The present disclosure provides compositions of microparticles and uses thereof for removing toxic or undesirable molecules from an environment, e.g. the blood of a subject. The microparticles can be liposomes. In one embodiment, the aqueous phase of the liposomes contains (i) a system of generating NAD.sup.+ from NADH, and (ii) one or more enzymes that are involved in one or more NAD.sup.+-dependent reactions that remove the toxic or undesirable molecules from the environment. In one embodiment, the liposomes contain NADH oxidase, alcohol dehydrogenase (ADH) and acetaldehyde dehydrogenase (ALDH) to remove ethanol from the blood of a subject.

Methods of treating wounds in a subject using one or both of a DNA methyltransferase 1 (DNMT1) inhibitor or a nicotinamide adenine dinucleotide phosphate oxidase 2 (NOX2) inhibitor, and compositions for use in these methods.

The present disclosure provides compositions of microparticles and uses thereof for removing toxic or undesirable molecules from an environment, e.g. the blood of a subject. The microparticles can be liposomes. In one embodiment, the aqueous phase of the liposomes contains (i) a system of generating NAD.sup.+ from NADH, and (ii) one or more enzymes that are involved in one or more NAD.sup.+-dependent reactions that remove the toxic or undesirable molecules from the environment. In one embodiment, the liposomes contain NADH oxidase, alcohol dehydrogenase (ADH) and acetaldehyde dehydrogenase (ALDH) to remove ethanol from the blood of a subject.

Provided herein are compositions and methods for the production of heterologous proteins in a cell including axonemes. The cells include a nucleic acid encoding a fusion protein expressed in the axoneme. The fusion protein includes an axonemal protein linked to a heterologous protein, and the fusion protein provides axonemal function to the cell.

The present disclosure features methods and compositions for treating amyotrophic lateral sclerosis (ALS). The disclosed methods comprise administering to a subject having or suspected of having ALS a hematopoietic stem progenitor cell expressing at least one neuroprotective agent. The compositions disclosed comprise hematopoietic stem progenitor cells transduced to express a neuroprotective agent.

Provided are various embodiments relating to compositions and methods for treating vascular disease, including core NOX1 promoters and variants thereof for regulating expression of transgenes in response to vascular pathology and allowing for increased transgene loading capacity. Also provided are variant FOXP polypeptides having a zinc finger and leucine zipper region of a different FOXP polypeptide. Further provided are vectors comprising the core NOX1 promoters and/or a coding sequence for variant FOXP polypeptides described herein and optionally coding sequence(s) for one or more additional therapeutic polypeptide(s), such as IL10, for treating inflammation-associated diseases, such as vascular disease. Also provided is a screening model for testing therapeutic agents capable of treating established and ongoing atherosclerotic pathology.

In a method for producing acetoin, butanediol, or butanol from ethanol according to the present invention, a cell-free catalysis method was used by designing an artificial synthetic pathway so that proteins of NOX, EtDH, FLS, BDH, and DDH and variant proteins thereof exhibit cascade catalytic activity as enzymes. Compared to existing fermentation methods using microorganisms, the production method according to the present invention does not require cell growth and has a short synthetic pathway, a fast reaction rate, high yield and productivity, adjustment of targeted reaction conditions is convenient, and butanol may be effectively produced. Moreover, same may be reused numerous times by fixing the proteins to nano-particles, and are also effective for producing acetoin, butanediol, or butanol, thus being economical. Therefore, the production method may be usefully adopted in the relevant industries requiring acetoin, butanediol, or butanol.

Provided are various embodiments relating to compositions and methods for treating vascular disease, including core NOX1 promoters and variants thereof for regulating expression of transgenes in response to vascular pathology and allowing for increased transgene loading capacity. Also provided are variant FOXP polypeptides having a zinc finger and leucine zipper region of a different FOXP polypeptide. Further provided are vectors comprising the core NOX1 promoters and/or a coding sequence for variant FOXP polypeptides described herein and optionally coding sequence(s) for one or more additional therapeutic polypeptide(s), such as IL10, for treating inflammation-associated diseases, such as vascular disease. Also provided is a screening model for testing therapeutic agents capable of treating established and ongoing atherosclerotic pathology.

Provided are various embodiments relating to compositions and methods for treating vascular disease, including core NOX1 promoters and variants thereof for regulating expression of transgenes in response to vascular pathology and allowing for increased transgene loading capacity. Also provided are variant FOXP polypeptides having a zinc finger and leucine zipper region of a different FOXP polypeptide. Further provided are vectors comprising the core NOX1 promoters and/or a coding sequence for variant FOXP polypeptides described herein and optionally coding sequence(s) for one or more additional therapeutic polypeptide(s), such as IL10, for treating inflammation-associated diseases, such as vascular disease. Also provided is a screening model for testing therapeutic agents capable of treating established and ongoing atherosclerotic pathology.

Provided are various embodiments relating to compositions and methods for treating vascular disease, including core NOX1 promoters and variants thereof for regulating expression of transgenes in response to vascular pathology and allowing for increased transgene loading capacity. Also provided are variant FOXP polypeptides having a zinc finger and leucine zipper region of a different FOXP polypeptide. Further provided are vectors comprising the core NOX1 promoters and/or a coding sequence for variant FOXP polypeptides described herein and optionally coding sequence(s) for one or more additional therapeutic polypeptide(s), such as IL10, for treating inflammation-associated diseases, such as vascular disease. Also provided is a screening model for testing therapeutic agents capable of treating established and ongoing atherosclerotic pathology.