Abstract: A bacteria-mediated platform that uses invasive, non-pathogenic bacteria to both produce and intracellularly deliver antibodies, antibody derivatives, and proteins/polypeptides to targeted eukaryotic cells and tissues. The bacteria can contain a prokaryotic expression cassette encoding the protein cargo.

Abstract: A transkingdom platform for the delivery of therapeutics to target cells. The system maintains the export and uptake functions of Inv while modifying its targeting away from 1 integrin to other proteins expressed on the surface of target eukaryotic cells (i.e., a cell surface protein) or chemical moieties (i.e., a cell surface chemical moiety) expressed on the surface of a target eukaryotic cell by replacing D4 and D5 of Inv with a binding domain from a heterologous protein via genetic engineering. These heterologous proteins could be derived from bacterial, fungal, animal, or viral genomes. This engineering would result in the construction of a chimeric Inv protein in which D1-D3 (i.e., the non-binding domains) are fused in frame to an alternative binding domain derived from a heterologous protein.

Abstract: A bacterial-mediated gene-editing delivery platform that uses invasive, non-pathogenic bacteria to deliver gene-editing cargo, including CRISPR/Cas systems, to eukaryotic cells. The bacteria contain a prokaryotic expression cassette encoding the gene-editing cargo.

Abstract: A transkingdom platform for the delivery of therapeutic nucleic acids to epithelial tissues where the nucleic acids are designed to have enhanced stability. The platform offers numerous improvements to prior delivery platforms including expression of the double-stranded RNA binding domain (dsRBD) domains of TAR RNA binding protein (TRBP), knockout of RNase R activity in the bacterial delivery vehicle, and expression of the methyltransferase gene, HEN1, for simultaneous packaging with a therapeutic nucleic acid delivery vehicle.

Abstract: A bacterial system for the generation and delivery of eukaryote-translatable mRNA to eukaryotic cells. The system uses invasive, non-pathogenic bacteria to generate and deliver functional mRNA cargo to eukaryotic cells. Additionally, the system uses bacteria to generate functional mRNA that can be extracted from the bacterial cell for downstream applications. The bacteria contain at least one prokaryotic expression cassette encoding the mRNA; the mRNA contains a bacterially transcribed poly-A sequence, and a 5? cap or pseudo-cap element, e.g., an internal ribosome entry site (IRES) element, that will mediate translation in the eukaryotic host cell. Examples of therapeutic mRNA function include, but are not limited to, providing genetic material encoding antibodies, vaccine antigens, and defective genes in the host.

Abstract: A transkingdom platform for the delivery of therapeutic nucleic acids to epithelial tissues where the nucleic acids are designed to have enhanced stability. The platform offers numerous improvements to prior delivery platforms including expression of the double-stranded RNA binding domain (dsRBD) domains of TAR RNA binding protein (TRBP), knockout of RNase R activity in the bacterial delivery vehicle, and expression of the methyltransferase gene, HEN1, for simultaneous packaging with a therapeutic nucleic acid delivery vehicle.

Abstract: Products and associated methods are described for the delivery of one or more small interfering RNAs (siRNAs) to an avian cell using a nonpathogenic bacterium for the prevention or treatment of Avian Influenza Virus (AIV). The siRNA is complementary to an mRNA of the AIV NP or PA sequence. In challenge studies with chickens, the siRNA is shown to prevent the onset of clinical symptoms or reduce the severity of disease, including reducing viral titers or virus shedding.

Abstract: Product, and associated methods are described for the delivery of one or more small interfering RNAs (siRNAs) to an avian cell using a nonpathogenic bacterium for the prevention or treatment of Avian Influenza Virus (AIV). The siRNA is complementary to an mRNA of the AIV NP or PA sequence. In challenge studies with chickens, the siRNA is shown to prevent the onset of clinical symptoms or reduce the severity of disease, including reducing viral titers or virus shedding.