Process development of a SARS-CoV-2 nanoparticle vaccine.

One of the outcomes from the global COVID-19 pandemic caused by SARS-CoV-2 has been an acceleration of development timelines to provide treatments in a timely manner. For example, it has recently been demonstrated that the development of monoclonal antibody therapeutics from vector construction to IND submission can be achieved in five to six months rather than the traditional ten-to-twelve-month timeline using CHO cells [1], [2]. This timeline is predicated on leveraging existing, robust platforms for upstream and downstream processes, analytical methods, and formulation.

Perfusion CHO cell culture applied to lower aggregation and increase volumetric productivity for a bispecific recombinant protein.

Secreted recombinant proteins can aggregate during cell culture. We studied a poorly-behaved bispecific scaffold that increasingly aggregated (up to 62% high molecular weight species, HMW) as a function of culture time in a fed-batch and intensified cell culture processes. We identified that protein aggregates increased with accumulated protein concentration inside the bioreactor.

A novel mammalian cell line development platform utilizing nanofluidics and optoelectro positioning technology.

Generating a highly productive cell line is resource intensive and typically involves long timelines because of the need to screen large numbers of candidates in protein production studies. This has led to miniaturization and automation strategies to allow for reductions in resources and higher throughput. Current approaches rely on the use of standard cell culture vessels and bulky liquid handling equipment.

Characterization of phenotypic and genotypic diversity in subclones derived from a clonal cell line.

Regulatory guidelines require the sponsors to provide assurance of clonality of the production cell line, and when such evidence is not available, additional studies are typically required to further ensure consistent long-term manufacturing of the product. One potential approach to provide such assurance of clonal derivation of a production cell line is to characterize subclones generated from the original cell line and assess their phenotypic and genotypic similarity with the hypothesis that cell lines derived from a clonal bank will share performance, productivity and product quality characteristics. In this study, a production cell line that was cloned by a validated FACS approach coupled with day 0 imaging for verification of single-cell deposition was subcloned using validated FACS and imaging methods.

Analysis of Tubespins as a suitable scale-down model of bioreactors for high cell density CHO cell culture.

High cell density (HCD) culture increases recombinant protein productivity via higher biomass. Compared to traditional fed-batch cultures, HCD is achieved by increased nutrient availability and removal of undesired metabolic components via regular medium replenishment. HCD process development is usually performed in instrumented lab-scale bioreactors (BR) that require time and labor for setup and operation.

Targeted codon optimization improves translational fidelity for an Fc fusion protein.

High levels of translational errors, both truncation and misincorporation in an Fc-fusion protein were observed. Here, we demonstrate the impact of several commercially available codon optimization services, and compare to a targeted strategy. Using the targeted strategy, only codons known to have translational errors are modified.

Isolation of a human single chain antibody fragment against oligomeric alpha-synuclein that inhibits aggregation and prevents alpha-synuclein-induced toxicity.

Protein misfolding and aggregation are pathological aspects of numerous neurodegenerative diseases. Aggregates of alpha-synuclein are major components of the Lewy bodies and Lewy neurites associated with Parkinson's Disease (PD). A natively unfolded protein, alpha-synuclein can adopt different aggregated morphologies, including oligomers, protofibrils and fibrils.

Isolating recombinant antibodies against specific protein morphologies using atomic force microscopy and phage display technologies.

Isolation of antibodies to antigens that are either unstable, exist in multiple morphologies or have very limited availability can be prohibitively difficult. Here we describe a novel technique combining the capabilities of phage display antibody technology and atomic force microscopy (AFM) that is used to isolate antibody fragments that bind to a specific morphology of the target antigen, alpha-synuclein. AFM imaging allows us to both visualize the presence and morphology of the target antigen as well as to monitor the efficiency of each step in the bio-panning process.

Trehalose differentially inhibits aggregation and neurotoxicity of beta-amyloid 40 and 42.

A key event in Alzheimer's disease (AD) pathogenesis is the conversion of the peptide beta-amyloid (Abeta) from its soluble monomeric form into various aggregated morphologies in the brain. Preventing aggregation of Abeta is being actively pursued as a primary therapeutic strategy for treating AD. Trehalose, a simple disaccharide, has been shown to be effective in preventing the deactivation of numerous proteins and in protecting cells against stress.