A PSMA-targeted bispecific antibody for prostate cancer driven by a small-molecule targeting ligand.

Despite the development of next-generation antiandrogens, metastatic castration-resistant prostate cancer (mCRPC) remains incurable. Here, we describe a unique semisynthetic bispecific antibody that uses site-specific unnatural amino acid conjugation to combine the potency of a T cell-recruiting anti-CD3 antibody with the specificity of an imaging ligand (DUPA) for prostate-specific membrane antigen. This format enabled optimization of structure and function to produce a candidate (CCW702) with specific, potent in vitro cytotoxicity and improved stability compared with a bispecific single-chain variable fragment format. In vivo, CCW702 eliminated C4-2 xenografts with as few as three weekly subcutaneous doses and prevented growth of PCSD1 patient-derived xenograft tumors in mice. In cynomolgus monkeys, CCW702 was well tolerated up to 34.1 mg/kg per dose, with near-complete subcutaneous bioavailability and a PK profile supporting testing of a weekly dosing regimen in patients. CCW702 is being evaluated in a first in-human clinical trial for men with mCRPC who had progressed on prior therapies (NCT04077021).

Capillary electrophoresis in the analysis and monitoring of biotechnological processes.

Capillary electrophoresis (CE) became a versatile technique for analysis of biological macromolecules. We have applied capillary zone electrophoresis (CZE) and SDS-gel CE for the characterization of recombinant proteins during development of major bioprocessing steps, including fermentation, hybridoma cell cultivation, chromatographic purification, and chemical transformation. Rapid SDS-gel CE was developed for the fast analysis of fermentation broth and hybridoma cell culture. The total analysis time was reduced to 4.5 min. We have developed system for fraction collection, which allows analyzing separated proteins by MALDI-TOF-MS. The main advantages of applied techniques were high resolution and selectivity, fast analysis, and high accuracy.

Protein crystallization: from HTS to kilogram-scale.

The first experiments on protein crystallization started randomly during the 19th century. This technique has been widely used for the determination of the tertiary structure of proteins since the 1950s, when an understanding of the physics of protein crystallization began to emerge. In the 1980s and 1990s, research focused on the study of protein crystal growth processes in microgravity environments, which were created in space shuttle experiments. High-throughput screening (HTS) systems were developed that later found broader laboratory applications. The combination of HTS with an engineering approach opens new opportunities for the protein crystallization process to become a robust, scalable, reproducible and economically viable industrial unit operation.

Recombinant human insulin IX. Investigation of factors, influencing the folding of fusion protein-S-sulfonates, biotechnological precursors of human insulin.

The peculiarities of molecular structures and the influence of reaction conditions on the folding efficiency of fusion proteins-biotechnological precursors of human insulin, expressed in Escherichia coli as inclusion bodies have been investigated. The fusion proteins contained proinsulin sequence with various leader peptides connected by an Arg residue to the insulin B-chain. The kind and the size of leader peptide do not have essential influence on folding efficiency. However, the efficiency of protein folding depends on the location of the (His)6 site, which is used for metal-chelating affinity chromatography. In our study the protein folding depends on the reaction medium composition (including additives), the presence of accompanied cell components, pH, temperature, concentrations of protein, and redox agents. A negative influence of nucleic acid and heavy metal ions on folding has been found. S-sulfonated fusion protein has proinsulin-like secondary structure (by CD-spectroscopy data) that is the key point for 95% efficient folding proceeding. Folded fusion proteins are transformed into insulin by enzymatic cleavage.

Methods for preparation of recombinant cytokine proteins V. mutant analogues of human interferon-gamma with higher stability and activity.

Mutant analogues of recombinant human immune interferon (IFN-gamma) with higher stability and biological activity were prepared. Depending on the analogue, protein structure modification might involve introduction of an intramonomer disulfide bond (through replacements of Glu7Cys and Ser69Cys), C-terminal shortening by 10 amino acid residues, as well as Gln133Leu substitution in truncated variant. Isolation, purification, and renaturation of the IFN-gamma analogues expressed in Escherichia coli as inclusion bodies were performed according to the scheme developed earlier for wild-type protein. The main idea of this scheme is to remove cellular impurities before recombinant protein renaturation. Folding kinetics of IFN-gamma was studied by reversed-phase HPLC. IFN-gamma and mutant proteins were characterized by their thermal stability and biological activity. Introduction of the intramolecular disulfide bond together with C-terminal shortening and replacement of C-terminal residue was shown to result in increasing the thermal stability by 19 degrees C and four times enhancement of biological activity compared with intact IFN-gamma molecule.