Competition triggers plasmid-mediated enhancement of substrate utilisation in Pseudomonas putida

Competition-driven phenotypic plasticity in Iron acquisition and aromatic utilization confers a fitness advantage to Pseudomonas putida in an Iron-limited rhizospheric environment

Iron scarcity poses a critical challenge for rhizospheric bacteria like Pseudomonas putida in the competitive rhizosphere. Despite its dependence on iron for essential functions such as root colonization, motility, and aromatic compound utilization, P. putida exhibits limited capability for heterologous siderophore utilization and primarily relies on the secretion of a single siderophore, pyoverdine. This study investigates the mechanisms by which P. putida acquires iron in an iron-limited, aromatic-rich, rhizosphere-like environment. Our findings demonstrate that P. putida exhibits significant phenotypic plasticity, dynamically modulating pyoverdine secretion in response to competitive pressures and substrate availability. This adaptive strategy optimizes energy expenditure and iron acquisition, providing a competitive advantage. Comparative gene expression analysis supports these observations, revealing the molecular underpinnings of this plasticity. Enhanced pyoverdine production driven by competition compensates for the bacterium's limited siderophore repertoire and facilitates rapid aromatic compound utilization, conferring a distinct fitness advantage in iron-deprived conditions. This study elucidates the complex interplay between competition, iron uptake, and aromatic compound utilization that underpins the rhizospheric success of P. putida.

High-throughput identification of genes influencing the competitive ability to obtain nutrients and performance of biocontrol in Pseudomonas putida JBC17

Elucidating underlying mechanisms of biocontrol agents (BCAs) could aid in selecting potent BCAs and increasing their biocontrol efficacy. Nutrient competition is an important biocontrol mechanism; however, essential nutrient sources, and contributing genes for nutrient competition still remain to be explored. Pseudomonas putida JBC17 (JBC17WT) suppressed green mold in satsuma mandarins by inhibiting conidial germination of Penicillium digitatum via nutrient competition. To analyze genes essential for biocontrol performance of JBC17WT, we generated a transposon (Tn)-mediated mutant library and selected mutants with the ability to suppress conidial germination. Several mutants in the genes of flagella-formation, including fliR, fliH, and flgG, increased biocontrol performance and enhanced inhibition of conidial germination. They lost swimming motility, exhibited increased growth and rapid carbon and nitrogen utilization than the wild type under nutrient-poor conditions. The nutrient competition assay using polytetrafluoroethylene cylinders revealed that conidial germination was inhibited by nutrient absorption under nutrient-poor conditions. In addition, genes, including amidohydrolase (ytcJ), tonB-dependent receptor (cirA), argininosuccinate synthase (argG), D-3-phosphoglycerate dehydrogenase (serA), and chaperone protein (dnaJ), were involved in the inhibition of conidial germination. The results of this study indicate that rapid and continuous absorption of nutrients by JBC17WT restrict nutrient availability for conidial germination on nutrient-limited fruit surfaces, thereby decreasing the chances of fungal spores infecting fruits. The high-throughput analysis of Tn mutants of this study highlighted the importance of nutrient competition and the genes that influence biocontrol ability, which contributes to the development of biocontrol applications.

Relating the prevalence of plasmid-mediated AmpC beta-lactamase genes to aquatic environmental factors

It is important that environmental parameters that may affect the prevalence of AmpC beta-lactamase genes are investigated to devise frameworks for their surveillance, management and prevention. The aim of this study was thus to determine which environmental parameters are associated with the prevalence of clinically relevant AmpC beta-lactamase genes in aquatic systems. River water was sampled from seven sites in the Crocodile West River, South Africa. Physical-chemical parameters, metal levels and beta-lactam levels were measured. Environmental DNA was extracted from the water samples and six AmpC beta-lactamase gene groups (ACC, ACT/MIR, BIL/LAT/CMY, DHA, FOX, MOX/CMY) were quantified using quantitative PCR. Additionally, 16S rRNA gene metabarcoding analyses were performed on eDNA for each site and metabolic pathways were predicted using PICRUST2. Network analysis was performed to establish co-occurrences of AmpC genes with environmental factors. Quantification results indicated that AmpC gene copy numbers were significantly high (Kruskal Wallis H Test, p < 0.05) at Sites 1-3 of the Crocodile West River. In contrast, no significant changes regarding environmental factors were observed across the seven sites. Results of network analysis indicated that the AmpC gene groups had limited associations with all the environmental parameters, except for some key bacterial families, specifically Pseudomonadaceae, Aeromonadaceae and Enterobacteriaceae. A significant positive correlation between population density and AmpC genes suggested that in more densely populated areas more faecal pollution will be prevalent which is associated with high AmpC gene levels. Areas such as these are also likely to be linked with more antibiotic use which supports the notion that pre-selection of AmpC genes occurs before entering the aquatic environment. Moreover, it was demonstrated that prevalent selectors of AmpC genes do not ensure that continuous selection occurs in an aquatic environment. This information could be vital in future detection and management of AmpC genes in aquatic systems.

Protein as chemical cue: non-nutritional growth enhancement by exogenous protein in Pseudomonas putida KT2440

Research pertaining to microbe-microbe and microbe-plant interactions has been largely limited to small molecules like quorum sensing chemicals. However, a few recent reports have indicated the role of complex molecules like proteins and polysaccharides in microbial communication. Here we demonstrate that exogenous proteins present in culture media can considerably accelerate the growth of Pseudomonas putida KT2440, even when such proteins are not internalized by the cells. The growth enhancement is observed when the exogenous protein is not used as a source of carbon or nitrogen. The data show non-specific nature of the protein inducing growth; growth enhancement was observed irrespective of the protein type. It is shown that growth enhancement is mediated via increased siderophore secretion in response to the exogenous protein, leading to better iron uptake. We highlight the ecological significance of the observation and hypothesize that exogenous proteins serve as chemical cues in the case of P.putida and are perceived as indicator of the presence of competitors in the environment. It is argued that enhanced siderophore secretion in response to exogenous protein helps P.putida establish numerical superiority over competitors by way of enhanced iron assimilation and quicker utilization of aromatic substrates.

Pumping iron to keep fit: modulation of siderophore secretion helps efficient aromatic utilization in Pseudomonas putida KT2440

Studies of biotechnology applications of Pseudomonas putida KT2440 have been predominantly focused on regulation and expression of the toluene degradation (TOL) pathway. Unfortunately, there is limited information on the role of other physiological factors influencing aromatic utilization. In this report, we demonstrate that P. putida KT2440 increases its siderophore secretion in response to the availability of benzyl alcohol, a model aromatic substrate. It is argued that accelerated siderophore secretion in response to aromatic substrates provides an iron ‘boost’ which is required for the effective functioning of the iron-dependent oxygenases responsible for ring opening. Direct evidence for the cardinal role of siderophores in aromatic utilization is provided by evaluation of per capita siderophore secretion and comparative growth assessments of wild-type and siderophore-negative mutant strains grown on an alternative carbon source. Accelerated siderophore secretion can be viewed as a compensatory mechanism in P. putida in the context of its inability to secrete more than one type of siderophore (pyoverdine) or to utilize heterologous siderophores. Stimulated siderophore secretion might be a key factor in successful integration and proliferation of this organism as a bio-augmentation agent for aromatic degradation. It not only facilitates efficient aromatic utilization, but also provides better opportunities for iron assimilation amongst diverse microbial communities, thereby ensuring better survival and proliferation.

Bacterial contact-dependent delivery systems

Bacteria have developed remarkable systems that sense neighboring target cells upon contact and initiate a series of events that enhance their survival and growth at the expense of the target cells. Four main classes of bacterial cell surface structures have been identified that interact with prokaryotic or eukaryotic target cells to deliver DNA or protein effectors. Type III secretion systems (T3SS) use a flagellum-like tube to deliver protein effectors into eukaryotic host cells, whereas Type IV systems use a pilus-based system to mediate DNA or protein transfer into recipient cells. The contact-dependent growth inhibition system (CDI) is a Type V system, using a long β-helical cell surface protein to contact receptors in target cells and deliver a growth inhibitory signal. Type VI systems utilize a phage-like tube and cell puncturing device to secrete effector proteins into both eukaryotic and prokaryotic target cells.

Novel biocatalytic polymer-based antimicrobial coatings as potential ureteral biomaterial: preparation and in vitro performance evaluation

Catheters and other indwelling devices placed inside human body are prone to bacterial infection, causing serious risk to patients. Infections associated with implants are difficult to resolve, and hence the prevention of bacterial colonization of such surfaces is quite appropriate. In this context, the development of novel antimicrobial biomaterials is currently gaining momentum. We describe here the preparation and antibacterial properties of an enzyme-embedded polycaprolactone (PCL)-based coating, coimpregnated with the antibiotic gentamicin sulfate (GS). The enzyme uses PCL itself as substrate; as a result, the antibiotic gets released at a rate controlled by the degradation of the PCL base. In vitro drug release studies demonstrated sustained release of GS from the PCL film throughout its lifetime. By modulating the enzyme concentration in the PCL film, we were able to vary the lifetime of the coating from 33 h to 16 days. In the end, the polymer is completely degraded, delivering the entire load of the antibiotic. The polymer exhibited antibacterial properties against three test isolates: Escherichia coli, Pseudomonas aeruginosa, and Staphylococcus aureus. Foley urinary catheters coated with the modified polymer exhibited sustained in vitro release of GS over a 60-h period. The results suggest that the antibiotic-plus-enzyme-loaded polymer can be used as tunable self-degrading antimicrobial biomaterial coating on catheters.

A new extant respirometric assay to estimate intrinsic growth parameters applied to study plasmid metabolic burden

Start-up phenomena in microbial biokinetic assays are not captured by the most commonly used growth-related equations. In this study we propose a new respirometric experimental design to estimate intrinsic growth parameters that allow us to avoid these limitations without data omission, separate mathematical treatment, or wake-up pulses prior to the analysis. Identifiability and sensitivity analysis were performed to confirm the robustness of the new approach for obtaining unique and accurate estimates of growth kinetic parameters. The new experimental design was applied to establish the metabolic burden caused by the carriage of a pWW0 TOL plasmid in the model organism Pseudomonas putida KT2440. The metabolic burden associated was manifested as a reduction in the yield and the specific growth rate of the host, with both plasmid maintenance and the over-expression of recombinant proteins from the plasmid contributing equally to the overall effect.