The present disclosure provides a library of engineered DNASE proteins (including DNASE1, DNASE1-LIKE 1, DNASE1-LIKE 2, DNASE1-LIKE 3, DNASE2A, DNASE2B) that allows to select drug candidates for developing therapeutics for treating conditions characterized by neutrophil extracellular trap (NET) accumulation and/or release. In accordance with the invention, the selected DNase variant has improved properties, including properties amenable to clinical development, including manufacturing, toxicology, pharmacokinetic, and/or use in therapy.

The present invention provides an application of transthyretin serving as a carrier for a protein and/or polypeptide drug to enter an eye through an eye barrier. The transthyretin is a protein consisting of amino acid as shown in SEQ ID NO: 1 or a mutation thereof or a modification thereof. Further provided are an application of transthyretin and/or a fusion protein of the transthyretin and a drug in preparation of a drops, and a drops. The drug is a protein and/or polypeptide drug. The transthyretin has good biocompatibility and safety in human bodies, can effectively convey a foreign protein and/or polypeptide into the eye, and achieves an effect of treating eye diseases.

The present disclosure provides engineered human extracellular DNASE proteins (e.g., variants of DNASE1 (D1), DNASE1-LIKE 1 (D1L1), DNASE1-LIKE 2 (DTL2), DNASE1-LIKE 3 Isoform 1 (DTL3), DNASE1-LIKE 3 Isoform 2 (DTL3-2), DNASE2A (D2A), and DNASE2B (D2B)) that are useful for treating conditions characterized by neutrophil extracellular trap (NET) accumulation and/or release. In accordance with the invention, the DNase variant has advantages for therapy and/or large-scale manufacturing.

The present disclosure provides engineered human extracellular DNASE proteins (e.g., variants of DNASE1 (D1), DNASE1-LIKE 1 (D1L1), DNASE1-LIKE 2 (DTL2), DNASE1-LIKE 3 Isoform 1 (DTL3), DNASE1-LIKE 3 Isoform 2 (DTL3-2), DNASE2A (D2A), and DNASE2B (D2B)) that are useful for treating conditions characterized by neutrophil extracellular trap (NET) accumulation and/or release. In accordance with the invention, the DNase variant has advantages for therapy and/or large-scale manufacturing.

Compositions of the inventive concept provide a therapeutic protein with less than 2% contamination by the therapeutic protein in denatured form. Such compositions provide enhanced specific activity and improved stability on storage and/or in serum than corresponding therapeutic protein preparations resulting from conventional isolation methods.

Compositions of the inventive concept provide a therapeutic protein with less than 2% contamination by the therapeutic protein in denatured form. Such compositions provide enhanced specific activity and improved stability on storage and/or in serum than corresponding therapeutic protein preparations resulting from conventional isolation methods.

Provided are ulinastatin glycoforms, ulinastatin fusion polypeptides, and related compositions, mixtures, and methods of use, including methods of recombinantly producing ulinastatin polypeptides and treating diseases.

Provided are ulinastatin glycoforms, ulinastatin fusion polypeptides, and related compositions, mixtures, and methods of use, including methods of recombinantly producing ulinastatin polypeptides and treating diseases.

The present invention provides a conjugate comprising an albumin binding peptide and a cargo, compositions for directing cargos to the lymphatic system, and vaccines. The methods of the invention can be used to increase an immune response, or to treat cancer or an infectious disease.

The present invention provides a conjugate comprising an albumin binding peptide and a cargo, compositions for directing cargos to the lymphatic system, and vaccines. The methods of the invention can be used to increase an immune response, or to treat cancer or an infectious disease.