Provided herein are binding proteins recognizing HPV16 E7 antigen and uses thereof.

An scFv-Fc dimer binds and neutralizes TGFβ1 selectively and with high affinity and avidity. The scFv region may comprise the same VH and VL domains or CDR regions as metelimumab. The unique combination of their smaller size, high selectivity, potency against TGFβ1, and long in vivo half-life makes the scFv-Fc dimers ideal candidates for therapeutic applications.

Erythrocyte-binding moieties coupled to tolerizing antigens are described. Provided for are peptidic ligands having sequences that specifically bind, or as antibodies or fragments thereof that provide specific binding, to erythrocytes. The erythrocyte-binding moieties may be prepared as molecular fusions with therapeutic agents, tolerizing antigens, or targeting peptides. Immunotolerance may be created by use of the fusions and choice of an antigen on a substance for which tolerance is desired.

The present invention is based, in part, on the discovery and characterization of the CD-NTase family of proteins, as well as compositions comprising CD-NTases, methods of producing nucleotide-based second messengers using such polypeptides, and methods of screening for modulators of the structure, expression, and/or activity of such polypeptides.

Provided is a gRNA targeting HPK1 and a method for editing HPK1 gene. The method can knock out the T cell HPK1 gene, enhance the T cell killing activity, increase the Th1 cytokine level of peripheral blood mononuclear cells, and knock out of the T cell HPK1 gene can also down-regulate the expression of PD-1 and TIM3 on the T cell surface and can inhibit the T cell depletion.

In one aspect, the present invention is directed to a method for preventing or treating necrotic enteritis by administering a hyperimmunized egg product obtained from an egg-producing animal to an avian. The hyperimmunized egg product may contain an antibody specific to an antigen selected from the group consisting of Clostridium perfringens α-toxin, Clostridium perfringens elongation factor Tu (EF-Tu), Clostridium perfringens necrotic enteritis B-like (NetB) toxin, Clostridium perfringens Pyruvate: Ferredoxin oxidoreductase (PFO), and Eimeria tenella elongation factor 1-alpha.

Described are a genetically modified microorganism and corresponding methods and products. The genetically modified microorganism may include a first gene that encodes an acyl transferase and a second gene that encodes a peptide or protein. One or both of the first and second gene may be heterologous. The genetically modified microorganism may include a modified acyl-CoA biosynthetic pathway configured for one or more of: inducible biosynthesis of an acyl-CoA and over-accumulation of the acyl-CoA. The genetically modified microorganism may be effective upon fermentation to cause acylation of the peptide or protein by the acyl transferase using the acyl-CoA to provide a N-acylated peptide or protein product.

The present invention provides a linear multimeric biomolecule polymer wherein a biomolecule is bonded to a polyubiquitin scaffold formed of two or more covalently bonded ubiquitins, by obtaining, from a host cell, a biomolecule bonded with a ubiquitin C-terminal tag through recombinant expression, and polyubiquitinating the biomolecule in vitro in the presence of proteins involved in ubiquitination, E1 (activation enzyme), E2 (conjugation enzyme), and E3 (ligase), and a substrate. The polymer according to the present invention may be used in the separation and purification of a biomolecule, the separation of a target material that binds to the biomolecule, etc.

The present disclosure concerns agents and their use in the treatment of endocrine, nutritional and/or metabolic diseases in a mammal. The disclosure furthermore concerns novel peptide fragments.

Described are a genetically modified microorganism and corresponding methods and products. The genetically modified microorganism may include a first gene that encodes an acyl transferase and a second gene that encodes a peptide or protein. One or both of the first and second gene may be heterologous. The genetically modified microorganism may include a modified acyl-CoA biosynthetic pathway configured for one or more of: inducible biosynthesis of an acyl-CoA and over-accumulation of the acyl-CoA. The genetically modified microorganism may be effective upon fermentation to cause acylation of the peptide or protein by the acyl transferase using the acyl-CoA to provide a N-acylated peptide or protein product.