The invention provides a method of extracting protein from a protein source material such as egg white material. The method comprises contacting a crosslinked alginate-based carrier with the protein source material and allowing the protein to bind to the carrier, so as to form a protein-loaded carrier product. The method then comprises separating the protein-loaded carrier product from the remaining protein source material.

Use of aprotinin as a carrier to produce a recombinant protein, polypeptide or peptide in algae The present invention relates to the use of aprotinin as a carrier to produce a recombinant protein, polypeptide or peptide in algae, in particular microalgae, wherein aprotinin and said recombinant protein, polypeptide or peptide are fused together to form a fusion protein. It also relates to a method to produce a recombinant protein, polypeptide or peptide in algae, wherein said method comprises genetic transformation of algae, in particular microalgae, with a recombinant nucleic acid sequence encoding a fusion protein, wherein said fusion protein comprises aprotinin and said recombinant protein, polypeptide or peptide. It further relates to a recombinant algae comprising a recombinant nucleic acid sequence encoding a fusion protein, wherein said fusion protein comprises aprotinin and a recombinant protein, polypeptide or peptide. The use of said recombinant algae, for producing said fusion protein is also contemplated.

The present invention relates to antibody-polypeptide-cytotoxin conjugates and methods of making, packaging, and using the conjugates. The polypeptide can be a Kunitz-type protease inhibitor or a derivative thereof that facilitates transport of the conjugate across the blood-brain barrier and/or into cancer cells outside the CNS, and the antibody moiety selectively binds a target within the CNS or in peripheral tumors to direct the cytotoxic agent to that target (e.g., a tumor or cancer cell). The conjugates can be further defined by the inclusion of a linker between the antibody moiety and the polypeptide; by the number of polypeptides and cytotoxic agents conjugated thereto; by the positions at which the entities within the conjugates are bound to one another; and by the larger configuration of the conjugate. Modified polypeptides (e.g., polypeptides conjugated to cytotoxic agents but not to an anti-body moiety), pharmaceutical compositions, kits (e.g., including a modified polypeptide and an as-yet unconjugated antibody), and methods of making and using the conjugates are also features of the invention.

The present invention relates to antibody-polypeptide-cytotoxin conjugates and methods of making, packaging, and using the conjugates. The polypeptide can be a Kunitz-type protease inhibitor or a derivative thereof that facilitates transport of the conjugate across the blood-brain barrier and/or into cancer cells outside the CNS, and the antibody moiety selectively binds a target within the CNS or in peripheral tumors to direct the cytotoxic agent to that target (e.g., a tumor or cancer cell). The conjugates can be further defined by the inclusion of a linker between the antibody moiety and the polypeptide; by the number of polypeptides and cytotoxic agents conjugated thereto; by the positions at which the entities within the conjugates are bound to one another; and by the larger configuration of the conjugate. Modified polypeptides (e.g., polypeptides conjugated to cytotoxic agents but not to an antibody moiety), pharmaceutical compositions, kits (e.g., including a modified polypeptide and an as-yet unconjugated antibody), and methods of making and using the conjugates are also features of the invention.

The present invention provides new compositions and methods for preventing and treating pathogen infection. In particular, the present invention provides compounds having an anchoring domain that anchors the compound to the surface of a target cell, and a therapeutic domain that can act extracellularly to prevent infection of a target cell by a pathogen, such as a virus. The present invention also comprises therapeutic compositions having sialidase activity, including protein-based compounds having sialidase catalytic domains. Compounds of the invention can be used for treating or preventing pathogen infection, and for treating and reducing allergic and inflammatory responses. The invention also provides compositions and methods for enhancing transduction of target cells by recombinant viruses. Such compositions and methods can be used in gene therapy.

The present invention relates to a method for the recombinant production of a serine protease comprising (a) culturing a host cell comprising one or more vectors, wherein the one or more vectors encode in expressible form the serine protease and a proteinaceous inhibitor of the serine protease, wherein the proteinaceous inhibitor of the serine protease is heterologous with respect to the serine protease, under conditions wherein the serine protease and the proteinaceous inhibitor of the serine protease are expressed; or (a′) culturing a host cell the genome of which encodes in expressible form the serine protease and a proteinaceous inhibitor of the serine protease, wherein the proteinaceous inhibitor of the serine protease is heterologous with respect to the serine protease, and wherein the coding sequences of the serine protease and/or the proteinaceous inhibitor have been introduced into the host cell genome by applying a CRISPR technology, under conditions wherein the serine protease and the proteinaceous inhibitor of the serine protease are expressed; and (b) isolating the serine protease expressed in step (a) or (a′) from the host cell. The present invention also relates to a host cell comprising one or more vectors, wherein the one or more vectors encode in expressible form a serine protease and a proteinaceous inhibitor of the serine protease.

The present invention relates to a method for the recombinant production of a serine protease comprising (a) culturing a host cell comprising one or more vectors, wherein the one or more vectors encode in expressible form the serine protease and a proteinaceous inhibitor of the serine protease, wherein the proteinaceous inhibitor of the serine protease is heterologous with respect to the serine protease, under conditions wherein the serine protease and the proteinaceous inhibitor of the serine protease are expressed; or (a) culturing a host cell the genome of which encodes in expressible form the serine protease and a proteinaceous inhibitor of the serine protease, wherein the proteinaceous inhibitor of the serine protease is heterologous with respect to the serine protease, and wherein the coding sequences of the serine protease and/or the proteinaceous inhibitor have been introduced into the host cell genome by applying a CRISPR technology, under conditions wherein the serine protease and the proteinaceous inhibitor of the serine protease are expressed; and (b) isolating the serine protease expressed in step (a) or (a) from the host cell. The present invention also relates to a host cell comprising one or more vectors, wherein the one or more vectors encode in expressible form a serine protease and a proteinaceous inhibitor of the serine protease.

The disclosure provides compositions, methods, and kits for treatment of a condition, disease or disorder characterized by elevated trypsin activity or level, e.g., pancreatitis.

The present invention features a compound having the formula A-X-B, where A is peptide vector capable of enhancing transport of the compound across the blood-brain barrier or into particular cell types, X is a linker, and B is a peptide therapeutic selected from the group consisting of neurotensin, a neurotensin analog, or a neurotensin receptor agonist. The compounds of the invention can be used to treat any disease in which increased neurotensin activity is useful and can be used to induce hypothermia or analgesia.

The present invention relates to short polypeptides (e.g., fewer than 19 amino acids in length) and longer polypeptides (e.g., 19 or more amino acids in length) having one or more D-amino acids as targeting moieties. These polypeptides, when conjugated to agents (e.g., therapeutic agents or transport vectors) are capable of transporting the agents across the BBB or into particular cell types. In particular, the short polypeptides can include one or more D-amino acids. These compounds are therefore particularly useful in the treatment of neurological diseases or diseases associated with particular cell types, organs, or tissues.