An immobilized polypeptide including a polypeptide bound to a surface of a polypeptide array or a chip, wherein the polypeptide has the amino acid sequence of SEQ ID NO:1, SEQ ID NO:3, SEQ ID NO:1 lacking the N-terminal methionine, SEQ ID NO:3 lacking the N-terminal methionine, or a combination thereof.

The present invention relates to heterotandem bicyclic peptide complexes which comprise a first peptide ligand, which binds to a component present on an immune cell, conjugated via a linker to a second peptide ligand, which binds to a component present on a cancer cell. The invention also relates to the use of said heterotandem bicyclic peptide complexes in preventing, suppressing or treating cancer.

A carrier system that includes a nanocarrier and a peptide non-covalently associated with the nanocarrier. The peptide contains an adaptor peptide sequence fused to the N-terminus of a target peptide, the adaptor peptide sequence being designed to facilitate the association to the nanocarrier. Also disclosed is a method for improving the immunogenicity of a peptide antigen by fusing it to an adaptor peptide sequence to form an immunizing peptide and contacting the immunizing peptide with a compatible nanocarrier. Further, a method is provided for treating a condition by immunization with a target peptide that has been fused to an adaptor peptide sequence and thereby associated with a nanocarrier. The method induces an immune response against the target peptide for treating cancer, viral infection, bacterial infection, parasitic infection, autoimmunity, or undesired immune responses to a biologies treatment.

A carrier system that includes a nanocarrier and a peptide non-covalently associated with the nanocarrier. The peptide contains an adaptor peptide sequence fused to the N-terminus of a target peptide, the adaptor peptide sequence being designed to facilitate the association to the nanocarrier. Also disclosed is a method for improving the immunogenicity of a peptide antigen by fusing it to an adaptor peptide sequence to form an immunizing peptide and contacting the immunizing peptide with a compatible nanocarrier. Further, a method is provided for treating a condition by immunization with a target peptide that has been fused to an adaptor peptide sequence and thereby associated with a nanocarrier. The method induces an immune response against the target peptide for treating cancer, viral infection, bacterial infection, parasitic infection, autoimmunity, or undesired immune responses to a biologies treatment.

The present invention novel methods of preparing biomimetic proteoglycans, such as bottle-brush, chondroitin sulfate-containing, biomimetic proteoglycans. In certain embodiments, the methods of the invention comprise contacting a core polymer comprising at least one acyl chloride group with a GAG comprising a terminal primary amine.

A solid supported branched linker assay system, including an alpha compound and a beta compounds reversibly tethered to a solid support; a branched linker coupled to the solid support that tethers the alpha and beta compounds to the solid support; the branched linker having two cleavable linkers that are chemically distinct from one another, wherein a first chemically distinct linker tethers the β compound to the branched linker and a second chemically distinct linker tethers the α compound to the branched linker; and at least two means for cleaving the chemically distinct linkers, wherein a first cleavage means is configured to selectively cleave a first chemically distinct linker and a second cleavage means is configured to selectively cleave a second chemically distinct linker.

A solid supported branched linker assay system, including an alpha compound and a beta compounds reversibly tethered to a solid support; a branched linker coupled to the solid support that tethers the alpha and beta compounds to the solid support; the branched linker having two cleavable linkers that are chemically distinct from one another, wherein a first chemically distinct linker tethers the β compound to the branched linker and a second chemically distinct linker tethers the α compound to the branched linker; and at least two means for cleaving the chemically distinct linkers, wherein a first cleavage means is configured to selectively cleave a first chemically distinct linker and a second cleavage means is configured to selectively cleave a second chemically distinct linker.

Constructs having membrane proteins stabilized by functionalized beta-sheet peptides are provided. The constructs can be associated with or covalently linked to supports. The support can be a membrane. The membrane can be used to selectively move desired particles from one side of the membrane to the other while impeding passage of undesired particles through the membrane. Methods of making and using such constructs and membranes are provided.

Constructs having membrane proteins stabilized by functionalized beta-sheet peptides are provided. The constructs can be associated with or covalently linked to supports. The support can be a membrane. The membrane can be used to selectively move desired particles from one side of the membrane to the other while impeding passage of undesired particles through the membrane. Methods of making and using such constructs and membranes are provided.

There are provided efficient and cost-effective methods for purifying biomolecules in solution phase using stimuli-responsive protein-polymer conjugates. The protein-polymer conjugates comprise a target biomolecule-binding protein conjugated to a stimuli-responsive polymer and are reusable.