Linking phenotype to genotype in pseudonas aeruginosa

The global transcriptional regulator mexT, is a mutational hotspot; the sequence variants commonly seen to co-exist within the P. aeruginosa population are: drug susceptible (e.g. PAO1) and chloramphenicol and norfloxacin non-susceptible (nfxC mutant). The nfxC phenotype, selected for on chloramphenicol agar is characterised by reduced virulence. The conversion between PAO1 and nfxC phenotypes is associated with an 8-bp repeat sequence in mexT. To investigate the effects of the 8-bp repeat on the adaptive mode of survival of P. aeruginosa, isogenic mutants were generated: PA (8-bp, two copies) and PAdel (8-bp, one copy). The mutants were characterised using phenotypic microarrays (PM), motility, antibiotic susceptibility, Galleria virulence models and RNA-seq in defined media. PM revealed differences in central metabolism indicating that PAdel/PAnfxC were associated with a biological metabolic cost. Strains with the single copy of the 8-bp sequence showed reduced motility and virulence. Transcriptome analysis revealed that mexT, in PA, consists of two regulatory elements defined by an intact helix-turn-helix motif (across the repeat region) which is capable of regulating the downstream LysR region via repressor and autoregulative mechanisms. Whole genome sequencing identified regions of compensatory mutations that were associated with differences in phenotype between PAdel (genetically modified) and PAnfxC (selected). To link phenotype and genotype and to understand the metabolic effects of this mutation, a genome wide metabolic reconstruction was performed. This revealed differences in key metabolic pathways such as glycolysis, gluconeogenesis and oxidative phosphorylation. This study has shown that an 8-bp repeat in mexT is a driver of genetic diversity. Regulatory elements linked to the effect of the 8-bp sequence on antibiotic resistance, central metabolism, chemotaxis, motility and virulence have also been identified. These methods can be used to define phenotype in any pair of isogenic mutants, at the genome level, and to investigate the clinical risk of strains

Engineering bacteriocin-mediated resistance against the plant pathogen Pseudomonas syringae.

The plant pathogen, Pseudomonas syringae (Ps), together with related Ps species, infects and attacks a wide range of agronomically important crops, including tomato, kiwifruit, pepper, olive and soybean, causing economic losses. Currently, chemicals and introduced resistance genes are used to protect plants against these pathogens but have limited success and may have adverse environmental impacts. Consequently, there is a pressing need to develop alternative strategies to combat bacterial disease in crops. One such strategy involves using narrow-spectrum protein antibiotics (so-called bacteriocins), which diverse bacteria use to compete against closely related species. Here, we demonstrate that one bacteriocin, putidacin L1 (PL1), can be expressed in an active form at high levels in Arabidopsis and in Nicotiana benthamiana in planta to provide effective resistance against diverse pathovars of Ps. Furthermore, we find that Ps strains that mutate to acquire tolerance to PL1 lose their O-antigen, exhibit reduced motility and still cannot induce disease symptoms in PL1-transgenic Arabidopsis. Our results provide proof-of-principle that the transgene-mediated expression of a bacteriocin in planta can provide effective disease resistance to bacterial pathogens. Thus, the expression of bacteriocins in crops might offer an effective strategy for managing bacterial disease, in the same way that the genetic modification of crops to express insecticidal proteins has proven to be an extremely successful strategy for pest management. Crucially, nearly all genera of bacteria, including many plant pathogenic species, produce bacteriocins, providing an extensive source of these antimicrobial agents