Methods and compositions for making bacteriocins are described in some embodiments herein. In some embodiments, pro-polypeptide comprising the bacteriocins in the desired ratios in cis, and separated by cleavage sited can be produced by a microbial cell comprising a nucleic acid encoding the pro-polypeptide. In some embodiments microfluidic devices and methods for making specified mixtures of antimicrobial peptides and/or bacteriocins are described.

The present invention relates to polymeric particles comprising a biodegradable polymer, and at least one microorganism in a total concentration of at least 10.sup.8 CFU/g dry weight that is stable for at least 35 weeks at 30 C. and optionally additional carriers and additives as well as to methods for producing polymeric particles and use thereof.

The present invention relates to polymeric particles comprising a biodegradable polymer, and at least one microorganism in a total concentration of at least 10.sup.8 CFU/g dry weight that is stable for at least 35 weeks at 30 C. and optionally additional carriers and additives as well as to methods for producing polymeric particles and use thereof.

The present disclosure relates to a plant disease control composition comprising a culture broth of Streptomyces sp. JCK-6141 strain or an extract of the culture broth of the strain, a preparation method therefor and a plant disease control method. The culture broth of the strain or an extract thereof exhibits extremely excellent antimicrobial activity when applied to a causative pathogen of plant disease and thus may be effectively used for plant disease control.

The present disclosure relates to a plant disease control composition comprising a culture broth of Streptomyces sp. JCK-6141 strain or an extract of the culture broth of the strain, a preparation method therefor and a plant disease control method. The culture broth of the strain or an extract thereof exhibits extremely excellent antimicrobial activity when applied to a causative pathogen of plant disease and thus may be effectively used for plant disease control.

The present disclosure includes genetically engineered, non-pathogenic Streptomyces bacterium with exogenous, non-native Thaxtomin A (ThxA) biosynthetic gene clusters conferring the genetically engineered, non-pathogenic Streptomyces bacterium with the ability to produce thaxtomin A. Also included are methods of providing thaxtomin producing capability in non-native Streptomyces bacterial strains, methods of producing thaxtomin compounds with the genetically engineered Streptomyces bacteria of the present disclosure, and methods of producing thaxtomin compounds and nitro-tryptophan analogs, and fluorinated thaxtomin compounds, analogs, and intermediates with the genetically engineered Streptomyces bacteria of the present disclosure.

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.

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.

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.

The present disclosure provides inoculant compositions and methods for enhancing the survival and/or stability of microbial cells/spores in an inoculant composition. In some embodiments, inoculant compositions of the present disclosure comprise microbial cells/spores in a carrier comprising one or more methylated plant oils.