Project description:bacteria microbial diversity in paddy soils

Project description:paddy soils microbial diversity

Project description:Aluminum (Al)–tolerant phosphobacteria can improve plant performance in acidic soils by increasing Al complexing and phosphorus (P) availability. However, it is almost unknown how Al stress along with P deficiency affect the bacterial biochemistry and physiology. Because high Al levels and low P availability often occur simultaneously in acidic soils, we have evaluated the single and mutual effects of a high Al stress and P deficiency on the proteome of the Al‒tolerant phosphobacteria strain Enterobacter sp. RJAL6. This strain was previously isolated from the rhizosphere of Lollium perenne plants grown in acidic soil. The strain was cultivated in mineral media modified to contain i) high P (1.4 mM) in the absence of Al, ii) high P (1.4 mM) and high Al (10 mM), iii) low P (0.05 mM) in the absence of Al, and iv) low P (0.05 mM) and high Al (10 mM). Total proteins from bacterial cells were extracted at the end of the exponential phase of growth and subjected to high–throughput proteomics analysis. The results showed that P deficiency was mainly associated with an upregulation of the P metabolism proteins subject to Pho regulon control, including phosphatases and transporters involved in the uptake of organophosphorus compounds such as phosphomonoesters, phosphonates and glycerol–3–phosphate. Aluminum exposure primarily decreased the expression of iron (Fe)–sulfur and haem-containing proteins with a concomitant upregulation of Fe acquisition and metabolism proteins, including siderophore precursors and receptors of Fe–chelator complexes. Here, we demonstrated the preponderant role that Al plays in the adjustment of Fe homeostasis, and consequently in the central metabolism of the bacteria. This is the first report of a proteomic study of the interaction between high Al and P deficiency in acidic soil–adapted bacteria. This knowledge is crucial for developing bioinoculants for crops affected by both Al toxicity and P deficiency.

Project description:Aluminum (Al)–tolerant phosphobacteria can improve plant performance in acidic soils by increasing Al complexing and phosphorus (P) availability. However, it is almost unknown how Al stress along with P deficiency affect the bacterial biochemistry and physiology. Because high Al levels and low P availability often occur simultaneously in acidic soils, we have evaluated the single and mutual effects of a high Al stress and P deficiency on the proteome of the Al‒tolerant phosphobacteria strain Enterobacter sp. 198. This strain was previously isolated from the rhizosphere of Lollium perenne plants grown in acidic soil. The strain was cultivated in mineral media modified to contain i) high P (1.4 mM) in the absence of Al, ii) high P (1.4 mM) and high Al (10 mM), iii) low P (0.05 mM) in the absence of Al, and iv) low P (0.05 mM) and high Al (10 mM). Total proteins from bacterial cells were extracted at the end of the exponential phase of growth and subjected to high–throughput proteomics analysis. The results showed that P deficiency was mainly associated with an upregulation of the P metabolism proteins subject to Pho regulon control, including phosphatases and transporters involved in the uptake of organophosphorus compounds such as phosphomonoesters, phosphonates and glycerol–3–phosphate. Aluminum exposure primarily decreased the expression of iron (Fe)–sulfur and haem-containing proteins with a concomitant upregulation of Fe acquisition and metabolism proteins, including siderophore precursors and receptors of Fe–chelator complexes. Here, we demonstrated the preponderant role that Al plays in the adjustment of Fe homeostasis, and consequently in the central metabolism of the bacteria. This is the first report of a proteomic study of the interaction between high Al and P deficiency in acidic soil–adapted bacteria. This knowledge is crucial for developing bioinoculants for crops affected by both Al toxicity and P deficiency.

Project description:Aluminum (Al)–tolerant phosphobacteria can improve plant performance in acidic soils by increasing Al complexing and phosphorus (P) availability. However, it is almost unknown how Al stress along with P deficiency affect the bacterial biochemistry and physiology. Because high Al levels and low P availability often occur simultaneously in acidic soils, we have evaluated the single and mutual effects of a high Al stress and P deficiency on the proteome of the Al‒tolerant phosphobacteria strain Klebsiella sp. RCJ4. This strain was previously isolated from the rhizosphere of Lollium perenne plants grown in acidic soil. The strain was cultivated in mineral media modified to contain i) high P (1.4 mM) in the absence of Al, ii) high P (1.4 mM) and high Al (10 mM), iii) low P (0.05 mM) in the absence of Al, and iv) low P (0.05 mM) and high Al (10 mM). Total proteins from bacterial cells were extracted at the end of the exponential phase of growth and subjected to high–throughput proteomics analysis. The results showed that P deficiency was mainly associated with an upregulation of the P metabolism proteins subject to Pho regulon control, including phosphatases and transporters involved in the uptake of organophosphorus compounds such as phosphomonoesters, phosphonates and glycerol–3–phosphate. Aluminum exposure primarily decreased the expression of iron (Fe)–sulfur and haem-containing proteins with a concomitant upregulation of Fe acquisition and metabolism proteins, including siderophore precursors and receptors of Fe–chelator complexes. Here, we demonstrated the preponderant role that Al plays in the adjustment of Fe homeostasis, and consequently in the central metabolism of the bacteria. This is the first report of a proteomic study of the interaction between high Al and P deficiency in acidic soil–adapted bacteria. This knowledge is crucial for developing bioinoculants for crops affected by both Al toxicity and P deficiency.

Project description:Carbon sequestering bacteria in paddy soils

Project description:Iron (Fe) is an essential plant micronutrient, and its deficiency limits plant growth and development on alkaline soils. Under Fe deficiency, plant responses include upregulation of genes involved in Fe uptake from the soil. However, little is known about shoot responses to Fe deficiency. Using microarrays to probe gene expression in Kas-1 and Tsu-1 ecotypes of Arabidopsis thaliana revealed conserved rosette gene expression responses to Fe deficiency. Fe regulated genes included known metal homeostasis-related genes, and a number of genes of unknown function.

Project description:Bacteria in paddy soil under P and Fe addition

Project description:Bt toxins concentration and bacteria diversity

Project description:Iron deficiency is a yield-limiting factor and a worldwide problem for crop production in many agricultural regions, particularly in aerobic and calcareous soils. Graminaceous species, like maize, improve Fe acquisition through the release of phytosiderophores (PS) into the rhizosphere and the following uptake of Fe(III)-PS complexes through specific transporters. Transcriptional profile obtained by roots 12-d-old maize plants under Fe starvation for 1 week (Fe-deficient; 19-d-old plants) were compared with the transcriptional profile obtained by roots of 12-d-old maize plants grown in a nutrient solution containing 100 μM Fe-EDTA for 1 week (Fe-sufficient; 19-d-old plants).