An active β‐lactamase is a part of an orchestrated cell wall stress resistance network of <i>Bacillus subtilis</i> and related rhizosphere species

Bucher, Tabitha; Keren-Paz, Alona; Hausser, Jean; Olender, Tsviya; Cytryn, Eddie; Kolodkin‐Gal, Ilana

doi:10.1111/1462-2920.14526

Cited by 16 publications

(18 citation statements)

References 78 publications

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“…Soil dwelling microbes typically use antibiotic production, especially ß-lactams, to protect their niche in this nutrient-poor environment. Therefore, successful soil inhabitants often exhibit antibiotic resistances (Butterworth et al, 1979;Bucher et al, 2019). Both PBTS strains appeared to be characterized by a differential set of ß-lactamases ( Supplementary Table S10) and, in agreement with the higher number of putative ß-lactamase genes in PBTS2 compared to PBTS1 (5 versus 2), antibiograms showed that the former was indeed much more resistant to different penicillins (Table 4).…”

Section: Different (Supplementarymentioning

confidence: 67%

Functional Genomics Insights Into the Pathogenicity, Habitat Fitness, and Mechanisms Modifying Plant Development of Rhodococcus sp. PBTS1 and PBTS2

et al. 2020

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Pistachio Bushy Top Syndrome (PBTS) is a recently emerged disease that has strongly impacted the pistachio industry in California, Arizona, and New Mexico. The disease is caused by two bacteria, designated PBTS1 that is related to Rhodococcus corynebacterioides and PBTS2 that belongs to the species R. fascians. Here, we assessed the pathogenic character of the causative agents and examined their chromosomal sequences to predict the presence of particular functions that might contribute to the observed co-occurrence and their effect on plant hosts. In diverse assays, we confirmed the pathogenicity of the strains on "UCB-1" pistachio rootstock and showed that they can also impact the development of tobacco species, but concurrently inconsistencies in the ability to induce symptoms were revealed. We additionally evidence that fas genes are present only in a subpopulation of pure PBTS1 and PBTS2 cultures after growth on synthetic media, that these genes are easily lost upon cultivation in rich media, and that they are enriched for in an in planta environment. Analysis of the chromosomal sequences indicated that PBTS1 and PBTS2 might have complementary activities that would support niche partitioning. Growth experiments showed that the nutrient utilization pattern of both PBTS bacteria was not identical, thus avoiding co-inhabitant competition. PBTS2 appeared to have the potential to positively affect the habitat fitness of PBTS1 by improving its resistance against increased concentrations of copper and penicillins. Finally, mining the chromosomes of PBTS1 and PBTS2 suggested that the bacteria could produce cytokinins, auxins, and plant growth-stimulating volatiles and that PBTS2 might interfere with ethylene levels, in support of their impact on plant development. Subsequent experimentation supported these in silico predictions. Altogether, our data provide an explanation for the observed pathogenic behavior and unveil part of the strategies used by PBTS1 and PBTS2 to interact with plants.

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Section: Different (Supplementarymentioning

confidence: 67%

Functional Genomics Insights Into the Pathogenicity, Habitat Fitness, and Mechanisms Modifying Plant Development of Rhodococcus sp. PBTS1 and PBTS2

et al. 2020

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“…β-lactamases are enzymes that account for an additional layer of defense as they hydrolyze the β-lactam ring of β-lactams, thus inactivating the antibiotic before it reaches its target, the PBPs (penicillin binding proteins) ( Therrien and Levesque, 2000 ). The active β-lactamase of B. subtilis ( Takagi et al., 1993 ; Bucher et al., 2019 ) was not induced but rather modestly decreased ( p = 0.015) in the presence of the plant ( Supplementary Figure S1 ). In addition, the expression of the core metabolic enzyme lactate dehydrogenase ldh was also unaffected by the root ( Supplementary Figure S1 ).…”

Section: Resultsmentioning

confidence: 99%

“…the PBPs (penicillin binding proteins) (Therrien and Levesque, 2000). The active b-lactamase of B. subtilis (Takagi et al, 1993;Bucher et al, 2019) was not induced but rather modestly decreased (p = 0.015) in the presence of the plant (Supplementary Figure S1). In addition, the expression of the core metabolic enzyme lactate dehydrogenase ldh was also unaffected by the root (Supplementary Figure S1).…”

Section: A B D Cmentioning

confidence: 99%

Bacillus subtilis Colonization of Arabidopsis thaliana Roots Induces Multiple Biosynthetic Clusters for Antibiotic Production

Maan

Gilhar

Porat

et al. 2021

Front. Cell. Infect. Microbiol.

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Beneficial and probiotic bacteria play an important role in conferring immunity of their hosts to a wide range of bacterial, viral, and fungal diseases. Bacillus subtilis is a Gram-positive bacterium that protects the plant from various pathogens due to its capacity to produce an extensive repertoire of antibiotics. At the same time, the plant microbiome is a highly competitive niche, with multiple microbial species competing for space and resources, a competition that can be determined by the antagonistic potential of each microbiome member. Therefore, regulating antibiotic production in the rhizosphere is of great importance for the elimination of pathogens and establishing beneficial host-associated communities. In this work, we used B. subtilis as a model to investigate the role of plant colonization in antibiotic production. Flow cytometry and imaging flow cytometry (IFC) analysis supported the notion that Arabidopsis thaliana specifically induced the transcription of the biosynthetic clusters for the non-ribosomal peptides surfactin, bacilysin, plipastatin, and the polyketide bacillaene. IFC was more robust in quantifying the inducing effects of A. thaliana, considering the overall heterogeneity of the population. Our results highlight IFC as a useful tool to study the effect of association with a plant host on bacterial gene expression. Furthermore, the common regulation of multiple biosynthetic clusters for antibiotic production by the plant can be translated to improve the performance and competitiveness of beneficial members of the plant microbiome.

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“…In nature, bacteria form complex and differentiated multicellular communities, known as biofilms 1 . The coordinated actions of many cells, communicating and dividing labour, improve the ability of the biofilm community to resist antibiotics and environmental assaults [2][3][4] . Bacterial biofilms are associated with persistent chronic infections, and thus pose a global threat of extreme clinical importance 5,6 .…”

Section: Introductionmentioning

confidence: 99%

Weaponizing volatiles to inhibit competitor biofilms from a distance

Hou

Keren-Paz

Korenblum

et al. 2021

npj Biofilms Microbiomes

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The soil bacterium Bacillus subtilis forms beneficial biofilms that induce plant defences and prevent the growth of pathogens. It is naturally found in the rhizosphere, where microorganisms coexist in an extremely competitive environment, and thus have evolved a diverse arsenal of defence mechanisms. In this work, we found that volatile compounds produced by B. subtilis biofilms inhibited the development of competing biofilm colonies, by reducing extracellular matrix gene expression, both within and across species. This effect was dose-dependent, with the structural defects becoming more pronounced as the number of volatile-producing colonies increased. This inhibition was mostly mediated by organic volatiles, and we identified the active molecules as 3-methyl-1-butanol and 1-butanol. Similar results were obtained with biofilms formed by phylogenetically distinct bacterium sharing the same niche, Escherichia coli, which produced the biofilm-inhibiting 3-methyl-1-butanol and 2-nonanon. The ability of established biofilms to inhibit the development and spreading of new biofilms from afar might be a general mechanism utilized by bacterial biofilms to protect an occupied niche from the invasion of competing bacteria.

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An active β‐lactamase is a part of an orchestrated cell wall stress resistance network of Bacillus subtilis and related rhizosphere species

Cited by 16 publications

References 78 publications

Functional Genomics Insights Into the Pathogenicity, Habitat Fitness, and Mechanisms Modifying Plant Development of Rhodococcus sp. PBTS1 and PBTS2

Functional Genomics Insights Into the Pathogenicity, Habitat Fitness, and Mechanisms Modifying Plant Development of Rhodococcus sp. PBTS1 and PBTS2

Bacillus subtilis Colonization of Arabidopsis thaliana Roots Induces Multiple Biosynthetic Clusters for Antibiotic Production

Weaponizing volatiles to inhibit competitor biofilms from a distance

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