Abstract: Disclosed herein are engineered rhizobia having nif clusters that enable the fixation of nitrogen under free-living conditions, as well as ammonium and oxygen tolerant nitrogen fixation under free-living conditions. Also provided are methods for producing nitrogen for consumption by a cereal crop using these engineered rhizobia.

Abstract: Methods and systems are provided for generating and utilizing a genetically engineered bacterium comprising a modification in a nifA gene or homolog thereof that can result in a bacterium with modified regulation of nitrogen fixation or assimilation activity. Genetically engineered bacteria with modified nitrogen fixation or assimilation activity are also provided. The genetically engineered bacterium can fix nitrogen in the presence of nitrogen (e.g., ammonium), and/or oxygen.

Abstract: The present disclosure provides engineered gram-positive microbes that are able to fix atmospheric nitrogen and deliver such to plants in a targeted, efficient, and environmentally sustainable manner. The utilization of the taught microbial products will enable farmers to realize more productive and predictable crop yields without the nutrient degradation, leaching, or toxic runoff associated with traditional synthetically derived nitrogen fertilizer.

Abstract: The invention relates to methods for promoting fixed nitrogen from atmospheric nitrogen, and related products. Endophytic bacteria having an exogenous nif cluster promote fixed nitrogen for cereal plants.

Abstract: The invention relates to methods for promoting fixed nitrogen from atmospheric nitrogen, and related products. Endophytic bacteria having an exogenous nif cluster promote fixed nitrogen for cereal plants.

Abstract: The present disclosure provides high-throughput methods for rapidly mutagenizing, screening, and targeting candidate microbes that are capable of fixing atmospheric nitrogen in the presence of exogenous nitrogen. The methods utilize a microbial biosensor capable of detecting the presence/absence of ammonium and/or glutamine in a composition and signaling with a fluorescent reporter. The present disclosure further utilizes rapid visual detection assays capable of processing thousands of candidate microbes. The disclosed methods and biosensor can be used to identify mutant bacteria with improved nitrogen fixing capabilities. Mutant bacteria with improved nitrogen fixing capabilities are also disclosed, as well as methods of utilizing these novel bacteria to provide fixed nitrogen to a plant.

Abstract: Disclosed herein are engineered rhizobia having nif clusters that enable the fixation of nitrogen under free-living conditions, as well as ammonium and oxygen tolerant nitrogen fixation under free-living conditions. Also provided are methods for producing nitrogen for consumption by a cereal crop using these engineered rhizobia.

Abstract: Disclosed herein are engineered rhizobia having nif clusters that enable the fixation of nitrogen under free-living conditions, as well as ammonium and oxygen tolerant nitrogen fixation under free-living conditions. Also provided are methods for producing nitrogen for consumption by a cereal crop using these engineered rhizobia.

Abstract: The invention relates to methods for promoting fixed nitrogen from atmospheric nitrogen, and related products. Endophytic bacteria having an exogenous nif cluster promote fixed nitrogen for cereal plants.

Abstract: Methods and constructs are provided for controlling processes in live animals, plants or microbes via genetically engineered near-infrared light-activated or light-inactivated proteins including chimeras including the photosensory modules of bacteriohytochromes and output modules that possess enzymatic activity and/or ability to bind to DNA, RNA, protein, or small molecules. DNA encoding these proteins are introduced as genes into live animals, plants or microbes, where their activities can be turned on by near-infrared light, controlled by the intensity of light, and turned off by near-infrared light of a different wavelength than the activating light. These proteins can regulate diverse cellular processes with high spatial and temporal precision, in a nontoxic manner, often using external light sources.

Abstract: Methods and constructs are provided for controlling processes in live animals, plants or microbes via genetically engineered near-infrared light-activated or light-inactivated proteins including chimeras including the photosensory modules of bacteriohytochromes and output modules that possess enzymatic activity and/or ability to bind to DNA, RNA, protein, or small molecules. DNA encoding these proteins are introduced as genes into live animals, plants or microbes, where their activities can be turned on by near-infrared light, controlled by the intensity of light, and turned off by near-infrared light of a different wavelength than the activating light. These proteins can regulate diverse cellular processes with high spatial and temporal precision, in a nontoxic manner, often using external light sources.

Abstract: Methods and constructs are provided for controlling processes in live animals, plants or microbes via genetically engineered near-infrared light-activated or light-inactivated proteins including chimeras including the photosensory modules of bacteriohytochromes and output modules that possess enzymatic activity and/or ability to bind to DNA, RNA, protein, or small molecules. DNA encoding these proteins are introduced as genes into live animals, plants or microbes, where their activities can be turned on by near-infrared light, controlled by the intensity of light, and turned off by near-infrared light of a different wavelength than the activating light. These proteins can regulate diverse cellular processes with high spatial and temporal precision, in a nontoxic manner, often using external light sources.

Abstract: Methods and constructs are provided for controlling processes in live animals, plants or microbes via genetically engineered near-infrared light-activated or light-inactivated proteins including chimeras including the photosensory modules of bacteriophytochromes and output modules that possess enzymatic activity and/or ability to bind to DMA, RNA, protein, or small molecules. DNA encoding these proteins are introduced as genes into live animals, plants or microbes, where their activities can be turned on by near-infrared light, controlled by the intensity of light, and turned off by near-infrared light of a different wavelength than the activating light. These proteins can regulate diverse cellular processes with high spatial and temporal precision, in a nontoxic manner, often using external light sources.

Abstract: Methods and constructs are provided for controlling processes in live animals, plants or microbes via genetically engineered near-infrared light-activated or light-inactivated proteins including chimeras including the photosensory modules of bacteriohytochromes and output modules that possess enzymatic activity and/or ability to bind to DMA, RNA, protein, or small molecules. DNA encoding these proteins are introduced as genes into live animals, plants or microbes, where their activities can be turned on by near-infrared light, controlled by the intensity of light, and turned off by near-infrared light of a different wavelength than the activating light. These proteins can regulate diverse cellular processes with high spatial and temporal precision, in a nontoxic manner, often using external light sources.