Your search keyword '"Theresa F. Law"' showing total 5 results

1. Specific modulation of the root immune system by a community of commensal bacteria

Author

Darshana Panda, Nicole M. Del Risco, Omri M. Finkel, Corbin D. Jones, Piotr A. Mieczkowski, Haofan Li, Isai Salas-González, Paulo José Pereira Lima Teixeira, Nicholas R. Colaianni, Jeffery L. Dangl, Sarah Gilbert, Jonathan M. Conway, Theresa F. Law, and Gabriel Castrillo

Subjects

Arabidopsis, Virulence, Plant Immunity, Gene Expression, Biology, Flagellum, Plant Roots, Immune system, Gene Expression Regulation, Plant, Symbiosis, MAMP, Soil Microbiology, Plant Diseases, Multidisciplinary, Innate immune system, Bacteria, Arabidopsis Proteins, Microbiota, fungi, Root microbiome, Immunity, Plants, Biological Sciences, biology.organism_classification, Cell biology, human activities

Abstract

Plants have an innate immune system to fight off potential invaders that is based on the perception of nonself or modified-self molecules. Microbe-associated molecular patterns (MAMPs) are evolutionarily conserved microbial molecules whose extracellular detection by specific cell surface receptors initiates an array of biochemical responses collectively known as MAMP-triggered immunity (MTI). Well-characterized MAMPs include chitin, peptidoglycan, and flg22, a 22-amino acid epitope found in the major building block of the bacterial flagellum, FliC. The importance of MAMP detection by the plant immune system is underscored by the large diversity of strategies used by pathogens to interfere with MTI and that failure to do so is often associated with loss of virulence. Yet, whether or how MTI functions beyond pathogenic interactions is not well understood. Here we demonstrate that a community of root commensal bacteria modulates a specific and evolutionarily conserved sector of the Arabidopsis immune system. We identify a set of robust, taxonomically diverse MTI suppressor strains that are efficient root colonizers and, notably, can enhance the colonization capacity of other tested commensal bacteria. We highlight the importance of extracellular strategies for MTI suppression by showing that the type 2, not the type 3, secretion system is required for the immunomodulatory activity of one robust MTI suppressor. Our findings reveal that root colonization by commensals is controlled by MTI, which, in turn, can be selectively modulated by specific members of a representative bacterial root microbiota.

Published

2021

2. The effects of soil phosphorous content on microbiota are driven by the plant phosphate starvation response

Author

Corbin D. Jones, Stijn Spaepen, Paulo José Pereira Lima Teixeira, Jeffery L. Dangl, Theresa F. Law, Omri M. Finkel, Gabriel Castrillo, and Isai Salas-González

Subjects

Microorganism, fungi, food and beverages, Plant Immunity, Biology, biology.organism_classification, Phosphate, chemistry.chemical_compound, Burkholderia, chemistry, Botany, Shoot, Microbiome, Starvation response, Bacteria

Abstract

Phosphate starvation response (PSR) in non-mycorrhizal plants comprises transcriptional reprogramming resulting in severe physiological changes to the roots and shoots and repression of plant immunity. Thus, plant-colonizing microorganisms – the plant microbiota – are exposed to direct influence by the soil’s phosphorous (P) content itself, as well as to the indirect effects of soil P on the microbial niches shaped by the plant. The individual contribution of these factors to plant microbiota assembly remains unknown. To disentangle these direct and indirect effects, we planted PSR-deficient Arabidopsis mutants in a long-term managed soil P gradient, and compared the composition of their shoot and root microbiota to wild type plants across different P concentrations. PSR-deficiency had a larger effect on the composition of both bacterial and fungal plant-associated microbiota composition than P concentrations in both roots and shoots. The fungal microbiota was more sensitive to P concentrationsper sethan bacteria, and less depended on the soil community composition.Using a 185-member bacterial synthetic community (SynCom) across a wide P concentration gradient in an agar matrix, we demonstrated a shift in the effect of bacteria on the plant from a neutral or positive interaction to a negative one, as measured by rosette size. This phenotypic shift is accompanied by changes in microbiota composition: the genusBurkholderiais specifically enriched in plant tissue under P starvation. Through a community drop-out experiment, we demonstrate that in the absence ofBurkholderiafrom the SynCom, plant shoots accumulate higher phosphate levels than shoots colonized with the full SynCom, only under P starvation, but not under P-replete conditions. Therefore, P-stressed plants allow colonization by latent opportunistic competitors found within their microbiome, thus exacerbating the plant’s P starvation.

Published

2019

3. The effects of soil phosphorus content on plant microbiota are driven by the plant phosphate starvation response

Author

Jeffery L. Dangl, Isai Salas-González, Omri M. Finkel, Paulo José Pereira Lima Teixeira, Theresa F. Law, Stijn Spaepen, Corbin D. Jones, and Gabriel Castrillo

Subjects

0301 basic medicine, Life Sciences & Biomedicine - Other Topics, DIVERSITY, Arabidopsis, Plant Science, Pathology and Laboratory Medicine, Plant Roots, Soil, 0302 clinical medicine, BACTERIAL ADAPTATION, Edaphology, Medicine and Health Sciences, Arabidopsis thaliana, R PACKAGE, Biology (General), 2. Zero hunger, biology, WILT DISEASE, General Neuroscience, Microbiota, Plant physiology, RHIZOSPHERE, food and beverages, Eukaryota, Phosphorus, Genomics, Plants, ARABIDOPSIS, Bacterial Pathogens, Chemistry, Experimental Organism Systems, Medical Microbiology, Plant Physiology, Shoot, Physical Sciences, Pathogens, General Agricultural and Biological Sciences, Starvation response, Life Sciences & Biomedicine, Plant Shoots, Research Article, Biochemistry & Molecular Biology, QH301-705.5, Burkholderia, Arabidopsis Thaliana, Plant Immunity, Soil Science, Microbial Genomics, Brassica, Research and Analysis Methods, Microbiology, General Biochemistry, Genetics and Molecular Biology, Phosphorus metabolism, Phosphates, 03 medical and health sciences, LEAF, Model Organisms, Stress, Physiological, Plant and Algal Models, SEARCH, Botany, Genetics, Biology, Microbial Pathogens, Science & Technology, General Immunology and Microbiology, Bacteria, fungi, Ecology and Environmental Sciences, Chemical Compounds, Organisms, Fungi, Biology and Life Sciences, 15. Life on land, biology.organism_classification, SIMBIOSE, NITROGEN, 030104 developmental biology, Animal Studies, Microbiome, COMMUNITIES, 030217 neurology & neurosurgery

Abstract

Phosphate starvation response (PSR) in nonmycorrhizal plants comprises transcriptional reprogramming resulting in severe physiological changes to the roots and shoots and repression of plant immunity. Thus, plant-colonizing microorganisms—the plant microbiota—are exposed to direct influence by the soil’s phosphorus (P) content itself as well as to the indirect effects of soil P on the microbial niches shaped by the plant. The individual contribution of these factors to plant microbiota assembly remains unknown. To disentangle these direct and indirect effects, we planted PSR-deficient Arabidopsis mutants in a long-term managed soil P gradient and compared the composition of their shoot and root microbiota to wild-type plants across different P concentrations. PSR-deficiency had a larger effect on the composition of both bacterial and fungal plant-associated microbiota than soil P concentrations in both roots and shoots. To dissect plant–microbe interactions under variable P conditions, we conducted a microbiota reconstitution experiment. Using a 185-member bacterial synthetic community (SynCom) across a wide P concentration gradient in an agar matrix, we demonstrated a shift in the effect of bacteria on the plant from a neutral or positive interaction to a negative one, as measured by rosette size. This phenotypic shift was accompanied by changes in microbiota composition: the genus Burkholderia was specifically enriched in plant tissue under P starvation. Through a community drop-out experiment, we demonstrated that in the absence of Burkholderia from the SynCom, plant shoots accumulated higher ortophosphate (Pi) levels than shoots colonized with the full SynCom but only under Pi starvation conditions. Therefore, Pi-stressed plants are susceptible to colonization by latent opportunistic competitors found within their microbiome, thus exacerbating the plant’s Pi starvation., This study shows that plants' response to phosphate starvation has more influence on plant microbiota than does the phosphate concentration itself; these changes are not necessarily beneficial for the plant, and can even exacerbate the phosphate starvation.

Published

2019

4. A complex immune response to flagellin epitope variation in commensal communities

Author

Youssef Belkhadir, Corbin D. Jones, Katarzyna Parys, Jeffery L. Dangl, Ho-Seok Lee, Tatiana S. Mucyn, Theresa F. Law, Nicholas R. Colaianni, Natalie Edelbacher, Jonathan M. Conway, Mathias Madalinski, and Nak Hyun Kim

Subjects

Genetics, 0303 health sciences, biology, Host (biology), fungi, Pattern recognition receptor, Plant Immunity, chemical and pharmacologic phenomena, biochemical phenomena, metabolism, and nutrition, Microbiology, Epitope, 03 medical and health sciences, 0302 clinical medicine, Immune system, Immunity, Virology, biology.protein, bacteria, Parasitology, MAMP, 030217 neurology & neurosurgery, Flagellin, 030304 developmental biology

Abstract

Immune systems restrict microbial pathogens by identifying "non-self" molecules called microbe-associated molecular patterns (MAMPs). It is unclear how immune responses are tuned to or by MAMP diversity present in commensal microbiota. We systematically studied the variability of commensal peptide derivatives of flagellin (flg22), a MAMP detected by plants. We define substantial functional diversity. Most flg22 peptides evade recognition, while others contribute to evasion by manipulating immunity through antagonism and signal modulation. We establish a paradigm of signal integration, wherein the sequential signaling outputs of the flagellin receptor are separable and allow for reprogramming by commensal-derived flg22 epitope variants. Plant-associated communities are enriched for immune evading flg22 epitopes, but upon physiological stress that represses the immune system, immune-activating flg22 epitopes become enriched. The existence of immune-manipulating epitopes suggests that they evolved to either communicate or utilize the immune system for host colonization and thus can influence commensal microbiota community composition.

Published

2021

5. Design of synthetic bacterial communities for predictable plant phenotypes

Author

Tianxiang Gao, Corbin D. Jones, Tatiana S. Mucyn, Isai Salas González, Elizabeth A. Shank, Matthew J. Powers, Sur Herrera Paredes, Meghan E. Feltcher, Jeffery L. Dangl, Paulo José Pereira Lima Teixeira, Omri M. Finkel, Theresa F. Law, Vladimir Jojic, and Gabriel Castrillo

Subjects

0106 biological sciences, 0301 basic medicine, Gene Expression, Plant Science, Biochemistry, Plant Roots, 01 natural sciences, RNA, Ribosomal, 16S, Metabolites, Arabidopsis thaliana, Biology (General), RNA RIBOSOMAL 16S, Plant Growth and Development, 2. Zero hunger, Abiotic component, Gene Ontologies, General Neuroscience, Eukaryota, food and beverages, Genomics, Plants, Phenotype, Chemistry, Root Growth, Experimental Organism Systems, Physical Sciences, General Agricultural and Biological Sciences, Plant Shoots, Research Article, QH301-705.5, Arabidopsis Thaliana, Microbial Consortia, Brassica, Computational biology, Biology, Research and Analysis Methods, Genes, Plant, General Biochemistry, Genetics and Molecular Biology, Phosphates, 03 medical and health sciences, Model Organisms, Bacterial colonization, Plant and Algal Models, Genetics, Symbiosis, Gene, Bacteria, Host Microbial Interactions, General Immunology and Microbiology, Plant roots, Host (biology), Chemical Compounds, Organisms, Biology and Life Sciences, Computational Biology, Genome Analysis, biology.organism_classification, Metabolism, 030104 developmental biology, Seedlings, Genes, Bacterial, Brassicaceae, Developmental Biology, 010606 plant biology & botany

Abstract

Specific members of complex microbiota can influence host phenotypes, depending on both the abiotic environment and the presence of other microorganisms. Therefore, it is challenging to define bacterial combinations that have predictable host phenotypic outputs. We demonstrate that plant–bacterium binary-association assays inform the design of small synthetic communities with predictable phenotypes in the host. Specifically, we constructed synthetic communities that modified phosphate accumulation in the shoot and induced phosphate starvation–responsive genes in a predictable fashion. We found that bacterial colonization of the plant is not a predictor of the plant phenotypes we analyzed. Finally, we demonstrated that characterizing a subset of all possible bacterial synthetic communities is sufficient to predict the outcome of untested bacterial consortia. Our results demonstrate that it is possible to infer causal relationships between microbiota membership and host phenotypes and to use these inferences to rationally design novel communities., Author summary Symbiotic microbes influence host development and health, but predicting which microbes or groups of microbes will have a helpful or harmful effect is a major challenge in microbiome research. In this article, we describe a new method to design and predict bacterial communities that alter the plant host response to phosphate starvation. The method uses plant–bacterium binary-association assays to define groups of bacteria that elicit similar effects on the host plant. By constructing partially overlapping bacterial communities, we demonstrated that it is possible to modify phosphate accumulation in the plant shoot and the induction of plant phosphate starvation genes in a controlled manner. We found that bacterial colonization of the plant root does not predict the capacity to produce this phenotype. We evaluated the predictive performance of different statistical models and identified one best able to predict the behavior of untested communities. Our work demonstrates that studying a subset of all possible bacterial communities is sufficient to anticipate the outcome of novel bacterial combinations, and we establish that it is possible to deduce causality between microbiome composition and host phenotypes in complex systems.

Published

2018