This invention provides biosensors, cell models, and methods of their use for monitoring ionic or voltage responses to contact with bioactive agents. Biosensors can include targeting domains, sensing domains and reporting domains. Biosensors can be introduced into cells reprogrammed to represent experimental or pathologic cells of interest. Model cells expressing the biosensors can be contacted with putative bioactive agents to determine possible activities.

The present disclosure provides light-responsive polypeptides, and nucleic acids comprising nucleotide sequences encoding the light-responsive polypeptides. The present disclosure provides methods, devices, and systems for controlling the activity of a cell expressing a light-responsive polypeptide of the present disclosure.

A hook fusion protein, which includes a hook domain and at least one cytoplasmic carboxyl endoplasmic reticulum (ER) retention signal and/or at least one cytoplasmic amino terminal endoplasmic reticulum (ER) retention signal; wherein the hook fusion protein is a soluble protein that localizes in the cytoplasm. Also, a nucleic acid system for intracellular targeting control including a nucleic acid encoding a target fusion protein including a hook fusion protein, and a nucleic acid encoding a target fusion protein including a hook-binding domain; wherein the target fusion protein is a membrane protein; and wherein the hook fusion protein localizes in the ER when bound to the target fusion protein. Additionally, a vector system, viral particle system, host cell and kit include these nucleic acids. Further, the vector system, viral particle system, host cell or kit for use as a medicament, in particular for immunotherapy.

The invention relates to building a chimeric polypeptide used for preventing or treating a Flaviviridae infection. The use of the inventive chimeric polypeptide for producing recombinant viral vectors such as a measles living viral vector is also disclosed.

We tested the in vitro and in vivo efficacy of a recombinant bispecific immunotoxin that recognizes both EGFRwt and tumor-specific EGFRvIII receptors. A single chain antibody was cloned from a hybridoma and fused to toxin, carrying a C-terminal peptide which increases retention within cells. The binding affinity and specificity of the recombinant bispecific immunotoxin for the EGFRwt and the EGFRvIII proteins was measured. In vitro cytotoxicity was measured. In vivo activity of the recombinant bispecific immunotoxin was evaluated in subcutaneous models and compared to that of an established monospecific immunotoxin. In our preclinical studies, the bispecific recombinant immunotoxin, exhibited significant potential for treating brain tumors.

A fusion protein for use as an immunogen enhancer for enhancing antigen-specific T cell responses is disclosed. The fusion protein comprises: (a) an antigen-presenting cell (APC)-binding domain or a CD91 receptor-binding domain; (b) a protein transduction domain; and (c) an antigen of a pathogen, wherein the APC-binding domain or the CD91 receptor-binding domain is located at the N-terminus of the fusion protein, and the antigen of the pathogen is located at the C-terminus of the protein transduction domain. The protein transduction domain is selected from the group consisting of: (i) a fusion polypeptide, comprising a T cell sensitizing signal-transducing peptide, a linker, and a translocation peptide; (ii) a T cell-sensitizing signal-transducing peptide; and (iii) a translocation peptide of 34-112 amino acid residues in length.

An immunogen-specific is adjuvant for a vaccine or inoculum is disclosed. The adjuvant is comprised of particulate recombinant protein body-like assemblies (RPBLAs) that contain a recombinant fusion protein that contains two portions peptide-linked together. A first portion is a protein body-inducing sequence (PBIS) and a second portion is a T-cell stimulating immunogenic polypeptide whose sequence is that of a pathogenic polypeptide sequence present in or induced by a vaccine or inoculum. The adjuvant, when used as an inoculum in a host animal without a prior priming vaccination or inoculation, does not induce production of antibodies or T cell activation to the pathogenic sequence.

The subject invention concerns materials and methods for treating or preventing disease and conditions associated with various sulfatase enzymes that are defective or that are not properly expressed in a person or animal. In one embodiment, the disease is Sanfilippo A (MPS-IIIA) disease. The subject invention also concerns materials and methods for treating or preventing multiple sulfatase deficiency (MSD) in a person or animal. Compounds of the invention include a fusion protein comprising i) a mammalian sulfatase, or an enzymatically active fragment or variant thereof, and ii) a plant lectin or a binding subunit thereof. In a specific embodiment, the mammalian sulfatase is a human sulfatase, or an enzymatically active fragment or variant thereof. Polynucleotides encoding the fusion proteins are also contemplated for the subject invention. The subject invention also concerns materials and methods for producing proteins of the invention.

This invention provides biosensors, cell models, and methods of their use for monitoring heme, oxygen or ATP. Biosensors can include targeting domains, sensing domains and reporting domains. Biosensors can be introduced into cells reprogrammed to represent experimental or pathologic cells of interest. Model cells expressing the biosensors can be contacted with putative bioactive agents to determine possible activities.

This invention provides biosensors, cell models, and methods of their use for monitoring heme, oxygen or ATP. Biosensors can include targeting domains, sensing domains and reporting domains. Biosensors can be introduced into cells reprogrammed to represent experimental or pathologic cells of interest. Model cells expressing the biosensors can be contacted with putative bioactive agents to determine possible activities.