Aspects of the invention described herein relate to synthetic compounds that are useful for targeting and labeling tumor cells so as to facilitate recognition by binding agents including Chimeric Antigen Receptor T cells (CAR T cells), which are administered to a subject by intravenous or locoregional administration. Several compositions and methods of making and using these compositions to treat or inhibit a disease in a subject are contemplated.

Disclosed herein are compounds having activity as cell penetrating peptides. In some examples, the compounds can comprise a cell penetrating peptide moiety and a cargo moiety. The cargo moiety can comprise one or more detectable moieties, one or more therapeutic moieties, one or more targeting moieties, or any combination thereof. In some examples, the cell penetrating peptide moiety is cyclic. In some examples, the cell penetrating peptide moiety and cargo moiety together are cyclic. In some examples, the cell penetrating peptide moiety is cyclic and the cargo moiety is appended to the cyclic cell penetrating peptide moiety structure. In some examples, the cargo moiety is cyclic and the cell penetrating peptide moiety is cyclic, and together they form a fused bicyclic system.

The present invention relates generally to the field of endosymbiosis, eukaryotic cells engineered with artificial endosymbionts, and magnetotactic bacteria. In particular, the invention provides single-celled organisms such as artificial endosymbionts, including magnetotactic bacteria, eukaryotic cells to host those single-celled organisms, and methods of using eukaryotic cells containing single-celled organisms. The invention also provides eukaryotic cells engineered with intracellular single-celled organisms which eukaryotic cells can be tracked in an animal and monitored for viability. The invention also provides for multimodal detection of a eukaryotic cell in an animal to monitor the location and viability of the eukaryotic cell.

The present disclosure relates to methods and compositions comprising naturally occurring light absorbing molecules for preventing damages from light exposure. Specific embodiments of this disclosure include fluorescent proteins from Brachiostoma lanceolatum.

Disclosed herein are compounds having activity as cell penetrating peptides. In some examples, the compounds can comprise a cell penetrating peptide moiety and a cargo moiety. The cargo moiety can comprise one or more detectable moieties, one or more therapeutic moieties, one or more targeting moieties, or any combination thereof. In some examples, the cell penetrating peptide moiety is cyclic. In some examples, the cell penetrating peptide moiety and cargo moiety together are cyclic. In some examples, the cell penetrating peptide moiety is cyclic and the cargo moiety is appended to the cyclic cell penetrating peptide moiety structure. In some examples, the cargo moiety is cyclic and the cell penetrating peptide moiety is cyclic, and together they form a fused bicyclic system.

The present invention relates to a nucleic acid molecule encoding a fusion protein, wherein the nucleic acid molecule comprises: (a) a first nucleic acid sequence encoding a first biosensor, wherein said first biosensor is a first molecule capable of interacting with a second molecule; (b) a second nucleic acid sequence encoding an effector-activating module, wherein the effector-activating module comprises a nucleic acid sequence encoding a first part of a protease, wherein said first part of the protease is capable of interacting with a second part of said protease to form an active form of said protease; (c) a third nucleic acid sequence encoding a third biosensor comprising a protease cleavage site, wherein the protease cleavage site is sterically occluded in the absence of a stimulus for said third biosensor and wherein the protease cleavage site becomes accessible in the presence of said stimulus.

Disclosed herein are compounds having activity as cell penetrating peptides. In some examples, the compounds can comprise a cell penetrating peptide moiety and a cargo moiety. The cargo moiety can comprise one or more detectable moieties, one or more therapeutic moieties, one or more targeting moieties, or any combination thereof. In some examples, the cell penetrating peptide moiety is cyclic. In some examples, the cell penetrating peptide moiety and cargo moiety together are cyclic. In some examples, the cell penetrating peptide moiety is cyclic and the cargo moiety is appended to the cyclic cell penetrating peptide moiety structure. In some examples, the cargo moiety is cyclic and the cell penetrating peptide moiety is cyclic, and together they form a fused bicyclic system.

Described herein are flash nanoprecipitation methods capable of encapsulating hydrophobic molecules, hydrophilic molecules, bioactive protein therapeutics, or other target molecules in amphiphilic copolymer nanocarriers.

Aspects of the invention described herein relate to synthetic compounds that are useful for targeting and labeling tumor cells so as to facilitate recognition by binding agents including Chimeric Antigen Receptor T cells (CAR T cells), which are administered to a subject by intravenous or locoregional administration. Several compositions and methods of making and using these compositions to treat or inhibit a disease in a subject are contemplated.

The present invention relates to, inter alia, engineered bacteria expressing (i) a surface protein, which specifically interacts cell membrane receptors that are exposed to the luminal side of epithelial cells of diseased gastrointestinal tissue and/or epithelial tissue lining the bile duct, pancreatic duct, or common bile duct, etc., and (ii) a detection marker. The engineered bacteria of the present technology are useful for detecting diseased gastrointestinal tissue and/or epithelial tissue lining the bile duct, pancreatic duct, or common bile duct, etc.