Accelerating the speed of innovative anti-tumor drugs to first-in-human trials incorporating key de-risk strategies.

Pharmaceutical companies have recently focused on accelerating the timeline for initiating first-in-human (FIH) trials to allow quick assessment of biologic drugs. For example, a stable cell pool can be used to produce materials for the toxicology (Tox) study, reducing time to the clinic by 4-5 months. During the coronavirus disease 2019 (COVID-19) pandemic, the anti-COVID drugs timeline from DNA transfection to the clinical stage was decreased to 6 months using a stable pool to generate a clinical drug substrate (DS) with limited stability, virus clearance, and Tox study package. However, a lean chemistry, manufacturing, and controls (CMC) package raises safety and comparability risks and may leave extra work in the late-stage development and commercialization phase. In addition, whether these accelerated COVID-19 drug development strategies can be applied to non-COVID projects and established as a standard practice in biologics development is uncertain. Here, we present a case study of a novel anti-tumor drug in which application of "fast-to-FIH" approaches in combination with BeiGene's de-risk strategy achieved successful delivery of a complete CMC package within 10 months. A comprehensive comparability study demonstrated that the DS generated from a stable pool and a single-cell-derived master cell bank were highly comparable with regards to process performance, product quality, and potency. This accomplishment can be a blueprint for non-COVID drug programs that approach the pace of drug development during the pandemic, with no adverse impact on the safety, quality, and late-stage development of biologics.

A functional motif QLYxxYP is essential for osteopontin induced T lymphocyte activation and migration.

Osteopontin (OPN) plays an important role in regulating lymphocyte adhesion and cytokine production associated with inflammatory processes and autoimmune diseases. Here we developed and characterized a monoclonal antibody F8E11 specific for human OPN (hOPN). F8E11 could inhibit OPN-induced lymphocyte activation and migration. Epitope mapping showed that F8E11 could specifically recognize the peptide QLYxxYP. In addition, a synthesized mimetic peptide F8P (EEKQLYNKYPDA) could block the binding of F8E11 to hOPN and significantly inhibit the hOPN-induced lymphocyte migration. Moreover, mutations on the QLYxxYP motif of hOPN also markedly diminished its activity for lymphocyte activation and migration. The functioning assay indicated that this novel epitope is critically involved in the lymphocyte migration through activating MAPK/ERK/AP-1 pathway, which can be inhibited by the motif QLYxxYP blocking antibody, F8E11. These results suggest that this novel epitope of OPN may provide a potential therapeutic target for the treatment of T cell mediated-immune diseases.