Your search keyword '"Barney A. Geddes"' showing total 28 results

1. Engineering transkingdom signalling in plants to control gene expression in rhizosphere bacteria

Author

Barney A. Geddes, Ponraj Paramasivan, Amelie Joffrin, Amber L. Thompson, Kirsten Christensen, Beatriz Jorrin, Paul Brett, Stuart J. Conway, Giles E. D. Oldroyd, and Philip S. Poole

Subjects

Science

Abstract

The root microbiota is critical for promoting crop yield. Here, the authors create a synthetic pathway for the production of the rhizopine scyllo-inosamine in Medicago truncatula and barley, and show its perception by rhizosphere bacteria for targeted regulation of bacterial gene expression.

Published

2019

2. Succinoglycan Production Contributes to Acidic pH Tolerance in Sinorhizobium meliloti Rm1021

Author

Justin P. Hawkins, Barney A. Geddes, and Ivan J. Oresnik

Subjects

Microbiology, QR1-502, Botany, QK1-989

Abstract

In this work, the hypothesis that exopolysaccharide plays a role in the survival of Sinorhizobium meliloti at low pH levels is addressed. When S. meliloti was grown at pH 5.75, synthesis of succinoglycan increased, whereas synthesis of galactoglucan decreased. Succinoglycan that was isolated from cultures grown at low pH had a lower degree of polymerization relative to that which was isolated from cultures grown at neutral pH, suggesting that low–molecular weight (LMW) succinoglycan might play a role in adaptation to low pH. Mutants unable to produce succinoglycan or only able to produce high–molecular weight polysaccharide were found to be sensitive to low pH. However, strains unable to produce LMW polysaccharide were 10-fold more sensitive. In response to low pH, transcription of genes encoding proteins for succinoglycan, glycogen, and cyclic β(1-2) glucans biosynthesis increased, while those encoding proteins necessary for the biosynthesis of galactoglucan decreased. While changes in pH did not affect the production of glycogen or cyclic β(1-2) glucan, it was found that the inability to produce cyclic β(1-2) glucan did contribute to pH tolerance in the absence of succinoglycan. Finally, in addition to being sensitive to low pH, a strain carrying mutations in exoK and exsH, which encode the glycanases responsible for the cleavage of succinoglycan to LMW succinoglycan, exhibited a delay in nodulation and was uncompetitive for nodule occupancy. Taken together, the data suggest that the role for LMW succinoglycan in nodule development may be to enhance survival in the colonized curled root hair.

Published

2017

3. A Bacterial Expression Vector Archive (BEVA) for Flexible Modular Assembly of Golden Gate-Compatible Vectors

Author

Barney A. Geddes, Marcela A. Mendoza-Suárez, and Philip S. Poole

Subjects

Golden Gate, modular assembly, cloning vector, shuttle vector, broad-host range plasmid, open source, Microbiology, QR1-502

Abstract

We present a Bacterial Expression Vector Archive (BEVA) for the modular assembly of bacterial vectors compatible with both traditional and Golden Gate cloning, utilizing the Type IIS restriction enzyme Esp3I, and have demonstrated its use for Golden Gate cloning in Escherichia coli. Ideal for synthetic biology and other applications, this modular system allows a rapid, low-cost assembly of new vectors tailored to specific tasks. Using the principles outlined here, new modules (e.g., origin of replication for plasmids in other bacteria) can easily be designed for specific applications. It is hoped that this vector construction system will be expanded by the scientific community over time by creation of novel modules through an open source approach. To demonstrate the potential of the system, three example vectors were constructed and tested. The Golden Gate level 1 vector pOGG024 (pBBR1-based broad-host range and medium copy number) was used for gene expression in laboratory-cultured Rhizobium leguminosarum. The Golden Gate level 1 vector pOGG026 (RK2-based broad-host range, lower copy number and stable in the absence of antibiotic selection) was used to demonstrate bacterial gene expression in nitrogen-fixing nodules on pea plant roots formed by R. leguminosarum. Finally, the level 2 cloning vector pOGG216 (RK2-based broad-host range, medium copy number) was used to construct a dual reporter plasmid expressing green and red fluorescent proteins.

Published

2019

4. Exopolysaccharide Production in Response to Medium Acidification Is Correlated With an Increase in Competition for Nodule Occupancy

Author

Barney A. Geddes, Juan E. González, and Ivan J. Oresnik

Subjects

Microbiology, QR1-502, Botany, QK1-989

Abstract

Sinorhizobium meliloti strains unable to utilize galactose as a sole carbon source, due to mutations in the De-Ley Doudoroff pathway (dgoK), were previously shown to be more competitive for nodule occupancy. In this work, we show that strains carrying this mutation have galactose-dependent exopolysaccharide (EPS) phenotypes that were manifested as aberrant Calcofluor staining as well as decreased mucoidy when in an expR+ genetic background. The aberrant Calcofluor staining was correlated with changes in the pH of the growth medium. Strains carrying dgoK mutations were subsequently demonstrated to show earlier acidification of their growth medium that was correlated with an increase expression of genes associated with succinoglycan biosynthesis as well as increased accumulation of high and low molecular weight EPS in the medium. In addition, it was shown that the acidification of the medium was dependent on the inability of S. meliloti strains to initiate the catabolism of galactose. To more fully understand why strains carrying the dgoK allele were more competitive for nodule occupancy, early nodulation phenotypes were investigated. It was found that strains carrying the dgoK allele had a faster rate of nodulation. In addition, nodule competition experiments using genetic backgrounds unable to synthesize either succinoglycan or EPSII were consistent with the hypothesis that the increased competition phenotype was dependent upon the synthesis of succinoglycan. Fluorescent microscopy experiments on infected root-hair cells, using the acidotropic dye Lysotracker Red DND-99, provide evidence that the colonized curled root hair is an acidic compartment.

Published

2014

5. Rhizopine biosensors for plant-dependent control of bacterial gene expression

Author

Timothy L. Haskett, Barney A. Geddes, Ponraj Paramasivan, Patrick Green, Samir Chitnavis, Marta D. Mendes, Beatriz Jorrín, Hayley E. Knights, Tahlia R. Bastholm, Joshua P. Ramsay, Giles E. D. Oldroyd, Philip S. Poole, Haskett, Timothy L [0000-0003-4675-6009], Geddes, Barney A [0000-0001-8309-2083], Paramasivan, Ponraj [0000-0002-1268-4505], Jorrín, Beatriz [0000-0002-6198-0925], Knights, Hayley E [0000-0003-2002-4141], Bastholm, Tahlia R [0000-0002-3729-2356], Ramsay, Joshua P [0000-0002-1301-7077], Oldroyd, Giles ED [0000-0002-5245-6355], Poole, Philip S [0000-0001-5087-6455], and Apollo - University of Cambridge Repository

Subjects

Bacteria, Genes, Bacterial, Gene Expression, Biosensing Techniques, Microbiology, Ecology, Evolution, Behavior and Systematics

Abstract

Engineering signalling between plants and microbes could be exploited to establish host-specificity between plant-growth-promoting bacteria and target crops in the environment. We previously engineered rhizopine-signalling circuitry facilitating exclusive signalling between rhizopine-producing (RhiP) plants and model bacterial strains. Here, we conduct an in-depth analysis of rhizopine-inducible expression in bacteria. We characterize two rhizopine-inducible promoters and explore the bacterial host-range of rhizopine biosensor plasmids. By tuning the expression of rhizopine uptake genes, we also construct a new biosensor plasmid pSIR05 that has minimal impact on host cell growth in vitro and exhibits markedly improved stability of expression in situ on RhiP barley roots compared to the previously described biosensor plasmid pSIR02. We demonstrate that a sub-population of Azorhizobium caulinodans cells carrying pSIR05 can sense rhizopine and activate gene expression when colonizing RhiP barley roots. However, these bacteria were mildly defective for colonization of RhiP barley roots compared to the wild-type parent strain. This work provides advancement towards establishing more robust plant-dependent control of bacterial gene expression and highlights the key challenges remaining to achieve this goal.

Published

2022

6. qPCR assay targeting Bradyrhizobium japonicum shows that row spacing and soybean density affects Bradyrhizobium population

Author

Robert H. Gulden, Ivan J. Oresnik, Harry Yudistira, Barney A. Geddes, and Charles M. Geddes

Subjects

0303 health sciences, education.field_of_study, biology, fungi, Immunology, Population, Plant density, food and beverages, 04 agricultural and veterinary sciences, General Medicine, biology.organism_classification, Applied Microbiology and Biotechnology, Microbiology, Bradyrhizobium, Crop, 03 medical and health sciences, Agronomy, parasitic diseases, 040103 agronomy & agriculture, Genetics, 0401 agriculture, forestry, and fisheries, education, Molecular Biology, 030304 developmental biology, Bradyrhizobium japonicum

Abstract

The ability for a soybean plant to be efficiently nodulated when grown as a crop is dependent on the number of effective Bradyrhizobium japonicum that can be found in close proximity to the developing seedling shortly after planting. In Manitoba, the growing of soybean as a crop has increased from less than 500 000 acres in 2008 to over 2.3 million acres in 2017. Since the large increase in soybean production is relatively recent, populations of B. japonicum have not yet developed. In response to this, we developed a primer pair that can identify B. japonicum, and be used to determine the titre found in field soil. Their utility was demonstrated by being used to determine whether row spacing of soybean affects B. japonicum populations, as well as to follow B. japonicum populations in a soybean field over the course of a field season. The data show that plant density can affect B. japonicum populations. Moreover, evidence is presented that suggests plant development affects overall B. japonicum populations.

Published

2021

7. Engineered plant control of associative nitrogen fixation

Author

Timothy L. Haskett, Ponraj Paramasivan, Marta D. Mendes, Patrick Green, Barney A. Geddes, Hayley E. Knights, Beatriz Jorrin, Min-Hyung Ryu, Paul Brett, Christopher A. Voigt, Giles E. D. Oldroyd, and Philip S. Poole

Subjects

Multidisciplinary, Nitrogen Fixation, Nitrogenase, Hordeum, Edible Grain, Symbiosis, Plant Roots, Inositol, Azorhizobium caulinodans

Abstract

Engineering N2-fixing symbioses between cereals and diazotrophic bacteria represents a promising strategy to sustainably deliver biologically fixed nitrogen (N) in agriculture. We previously developed novel transkingdom signaling between plants and bacteria, through plant production of the bacterial signal rhizopine, allowing control of bacterial gene expression in association with the plant. Here, we have developed both a homozygous rhizopine producing (RhiP) barley line and a hybrid rhizopine uptake system that conveys upon our model bacterium Azorhizobium caulinodans ORS571 (Ac) 103-fold improved sensitivity for rhizopine perception. Using this improved genetic circuitry, we established tight rhizopine-dependent transcriptional control of the nitrogenase master regulator nifA and the N metabolism σ-factor rpoN, which drove nitrogenase expression and activity in vitro and in situ by bacteria colonizing RhiP barley roots. Although in situ nitrogenase activity was suboptimally effective relative to the wild-type strain, activation was specific to RhiP barley and was not observed on the roots of wild-type plants. This work represents a key milestone toward the development of a synthetic plant-controlled symbiosis in which the bacteria fix N2 only when in contact with the desired host plant and are prevented from interaction with nontarget plant species.

Published

2022

8. Engineering transkingdom signalling in plants to control gene expression in rhizosphere bacteria

Author

Giles E. D. Oldroyd, Philip S. Poole, Ponraj Paramasivan, Barney A. Geddes, Kirsten E. Christensen, Amber L. Thompson, Paul Brett, Amelie Joffrin, Stuart J. Conway, Beatriz Jorrin, Geddes, Barney A [0000-0001-8309-2083], Paramasivan, Ponraj [0000-0002-1268-4505], Joffrin, Amelie [0000-0002-5810-6073], Thompson, Amber L [0000-0001-8258-860X], Christensen, Kirsten [0000-0003-1683-2066], Jorrin, Beatriz [0000-0002-6198-0925], Conway, Stuart J [0000-0002-5148-117X], Oldroyd, Giles ED [0000-0002-5245-6355], Poole, Philip S [0000-0001-5087-6455], Apollo - University of Cambridge Repository, Geddes, Barney A. [0000-0001-8309-2083], Thompson, Amber L. [0000-0001-8258-860X], Conway, Stuart J. [0000-0002-5148-117X], Oldroyd, Giles E. D. [0000-0002-5245-6355], and Poole, Philip S. [0000-0001-5087-6455]

Subjects

0301 basic medicine, Crops, Agricultural, Agricultural microbiology, Microorganism, Science, Microbial metabolism, General Physics and Astronomy, Molecular engineering in plants, 02 engineering and technology, Biology, Plant Roots, General Biochemistry, Genetics and Molecular Biology, Applied microbiology, 03 medical and health sciences, 14/5, Medicago truncatula, Bioluminescence, 631/449/2667, lcsh:Science, Soil Microbiology, 2. Zero hunger, 631/61/447/2311, Rhizosphere, Multidisciplinary, Bacteria, business.industry, Microbiota, fungi, 631/326/2522, article, food and beverages, Agriculture, Hordeum, General Chemistry, 021001 nanoscience & nanotechnology, biology.organism_classification, Biotechnology, 030104 developmental biology, lcsh:Q, Secondary metabolism, 0210 nano-technology, business, Soil microbiology, Inositol

Abstract

The root microbiota is critical for agricultural yield, with growth-promoting bacteria able to solubilise phosphate, produce plant growth hormones, antagonise pathogens and fix N2. Plants control the microorganisms in their immediate environment and this is at least in part through direct selection, the immune system, and interactions with other microorganisms. Considering the importance of the root microbiota for crop yields it is attractive to artificially regulate this environment to optimise agricultural productivity. Towards this aim we express a synthetic pathway for the production of the rhizopine scyllo-inosamine in plants. We demonstrate the production of this bacterial derived signal in both Medicago truncatula and barley and show its perception by rhizosphere bacteria, containing bioluminescent and fluorescent biosensors. This study lays the groundwork for synthetic signalling networks between plants and bacteria, allowing the targeted regulation of bacterial gene expression in the rhizosphere for delivery of useful functions to plants., The root microbiota is critical for promoting crop yield. Here, the authors create a synthetic pathway for the production of the rhizopine scyllo-inosamine in Medicago truncatula and barley, and show its perception by rhizosphere bacteria for targeted regulation of bacterial gene expression.

Published

2019

9. Minimal gene set from Sinorhizobium ( Ensifer ) meliloti pSymA required for efficient symbiosis with Medicago

Author

George C. diCenzo, Jiarui Huang, Leah Sather, Aakanx K. Panchal, Jason V. S. Kearsley, Barney A. Geddes, Turlough M. Finan, Maryam Zamani, and Zahed Muhammed

Subjects

Nitrogen-Fixing Bacteria, Root nodule, Sinorhizobium, Computational biology, Plant Root Nodulation, Plant Roots, Rhizobia, 03 medical and health sciences, Symbiosis, Nitrogen Fixation, Medicago truncatula, Gene, 030304 developmental biology, 2. Zero hunger, 0303 health sciences, Multidisciplinary, Medicago, biology, 030306 microbiology, food and beverages, Biological Sciences, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Genes, Bacterial, Nitrogen fixation, Rhizobium, Root Nodules, Plant, Sinorhizobium meliloti

Abstract

Reduction of N(2) gas to ammonia in legume root nodules is a key component of sustainable agricultural systems. Root nodules are the result of a symbiosis between leguminous plants and bacteria called rhizobia. Both symbiotic partners play active roles in establishing successful symbiosis and nitrogen fixation: while root nodule development is mostly controlled by the plant, the rhizobia induce nodule formation, invade, and perform N(2) fixation once inside the plant cells. Many bacterial genes involved in the rhizobia–legume symbiosis are known, and there is much interest in engineering the symbiosis to include major nonlegume crops such as corn, wheat, and rice. We sought to identify and combine a minimal bacterial gene complement necessary and sufficient for symbiosis. We analyzed a model rhizobium, Sinorhizobium (Ensifer) meliloti, using a background strain in which the 1.35-Mb symbiotic megaplasmid pSymA was removed. Three regions representing 162 kb of pSymA were sufficient to recover a complete N(2)-fixing symbiosis with alfalfa, and a targeted assembly of this gene complement achieved high levels of symbiotic N(2) fixation. The resulting gene set contained just 58 of 1,290 pSymA protein-coding genes. To generate a platform for future synthetic manipulation, the minimal symbiotic genes were reorganized into three discrete nod, nif, and fix modules. These constructs will facilitate directed studies toward expanding the symbiosis to other plant partners. They also enable forward-type approaches to identifying genetic components that may not be essential for symbiosis, but which modulate the rhizobium’s competitiveness for nodulation and the effectiveness of particular rhizobia–plant symbioses.

Published

2020

10. qPCR assay targeting

Author

Harry, Yudistira, Barney A, Geddes, Charles M, Geddes, Robert H, Gulden, and Ivan J, Oresnik

Subjects

Seedlings, Manitoba, Bradyrhizobium, Soybeans, Polymerase Chain Reaction, Crop Production, Soil Microbiology, DNA Primers

Abstract

The ability for a soybean plant to be efficiently nodulated when grown as a crop is dependent on the number of effective

Published

2020

11. A multi-sensor system provides spatiotemporal oxygen regulation of gene expression in a Rhizobium-legume symbiosis

Author

Lucie McMurtry, Graham A. Hood, Paul J. Rutten, Antonis Papachristodoulou, Barney A. Geddes, Harrison Steel, and Philip S. Poole

Subjects

Root nodule, biology, Chemistry, Nitrogenase, biology.organism_classification, medicine.disease_cause, Rhizobium leguminosarum, Cell biology, Rhizobia, Symbiosis, Nitrogen fixation, medicine, Rhizobium, Limiting oxygen concentration

Abstract

Regulation by oxygen (O2) in rhizobia is essential for their symbioses with plants and involves multiple O2 sensing proteins. Three sensors exist in the pea microsymbiont Rhizobium leguminosarum Rlv3841: hFixL, FnrN and NifA. At low O2 concentrations (1%) hFixL signals via FxkR to induce expression of the FixK transcription factor, which activates transcription of downstream genes. These include fixNOQP, encoding the high-affinity cbb3-type terminal oxidase used in symbiosis. In vitro, the Rlv3841 hFixL-FxkR-FixK cascade was active at 1% O2, and confocal microscopy showed the cascade is active in the earliest stages of Rlv3841 differentiation in nodules (zones I-II). In vitro and in vivo work showed that the hFixL-FxkR-FixK cascade also induces transcription of fnrN at 1% O2 and in the earliest stages of Rlv3841 differentiation in nodules. We confirmed past findings suggesting a role for FnrN in fixNOQP expression. However, unlike hFixL-FxkR-FixK, Rlv3841 FnrN was only active in the near-anaerobic zones III-IV of pea nodules. Quantification of fixNOQP expression in nodules showed this was driven primarily by FnrN, with minimal direct hFixL-FxkR-FixK induction. Thus, FnrN is key for full symbiotic expression of fixNOQP. Without FnrN, nitrogen fixation was reduced by 85% in Rlv3841, while eliminating hFixL only reduced fixation by 25%. The hFixL-FxkR-FixK system effectively primes the O2 response by increasing fnrN expression in early differentiation (zones I-II). In Zone III of mature nodules, the near-anaerobic conditions activate FnrN, which induces fixNOQP transcription to the level required to achieve wild-type nitrogen fixation activity. Modelling and transcriptional analysis indicates that the different O2 sensitivities of hFixL and FnrN lead to a nuanced spatiotemporal pattern of gene regulation in different nodule zones in response to changing O2 concentration. Multi-sensor O2 regulation systems are prevalent in rhizobia, suggesting the fine-tuned control they enable is common and maximizes the effectiveness of the symbioses.Author SummaryRhizobia are soil bacteria that form a symbiosis with legume plants. In exchange for shelter from the plant, rhizobia provide nitrogen fertilizer, produced by nitrogen fixation. Fixation is catalysed by the nitrogenase enzyme, which is inactivated by oxygen. To prevent this, plants house rhizobia in root nodules, which create a low oxygen environment. However, rhizobia need oxygen, and must adapt to survive low oxygen in the nodule. Key to this is regulating their genes based on oxygen concentration. We studied one Rhizobium species which uses three different protein sensors of oxygen, each turning on at a different oxygen concentration. As the bacteria get deeper inside the plant nodule and the oxygen concentration drops, each sensor switches on in turn. Our results also show that the first sensor to turn on, hFixL, primes the second sensor, FnrN. This prepares the rhizobia for the core region of the nodule where oxygen concentration is lowest and most nitrogen fixation takes place. If both sensors are removed, the bacteria cannot fix nitrogen. Many rhizobia have several oxygen sensing proteins, so using multiple sensors is likely a common strategy that makes it possible for rhizobia to adapt to low oxygen gradually in stages during symbiosis.

Published

2020

12. Optimizing Rhizobium-legume symbioses by simultaneous measurement of rhizobial competitiveness and N2 fixation in nodules

Author

Philip S. Poole, Marcela Mendoza-Suárez, Beatriz Jorrin, Charlotte Kirchhelle, Ricardo H. Ramirez-Gonzalez, Carmen Sánchez-Cañizares, and Barney A. Geddes

Subjects

Multidisciplinary, biology, food and beverages, biology.organism_classification, medicine.disease_cause, Rhizobium leguminosarum, Rhizobia, N2 Fixation, Agronomy, Symbiosis, medicine, Rhizobium, Microbial inoculant, Legume

Abstract

Legumes tend to be nodulated by competitive rhizobia that do not maximize nitrogen (N 2 ) fixation, resulting in suboptimal yields. Rhizobial nodulation competitiveness and effectiveness at N 2 fixation are independent traits, making their measurement extremely time-consuming with low experimental throughput. To transform the experimental assessment of rhizobial competitiveness and effectiveness, we have used synthetic biology to develop reporter plasmids that allow simultaneous high-throughput measurement of N 2 fixation in individual nodules using green fluorescent protein (GFP) and barcode strain identification (Plasmid ID) through next generation sequencing (NGS). In a proof-of-concept experiment using this technology in an agricultural soil, we simultaneously monitored 84 different Rhizobium leguminosarum strains, identifying a supercompetitive and highly effective rhizobial symbiont for peas. We also observed a remarkable frequency of nodule coinfection by rhizobia, with mixed occupancy identified in ∼20% of nodules, containing up to six different strains. Critically, this process can be adapted to multiple Rhizobium -legume symbioses, soil types, and environmental conditions to permit easy identification of optimal rhizobial inoculants for field testing to maximize agricultural yield.

Published

2020

13. Optimizing

Author

Marcela A, Mendoza-Suárez, Barney A, Geddes, Carmen, Sánchez-Cañizares, Ricardo H, Ramírez-González, Charlotte, Kirchhelle, Beatriz, Jorrin, and Philip S, Poole

Subjects

Rhizobium leguminosarum, Nitrogen, Green Fluorescent Proteins, Peas, food and beverages, High-Throughput Nucleotide Sequencing, Fabaceae, Biological Sciences, Nitrogen Fixation, Synthetic Biology, Root Nodules, Plant, Symbiosis, Soil Microbiology, Plasmids

Abstract

Legumes tend to be nodulated by competitive rhizobia that do not maximize nitrogen (N(2)) fixation, resulting in suboptimal yields. Rhizobial nodulation competitiveness and effectiveness at N(2) fixation are independent traits, making their measurement extremely time-consuming with low experimental throughput. To transform the experimental assessment of rhizobial competitiveness and effectiveness, we have used synthetic biology to develop reporter plasmids that allow simultaneous high-throughput measurement of N(2) fixation in individual nodules using green fluorescent protein (GFP) and barcode strain identification (Plasmid ID) through next generation sequencing (NGS). In a proof-of-concept experiment using this technology in an agricultural soil, we simultaneously monitored 84 different Rhizobium leguminosarum strains, identifying a supercompetitive and highly effective rhizobial symbiont for peas. We also observed a remarkable frequency of nodule coinfection by rhizobia, with mixed occupancy identified in ∼20% of nodules, containing up to six different strains. Critically, this process can be adapted to multiple Rhizobium-legume symbioses, soil types, and environmental conditions to permit easy identification of optimal rhizobial inoculants for field testing to maximize agricultural yield.

Published

2020

14. The genomes of rhizobia

Author

Barney A. Geddes, George C. diCenzo, Jason V. S. Kearsley, Richard A. Morton, and Turlough M. Finan

Subjects

Nod factor, Genetics, Plasmid, Symbiosis, Nitrogen fixation, food and beverages, Chromosome, Biology, biology.organism_classification, Genome, Gene, Rhizobia

Abstract

The genomes of α- and β-rhizobia belonging to the α- and β-proteobacteria respectively contain genes for nitrogen fixation in symbiosis with host plants (encoded by nif and fix genes) and nodulation of their host plants, most often using Nod Factor (synthesized by nod, noe, nol gene products). In α-rhizobia symbiotic genes are often organized on plasmids of the repABC family, and symbiotic genes for the β-rhizobia are also plasmid borne. In some α-rhizobia, symbiotic genes are encoded on the chromosome within symbiotic islands that are integrative conjugal elements. In this chapter we give an overview of general features of rhizobial genomes including the symbiotic genes they contain and their organization. We review the current understanding of common features of rhizobial genomes and genomic backgrounds that support nodulation and nitrogen fixation and discuss genome deconstruction as a tool for uncovering new genes involved in symbiosis with legume plants.

Published

2020

15. Common dyes used to determine bacterial polysaccharides on agar are affected by medium acidification

Author

Justin P. Hawkins, Ivan J. Oresnik, and Barney A. Geddes

Subjects

0301 basic medicine, food.ingredient, 030106 microbiology, Immunology, Mutant, Applied Microbiology and Biotechnology, Microbiology, 03 medical and health sciences, chemistry.chemical_compound, food, Genetics, Agar, Coloring Agents, Molecular Biology, Sinorhizobium meliloti, Growth medium, biology, Benzenesulfonates, Polysaccharides, Bacterial, Bacterial polysaccharide, Wild type, General Medicine, Hydrogen-Ion Concentration, biology.organism_classification, Culture Media, Congo red, Phenotype, Biochemistry, chemistry, Galactose

Abstract

In this work, we highlight effects of pH on bacterial phenotypes when using the bacteriological dyes Aniline blue, Congo red, and Calcofluor white to analyze polysaccharide production. A study of galactose catabolism in Sinorhizobium meliloti led to the isolation of a mutation in dgoK1, which was observed to overproduce exopolysaccharides when grown in the presence of galactose. When this mutant strain was spotted onto plates containing Aniline blue, Congo red, or Calcofluor white, the intensity of the associated staining was strikingly different from that of the wild type. Additionally, a Calcofluor dull phenotype was observed, suggesting production of a polysaccharide other than succinoglycan. Further investigation of this phenotype revealed that these results were dependent on medium acidification, as buffering at pH 6 had no effect on these phenotypes, while medium buffered at pH 6.5 resulted in a reversal of the phenotypes. Screening for mutants of the dgoK1 strain that were negative for the Aniline blue phenotype yielded a strain carrying a mutation in tkt2, which is annotated as a putative transketolase. Consistent with the plate phenotypes, when this mutant was grown in broth cultures, it did not acidify its growth medium. Overall, this work shows that caution should be exercised in evaluating polysaccharide phenotypes based strictly on the use of dyes.

Published

2017

16. Control of nitrogen fixation in bacteria that associate with cereals

Author

Barney A. Geddes, Philip S. Poole, Tyler Toth, Amaya Garcia-Costas, Min-Hyung Ryu, Florence Mus, Devanshi Khokhani, Jing Zhang, Jean-Michel Ané, Christopher A. Voigt, and John W. Peters

Subjects

Microbiology (medical), Root nodule, Immunology, Applied Microbiology and Biotechnology, Microbiology, Plant Root Nodulation, Article, Rhizobia, Azorhizobium caulinodans, 03 medical and health sciences, Pseudomonas protegens, Bacterial Proteins, Nitrogen Fixation, Pseudomonas, Botany, Nitrogenase, Genetics, Escherichia coli, Symbiosis, 030304 developmental biology, 0303 health sciences, biology, 030306 microbiology, Chemistry, Nif gene, food and beverages, Cell Biology, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Azotobacter vinelandii, Metabolic Engineering, Genes, Bacterial, Multigene Family, Nitrogen fixation, bacteria, Edible Grain, Rhizobium

Abstract

Legumes obtain nitrogen from air through rhizobia residing in root nodules. Some species of rhizobia can colonize cereals but do not fix nitrogen on them. Disabling native regulation can turn on nitrogenase expression, even in the presence of nitrogenous fertilizer and low oxygen, but continuous nitrogenase production confers an energy burden. Here, we engineer inducible nitrogenase activity in two cereal endophytes (Azorhizobium caulinodans ORS571 and Rhizobium sp. IRBG74) and the well-characterized plant epiphyte Pseudomonas protegens Pf-5, a maize seed inoculant. For each organism, different strategies were taken to eliminate ammonium repression and place nitrogenase expression under the control of agriculturally relevant signals, including root exudates, biocontrol agents and phytohormones. We demonstrate that R. sp. IRBG74 can be engineered to result in nitrogenase activity under free-living conditions by transferring a nif cluster from either Rhodobacter sphaeroides or Klebsiella oxytoca. For P. protegens Pf-5, the transfer of an inducible cluster from Pseudomonas stutzeri and Azotobacter vinelandii yields ammonium tolerance and higher oxygen tolerance of nitrogenase activity than that from K. oxytoca. Collectively, the data from the transfer of 12 nif gene clusters between 15 diverse species (including Escherichia coli and 12 rhizobia) help identify the barriers that must be overcome to engineer a bacterium to deliver a high nitrogen flux to a cereal crop.

Published

2019

17. Multiple sensors provide spatiotemporal oxygen regulation of gene expression in a Rhizobium-legume symbiosis

Author

Graham A. Hood, Philip S. Poole, Harrison Steel, Paul J. Rutten, Barney A. Geddes, Antonis Papachristodoulou, Vinoy K. Ramachandran, and Lucie McMurtry

Subjects

0106 biological sciences, Cancer Research, Histidine Kinase, Physiology, Gene Expression, Artificial Gene Amplification and Extension, Plant Science, QH426-470, medicine.disease_cause, Biochemistry, Polymerase Chain Reaction, 01 natural sciences, Transcription (biology), Nucleic Acids, Gene expression, Genetics (clinical), Regulation of gene expression, 0303 health sciences, biology, Fabaceae, Cell biology, Chemistry, Plant Physiology, Physical Sciences, Rhizobium, Research Article, Chemical Elements, Research and Analysis Methods, Rhizobium leguminosarum, Rhizobia, 03 medical and health sciences, Bacterial Proteins, Symbiosis, Nitrogen Fixation, DNA-binding proteins, Operon, Genetics, medicine, Gene Regulation, Operons, Molecular Biology Techniques, Molecular Biology, Transcription factor, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Biology and Life Sciences, Proteins, DNA, Gene Expression Regulation, Bacterial, biology.organism_classification, Regulatory Proteins, Oxygen, Species Interactions, Mutation, Transcription Factors, 010606 plant biology & botany

Abstract

Regulation by oxygen (O2) in rhizobia is essential for their symbioses with plants and involves multiple O2 sensing proteins. Three sensors exist in the pea microsymbiont Rhizobium leguminosarum Rlv3841: hFixL, FnrN and NifA. At low O2 concentrations (1%) hFixL signals via FxkR to induce expression of the FixK transcription factor, which activates transcription of downstream genes. These include fixNOQP, encoding the high-affinity cbb3-type terminal oxidase used in symbiosis. In free-living Rlv3841, the hFixL-FxkR-FixK pathway was active at 1% O2, and confocal microscopy showed hFixL-FxkR-FixK activity in the earliest stages of Rlv3841 differentiation in nodules (zones I and II). Work on Rlv3841 inside and outside nodules showed that the hFixL-FxkR-FixK pathway also induces transcription of fnrN at 1% O2 and in the earliest stages of Rlv3841 differentiation in nodules. We confirmed past findings suggesting a role for FnrN in fixNOQP expression. However, unlike hFixL-FxkR-FixK, Rlv3841 FnrN was only active in the near-anaerobic zones III and IV of pea nodules. Quantification of fixNOQP expression in nodules showed this was driven primarily by FnrN, with minimal direct hFixL-FxkR-FixK induction. Thus, FnrN is key for full symbiotic expression of fixNOQP. Without FnrN, nitrogen fixation was reduced by 85% in Rlv3841, while eliminating hFixL only reduced fixation by 25%. The hFixL-FxkR-FixK pathway effectively primes the O2 response by increasing fnrN expression in early differentiation (zones I-II). In zone III of mature nodules, near-anaerobic conditions activate FnrN, which induces fixNOQP transcription to the level required for wild-type nitrogen fixation activity. Modelling and transcriptional analysis indicates that the different O2 sensitivities of hFixL and FnrN lead to a nuanced spatiotemporal pattern of gene regulation in different nodule zones in response to changing O2 concentration. Multi-sensor O2 regulation is prevalent in rhizobia, suggesting the fine-tuned control this enables is common and maximizes the effectiveness of the symbioses., Author summary Rhizobia are soil bacteria that form a symbiosis with legume plants. In exchange for shelter from the plant, rhizobia provide nitrogen fertilizer, produced by nitrogen fixation. Fixation is catalysed by the nitrogenase enzyme, which is inactivated by oxygen. To prevent this, plants house rhizobia in root nodules, which create a low oxygen environment. However, rhizobia need oxygen, and must adapt to survive the low oxygen concentration in the nodule. Key to this is regulating their genes based on oxygen concentration. We studied one Rhizobium species which uses three different protein sensors of oxygen, each turning on at a different oxygen concentration. As the bacteria get deeper inside the plant nodule and the oxygen concentration drops, each sensor switches on in turn. Our results also show that the first sensor to turn on, hFixL, primes the second sensor, FnrN. This prepares the rhizobia for the core region of the nodule where oxygen concentration is lowest and most nitrogen fixation takes place. If both sensors are removed, the bacteria cannot fix nitrogen. Many rhizobia have several oxygen sensing proteins, so using multiple sensors is likely a common strategy enabling rhizobia to adapt to low oxygen precisely and in stages during symbiosis.

Published

2021

18. A Bacterial Expression Vector Archive (BEVA) for Flexible Modular Assembly of Golden Gate-Compatible Vectors

Author

Barney A, Geddes, Marcela A, Mendoza-Suárez, and Philip S, Poole

Subjects

open source, broad-host range plasmid, Golden Gate, modular assembly, Methods, cloning vector, Microbiology, shuttle vector

Abstract

We present a Bacterial Expression Vector Archive (BEVA) for the modular assembly of bacterial vectors compatible with both traditional and Golden Gate cloning, utilizing the Type IIS restriction enzyme Esp3I, and have demonstrated its use for Golden Gate cloning in Escherichia coli. Ideal for synthetic biology and other applications, this modular system allows a rapid, low-cost assembly of new vectors tailored to specific tasks. Using the principles outlined here, new modules (e.g., origin of replication for plasmids in other bacteria) can easily be designed for specific applications. It is hoped that this vector construction system will be expanded by the scientific community over time by creation of novel modules through an open source approach. To demonstrate the potential of the system, three example vectors were constructed and tested. The Golden Gate level 1 vector pOGG024 (pBBR1-based broad-host range and medium copy number) was used for gene expression in laboratory-cultured Rhizobium leguminosarum. The Golden Gate level 1 vector pOGG026 (RK2-based broad-host range, lower copy number and stable in the absence of antibiotic selection) was used to demonstrate bacterial gene expression in nitrogen-fixing nodules on pea plant roots formed by R. leguminosarum. Finally, the level 2 cloning vector pOGG216 (RK2-based broad-host range, medium copy number) was used to construct a dual reporter plasmid expressing green and red fluorescent proteins.

Published

2018

19. A Bacterial Expression Vector Archive(BEVA) for flexible modular assembly of Golden Gate-compatible vectors

Author

Marcela Mendoza-Suárez, Barney A. Geddes, and Philip S. Poole

Subjects

Synthetic biology, Restriction enzyme, Plasmid, Expression vector, Golden Gate Cloning, Gene expression, Cloning vector, medicine, Computational biology, Biology, medicine.disease_cause, Rhizobium leguminosarum

Abstract

We present a Bacterial Expression Vector Archive (BEVA) for the modular assembly of bacterial vectors compatible with both traditional and Golden Gate cloning, utilizing the Type IIS restriction enzyme Esp3I. Ideal for synthetic biology and other applications, this modular system allows a rapid, low-cost assembly of new vectors tailored to specific tasks. To demonstrate the potential of the system three example vectors were constructed and tested. Golden Gate level 1 vectors; pOGG024, with a broad-host range and high copy number was used for gene expression in laboratory-culturedRhizobium leguminosarum, and pOGG026, with a broad-host range a lower copy number and excellent stability, even in the absence of antibiotic selection. The application of pOGG026 is demonstrated in environmental samples by bacterial gene expression in nitrogen-fixing nodules on pea plants roots formed byR. leguminosarum. Finally, the level 2 cloning vector pOGG216 is a broad-host range, medium copy number, for which we demonstrate an application by constructing a dual reporter plasmid expressing green and red fluorescent proteins.IMPORTANCEModular assembly is powerful as it allows easy combining of different components from a library of parts. In designing a modular vector assembly system, the key constituent parts (and modules) are; an origin of plasmid replication, antibiotic resistance marker(s), cloning site(s), together with additional accessory modules as required. In an ideal vector, the size of each module would be minimized, and this we have addressed. We have designed such a vector assembly system by utilizing the Type IIS restriction enzyme Esp3I and have demonstrated its use for Golden Gate cloning inEscherichia coli. An important attribute of this modular vector assembly is that using the principles outlined here, new modules for specific applications, e.g. origin of replication for plasmids in other bacteria, can easily be designed. It is hoped that this vector construction system will be expanded by the scientific community over time by creation of novel modules through an open source approach.

Published

2018

20. Succinoglycan Production Contributes to Acidic pH Tolerance in Sinorhizobium meliloti Rm1021

Author

Barney A. Geddes, Ivan J. Oresnik, and Justin P. Hawkins

Subjects

0301 basic medicine, Physiology, 030106 microbiology, Polymerization, 03 medical and health sciences, Stress, Physiological, Botany, Symbiosis, Sinorhizobium meliloti, biology, Polysaccharides, Bacterial, food and beverages, General Medicine, Gene Expression Regulation, Bacterial, Hydrogen-Ion Concentration, biology.organism_classification, Adaptation, Physiological, Molecular Weight, Biochemistry, Genes, Bacterial, Mutation, Root Nodules, Plant, Agronomy and Crop Science, Acids, Glycogen

Abstract

In this work, the hypothesis that exopolysaccharide plays a role in the survival of Sinorhizobium meliloti at low pH levels is addressed. When S. meliloti was grown at pH 5.75, synthesis of succinoglycan increased, whereas synthesis of galactoglucan decreased. Succinoglycan that was isolated from cultures grown at low pH had a lower degree of polymerization relative to that which was isolated from cultures grown at neutral pH, suggesting that low–molecular weight (LMW) succinoglycan might play a role in adaptation to low pH. Mutants unable to produce succinoglycan or only able to produce high–molecular weight polysaccharide were found to be sensitive to low pH. However, strains unable to produce LMW polysaccharide were 10-fold more sensitive. In response to low pH, transcription of genes encoding proteins for succinoglycan, glycogen, and cyclic β(1-2) glucans biosynthesis increased, while those encoding proteins necessary for the biosynthesis of galactoglucan decreased. While changes in pH did not affect the production of glycogen or cyclic β(1-2) glucan, it was found that the inability to produce cyclic β(1-2) glucan did contribute to pH tolerance in the absence of succinoglycan. Finally, in addition to being sensitive to low pH, a strain carrying mutations in exoK and exsH, which encode the glycanases responsible for the cleavage of succinoglycan to LMW succinoglycan, exhibited a delay in nodulation and was uncompetitive for nodule occupancy. Taken together, the data suggest that the role for LMW succinoglycan in nodule development may be to enhance survival in the colonized curled root hair.

Published

2017

21. Physiology, genetics, and biochemistry of carbon metabolism in the alphaproteobacteriumSinorhizobium meliloti

Author

Barney A. Geddes and Ivan J. Oresnik

Subjects

Immunology, Genomics, Applied Microbiology and Biotechnology, Microbiology, Genome, Bacterial Proteins, Genetics, Glycosides, Molecular Biology, Gene, Organism, Sinorhizobium meliloti, biology, Monosaccharides, Alphaproteobacteria, food and beverages, General Medicine, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Carbon, Biochemistry, Genes, Bacterial, Rhizosphere, Carbohydrate Metabolism, bacteria, Rhizobium, Metabolic Networks and Pathways, Bacteria

Abstract

A large proportion of genes within a genome encode proteins that play a role in metabolism. The Alphaproteobacteria are a ubiquitous group of bacteria that play a major role in a number of environments. For well over 50 years, carbon metabolism in Rhizobium has been studied at biochemical and genetic levels. Here, we review the pre- and post-genomics literature of the metabolism of the alphaproteobacterium Sinorhizobium meliloti. This review provides an overview of carbon metabolism that is useful to readers interested in this organism and to those working on other organisms that do not follow other model system paradigms.

Published

2014

22. Use of plant colonizing bacteria as chassis for transfer of N2-fixation to cereals

Author

Amaya M. Garcia Costas, John W. Peters, Min-Hyung Ryu, Christopher A. Voigt, Philip S. Poole, Florence Mus, and Barney A. Geddes

Subjects

biology, business.industry, Microorganism, fungi, digestive, oral, and skin physiology, Biomedical Engineering, Nitrogenase, food and beverages, Bioengineering, biology.organism_classification, Biotechnology, N2 Fixation, Synthetic biology, Agronomy, Nitrogen fixation, Engineering tool, business, Nitrogen cycle, Bacteria

Abstract

Engineering cereal crops that are self-supported by nitrogen fixation has been a dream since the 1970s when nitrogenase was transferred from Klebsiella pneumoniae to Escherichia coli. A renewed interest in this area has generated several new approaches with the common aim of transferring nitrogen fixation to cereal crops. Advances in synthetic biology have afforded the tools to rationally engineer microorganisms with traits of interest. Nitrogenase biosynthesis has been a recent target for the application of new synthetic engineering tools. Early successes in this area suggest that the transfer of nitrogenase and other supporting traits to microorganisms that already closely associate with cereal crops is a logical approach to deliver nitrogen to cereal crops.

Published

2016

23. Role of O2 in the Growth of Rhizobium leguminosarum bv. viciae 3841 on Glucose and Succinate

Author

Christopher K. Yost, Vinoy K. Ramachandran, Benjamin J. Perry, Barney A. Geddes, Rachel M. Wheatley, and Philip S. Poole

Subjects

0301 basic medicine, 030106 microbiology, Succinic Acid, Biology, medicine.disease_cause, Microbiology, Rhizobium leguminosarum, 03 medical and health sciences, Bacterial Proteins, medicine, Methylglyoxal pathway, Molecular Biology, chemistry.chemical_classification, Dose-Response Relationship, Drug, Metabolism, Gene Expression Regulation, Bacterial, biology.organism_classification, Culture Media, Citric acid cycle, Oxygen, Enzyme, Glucose, Biochemistry, Gluconeogenesis, chemistry, Flux (metabolism), Nucleic Acid Amplification Techniques, Bacteria, Research Article

Abstract

Insertion sequencing (INSeq) analysis of Rhizobium leguminosarum bv. viciae 3841 (Rlv3841) grown on glucose or succinate at both 21% and 1% O 2 was used to understand how O 2 concentration alters metabolism. Two transcriptional regulators were required for growth on glucose (pRL120207 [ eryD ] and RL0547 [ phoB ]), five were required on succinate (pRL100388, RL1641, RL1642, RL3427, and RL4524 [ ecfL ]), and three were required on 1% O 2 (pRL110072, RL0545 [ phoU ], and RL4042). A novel toxin-antitoxin system was identified that could be important for generation of new plasmidless rhizobial strains. Rlv3841 appears to use the methylglyoxal pathway alongside the Entner-Doudoroff (ED) pathway and tricarboxylic acid (TCA) cycle for optimal growth on glucose. Surprisingly, the ED pathway was required for growth on succinate, suggesting that sugars made by gluconeogenesis must undergo recycling. Altered amino acid metabolism was specifically needed for growth on glucose, including RL2082 ( gatB ) and pRL120419 ( opaA , encoding omega-amino acid:pyruvate transaminase). Growth on succinate specifically required enzymes of nucleobase synthesis, including ribose-phosphate pyrophosphokinase (RL3468 [ prs ]) and a cytosine deaminase (pRL90208 [ codA ]). Succinate growth was particularly dependent on cell surface factors, including the PrsD-PrsE type I secretion system and UDP-galactose production. Only RL2393 ( glnB , encoding nitrogen regulatory protein PII) was specifically essential for growth on succinate at 1% O 2 , conditions similar to those experienced by N 2 -fixing bacteroids. Glutamate synthesis is constitutively activated in glnB mutants, suggesting that consumption of 2-ketoglutarate may increase flux through the TCA cycle, leading to excess reductant that cannot be reoxidized at 1% O 2 and cell death. IMPORTANCE Rhizobium leguminosarum , a soil bacterium that forms N 2 -fixing symbioses with several agriculturally important leguminous plants (including pea, vetch, and lentil), has been widely utilized as a model to study Rhizobium -legume symbioses. Insertion sequencing (INSeq) has been used to identify factors needed for its growth on different carbon sources and O 2 levels. Identification of these factors is fundamental to a better understanding of the cell physiology and core metabolism of this bacterium, which adapts to a variety of different carbon sources and O 2 tensions during growth in soil and N 2 fixation in symbiosis with legumes.

Published

2016

24. The Mechanism of Symbiotic Nitrogen Fixation

Author

Barney A. Geddes and Ivan J. Oresnik

Subjects

0301 basic medicine, education.field_of_study, biology, business.industry, Microorganism, 030106 microbiology, Population, Fossil fuel, chemistry.chemical_element, Nitrogenase, biology.organism_classification, Nitrogen, 03 medical and health sciences, 030104 developmental biology, chemistry, Environmental chemistry, Nitrogen fixation, Diazotroph, education, business, Bacteria

Abstract

Nitrogen is a building block of life. Molecular nitrogen is the relatively inert atmospheric form of this element, and it must be fixed into more biologically accessible forms in order to be used for organic processes. In total, approximately 380 teragrams of nitrogen per year are fixed by atmospheric, biological, and industrial nitrogen fixation processes. Whereas the Haber–Bosch process currently accounts for the majority of the reduced nitrogen that is used agriculturally with the world’s increasing dependence on agriculture to feed its population, the use of reduced nitrogen derived from energy provided by fossil fuels in not likely to be sustainable. Biological nitrogen fixation is mediated by diazotrophic microorganisms that are capable of fixing atmospheric nitrogen using the enzyme nitrogenase. Much of this is carried out as a symbiotic association between plants and some diazotrophic bacteria. The study of symbiotic nitrogen fixation is an area of research that spans both microbiology and plant biology. Since this is an area that has had a great deal of renewed interest, this chapter reviews what is currently understood about the process of symbiotic nitrogen fixation at the molecular and physiological level from both the plant and bacterial perspective.

Published

2016

25. Inability To Catabolize Galactose Leads to Increased Ability To Compete for Nodule Occupancy in Sinorhizobium meliloti

Author

Ivan J. Oresnik and Barney A. Geddes

Subjects

Arabinose, Mutant, Locus (genetics), Real-Time Polymerase Chain Reaction, Microbiology, chemistry.chemical_compound, Molecular Biology, Gene, Sinorhizobium meliloti, biology, Gene Expression Profiling, Genetic Complementation Test, Galactose, Articles, biology.organism_classification, Phosphotransferases (Alcohol Group Acceptor), chemistry, Biochemistry, Dehydratase, Cosmid, Root Nodules, Plant, Gene Deletion, Metabolic Networks and Pathways, Medicago sativa

Abstract

A mutant unable to utilize galactose was isolated inSinorhizobium melilotistrain Rm1021. The mutation was found to be in a gene annotateddgoK1, a putative 2-keto-3-deoxygalactonokinase. The genetic region was isolated on a complementing cosmid and subsequently characterized. Based on genetic and bioinformatic evidence, the locus encodes all five enzymes (galD,dgoK,dgoA,SMc00883, andilvD1) involved in the De Ley-Doudoroff pathway for galactose catabolism. Although all five genes are present, genetic analysis suggests that the galactonase (SMc00883) and the dehydratase (ilvD1) are dispensable with respect to the ability to catabolize galactose. In addition, we show that the transport of galactose is partially facilitated by the arabinose transporter (AraABC) and that both glucose and galactose compete with arabinose for transport. Quantitative reverse transcription-PCR (qRT-PCR) data show that in adgoKbackground, the galactose locus is constitutively expressed, and the induction of thearalocus seems to be enhanced. Assays of competition for nodule occupancy show that the inability to catabolize galactose is correlated with an increased ability to compete for nodule occupancy.

Published

2012

26. Use of plant colonizing bacteria as chassis for transfer of N₂-fixation to cereals

Author

Barney A, Geddes, Min-Hyung, Ryu, Florence, Mus, Amaya, Garcia Costas, John W, Peters, Christopher A, Voigt, and Philip, Poole

Subjects

Crops, Agricultural, Genetic Loci, Nitrogen, Nitrogen Fixation, Synthetic Biology, Edible Grain

Abstract

Engineering cereal crops that are self-supported by nitrogen fixation has been a dream since the 1970s when nitrogenase was transferred from Klebsiella pneumoniae to Escherichia coli. A renewed interest in this area has generated several new approaches with the common aim of transferring nitrogen fixation to cereal crops. Advances in synthetic biology have afforded the tools to rationally engineer microorganisms with traits of interest. Nitrogenase biosynthesis has been a recent target for the application of new synthetic engineering tools. Early successes in this area suggest that the transfer of nitrogenase and other supporting traits to microorganisms that already closely associate with cereal crops is a logical approach to deliver nitrogen to cereal crops.

Published

2015

27. Genetic characterization of a complex locus necessary for the transport and catabolism of erythritol, adonitol and L-arabitol in Sinorhizobium meliloti

Author

Barney A. Geddes and Ivan J. Oresnik

Subjects

Genetics, Sinorhizobium meliloti, Catabolism, Genetic Complementation Test, Locus (genetics), ATP-binding cassette transporter, Biological Transport, Erythritol, Biology, Ribitol, biology.organism_classification, Microbiology, Complementation, chemistry.chemical_compound, Sugar Alcohols, Biochemistry, chemistry, Bacterial Proteins, Gene

Abstract

The Sinorhizobium meliloti locus necessary for the utilization of erythritol as a sole carbon source, contains 17 genes, including genes that encode an ABC transporter necessary for the transport of erythritol, as well as the genes encoding EryA, EryB, EryC, TpiB and the regulators EryD and EryR (SMc01615). Construction of defined deletions and complementation experiments show that the other genes at this locus encode products that are necessary for the catabolism of adonitol (ribitol) and l-arabitol, but not d-arabitol. These analyses show that aside from one gene that is specific for the catabolism of l-arabitol (SMc01619, lalA), the rest of the catabolic genes are necessary for both polyols (SMc01617, rbtC; SMc01618, rbtB; SMc01622, rbtA). Genetic and biochemical data show that in addition to utilizing erythritol as a substrate, EryA is also capable of utilizing adonitol and l-arabitol. Similarly, transport experiments using labelled erythritol show that adonitol, l-arabitol and erythritol share a common transporter (MptABCDE). Quantitative RT-PCR experiments show that transcripts containing genes necessary for adonitol and l-arabitol utilization are induced by these sugars in an eryA-dependent manner.

Published

2012

28. Glycerol utilization by Rhizobium leguminosarum requires an ABC transporter and affects competition for nodulation

Author

Ivan J. Oresnik, Michael F. Hynes, Barney A. Geddes, Cynthia B. Yip, and Hao Ding

Subjects

DNA, Bacterial, Glycerol, Agrobacterium, Operon, ATP-binding cassette transporter, Biology, medicine.disease_cause, Microbiology, Plant Root Nodulation, Rhizobium leguminosarum, chemistry.chemical_compound, Plasmid, Bacterial Proteins, Rhizobium etli, Glycerol Kinase, medicine, Regulator gene, Peas, food and beverages, Computational Biology, Gene Expression Regulation, Bacterial, Sequence Analysis, DNA, biology.organism_classification, Repressor Proteins, Mutagenesis, Insertional, Biochemistry, chemistry, Genes, Bacterial, Glycerophosphates, bacteria, ATP-Binding Cassette Transporters, Plasmids

Abstract

Plasmid curing has shown that the ability to use glycerol as a carbon source is plasmid-encoded in Rhizobium leguminosarum. We isolated the locus responsible for glycerol utilization from plasmid pRleVF39c in R. leguminosarum bv. viciae VF39. This region was analyzed by DNA sequencing and mutagenesis. The locus encompasses a gene encoding GlpR (a DeoR regulator), genes encoding an ABC transporter, and genes glpK and glpD, encoding a kinase and dehydrogenase, respectively. All the genes except the regulatory gene glpR were organized into a single operon, and were required for growth on glycerol. The glp operon was strongly induced by both glycerol and glycerol 3-phosphate, as well as by pea seed exudate. GlpR repressed the operon in the absence of inducer. Mutation of genes encoding the ABC transporter abolished all transport of glycerol in transport assays using radiolabelled glycerol. This confirms that, unlike in other organisms such as Escherichia coli and Pseudomonas aeruginosa, which use facilitated diffusion, glycerol uptake occurs by an active process in R. leguminosarum. Since the glp locus is highly conserved in all sequenced R. leguminosarum and Rhizobium etli strains, as well as in Sinorhizobium spp. and Agrobacterium spp. and other alphaproteobacteria, this process for glycerol uptake is probably widespread. Mutants unable to use glycerol were deficient in competitiveness for nodulation of peas compared with the wild-type, suggesting that glycerol catabolism confers an advantage upon the bacterium in the rhizosphere or in the infection thread.

Published

2012