The present invention relates to fibronectin-based scaffold domain proteins that bind to myostatin. The invention also relates to the use of these proteins in therapeutic applications to treat muscular dystrophy, cachexia, sarcopenia, osteoarthritis, osteoporosis, diabetes, obesity, COPD, chronic kidney disease, heart failure, myocardial infarction, and fibrosis. The invention further relates to cells comprising such proteins, polynucleotides encoding such proteins or fragments thereof, and to vectors comprising the polynucleotides encoding the proteins.

A compound for the sequestration of undesirable antibodies associated with hemophilia A, in particular when treated by factor VIII replacement therapy. The compound includes a biopolymer scaffold and at least two peptides derived from factor VIII with a sequence length of 6-13 amino acid, wherein each of the peptides independently includes a 6-amino-acid fragment of the amino-acid sequence of factor VIII, optionally wherein at most three, preferably at most two, more preferably at most one amino acid is independently substituted by any other amino acid. Also provided are pharmaceutical compositions including the compound, as well as methods for treating hemophilia A.

Protein double-shell nanostructures comprising apoferritin for carrying cargo proteins of interest are provided. Such nanostructures can be used to increase rigidity of a cargo protein of interest to allow structures of small and flexible proteins to be determined by cryogenic-electron microscopy (cryo-EM). Recombinant vectors for producing protein double-shell nanostructures are also provided. The nanostructures described herein may find use in various applications in research and drug discovery.

Protein double-shell nanostructures comprising apoferritin for carrying cargo proteins of interest are provided. Such nanostructures can be used to increase rigidity of a cargo protein of interest to allow structures of small and flexible proteins to be determined by cryogenic-electron microscopy (cryo-EM). Recombinant vectors for producing protein double-shell nanostructures are also provided. The nanostructures described herein may find use in various applications in research and drug discovery.

The present disclosure relates to methods of making of one or more bioengineered ferritin proteins having a preselected ratio of H-subunits (ferritin heavy chain (FTH or H)) to L-subunits (ferritin light chain (FTL or L)). The disclosure further relates to cDNAs, vectors, and host cells for forming the bioengineered ferritin proteins of the present disclosure.

The present disclosure relates to methods of making of one or more bioengineered ferritin proteins having a preselected ratio of H-subunits (ferritin heavy chain (FTH or H)) to L-subunits (ferritin light chain (FTL or L)). The disclosure further relates to cDNAs, vectors, and host cells for forming the bioengineered ferritin proteins of the present disclosure.

The present disclosure provides methods of modulating an immune response in an individual. The present disclosure provides methods of treatment. The present disclosure provides methods comprising administering a multimeric polypeptide (synTac) and an immune checkpoint inhibitor to an individual. The present disclosure provides methods comprising administering a multimeric polypeptide (synTac) to an individual who is undergoing treatment with immune checkpoint inhibitor.

The present disclosure provides methods of modulating an immune response in an individual. The present disclosure provides methods of treatment. The present disclosure provides methods comprising administering a multimeric polypeptide (synTac) and an immune checkpoint inhibitor to an individual. The present disclosure provides methods comprising administering a multimeric polypeptide (synTac) to an individual who is undergoing treatment with immune checkpoint inhibitor.

The present invention relates to a ferritin nanocage fused with PD-L1-binding peptide 1 and a use thereof as an anticancer immunotherapy agent. Prepared in the present invention were nanocages that are formed by fusing a human ferritin monomer with a peptide 1 (PD-L1pep1: CLQKTPKQC (SEQ ID NO: 2)) binding to the immune checkpoint receptor PD-L1 overexpressed in many cancers such as breast cancer, colorectal cancer, renal cancer, glioblastoma, etc. and which display 24 Pd-L1prep1.

The present invention relates to a ferritin nanocage fused with PD-L1-binding peptide 1 and a use thereof as an anticancer immunotherapy agent. Prepared in the present invention were nanocages that are formed by fusing a human ferritin monomer with a peptide 1 (PD-L1pep1: CLQKTPKQC (SEQ ID NO: 2)) binding to the immune checkpoint receptor PD-L1 overexpressed in many cancers such as breast cancer, colorectal cancer, renal cancer, glioblastoma, etc. and which display 24 Pd-L1prep1.