Arabidopsis Growth-Promotion and Root Architecture Responses to the Beneficial Rhizobacterium Strain STM196 Are Independent of the Nitrate Assimilatory Pathway.

STM196, a plant growth-promoting rhizobacterium isolated from roots of oilseed rape, stimulates growth. We have previously shown that the and genes are required for this growth promotion response. Since these genes are members of the family of nitrate transporters, the nitrogen assimilatory pathway could be involved in growth promotion by STM196.

Ethanol, at physiological concentrations, affects ethylene sensing in tomato germinating seeds and seedlings.

Ethanol is known to accumulate in various plant organs under various environmental conditions. However, there are very scarce data about ethanol sensing by plants. We observed that ethanol accumulates up to 3.

Natural allelic variation of the AZI1 gene controls root growth under zinc-limiting condition.

Zinc is an essential micronutrient for all living organisms and is involved in a plethora of processes including growth and development, and immunity. However, it is unknown if there is a common genetic and molecular basis underlying multiple facets of zinc function. Here we used natural variation in Arabidopsis thaliana to study the role of zinc in regulating growth.

Dynamics of Ethylene Production in Response to Compatible Nod Factor.

Establishment of symbiotic nitrogen-fixation in legumes is regulated by the plant hormone ethylene, but it has remained unclear whether and how its biosynthesis is regulated by the symbiotic pathway. We established a sensitive ethylene detection system for and found that ethylene production increased as early as 6 hours after inoculation with This ethylene response was dependent on Nod factor production by compatible rhizobia. Analyses of nodulation mutants showed that perception of Nod factor was required for ethylene emission, while downstream transcription factors including CYCLOPS, NIN, and ERN1 were not required for this response.

Differential Contribution of Plant-Beneficial Functions from Pseudomonas kilonensis F113 to Root System Architecture Alterations in Arabidopsis thaliana and Zea mays.

Fluorescent pseudomonads are playing key roles in plant-bacteria symbiotic interactions due to the multiple plant-beneficial functions (PBFs) they are harboring. The relative contributions of PBFs to plant-stimulatory effects of the well-known plant growth-promoting rhizobacteria Pseudomonas kilonensis F113 (formerly P. fluorescens F113) were investigated using a genetic approach.