). The distribution of VD is examined and shown to approach normality as the sample size increases. This makes the new formula a useful tool in the investigation of large data sets, where testing for linkage using Monte Carlo simulation can be very time consuming. Application of the new formula, in conjunction with Monte Carlo simulation, to populations of Bradyrhizobium japonicum, Rhizobium leguminosarum, and Bacillus subtilis reveals linkage disequilibrium where linkage equilibrium has previously been reported.

Bacterial genomics and adaptation to life on plants: implications for the evolution of pathogenicity and symbiosis

Many bacteria form intimate associations with plants. Despite the agricultural and biotechnological significance of these bacteria, no whole genome sequences have yet been described. Plant-associated bacteria form a phylogenetically diverse group, with representative species from many major taxons. Sequence information from genomes of closely related bacteria, in combination with technological developments in the field of functional genomics, provides new opportunities for determining the origin and evolution of traits that contribute to bacterial fitness and interactions with plant hosts.

Adaptive radiation in a heterogeneous environment

Successive adaptive radiations have played a pivotal role in the evolution of biological diversity. The effects of adaptive radiation are often seen, but the underlying causes are difficult to disentangle and remain unclear. Here we examine directly the role of ecological opportunity and competition in driving genetic diversification. We use the common aerobic bacterium Pseudomonas fluorescens, which evolves rapidly under novel environmental conditions to generate a large repertoire of mutants. When provided with ecological opportunity (afforded by spatial structure), identical populations diversify morphologically, but when ecological opportunity is restricted there is no such divergence. In spatially structured environments, the evolution of variant morphs follows a predictable sequence and we show that competition among the newly evolved niche-specialists maintains this variation. These results demonstrate that the elementary processes of mutation and selection alone are sufficient to promote rapid proliferation of new designs and support the theory that trade-offs in competitive ability drive adaptive radiation.

Single-step conjugative cloning of bacterial gene fusions involved in microbe-host interactions

In vivo expression technology (IVET) is a genetic strategy for isolating genes expressed in vivo. In order to full exploit this technology, it is necessary to analyse large numbers of IVET-generated gene fusions, which must be recovered from the chromosome of host bacteria. In bacteria for which transductional methods are not available, the recovery of integrated fusion plasmids is problematic and currently limits broad application of IVET. We describe a rapid, single-step, triparental conjugative approach for recovering chromosomally integrated fusion plasmids from both Pseudomonas fluorescens and Salmonella typhimurium. This simple and broadly applicable conjugative cloning system extends the utility of the IVET approach to clinically and agronomically relevant microbes and may be employed to recover non-replicating and integrated plasmids in other systems.

Physical and genetic map of the Pseudomonas fluorescens SBW25 chromosome

Pseudomonas fluorescens is a saprophytic bacterium commonly isolated from soil, water, and the surfaces and tissues of plants and animals. The species has important applications in biotechnology because it can enhance plant growth and protect crops against disease. A complete physical map of the 6.63 Mbp P. fluorescens SBW25 chromosome was constructed using data obtained from combinations of one- and two-dimensional electrophoresis of completely or partially digested chromosomal DNA with end labelling. In total, 139 restriction sites (15 PacI, 53 SpeI, 71 XbaI) were placed on the physical map and complete maps of the circular chromosome were obtained for both PacI and SpeI; only XbaI fragments linking SpeI fragments were positioned. The average resolution of restriction sites was 48 kbp. A genetic map was derived from the physical map by southern hybridization and 31 genes were positioned including oriC, rDNA operons (rnnA-E), recA, gacA, and pyvD.

Site directed chromosomal marking of a fluorescent pseudomonad isolated from the phytosphere of sugar beet; stability and potential for marker gene transfer

A plasmid-free, non-pathogenic, ribosomal RNA group 1 fluorescent pseudomonad, Pseudomonas fluorescens SBW25, was selected from the microflora of sugar beet (Beta vulgaris) and modified to contain constitutively expressed marker genes. By site directed homologous recombination a KX cassette [kanamycin resistance (kanr) and catechol 2,3 dioxygenase (xylE)] and a ZY cassette [lactose utilization (lacZY, beta-galactosidase, lactose permease)] were introduced at least 1 Mbp apart on the 6.6 Mbp bacterial chromosome. Separate sites were selected to provide sensitive detection methods and allow assessments of marker gene stability of the genetically modified micro-organism (GMM), SBW25EeZY6KX, when it colonized the leaves and roots of sugar beet plants following seed inoculation.

Comparison of Borrelia isolated from UK foci of Lyme disease

Restriction endonuclease digestion of linear borrelial chromosomal DNA showed that three isolates of UK Lyme disease spirochaetes differed markedly from each other and from published data for other isolates from North America and continental Europe. Analysis of linear plasmid bands revealed that UK isolates differed from each other in the number and sizes of the plasmids in isolates from different foci of UK Lyme disease. Fatty acid analysis (of fatty acid methyl ester (FAME) profiles) showed the UK isolates clustering together with the relapsing fever spirochaetes, Borrelia turicatae and Borrelia parkeri. These data are discussed in respect of current knowledge of Lyme borreliosis in the UK.

Phenotypic and genotypic diversity of fluorescent pseudomonads isolated from field-grown sugar beet

A sample of 30 fluorescent pseudomonads isolated from the phyllosphere of sugar beet throughout a single growing season and shown to be closely related on the basis of fatty acid methyl ester (FAME) analysis was subjected to detailed phenotypic and genotypic characterization. Phenotypic traits were assessed on the basis of biochemical properties, assimilation of sole carbon sources, FAME analysis, organic pyrolysate content (MS-pyrolysis), and total cellular protein profiles. With the exception of total cellular protein profiles, numerical analysis of the data revealed two main clusters, each of which was divided into several subclusters. Numerical analysis of total cellular protein data failed to differentiate isolates into two main clusters, but nevertheless grouped isolates into six subclusters. On the basis of biochemical and carbon source assimilation profiles, 19 isolates were identified as Pseudomonas fluorescens biovar V, eight isolates as P. fluorescens biovar III and three isolates as P. syringae pathovar syringae. In general, all methods of phenotypic analysis grouped isolates according to time of sampling and leaf type. Genome analysis was undertaken by pulsed-field gel electrophoresis (PFGE) of PacI, SpeI, SwaI and XbaI macrorestriction fragments and revealed the presence of eight distinct genomic (clonal) groups. These groups correlated closely with the clusters generated by numerical analysis of phenotypic data, but there was no correlation between macrorestriction fragment profile and isolate identification; in fact the variation in macrorestriction fragment patterns within P. fluorescens biovars was as great as the variation detected between biovars, and between P. fluorescens and P. syringae. Statistical evaluation of macrorestriction fragment patterns revealed two examples of recent strain divergence: one was due to the presence of a 400 kbp plasmid within one isolate of a collection of nine otherwise genomically identical isolates, and the other was observed between two phenotypically similar isolates sampled 220 d apart. Genetic variation was expressed in terms of nucleotide diversity (pi) and pairwise comparisons yielded values ranging from 0.0029 to 0.1517. The mean intrapopulation genetic variation was high (0.0993), but limited genetic variation was detected among isolates sampled on each occasion. Taken together this suggests a population comprised of a variety of apparently distantly related clones (genomic groups), each adapted to local conditions. Genome sizes were estimated from the sum of SpeI restriction fragments and ranged from 4.2 to 5.5 Mbp. Examination of the distribution of XbaI, SpeI, SwaI and PacI restriction endonuclease sites showed that the distribution of SpeI sites differed significantly from the expected (random) distribution.

Adaptive evolution of highly mutable loci in pathogenic bacteria

Bacteria have specific loci that are highly mutable. We argue that the coexistence within bacterial genomes of such 'contingency' genes with high mutation rates, and 'housekeeping' genes with low mutation rates, is the result of adaptive evolution, and facilitates the efficient exploration of phenotypic solutions to unpredictable aspects of the host environment while minimizing deleterious effects on fitness.

Genome and fatty acid analysis of Pseudomonas stutzeri

A genome and fatty acid analysis of 16 Pseudomonas stutzeri reference strains having DNA compositions ranging from 62.2 to 65.5 mol% G+C was performed by pulsed-field gel electrophoresis of XbaI and SpeI macrorestriction fragments and gas chromatography of total cellular fatty acids. Macrorestriction fragment patterns were evaluated by using previously described algorithms (D. Grothues and B. Tümmler, Mol. Microbiol. 5:2763-2776, 1991), and the results allowed us to subdivide the species into two groups which correlated with G+C content. Two examples of recent strain divergence were observed among clinical isolates, but in general a marked degree of heterogeneity was observed in the macrorestriction fragment patterns, and even phenotypically similar strains produced divergent patterns. While the differences were not sufficiently great to exclude any strain from P. stutzeri, they suggest that recombination and niche-specific selection may be significant factors responsible for generating and maintaining the heterogeneity inherent in the species. Genome sizes were estimated from the sums of SpeI restriction fragment sizes and ranged from 3.4 to 4.3 Mbp; the genome sizes of the low-G+C-content strains (G+C contents, approximately 62 mol%) were confined to a narrow range between 3.9 and 4.1 Mbp. An examination of the distributions of macrorestriction fragments resulting from digestion with XbaI and SpeI showed that both distributions differed significantly from the expected (random) distribution, suggesting that there is a supragenic level of chromosomal organization. An analysis of fatty acid methyl ester data by using Microbial Identification System software revealed a similar correlation between phenotype and G+C content, indicating that division of the species is possible by the method used in this study.(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of a gene cluster encoding three high-molecular-weight proteins, which is required for synthesis of tolaasin by the mushroom pathogen Pseudomonas tolaasii

The extracellular lipodepsipeptide toxin tolaasin is the primary disease determinant of pathogenicity of Pseudomonas tolaasii on the cultivated mushroom, Agaricus bisporus. Transposon mutagenesis of P. tolaasii NCPPB 1116 with Tn5-generated 5000 chromosomal insertions of which 35 (0.7%) were tolaasin negative and 12 (0.25%) produced a reduced amount of tolaasin. In addition, TnphoA mutagenesis yielded a single tolaasin-negative mutant which was phoA active. Restriction enzyme mapping of mutant DNAs by Southern hybridization analysis revealed that the majority of Tn5 insertions were confined to a single genetic locus of approximately 65 kbp. Pulsed-field gel electrophoresis of representative Tn5 mutant DNAs showed that this region is at one end of a 640 kbp PacI chromosomal fragment and that the P. tolaasii genome is 6.7 Mbp. SDS-PAGE analysis of protein extracts from wild-type P. tolaasii demonstrated the presence of three high-molecular-weight proteins (designated TL1, TL2 and TL3). Alterations in the presence of these proteins, as well as apparently truncated forms of the 465 kDa (TL1), 440 kDa (TL2) and 435 kDa (TL3) proteins were observed in some mutants, enabling the direction and order of the transcriptional units to be determined. Two other Tn5 mutations were also identified which resulted in a tolaasin-negative phenotype, but which did not affect the expression of TL1, TL2, or TL3. One of these mutants is linked to the TL-cluster, but the other is located outside this region. It is concluded that at least five genetic loci, including those encoding TL1, TL2 and TL3, are required for tolaasin synthesis.

Phenotypic variation of Pseudomonas putida and P. tolaasii affects the chemotactic response to Agaricus bisporus mycelial exudate

The chemotactic response of wild-type Pseudomonas putida and P. tolaasii, and a phenotypic variant of each species, to Agaricus bisporus mycelial exudate was examined. Both P. putida, the bacterium responsible for initiating basidiome development of A. bisporus, and P. tolaasii, the causal organism of bacterial blotch disease of the mushroom, displayed a positive chemotactic response to Casamino acids and to A. bisporus mycelial exudate. The response was both dose- and time-dependent and marked differences were observed between the response time of the wild-type strains and their phenotypic variants. Phenotypic variants responded rapidly to both attractants and reached a maximum response after 10-20 min, whereas the wild-types took 45-60 min. The differences are partly explained by the more rapid swimming speed of the phenotypic variants. Both variants responded maximally to similar concentrations of Casamino acids and mycelial exudates. Investigations into the nature of the attractants contained in the mycelial exudate indicated that they are predominantly small (Mr less than 2000) thermostable compounds. Sugars present in the exudate did not elicit a chemotactic response in any isolate, but a mixture of 14 amino acids detected in the exudate accounted for between 50 and 75% of the chemotactic response of the fungal exudate.

Phenotypic variation of Pseudomonas putida and P. tolaasii affects attachment to Agaricus bisporus mycelium

The effect of phenotypic variation on attachment of Pseudomonas tolaasii and P. putida to Agaricus bisporus mycelium was investigated. Quantitative studies demonstrated the ability of each isolate to attach rapidly and firmly to A. bisporus mycelium and significant differences in attachment of wild-type and phenotypic variant strains were observed. This was most pronounced in P. tolaasii, where the percentage attachment of the wild-type form was always greater than that of the phenotypic variant. The medium upon which the bacteria were cultured, prior to conducting an attachment assay, had a significant effect on their ability to attach. Attachment of the wild-type form of P. putida was enhanced when the assay was performed in the presence of CaCl2, suggesting the involvement of electrostatic forces. No correlation was observed between bacterial hydrophobicity and ability to attach to A. bisporus mycelium. Scanning electron microscopy confirmed the results obtained from the quantitative studies and provided further evidence for marked differences in the ability of the pseudomonads to attach to mycelium. Fibrillar structures and amorphous material were frequently associated with attached cells and appeared to anchor bacteria to each other and to the hyphal surface. A time-course study of attachment using transmission electron microscopy revealed the presence of uneven fibrillar material on the surface of cells. This material stained positive for polysaccharide and may be involved in ensuring rapid, firm attachment of the cells.