Host–Pathogen Coevolution: The Selective Advantage of Bacillus thuringiensis Virulence and Its Cry Toxin Genes

Masri, Leila; Branca, Antoine; Sheppard, Anna E.; Papkou, Andrei; Laehnemann, David; Guenther, Patrick S.; Prahl, Swantje; Saebelfeld, Manja; Hollensteiner, Jacqueline; Liesegang, Heiko; Brzuszkiewicz, Elżbieta; Daniel, Rolf; Michiels, Nico K.; Schulte, Rebecca D.; Kurtz, Joachim; Rosenstiel, Philip; Telschow, Arndt; Bornberg‐Bauer, Erich; Schulenburg, Hinrich

doi:10.1371/journal.pbio.1002169

Cited by 73 publications

(102 citation statements)

References 56 publications

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“…The original selection of E. coli as a nutritional source for C. elegans was not based on knowledge of the natural microbes associated with C. elegans in its natural habitat, but on the availability of E. coli in research laboratories and in the history of Sydney Brenner, an E. coli bacteriophage geneticist, as he developed C. elegans as a model organism (12). Since the effect of diverse pathogenic bacteria has been studied in C. elegans (13)(14)(15)(16), however, little effort has been made to isolate ecologically relevant and not necessarily detrimental bacteria. A recent study has also made use of soil where C. elegans does not proliferate to isolate bacteria and study their community assembly (17).…”

mentioning

confidence: 99%

Caenorhabditis elegans responses to bacteria from its natural habitats

Samuel

Rowedder

Braendle

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

359

479

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Most Caenorhabditis elegans studies have used laboratory Escherichia coli as diet and microbial environment. Here we characterize bacteria of C. elegans' natural habitats of rotting fruits and vegetation to provide greater context for its physiological responses. By the use of 16S ribosomal DNA (rDNA)-based sequencing, we identified a large variety of bacteria in C. elegans habitats, with phyla Proteobacteria, Bacteroidetes, Firmicutes, and Actinobacteria being most abundant. From laboratory assays using isolated natural bacteria, C. elegans is able to forage on most bacteria (robust growth on ∼80% of >550 isolates), although ∼20% also impaired growth and arrested and/or stressed animals. Bacterial community composition can predict wild C. elegans population states in both rotting apples and reconstructed microbiomes: alpha-Proteobacteria-rich communities promote proliferation, whereas Bacteroidetes or pathogens correlate with nonproliferating dauers. Combinatorial mixtures of detrimental and beneficial bacteria indicate that bacterial influence is not simply nutritional. Together, these studies provide a foundation for interrogating how bacteria naturally influence C. elegans physiology.Caenorhabditis elegans | host-microbe interactions | ecology B iological organisms constantly live in contact with other organisms in a complex web of ecological interactions, which include prey-predator, host-parasite, competitive, or positive symbiotic relationships. Bacteria are now considered key players in multiple aspects of the biology of multicellular organisms (1-3). The richness and importance of these interactions were so far neglected because laboratory biology had succeeded in simplifying and standardizing the environment of the model organisms, providing in most cases a single microbe as a food source, and not necessarily even a naturally encountered one. The many aspects of organismal biology that were shaped by evolution in natural environments are thus undetectable in the artificial laboratory environment and can only be revealed in the presence of other interacting species. Examples include feeding behavior, metabolism of diverse natural food sources, interactions with natural pathogens that have shaped the organism's immune system, behavioral traits, and regulation of development and reproduction. At the genomic level, many individual genes may not be required in a standard laboratory environment but their role may be revealed by using more diverse and relevant environments (4, 5).The nematode Caenorhabditis elegans is a typical example of a model organism that has been disconnected from its natural ecology: although the species has been studied intensively in the laboratory for half a century, its habitat and natural ecology-what it naturally feeds on, its natural predators and pathogens,

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mentioning

confidence: 99%

Caenorhabditis elegans responses to bacteria from its natural habitats

Samuel

Rowedder

Braendle

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

359

479

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“…This toxin arsenal, especially the copy number of individual toxin genes, can be shaped by reciprocal co-adaptation with a nematode host, as previously demonstrated using controlled evolution experiments in the laboratory [41,42]. The B. thuringiensis strain MYBT18246 described herein and its host Caenorhabditis elegans have been selected as a model system for such co-evolution experiments [41]. One aim of this sequencing project was to provide a high-quality reference genome sequence for the original B. thuringiensis MYBT18246 in order to obtain a detailed phylogeny and shed light on the evolution of this microparasite, with a particular focus on the presence of virulence factors, elements of genome plasticity and host adaptation factors.…”

Section: Introductionmentioning

confidence: 79%

“…The worldwide distribution of B. thuringiensis and its capacity to adapt to a diverse spectrum of invertebrate hosts is explained by the formation of spores and a remarkable variability in crystal protein families [13]. This toxin arsenal, especially the copy number of individual toxin genes, can be shaped by reciprocal co-adaptation with a nematode host, as previously demonstrated using controlled evolution experiments in the laboratory [41,42]. The B. thuringiensis strain MYBT18246 described herein and its host Caenorhabditis elegans have been selected as a model system for such co-evolution experiments [41].…”

Section: Introductionmentioning

confidence: 86%

“…The genome sequence was analyzed to identify virulence factors and fitness factors contributing to the efficient infection of C. elegans. Additionally, the phylogenetic position of B. thuringiensis MYBT18246 in the Bcsl group was determined [41]. The complete genome sequence has been deposited in GenBank with the accession numbers (CP015350-CP015361) and in the integrated Microbial Genomes database with the Taxon ID 2671180122 [53].…”

Section: Genome Project Historymentioning

confidence: 99%

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Complete genome sequence of the nematicidal Bacillus thuringiensis MYBT18247

Hollensteiner

Spröer

Bunk

et al. 2017

Journal of Biotechnology

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Bacillus thuringiensis is a rod-shaped facultative anaerobic spore forming bacterium of the genus Bacillus. The defining feature of the species is the ability to produce parasporal crystal inclusion bodies, consisting of δ-endotoxins, encoded by cry-genes. Here we present the complete annotated genome sequence of the nematicidal B. thuringiensis strain MYBT18246. The genome comprises one 5,867,749 bp chromosome and 11 plasmids which vary in size from 6330 bp to 150,790 bp. The chromosome contains 6092 protein-coding and 150 RNA genes, including 36 rRNA genes. The plasmids encode 997 proteins and 4 t-RNA's. Analysis of the genome revealed a large number of mobile elements involved in genome plasticity including 11 plasmids and 16 chromosomal prophages. Three different nematicidal toxin genes were identified and classified according to the Cry toxin naming committee as cry13Aa2, cry13Ba1, and cry13Ab1. Strikingly, these genes are located on the chromosome in close proximity to three separate prophages. Moreover, four putative toxin genes of different toxin classes were identified on the plasmids p120510 (Vip-like toxin), p120416 (Cry-like toxin) and p109822 (two Bin-like toxins). A comparative genome analysis of B. thuringiensis MYBT18246 with three closely related B. thuringiensis strains enabled determination of the pan-genome of B. thuringiensis MYBT18246, revealing a large number of singletons, mostly represented by phage genes, morons and cryptic genes.

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“…This natural preservation is not possible in most systems, so researchers have turned to models that can be reared and tested in experimental settings. Experimental host-parasite coevolution is a powerful tool to investigate the evolution of host defense mechanisms and resistance as well as parasite virulence factors (e.g., Schulte et al, 2010;Masri et al, 2015;see Brockhurst and Koskella, 2013 for a review). Samples taken after different time points provide insight into evolutionary adaptations and counter-adaptations and such experiments have been carried out using model hosts such as Caenorhabditis elegans (Schulte et al, 2010;Masri et al, 2015), Daphnia spp.…”

Section: Introductionmentioning

confidence: 99%

Coevolution of parasitic fungi and insect hosts

Joop

Vilcinskas

2016

Zoology

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Parasitic fungi and their insect hosts provide an intriguing model system for dissecting the complex co-evolutionary processes, which result in Red Queen dynamics. To explore the genetic basis behind host-parasite coevolution we chose two parasitic fungi (Beauveria bassiana and Metarhizium anisopliae, representing the most important entomopathogenic fungi used in the biological control of pest or vector insects) and two established insect model hosts (the greater wax moth Galleria mellonella and the red flour beetle Tribolium castaneum) for which sequenced genomes or comprehensive transcriptomes are available. Focusing on these model organisms, we review the knowledge about the interactions between fungal molecules operating as virulence factors and insect host-derived defense molecules mediating antifungal immunity. Particularly the study of the intimate interactions between fungal proteinases and corresponding host-derived proteinase inhibitors elucidated novel coevolutionary mechanisms such as functional shifts or diversification of involved effector molecules. Complementarily, we compared the outcome of coevolution experiments using the parasitic fungus B. bassiana and two different insect hosts which were initially either susceptible (Galleria mellonella) or resistant (Tribolium castaneum). Taking a snapshot of host-parasite coevolution, we show that parasitic fungi can overcome host barriers such as external antimicrobial secretions just as hosts can build new barriers, both within a relatively short time of coevolution.

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Host–Pathogen Coevolution: The Selective Advantage of Bacillus thuringiensis Virulence and Its Cry Toxin Genes

Cited by 73 publications

References 56 publications

Caenorhabditis elegans responses to bacteria from its natural habitats

Caenorhabditis elegans responses to bacteria from its natural habitats

Complete genome sequence of the nematicidal Bacillus thuringiensis MYBT18247

Coevolution of parasitic fungi and insect hosts

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