The present invention provides lyophilized formulations of active agents, particularly of TAT-NR2B9c, as chloride salts. TAT-NR2B9c has shown promise for treating stroke, aneurysm, subarachnoid hemorrhage and other neurological or neurotraumatic conditions. The chloride salt of TAT-NR2B9c shows improved stability compared with the acetate salt form of prior formulations. Formulations of the chloride salt of TAT-NR2B9c are stable at ambient temperature thus facilitating maintenance of supplies of such a formulation in ambulances for administration at the scene of illness or accident or in transit to a hospital.

The application provides data from a clinical trial of a PSD-95 inhibitor in subjects undergoing endovascular repair of an aneurysm in or otherwise affecting the CNS. The subjects were stratified by whether the aneurysm ruptured before performing the endovascular surgery. Rupture is associated with higher mortality or increased debilitation if a subject survives. The trial provided evidence of significant benefit in subjects with and without aneurysm rupture before endovascular was surgery performed. Surprisingly, the subjects benefitting most from treatment as judged both by pathology and neurocognitive outcome were those in which the aneurysm had ruptured causing a subarachnoid hemorrhage. These data constitute evidence that a PSD-95 inhibitor is beneficial not only in ischemic and hemorrhagic stroke but in forms of hemorrhage in or affecting the CNS, particularly, subarachnoid hemorrhage.

The invention provides compositions, methods, and kits for the treatment or prevention of viral infections. The polyvalent (e.g., 2-valent) vaccines described herein incorporate computationally-optimized viral polypeptides that can increase the diversity or breadth and depth of cellular immune response in vaccinated subjects.

Methods, systems, compositions and strategies for the delivery of RNA into cells in vivo, ex vivo, or in vitro via ARMMs are provided. In some aspects, ARMMs containing fusion proteins of ARRDC1 fused to an RNA binding protein or an RNA binding protein fused to a WW domain are provided. In some aspects, ARMMs containing binding RNAs associated with cargo RNAs are provided. In other aspects, cargo RNAs associated with a binding RNA, such as a TAR element, are loaded into ARMMs via ARRDC1 fusion proteins containing an RNA binding protein, such as trans-activator of transcription (Tat) protein.

Disclosed are methods for conditionally immortalizing stem cells, including adult and embryonic stem cells, the cells produced by such methods, therapeutic and laboratory or research methods of using such cells, and methods to identify compounds related to cell differentiation and development or to treat diseases, using such cells. A mouse model of acute myeloid leukemia (AML) and cells and methods related to such mouse model are also described.

The present invention relates to an isolated peptide, an anti-cancer medicinal composition including the same and a method of specifically reducing or inhibiting activities of cancer cells using the same. The isolated peptide including a TAT basic domain conjugated to a GABARAPL2 H2 domain can specifically reduce or inhibit an activity of cancer cells, thereby being applied to the anti-cancer medicinal composition and the method of specifically reducing or inhibiting activities of cancer cells using the same.

The present invention relates to novel immunogens based on overlapping peptides (OLPs) and peptides derived therefrom useful for the prevention and treatment of AIDS and its related opportunistic diseases. The invention also relates to isolated nucleic acids, vectors and host cells expressing these immunogens as well as vaccines including said immunogens.

The present application relates to methods of producing exosomes. The application also provides a method for preparing a protein composition comprising culturing an exosome-producing cell expressing a Nef-fusion protein comprising a Nef-derived peptide fused to a protein of interest; isolating exosomes from the exosome-producing cell culture; and purifying the protein of interest from the isolated exosomes. The application further discloses compositions that comprise exosomes containing the Nef-fusion protein, as well as methods of using the Nef-fusion protein and exosomes containing the Nef-fusion protein.

The present disclosure provides a fusion protein useful for treating a non-nuclear organelle associated disorder, such as a genetic disorder, e.g., Friedrich's Ataxia. The fusion protein may comprise a protein of interest to be delivered to a non-nuclear organelle; an organelle targeting sequence (OTS); a cell penetrating peptide (CPP); and a target enhancing sequence (TES); wherein the CPP is capable of interference with delivery of the protein of interest to the non-nuclear organelle; and wherein the TES prevents said interference by the CPP. The fusion protein may also comprise a protein of interest to be delivered to a non-nuclear organelle; a CPP and a TES. The present disclosure also provides methods for treating a non-nuclear organelle associated disorder by administering the fusion protein to a subject in need thereof.

The present invention provides a method and a reagent for increasing lentiviral vector production in 293T cells. When the 293T cells are cotransfected with a packaging mix comprising a plurality of plasmids that comprise genes encoding proteins essential for lentiviral particle formation and a plasmid that comprises a gene transcribed into RNA to be incorporated into lentiviral particles containing a transgene to be expressed in target cells according to the method for producing a lentiviral vector, HTLV-1 Tax, HIV-1 Tat, or NF-κB RelA are coexpressed in the 293T cells, so as to increase the amount of lentiviral vector production.