The present invention provides recombinant adenoviral compositions and methods for their use in treating disorders associated with epithelial tissues.

The invention provides compounds with enhanced permeability for selectively inhibiting glycosidases, prodrugs of the compounds, and pharmaceutical compositions including the compounds or prodrugs of the compounds. The invention also provides methods of treating diseases and disorders related to deficiency or overexpression of O-GlcNAcase, accumulation or deficiency of O-GlcNAc.

Light-generating fusion proteins having a ligand binding site and a light-generating polypeptide moiety and their use as diagnostics, in drug screening and discovery, and as therapeutics, are disclosed. The light-generating fusion protein has a feature where the bioluminescence of the polypeptide moiety changes upon binding of a ligand at the ligand binding site. The ligand may be, for example, an enzyme present in an environment only under certain conditions, e.g., ubiquitin ligase in a hypoxic state, such that the light-generating fusion protein is “turned on” only under such conditions.

The present disclosure an ELISA-based assay that uses a glycosylated polypeptide fragment derived from the SARS-CoV-2 spike protein (Covid-19) receptor binding domain (S1RBD) that has affinity for the extracellular domain of Angiotensin Converting Enzyme 2 (ACE2). The S1RBD polypeptide is generated by expression of an encoding nucleic acid by a human cell expression system resulting in glycosylation of the expressed spike receptor binding domain (S1RBD) protein at least at the N343 N-glycosylation site thereof, and which surprisingly and significantly increases the affinity of the S1RBD for ACE2, provides a significant increase in the sensitivity of the assay compared to other known assays.

Disclosed are LIMP-2 peptides, LIMP-2 polypeptides, variants thereof, and pharmaceutical compositions comprising the LIMP-2 peptides, LIMP-2 polypeptides, or variants thereof. The disclosed peptides and polypeptides preferably comprise an amino acid sequence that is sufficient for providing a biological activity associated with LIMP-2, which may include binding and/or activating biological molecules such as β-glucocerebrosidase and binding viral protein 1 (VP1) of enterovirus 71 (E71) or coxsackievirus A16 (CA16). Also disclosed are methods of using the LIMP-2 peptides, LIMP-2 polypeptides, and variants thereof as therapeutics for treating diseases and disorders associated with β-glucocerebrosidase activity in subjects in need thereof.

A peptide that binds specifically to neuropilin-1 (NRP1) without binding to neuropilin-2 (NRP2) is provided. A fusion protein, a fusion antibody, small-molecule drug, a nanoparticle, or a liposome, which comprises the peptide, and a pharmaceutical composition for treating or preventing cancer or angiogenesis-related diseases, and a composition for diagnosing cancer or angiogenesis-related diseases are provided. A polynucleotide encoding the peptide that binds specifically to NRP1 and a method for screening the peptide that binds specifically to NRP1 are provided. An antibody heavy-chain constant region Fc-fused peptide binding specifically to NRP1 has the property of binding specifically to NRP1, and thus when it is administered in vivo, it accumulates selectively in tumor tissue, and widens the intercellular space between tumor-associated endothelial cells to promote its extravasation and increases its tumor tissue penetration.

Antiviral biomimetic polymers (ABPs) are disclosed that can be used to prevent and/or treat viral disease. The ABPs are discovered by a process involving high-throughput screening of polymer libraries using disease-relevant bioactive molecules as target molecules. ABPs can be nanoscale (termed nanoABPs) or larger. Methods are described for the preparation and use of ABPs as prophylactics and therapeutics (in vivo) and as preventative agents, for example, in personal protective equipment (ex vivo). ABPs can be used to prevent and treat viral diseases including those caused by Filoviridae.

The present invention provides an in vitro method for identifying a compound that promotes endothelial cell adhesion, endothelial cell spreading, endothelial cell migration and/or endothelial cell proliferation for the manufacture of a diagnostic or therapeutic agent. The present invention further provides the identified compounds and pharmaceutical compositions, and assays and kits for identifying a compound or using a compound that promotes endothelial cell adhesion, endothelial cell spreading, endothelial cell migration and/or endothelial cell proliferation and is useful for bioprinting.

The present invention relates to variants of factor IX (F.IX) or activated factor IX (F.IXa), wherein the variant is characterized in that it has clotting activity in absence of its cofactor. The present invention furthermore relates to variants of factor IX (F.IX) or activated factor IX (F.IXa), wherein the variant is characterized in that it has increased F.IX clotting activity compared to wildtype. The present invention furthermore relates to the use of these variants for the treatment and/or prophylaxis of bleeding disorders, in particular hemophilia A and/or hemophilia B or hemophilia caused or complicated by inhibitory antibodies to F.VIII. The present invention also relates to further variants of factor IX (F.IX) which have desired properties and can, thus be tailored for respective specific therapeutic applications.

Disclosed are methods, kits and cells for screening for test compounds that are capable of inhibiting DNA-binding activity of a DNA-binding protein. The disclosed methods, kits and cells may include a reporter expression cassette that encodes a reporter expression product, wherein the reporter expression cassette comprises at least one binding site for the DNA-binding protein such that binding of the DNA-binding protein to the binding site inhibits expression of the reporter expression product. Also disclosed are methods for producing a helix-constrained peptide that may be used in the screening methods disclosed herein. The methods, kits and cells find application, for example, in the identification of antagonists that may be useful in the treatment of cancers involving the DNA-binding protein.