Abstract: Microbial consortia exert great influence over the physiology of humans, animals, plants, and ecosystems. However, difficulty in controlling their composition and population dynamics have limited their application in medicine, agriculture, biotechnology, and the environment. The approach disclosed herein provides an effective method to dynamically control population compositions in microbial consortia, which we demonstrate in the context of co-culture fermentations for chemical production. Co-culture fermentations can improve chemical production from complex biosynthetic pathways over monocultures by distributing enzymes across multiple strains, thereby reducing metabolic burden, overcoming endogenous regulatory mechanisms, or exploiting natural traits of different microbial species. However, stabilizing and optimizing microbial sub-populations for maximal chemical production remains a major obstacle in the field.

Abstract: Provided herein are compositions and methods to improve treatment of chronic infections, and reduce, delay, or inhibit formation of biofilms, using specific combinations of aminoglycoside antibiotics and high, localized concentrations of one or more PMF stimulating compounds. These novel methods are easily adapted to clinical settings as toxicity and efficacy of the antibiotics and metabolites used have already been studied in vivo, and as dosing for both the antibiotics and metabolites are known. These approaches and therapeutic methods are also useful with non-metabolic chemicals that induce proton-motive force in bacteria.

Abstract: Provided herein are compositions and methods to improve treatment of chronic infections, and reduce, delay, or inhibit formation of biofilms, using specific combinations of aminoglycoside antibiotics and high, localized concentrations of one or more PMF stimulating compounds. These novel methods are easily adapted to clinical settings as toxicity and efficacy of the antibiotics and metabolites used have already been studied in vivo, and as dosing for both the antibiotics and metabolites are known. These approaches and therapeutic methods are also useful with non-metabolic chemicals that induce proton-motive force in bacteria.

Abstract: Provided herein are compositions and methods to improve treatment of chronic infections, and reduce, delay, or inhibit formation of biofilms, using specific combinations of aminoglycoside antibiotics and high, localized concentrations of one or more PMF stimulating compounds. These novel methods are easily adapted to clinical settings as toxicity and efficacy of the antibiotics and metabolites used have already been studied in vivo, and as dosing for both the antibiotics and metabolites are known. These approaches and therapeutic methods are also useful with non-metabolic chemicals that induce proton-motive force in bacteria.

Abstract: Provided herein are compositions and methods to improve treatment of chronic infections, and reduce, delay, or inhibit formation of biofilms, using specific combinations of aminoglycoside antibiotics and high, localized concentrations of one or more PMF stimulating compounds. These novel methods are easily adapted to clinical settings as toxicity and efficacy of the antibiotics and metabolites used have already been studied in vivo, and as dosing for both the antibiotics and metabolites are known. These approaches and therapeutic methods are also useful with non-metabolic chemicals that induce proton-motive force in bacteria.

Abstract: Provided herein are compositions and methods to improve treatment of chronic infections, and reduce, delay, or inhibit formation of biofilms, using specific combinations of aminoglycoside antibiotics and high, localized concentrations of one or more PMF stimulating compounds. These novel methods are easily adapted to clinical settings as toxicity and efficacy of the antibiotics and metabolites used have already been studied in vivo, and as dosing for both the antibiotics and metabolites are known. These approaches and therapeutic methods are also useful with non-metabolic chemicals that induce proton-motive force in bacteria.

Abstract: Provided herein are compositions and methods to improve treatment of chronic infections, and reduce, delay, or inhibit formation of biofilms, using specific combinations of aminoglycoside antibiotics and high, localized concentrations of one or more PMF stimulating compounds. These novel methods are easily adapted to clinical settings as toxicity and efficacy of the antibiotics and metabolites used have already been studied in vivo, and as dosing for both the antibiotics and metabolites are known. These approaches and therapeutic methods are also useful with non-metabolic chemicals that induce proton-motive force in bacteria.

Abstract: Provided herein are compositions and methods comprising ROS target modulators that increase ROS flux and endogenus ROS production, thereby potentiating oxidative attack by antibiotics and biocides.

Abstract: Provided are microorganisms that catalyze the synthesis of biofuels from a suitable substrate such as glucose. Also provided are methods of generating such organisms and methods of synthesizing biofuels using such organisms. Provided are microorganisms comprising non-naturally occurring metabolic pathway for the production of higher alcohols.