A modified transferrin DNA binding domain. The transferrin is lactotransferrin (LTF), serotransferrin (TF), melanotransferrin (MTF) or ovotransferrin (OTF), and the N terminal of each transferrin has one homologous DNA binding domain, wherein the 10.sup.th site and 20.sup.th site of the DNA binding domain are C; and the amino acid sequence of the modified transferrin DNA binding domain is as follows: C in the 10.sup.th site and 20.sup.th site is replaced by other amino acids so that no disulfide bond can be formed. The present invention also discloses a recombinant DNA polymerase and a preparation method thereof. The preparation method comprises the step of coupling the modified transferrin DNA binding domain with a DNA polymerase. The present invention also discloses a PCR test kit containing the recombinant DNA polymerase.

Provided herein are multifunctional heteromer proteins. In specific embodiments is a heteromultimer that comprises: at least two monomeric proteins, wherein each monomeric protein comprises at least one cargo polypeptide, attached to a transporter polypeptide, such that said monomeric proteins associate to form the heteromultimer. These therapeutically novel molecules comprise monomers that function as scaffolds for the conjugation or fusion of therapeutic molecular entities resulting in the creation of bispecific or multivalent molecular species.

Provided herein are multifunctional heteromer proteins. In specific embodiments is a heteromultimer that comprises: at least two monomeric proteins, wherein each monomeric protein comprises at least one cargo polypeptide, attached to a transporter polypeptide, such that said monomeric proteins associate to form the heteromultimer. These therapeutically novel molecules comprise monomers that function as scaffolds for the conjugation or fusion of therapeutic molecular entities resulting in the creation of bispecific or multivalent molecular species.

The disclosure describes a transgenic dicot or monocot plant having bovine milk protein(s) and methods of producing the transgenic dicot or monocot plant containing bovine milk protein(s). These transgenic dicot or monocot plants can express and produce bovine milk protein(s). The methods involve introducing a recombinant DNA construct expressing a bovine milk protein into a dicot or monocot plant, obtaining the dicot or monocot plant containing the bovine milk protein(s) from a recombinant DNA construct, cultivating and harvesting the transgenic dicot or monocot plant, and extracting and purifying the bovine milk protein(s) from transgenic dicot or monocotyledonous plants. The disclosure also describes food compositions comprising milk proteins produced using the transgenic dicot or monocot plants described herein.

The disclosure describes a transgenic dicot or monocot plant having bovine milk protein(s) and methods of producing the transgenic dicot or monocot plant containing bovine milk protein(s). These transgenic dicot or monocot plants can express and produce bovine milk protein(s). The methods involve introducing a recombinant DNA construct expressing a bovine milk protein into a dicot or monocot plant, obtaining the dicot or monocot plant containing the bovine milk protein(s) from a recombinant DNA construct, cultivating and harvesting the transgenic dicot or monocot plant, and extracting and purifying the bovine milk protein(s) from transgenic dicot or monocotyledonous plants. The disclosure also describes food compositions comprising milk proteins produced using the transgenic dicot or monocot plants described herein.

The present invention relates to extracellular vesicles (EVs) as a novel therapeutic approach to lysosomal storage disorders (LSD). More specifically, the invention relates to the use of various protein engineering strategies for improving loading of hard-to-load LSD-related proteins and targeting of the resultant EVs to tissues and organs of interest.

The present invention relates to extracellular vesicles (EVs) as a novel therapeutic approach to lysosomal storage disorders (LSD). More specifically, the invention relates to the use of various protein engineering strategies for improving loading of hard-to-load LSD-related proteins and targeting of the resultant EVs to tissues and organs of interest.

Provided are fragments of human p97 (melanotransferrin) polypeptides having blood-brain barrier (BBB) transport activity, including variants and combinations thereof, conjugates comprising the p97 fragments, and related methods of use thereof, for instance, to facilitate the delivery of therapeutic or diagnostic agents across the BBB and into the central nervous system.

Provided are fragments of human p97 (melanotransferrin) polypeptides having blood-brain barrier (BBB) transport activity, including variants and combinations thereof, conjugates comprising the p97 fragments, and related methods of use thereof, for instance, to facilitate the delivery of therapeutic or diagnostic agents across the BBB and into the central nervous system.

Provided herein are polypeptides that bind to a transferrin receptor, Fc dimers and fusion proteins comprising such polypeptides, and methods of using the polypeptides to target a composition to a transferrin receptor-expressing cell.