Abstract: The present application relates to plant growth promoting microbes (PGPMs), compositions comprising these PGPMs and methods of using these PGPMs and/or compositions for enhancing plant health, plant growth and/or plant yield, and/or for preventing, inhibiting, or treating the development of plant pathogens or the development of phytopathogenic diseases. This application also provides non-naturally occurring plant varieties that are artificially infected with a PGPM descried herein, as well as seed, reproductive tissue, vegetative tissue, regenerative tissues, plant parts, or progeny thereof.

Abstract: The present application relates to plant growth promoting microbes (PGPMs), compositions comprising these PGPMs and methods of using these PGPMs and/or compositions for enhancing plant health, plant growth and/or plant yield, and/or for preventing, inhibiting, or treating the development of plant pathogens or the development of phytopathogenic diseases. This application also provides non-naturally occurring plant varieties that are artificially infected with a PGPM descried herein, as well as seed, reproductive tissue, vegetative tissue, regenerative tissues, plant parts, or progeny thereof.

Abstract: The present application relates to plant growth promoting microbes (PGPMs), compositions comprising these PGPMs and methods of using these PGPMs and/or compositions for enhancing plant health, plant growth and/or plant yield, and/or for preventing, inhibiting, or treating the development of plant pathogens or the development of phytopathogenic diseases. This application also provides non-naturally occurring plant varieties that are artificially infected with a PGPM descried herein, as well as seed, reproductive tissue, vegetative tissue, regenerative tissues, plant parts, or progeny thereof.

Abstract: The present application relates to plant growth promoting microbes (PGPMs), compositions comprising these PGPMs and methods of using these PGPMs and/or compositions for enhancing plant health, plant growth and/or plant yield, and/or for preventing, inhibiting, or treating the development of plant pathogens or the development of phytopathogenic diseases. This application also provides non-naturally occurring plant varieties that are artificially infected with a PGPM descried herein, as well as seed, reproductive tissue, vegetative tissue, regenerative tissues, plant parts, or progeny thereof.

Abstract: The present application relates to plant growth promoting microbes (PGPMs), compositions comprising these PGPMs and methods of using these PGPMs and/or compositions for enhancing plant health, plant growth and/or plant yield, and/or for preventing, inhibiting, or treating the development of plant pathogens or the development of phytopathogenic diseases. This application also provides non-naturally occurring plant varieties that are artificially infected with a PGPM descried herein, as well as seed, reproductive tissue, vegetative tissue, regenerative tissues, plant parts, or progeny thereof.

Abstract: The present application relates to plant growth promoting microbes (PGPMs), compositions comprising these PGPMs and methods of using these PGPMs and/or compositions for enhancing plant health, plant growth and/or plant yield, and/or for preventing, inhibiting, or treating the development of plant pathogens or the development of phytopathogenic diseases. This application also provides non-naturally occurring plant varieties that are artificially infected with a PGPM descried herein, as well as seed, reproductive tissue, vegetative tissue, regenerative tissues, plant parts, or progeny thereof.

Abstract: This invention generally relates to natural gas and methylotrophic energy generation, bio-generated fuels and microbiology. In alternative embodiments, the invention provides nutrient amendments and microbial compositions, e.g., consortia, that are both specifically optimized to stimulate methanogenesis, or for “methylotrophic” or other conversions. In alternative embodiments, the invention provides methods to develop nutrient amendments and microbial compositions that are both specifically optimized to stimulate methanogenesis in a given reservoir. The invention also provides methods for the evaluation of potentially damaging biomass formation and scale precipitation resulting from the addition of nutrient amendments. In other embodiments, the invention provides methods for simulating biogas in sub-surface conditions using a computational model.

Abstract: The present application relates to plant growth promoting microbes (PGPMs), compositions comprising these PGPMs and methods of using these PGPMs and/or compositions for enhancing plant health, plant growth and/or plant yield, and/or for preventing, inhibiting, or treating the development of plant pathogens or the development of phytopathogenic diseases. This application also provides non-naturally occurring plant varieties that are artificially infected with a PGPM descried herein, as well as seed, reproductive tissue, vegetative tissue, regenerative tissues, plant parts, or progeny thereof.

Abstract: In alternative embodiments, the invention provides products of manufacture and compositions, e.g., nucleic acid probes, for use as identifying agents or indicators to detect the presence of a hydrocarbon in a sample, e.g., in marine sediments, muds, sands and the like, or in a solution, e.g., an aqueous solution, such as a production water, fresh water, underground water or seawater. In alternative embodiments, the invention provides compositions, e.g., nucleic acid probes or primers or primer pairs, for use as sensors and/or identifying agents to detect the presence of a hydrocarbon in a sample (e.g., in fresh water, underground water or seawater, or a marine mud, sand or sediment), where the presence of the hydrocarbon indicates e.g., the presence of a subsurface oil, petroleum or gas accumulation or deposit. In alternative embodiments, the invention provides compositions and methods for use as tools for offshore oil exploration activities.

Abstract: Two genes which encode polypeptides that mediate post-prenylation processing steps in CAAX polypeptides such as Ras are provided. The two genes (AFC1 and RCE1) encode polypeptides that mediate the removal of the AAX tripeptide from the CAAX polypeptide following prenylation. The genes and encoded polypeptides provide assays for testing compounds for an effect on post-prenylation processing steps. A heat shock assay for assessing Ras activity is also provided.

Abstract: Two genes which encode polypeptides that mediate post-prenylation processing steps in CAAX polypeptides such as Ras are provided. The two genes (AFC1 and RCE1) encode polypeptides that mediate the removal of the AAX tripeptide from the CAAX polypeptide following prenylation. The genes and encoded polypeptides provide assays for testing compounds for an effect on post-prenylation processing steps. A heat shock assay for assessing Ras activity is also provided.

Abstract: Two genes which encode polypeptides that mediate post-prenylation processing steps in CAAX polypeptides such as Ras are provided. The two genes (AFC1 and RCE1) encode polypeptides that mediate the removal of the AAX tripeptide from the CAAX polypeptide following prenylation. The genes and encoded polypeptides provide assays for testing compounds for an effect on post-prenylation processing steps. A heat shock assay for assessing Ras activity is also provided.