Abstract: Provided herein are anti-Trop 2 antibodies or binding fragments thereof that bind Trop 2, e.g., human Trop 2. The anti-Trop 2 antibodies of the disclosure are useful for the treatment of proliferative disorders or cells that express Trop 2 or mutant Trop 2. Also provided herein are methods of use for the anti-Trop 2 antibodies or binding fragments thereof, as well as bi-valent or multi-valent anti-Trop 2 antibodies or binding fragments thereof that may form complexes that attract immune effectors or binding to other cells, such as, a second antibody, antigen-binding of the second antibody or fragment thereof; a target-binding protein, a cytokine; a lectin; or a toxin.

Abstract: Methods and systems are directed to multiplex detection of a bacterial pathogen in a sample. A first biotinylated lysin-derived cell wall binding domain is complexed with an avidin layer on a surface. A first bacterial pathogen detection complex including a second biotinylated lysin-derived cell wall binding domain, a detection domain, and an avidin linker complexed between the cell wall binding domain and the detection domain is also provided. The cell wall binding domains are derived from an endolysin, autolysin, bacteriocin, or exolysin, and are configured to bind a cell wall of a target bacterial pathogen. The detection domain includes one or more enzymes, fluorescent material, or DNA for emitting a signal for detection. Target bacterial pathogens present in a sample can thus be detected in a sandwich assay exhibiting increased selectivity and reduced limit of detection relative to traditional ELISA.

Abstract: Methods and systems are directed to multiplex detection of a bacterial pathogen in a sample. A first biotinylated lysin-derived cell wall binding domain is complexed with an avidin layer on a surface. A first bacterial pathogen detection complex including a second biotinylated lysin-derived cell wall binding domain, a detection domain, and an avidin linker complexed between the cell wall binding domain and the detection domain is also provided. The cell wall binding domains are derived from an endolysin, autolysin, bacteriocin, or exolysin, and are configured to bind a cell wall of a target bacterial pathogen. The detection domain includes one or more enzymes, fluorescent material, or DNA for emitting a signal for detection. Target bacterial pathogens present in a sample can thus be detected in a sandwich assay exhibiting increased selectivity and reduced limit of detection relative to traditional ELISA.

Abstract: Methods and systems are directed to multiplex detection of a bacterial pathogen in a sample. A first biotinylated lysin-derived cell wall binding domain is complexed with an avidin layer on a surface. A first bacterial pathogen detection complex including a second biotinylated lysin-derived cell wall binding domain, a detection domain, and an avidin linker complexed between the cell wall binding domain and the detection domain is also provided. The cell wall binding domains are derived from an endolysin, autolysin, bacteriocin, or exolysin, and are configured to bind a cell wall of a target bacterial pathogen. The detection domain includes one or more enzymes, fluorescent material, or DNA for emitting a signal for detection. Target bacterial pathogens present in a sample can thus be detected in a sandwich assay exhibiting increased selectivity and reduced limit of detection relative to traditional ELISA.