1. A TAL effector-like protein of an endofungal bacterium increases the stress tolerance and alters the transcriptome of the host
- Author
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Fabio C. Rinaldi, Sara C. D. Carpenter, Stephen J. Mondo, Teresa E. Pawlowska, Adam J. Bogdanove, Zoë E. Dubrow, Olga A. Lastovetsky, Mark R. Sabol, and Morgan E Carter
- Subjects
Rhizopus microsporus ,Evolution ,Burkholderia ,Physiological ,Mutant ,Stress ,Microbiology ,03 medical and health sciences ,TAL effector ,Stress, Physiological ,type III secretion ,Gene Expression Regulation, Fungal ,Genetics ,Type III Secretion Systems ,2.2 Factors relating to the physical environment ,Gene ,Gene knockout ,Transcription Activator-Like Effectors ,030304 developmental biology ,0303 health sciences ,Reporter gene ,Multidisciplinary ,biology ,urogenital system ,030306 microbiology ,Effector ,Biological Sciences ,biology.organism_classification ,symbiosis ,Btl proteins ,Fungal ,Gene Expression Regulation ,Infection ,Transcriptome ,Rhizopus - Abstract
Significance Endosymbiotic bacteria are found in diverse fungi, but little is known about how they communicate with their hosts. Some plant pathogenic bacteria use type III-translocated TAL effectors to control host transcription, and TAL-like proteins are encoded in genomes of the fungal endosymbiotic bacterium Mycetohabitans rhizoxinica. In this paper, we present evidence that these proteins are, like TAL effectors, type III-secreted, nuclear-localizing effectors that perturb host transcription and show that one enhances tolerance of the fungal host to cell membrane stress. Our characterization of an effector in a bacterial–fungal symbiosis opens a new door to molecular understanding of these interkingdom partnerships. Our findings also provide insight into the functional diversity and evolution of the TAL effector protein family., Symbioses of bacteria with fungi have only recently been described and are poorly understood. In the symbiosis of Mycetohabitans (formerly Burkholderia) rhizoxinica with the fungus Rhizopus microsporus, bacterial type III (T3) secretion is known to be essential. Proteins resembling T3-secreted transcription activator-like (TAL) effectors of plant pathogenic bacteria are encoded in the three sequenced Mycetohabitans spp. genomes. TAL effectors nuclear-localize in plants, where they bind and activate genes important in disease. The Burkholderia TAL-like (Btl) proteins bind DNA but lack the N- and C-terminal regions, in which TAL effectors harbor their T3 and nuclear localization signals, and activation domain. We characterized a Btl protein, Btl19-13, and found that, despite the structural differences, it can be T3-secreted and can nuclear-localize. A btl19-13 gene knockout did not prevent the bacterium from infecting the fungus, but the fungus became less tolerant to cell membrane stress. Btl19-13 did not alter transcription in a plant-based reporter assay, but 15 R. microsporus genes were differentially expressed in comparisons both of the fungus infected with the wild-type bacterium vs. the mutant and with the mutant vs. a complemented strain. Southern blotting revealed btl genes in 14 diverse Mycetohabitans isolates. However, banding patterns and available sequences suggest variation, and the btl19-13 phenotype could not be rescued by a btl gene from a different strain. Our findings support the conclusion that Btl proteins are effectors that act on host DNA and play important but varied or possibly host genotype-specific roles in the M. rhizoxinica–R. microsporus symbiosis.
- Published
- 2020