The present invention is directed to T-cell epitope delivering polypeptides which deliver one or more CD8+ T-cell epitopes to the MHC class I presentation pathway of a cell, including toxin-derived polypeptides which comprise embedded T-cell epitopes and are de-immunized. The present invention provides cell-targeted, CD8+ T-cell epitope delivering molecules for the targeted delivery of cytotoxicity to certain cells, e.g., infected or malignant cells, for the targeted killing of specific cell types, and the treatment of a variety of diseases, disorders, and conditions, including cancers, immune disorders, and microbial infections. The present invention also provides methods of generating polypeptides capable of delivering one or more heterologous T-cell epitopes to the MHC class I presentation pathway, including polypeptides which are 1) B-cell and/or CD4+ T-cell de-immunized, 2) comprise embedded T-cell epitopes, and/or 3) comprises toxin effectors which retain toxin functions.

Isolated polypeptides are provided that comprise a cholera toxin B subunit variant having one or more modifications to increase the expression of the polypeptide in a plant cell. Nucleic acids sequences, vectors, and plant cells for expressing the cholera toxin B subunit variant polypeptides are also provided. Further provided are methods for producing the cholera toxin B subunit variant polypeptides that include the steps of transforming a plant cell with a nucleic acid encoding the cholera toxin B subunit variant polypeptides; expressing the variant polypeptides; and purifying the polypeptides. Still further provided are methods of isolating the variant polypeptides that include the steps of obtaining a plant cell expressing the cholera toxin B subunit variant polypeptides; extracting the cholera toxin B subunit variant polypeptides from the plant cell; and purifying the cholera toxin B subunit variant polypeptides. Methods of eliciting an immune response are also provided.

Provided are NK-92 cells expressing a chimeric antigen receptor (CAR). The CAR can comprise an intracellular domain of Fc?RI?. Also described are methods for treating a patient having or suspected of having a disease that is treatable with NK-92 cells, such as cancer or a viral infection, comprising administering to the patient NK-92-CAR cells.

The present invention is directed to T-cell epitope delivering polypeptides which deliver one or more CD8+ T-cell epitopes to the MHC class I presentation pathway of a cell, including toxin-derived polypeptides which comprise embedded T-cell epitopes and are de-immunized. The present invention provides cell-targeted, CD8+ T-cell epitope delivering molecules for the targeted delivery of cytotoxicity to certain cells, e.g., infected or malignant cells, for the targeted killing of specific cell types, and the treatment of a variety of diseases, disorders, and conditions, including cancers, immune disorders, and microbial infections. The present invention also provides methods of generating polypeptides capable of delivering one or more heterologous T-cell epitopes to the MHC class I presentation pathway, including polypeptides which are 1) B-cell and/or CD4+ T-cell de-immunized, 2) comprise embedded T-cell epitopes, and/or 3) comprises toxin effectors which retain toxin functions.

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.

The present disclosure provides opsins, including variant opsins with increased activity and/or increased trafficking to the plasma membrane. The opsins are useful in therapeutic and screening applications, which are also provided.

The present invention provides a modified oleosin protein, a polynucleotide sequence encoding the modified protein, and a method for regulating subcellular lipid distribution by recombinantly expressing the modified oleosin protein. This invention also provides a method for generating cells and organisms comprising the modified oleosin protein and exhibiting an altered subcellular lipid distribution pattern, as well as cells and organisms generated by such a method.

Disclosed herein are methods for the large-scale production of a highly thermally stable acetylcholinesterase (AChE) and butyrylcholinesterase (BChE). Additionally, the expression methods disclosed herein can produce ChE preparations consisting of extract or purified forms that can be produced in high amounts and are highly thermally stable. These ChE products can be used in vitro detection, detoxification and decontamination methods.

Provided herein are devices and methods for reversibly controlling memory function in living non-human animals. Some variations of methods for affecting memory function comprise temporarily inhibiting neurons of the hippocampus (e.g., neurons of the dorsal CA1 field of the hippocampus) during the acquisition or retrieval of a memory. Alternatively or additionally, methods for reversibly affecting memory function comprise inhibiting neurons of the amygdala (e.g. basolateral amygdala) and/or neurons of the cingulate cortex (e.g., anterior cingulated cortex). Methods for disrupting the formation and recall of memories by inhibiting excitatory neurons expressing light-activated proteins are disclosed herein. One or more methods for reversibly affecting memory function described herein can be used to evaluate the effectiveness of pharmacological agents in treating PTSD and/or various memory disorders.

The present invention provides compositions comprising a protein expression blocker or PEBL comprising a target-binding molecule and localizing domain, and methods of using such compositions in cancer therapy. PEBLs are useful as a blockade of expression of target surface receptors (peptides or antigens) in immune cells. Also provided herein are CD3/TCR??-deficient T cells and CD3/TCR??-deficient chimeric antigen receptor T cells that express such PEBLs.