Reshaping cell line development and CMC strategy for fast responses to pandemic outbreak.

The global pandemic outbreak COVID-19 (SARS-COV-2), has prompted many pharmaceutical companies to develop vaccines and therapeutic biologics for its prevention and treatment. Most of the therapeutic biologics are common human IgG antibodies, which were identified by next-generation sequencing (NGS) with the B cells from the convalescent patients. To fight against pandemic outbreaks like COVID-19, biologics development strategies need to be optimized to speed up the timeline. Since the advent of therapeutic biologics, strategies of transfection and cell line selection have been continuously improved for greater productivity and efficiency. NGS has also been implemented for accelerated cell bank testing. These recent advances enable us to rethink and reshape the chemistry, manufacturing, and controls (CMC) strategy in order to start supplying Good Manufacturing Practices (GMP) materials for clinical trials as soon as possible. We elucidated an accelerated CMC workflow for biologics, including using GMP-compliant pool materials for phase I clinical trials, selecting the final clone with product quality similar to that of phase I materials for late-stage development and commercial production.

Two doses of sclerostin antibody in cynomolgus monkeys increases bone formation, bone mineral density, and bone strength.

The development of bone-rebuilding anabolic agents for treating bone-related conditions has been a long-standing goal. Genetic studies in humans and mice have shown that the secreted protein sclerostin is a key negative regulator of bone formation. More recently, administration of sclerostin-neutralizing monoclonal antibodies in rodent studies has shown that pharmacologic inhibition of sclerostin results in increased bone formation, bone mass, and bone strength. To explore the effects of sclerostin inhibition in primates, we administered a humanized sclerostin-neutralizing monoclonal antibody (Scl-AbIV) to gonad-intact female cynomolgus monkeys. Two once-monthly subcutaneous injections of Scl-AbIV were administered at three dose levels (3, 10, and 30 mg/kg), with study termination at 2 months. Scl-AbIV treatment had clear anabolic effects, with marked dose-dependent increases in bone formation on trabecular, periosteal, endocortical, and intracortical surfaces. Bone densitometry showed that the increases in bone formation with Scl-AbIV treatment resulted in significant increases in bone mineral content (BMC) and/or bone mineral density (BMD) at several skeletal sites (ie, femoral neck, radial metaphysis, and tibial metaphysis). These increases, expressed as percent changes from baseline were 11 to 29 percentage points higher than those found in the vehicle-treated group. Additionally, significant increases in trabecular thickness and bone strength were found at the lumbar vertebrae in the highest-dose group. Taken together, the marked bone-building effects achieved in this short-term monkey study suggest that sclerostin inhibition represents a promising new therapeutic approach for medical conditions where increases in bone formation might be desirable, such as in fracture healing and osteoporosis.

Divergence of Genbank and human tumor Bcl-2 sequences and implications for binding affinity to key apoptotic proteins.

Heterodimerization of antiapoptotic and pro-apoptotic Bcl-2 family of proteins provides an important mechanism for apoptosis regulation. Knowledge about key amino acids in the binding groove of native Bcl-2 contributing to this interaction will greatly facilitate the design of Bcl-2-specific inhibitors. There are two different Bcl-2 sequences, M13994 and M14745, in Genbank. Chimeric proteins Bcl-2(1) and Bcl-2(2) derived from the above sequences, although similar in structure, showed different binding affinities to Bak and Bad BH3 peptides (Petros et al., 2001). In this study, we show that the Bcl-2(1) sequence in normal and tumor human tissue samples differs from M13994 and M14745, and contains P59, T96, R110, S117 and G237. The actual sequence in the binding pocket matches the Bcl-2-Ig fusion sequence X06487, originally identified in a t(14:18) translocation of the Bcl-2 gene, associated with follicular lymphoma. The possible effects of the observed amino acid differences compared to M13994 and M14745 were investigated by combining structural data with fluorescence anisotropy. G110R substitution confers on Bcl-2(1) substantially increased binding affinity to Bak, Bad and Bax BH3 peptides, demonstrating that R110 is a key contributor to the BH3 binding affinity of Bcl-2. Although NMR structure did not predict R110 involvement in binding to these BH3 peptides, fluorescence anisotropy data clearly points to a critical role for this residue in binding to pro-apoptotic Bcl-2 family members.