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 invention relates to peptides, in particular cell penetrating peptides, of 40 amino acid residues or less comprising at least one directly glycosylated amino residue and one or more arginine rich arm domains, and to conjugates of such cell penetrating peptides with a therapeutic molecule. The present invention further relates to the use of the peptides or conjugates in methods of treatment or as a medicament, especially in the treatment of genetic disorders of the central nervous system.

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 present application relates to methods and compositions and methods for treating viral infections, especially those caused by SARS-CoV-2. In one aspect, a method of treatment comprises administering to a subject in need of such treatment an effective amount of a pharmaceutical composition comprising a multipartite SARS-CoV-2-inhibiting peptide comprising a secretion modulating region (VI-SMR) peptide from HIV-1 Nef in combination with a cell-penetrating peptide (CPP) domain, a Clusterin (Clu)-binding peptide (Clu-BP) domain, a mitochondrial targeting (Mito-T) peptide domain, an anti-fusogenic (AF) peptide domain, a viral attachment inhibitor (VAI) domain or combination thereof, optionally where the SARS-CoV-2-inhibiting peptide is pegylated and/or modified with one or more hydrophobic domains.

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.

Instead of generating immune responses to several HIV proteins and risk over activating more CD4+ T cells (easy targets for HIV-1 infection) as current candidate vaccines try to do, a lower magnitude, narrowly focused, well maintained virus specific CD8+ T cell response to multiple subtypes should destroy and eliminate a few founder viruses without inducing inflammatory responses that may activate more CD4+ T cells and provide more targets for HIV-1 virus infection. Specifically, described herein is a method that focuses the immune response to the 12 protease cleavage sites.

The present application relates to methods and compositions and methods for treating viral infections, especially those caused by SARS-CoV-2. In one aspect, a method of treatment comprises administering to a subject in need of such treatment an effective amount of a pharmaceutical composition comprising a multipartite SARS-CoV-2-inhibiting peptide comprising a secretion modulating region (VI-SMR) peptide from HIV-1 Nef in combination with a cell-penetrating peptide (CPP) domain, a Clusterin (Clu)-binding peptide (Clu-BP) domain, a mitochondrial targeting (Mito-T) peptide domain, an anti-fusogenic (AF) peptide domain, a viral attachment inhibitor (VAI) domain or combination thereof, optionally where the SARS-CoV-2-inhibiting peptide is pegylated and/or modified with one or more hydrophobic domains.

Instead of generating immune responses to several HIV proteins and risk over activating more CD4+ T cells (easy targets for HIV-1 infection) as current candidate vaccines try to do, a lower magnitude, narrowly focused, well maintained virus specific CD8+ T cell response to multiple subtypes should destroy and eliminate a few founder viruses without inducing inflammatory responses that may activate more CD4+ T cells and provide more targets for HIV-1 virus infection. Specifically, described herein is a method that focuses the immune response to the 12 protease cleavage sites.

Instead of generating immune responses to several HIV proteins and risk over activating more CD4+ T cells (easy targets for HIV-1 infection) as current candidate vaccines try to do, a lower magnitude, narrowly focused, well maintained virus specific CD8+ T cell response to multiple subtypes should destroy and eliminate a few founder viruses without inducing inflammatory responses that may activate more CD4+ T cells and provide more targets for HIV-1 virus infection. Specifically, described herein is a method that focuses the immune response to the 12 protease cleavage sites.

Both purinergic signaling through nucleotides such as ATP and noradrenergic signaling through molecules such as norepinephrine regulate vascular tone and blood pressure. Pannexin1 (Panx1), which forms large-pore, ATP-releasing channels, is present in vascular smooth muscle cells in peripheral blood vessels and participates in noradrenergic responses. Using pharmacological approaches and mice conditionally lacking Panx1 in smooth muscle cells, we found that Panx1 contributed to vasoconstriction mediated by the α1 adrenoreceptor (α1AR), whereas vasoconstriction in response to serotonin or endothelin-1 was independent of Panx1. Analysis of the Panx1-deficient mice showed that Panx1 contributed to blood pressure regulation especially during the night cycle when sympathetic nervous activity is highest. Using mimetic peptides and site-directed mutagenesis, we identified a specific amino acid sequence in the Panx1 intracellular loop that is essential for activation by α1AR signaling. Collectively, these data describe a specific link between noradrenergic and purinergic signaling in blood pressure homeostasis.