Transcriptome plasticity underlying plant root colonization and insect invasion by <i>Pseudomonas protegens</i>

Vesga, Pilar; Flury, Pascale; Vacheron, Jordan; Keel, Christoph; Croll, Daniel; Maurhofer, M.

doi:10.1038/s41396-020-0729-9

Cited by 46 publications

(85 citation statements)

References 98 publications

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“…According to our observations and to the discovery of several metabolites P. protegens may produce, the pathogenic interaction this bacterium can establish with different targets appear to be complex and multifactorial [16]. Evidence in our study of the biocidal potential against pests of veterinary importance, provides additional biological information to the previously reported bioinsecticidal action this bacterial species shows against crop pests and its plasticity establishing plant-beneficial interactions [19]. Despite different degrees of virulence are expected to be associated with diverse P. protegens strains, the maintenance within the species of an arsenal of toxins and virulence factors, suggests an evolutionary process in which a conserved pathogenic relationship with insects became established.…”

Section: Discussionsupporting

confidence: 61%

Oral Toxicity of Pseudomonas protegens against Muscoid Flies

Ruiu

Mura

2021

Toxins

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The bioinsecticidal action of Pseudomonas protegens has so far been reported against some target insects, and the mode of action remains unclear. In this study, the pathogenicity potential of a recently isolated strain of this bacterial species against fly larvae of medical and veterinary interest was determined. Preliminary experiments were conducted to determine the biocidal action by ingestion against Musca domestica and Lucilia caesar larvae, which highlighted a concentration-dependent effect, with LC50 values of 3.6 and 2.5 × 108 CFU/mL, respectively. Bacterial septicaemia was observed in the body of insects assuming bacterial cells by ingestion. Such rapid bacterial reproduction in the hemolymph supports a toxin-mediated mechanism of action involving the intestinal barrier overcoming. In order to gain more information on the interaction with the host, the relative time-course expression of selected P. protegens genes associated with virulence and pathogenicity, was determined by qPCR at the gut level during the first infection stage. Among target genes, chitinase D was the most expressed, followed by pesticin and the fluorescent insecticidal toxin fitD. According to our observations and to the diversity of metabolites P. protegens produces, the pathogenic interaction this bacterium can establish with different targets appears to be complex and multifactorial.

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Section: Discussionsupporting

confidence: 61%

Oral Toxicity of Pseudomonas protegens against Muscoid Flies

Ruiu

Mura

2021

Toxins

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“…Although pseudomonads were detected in field and laboratory-reared Lepidoptera (Çakici et al, 2014;Chen et al, 2016;Mashtoly et al, 2019;Skowronek et al, 2020) and Coleoptera (Bahar and Demirba g, 2007;Montagna et al, 2015a;Montagna et al, 2015b), and in laboratory-reared Diptera (Wong et al, 2015), it is still uncertain whether they have established a relationship with these insects or if they are just transient bacteria in their gut. Some plant-beneficial pseudomonads belonging to the Pseudomonas protegens, Pseudomonas chlororaphis and P. fluorescens species can also be pathogens of diverse pest insect species (Péchy-Tarr et al, 2008;Jang et al, 2013;Kupferschmied et al, 2013Kupferschmied et al, , 2014Péchy-Tarr et al, 2013;Ruffner et al, 2013Ruffner et al, , 2015Flury et al, 2016Flury et al, , 2019Loper et al, 2016;Vacheron et al, 2019;Vesga et al, 2020). Pseudomonas protegens and P. chlororaphis are known root colonizers and they can control soil-borne fungal pathogens (Haas and Défago, 2005).…”

Section: Introductionmentioning

confidence: 99%

“…This toxin is very similar to the Mcf (make caterpillars floppy) toxins of Photorhabdus luminescens and Xenorhabdus nematophila (Daborn et al, 2002;Waterfield et al, 2003;Ruffner et al, 2015). Subsequent work established that insecticidal activity in P. protegens and P. chlororaphis is a multifactorial trait that involves, besides the Fit toxin, various elements such as lipopolysaccharide O-antigens (Kupferschmied et al, 2014), the type VI secretion system (Vacheron et al, 2019), the cyclic lipopeptide orfamide A (Jang et al, 2013;Flury et al, 2016), a chitinase and a phospholipase C (Flury et al, 2016), hydrogen cyanide (Flury et al, 2017), the toxins rhizoxin (Loper et al, 2016) or IPD072Aa (Schellenberger et al, 2016), and two-partner secretion (TPS) systems (Vesga et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Phylogenetically closely related pseudomonads isolated from arthropods exhibit differential insect‐killing abilities and genetic variations in insecticidal factors

Vesga

Augustiny

Keel

et al. 2021

Environmental Microbiology

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Strains belonging to the Pseudomonas protegens and Pseudomonas chlororaphis species are able to control soilborne plant pathogens and to kill pest insects by producing virulence factors such as toxins, chitinases, antimicrobials or two-partner secretion systems. Most insecticidal Pseudomonas described so far were isolated from roots or soil. It is unknown whether these bacteria naturally occur in arthropods and how they interact with them. Therefore, we isolated P. protegens and P. chlororaphis from various healthy insects and myriapods, roots and soil collected in an agricultural field and a neighbouring grassland. The isolates were compared for insect killing, pathogen suppression and host colonization abilities. Our results indicate that neither the origin of isolation nor the phylogenetic position mirror the degree of insecticidal activity. Pseudomonas protegens strains appeared homogeneous regarding phylogeny, biocontrol and insecticidal capabilities, whereas P. chlororaphis strains were phylogenetically and phenotypically more heterogenous. A phenotypic and genomic analysis of five closely related P. chlororaphis isolates displaying varying levels of insecticidal activity revealed variations in genes encoding insecticidal factors that may account for the reduced insecticidal activity of certain isolates. Our findings point towards an adaption to insects within closely related pseudomonads and contribute to understand the ecology of insecticidal Pseudomonas.

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“…ExlA is a 172-kDa protein harboring (i) at the N-terminal end, a signal peptide (SP) followed by a TPS domain allowing interaction with its transporter ExlB, (ii) in the central part, a shaft consisting of a type-2 filamentous haemagglutinin adhesin (FHA2) domain, and (iii) a C-terminal domain that behaves like a molten globule in solution and has no characterized homolog [ 8 , 9 ] ( Figure S1 ). Interestingly, ExlA-like toxins have been identified in other Pseudomonas species ( P. putida , P. entomophila and P. protegens ) [ 10 , 11 ]. The ExlA-ExlB TPS is structurally related to TPSs present in other bacterial pathogens and exhibiting cytolytic activities, including ShlA-ShlB in Serratia marcescens , HpmA-HpmB in Proteus mirabilis , EthA-EthB in Edwardsiella tarda and HhdA-HhdB in Haemophilus ducreyi [ 12 ].…”

Section: Introductionmentioning

confidence: 99%

ExlA Pore-Forming Toxin: Localization at the Bacterial Membrane, Regulation of Secretion by Cyclic-Di-GMP, and Detection In Vivo

Deruelle

Berry

Bouillot

et al. 2021

Toxins

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ExlA is a highly virulent pore-forming toxin that has been recently discovered in outlier strains from Pseudomonas aeruginosa. ExlA is part of a two-partner secretion system, in which ExlA is the secreted passenger protein and ExlB the transporter embedded in the bacterial outer membrane. In previous work, we observed that ExlA toxicity in a host cell was contact-dependent. Here, we show that ExlA accumulates at specific points of the outer membrane, is likely entrapped within ExlB pore, and is pointing outside. We further demonstrate that ExlA is maintained at the membrane in conditions where the intracellular content of second messenger cyclic-di-GMP is high; lowering c-di-GMP levels enhances ExlB-dependent ExlA secretion. In addition, we set up an ELISA to detect ExlA, and we show that ExlA is poorly secreted in liquid culture, while it is highly detectable in broncho-alveolar lavage fluids of mice infected with an exlA+ strain. We conclude that ExlA translocation is halted at mid-length in the outer membrane and its secretion is regulated by c-di-GMP. In addition, we developed an immunological test able to quantify ExlA in biological samples.

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Transcriptome plasticity underlying plant root colonization and insect invasion by Pseudomonas protegens

Cited by 46 publications

References 98 publications

Oral Toxicity of Pseudomonas protegens against Muscoid Flies

Oral Toxicity of Pseudomonas protegens against Muscoid Flies

Phylogenetically closely related pseudomonads isolated from arthropods exhibit differential insect‐killing abilities and genetic variations in insecticidal factors

ExlA Pore-Forming Toxin: Localization at the Bacterial Membrane, Regulation of Secretion by Cyclic-Di-GMP, and Detection In Vivo

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