There are many methods that can be used to determine the infectious titer of your baculovirus stock. The TCID50 method is a simple end-point dilution method that determines the amount of baculovirus virus needed to produce a cytopathic effect or kill 50% of inoculated insect cells. Serial dilutions of baculovirus stock are added to Sf9 cells cultivated in 96-well plates and 3-5 days after infection, cells are monitored for cell death or cytopathic effect. The titer can then be calculated by the Reed-Muench method as described in this method.

Plaque assay method enables the quantification of infectious baculovirus when defined as plaque forming units (PFU). It allows to determine the amount of infectious virus needed to infect the cells at a specific multiplicity of infection (MOI). Serial dilutions of baculovirus stock are added to the Sf9 cells monolayer followed by addition of 5% Agarose overlay. Six days after infection clear infection halos are observed using a neutral red solution. Here we describe the quantification of recombinant baculovirus expression vector (rBEV) carrying a transgene in an rAAV expression cassette. Reproducible quantification of PFU is obtained with this method.

Purification of rAAV is a crucial unit operation of the AAV production process. It enables the capture of AAV and removal of contaminants such as host cell proteins, host cell DNA, and other cell culture-related impurities. Here we describe the purification of rAAV produced in insect cells Sf9/rBEV by immuno-affinity capture chromatography. The method is fully scale-amenable unlike other traditional purification methods based on ultracentrifugation. The method reported herein has two main steps: (1) the clarification of cell lysate by depth filtration and (2) the selective capture and single-step purification of AAV via immune-affinity chromatography. This purification method has been successfully implemented to purify the majority of wild-type AAV serotypes.

The insect cell-baculovirus expression vector (IC-BEV) platform has enabled small research-scale and large commercial-scale production of recombinant proteins and therapeutic biologics including recombinant adeno-associated virus (rAAV)-based gene delivery vectors. The wide use of this platform is comparable with other mammalian cell line-based platforms due to its simplicity, high-yield, comparable quality attributes, and robust bioprocessing features. In this chapter, we describe a rAAV production protocol employing one of the recent modifications of the One-Bac platform that consists of a stable transformed Sf9 cell line carrying AAV Rep2/Cap5 genes that are induced upon infection with a single recombinant baculovirus expression vector harboring the transgene of interest (rAAV genome). The overall protocol consists of essential steps including rBEV working stock preparation, rAAV production, and centrifugation-based clarification of cell culture lysate. The same protocol can also be applied for rAAV vector production using traditional Three-Bac, Two-Bac, and Mono-Bac platforms without requiring significant changes.

The Baculovirus Expression Vector System (BEVS) has revolutionized the field of recombinant protein expression by enabling efficient and high yield production. The platform offers many advantages including manufacturing speed, flexible design, and scalability. In this chapter, we describe the methods including strategies and considerations to successfully optimize and scale-up using BEVS as a tool for production (Fig. 1). As an illustrative case study, we present an example focused on the production of a viral glycoprotein.

The insect cell expression system has previously been proposed as the preferred biosecurity strategy for production of any vaccine, particularly for future influenza pandemic vaccines. The development and regulatory risk for new vaccine candidates is shortened as the platform is already in use for the manufacturing of the FDA-licensed seasonal recombinant influenza vaccine Flublok®. Large-scale production capacity is in place and could be used to produce other antigens as well. However, as demonstrated by the 2019 SARS-CoV-2 pandemic the insect cell expression system has limitations that need to be addressed to ensure that recombinant antigens will indeed play a role in combating future pandemics. The greatest challenge may be the ability to produce an adequate quantity of purified antigen in an accelerated manner. This review summarizes recent innovations in technology areas important for enhancing recombinant-protein production levels and shortening development timelines. Opportunities for increasing product concentrations through vector development, cell line engineering, or bioprocessing and for shortening timelines through standardization of manufacturing processes will be presented.

Tissue engineering is primarily associated with medical disciplines, and research has thus focused on mammalian cells. For applications where clinical relevance is not a constraint, it is useful to evaluate the potential of alternative cell sources to form tissues in vitro. Specifically, skeletal muscle tissue engineering for bioactuation and cultured foods could benefit from the incorporation of invertebrate cells because of their less stringent growth requirements and other versatile features. Here, we used a Drosophila muscle cell line to demonstrate the benefits of insect cells relative to those derived from vertebrates. The cells were adapted to serum-free media, transitioned between adherent and suspension cultures, and manipulated with hormones. Furthermore, we analyzed edible scaffolds to support cell adhesion and assayed cellular protein and minerals to evaluate nutrition potential. The insect muscle cells exhibited advantageous growth patterns and hold unique functionality for tissue engineering applications beyond the medical realm.

Insect cells have recently proven to be an excellent platform for the high-level production of functional recombinant proteins. Autophagy is an important mechanism that promotes cell survival by eliminating damaged organelles and protein aggregates, and it also may influence recombinant protein production. In the present study, we compared the effects that autophagy inducers rapamycin, everolimus, and lithium chloride exert on recombinant lepidopteran insect cells that secrete an engineered antibody molecule. Compared with nontreatment, treatment with either rapamycin or everolimus prolonged cell growth to allow high cell density, improved viability in the declining phase, and then increased the yield of secreted antibodies. These positive effects appeared to be induced via autophagy since autophagosomes were clearly detected, particularly in cells treated with rapamycin or everolimus. Unlike rapamycin, another autophagy inducer, FK506, was ineffective in insect cells. The addition of an appropriate autophagy inducer may be effective in increasing the productivity of recombinant proteins in insect cells.

Novel neuroactive insecticides are discovered/registered differently, have a lower value in use, and exert their physiological actions in manners distinct from neuroactive pharmaceuticals, but there are clear similarities in their biochemical modes of action. Insecticides are generally discovered using whole pest insect screens, and this eases difficulties in \'translational science\' from laboratory to field, as opposed to pharmaceutical translation from biochemical or cell-based targets to animal models to human clinical trials to registered drug. This paper examines recent trends in pharmaceutical science and identifies some technologies which may represent complementary approaches to insecticide discovery screening and mode of action determination beyond the sound processes in common practice today. Examples will be drawn from nanoparticle delivery of neuroactives, unique ligand-polymer conjugates, proposed advances in insect cell culture following from pharmaceutical cell biology, and laboratory or organ-on-a-chip approaches. It is hoped that these concepts will stimulate novel thinking which may enable discovery of efficacious new neuroactive insecticides. © 2020 Society of Chemical Industry.

Virus-like particles (VLPs) are hollow nanoparticles composed of recombinant viral surface proteins without a virus genome. In the present study, we investigated the production of influenza VLPs using recombinant insect cells. DNA fragments encoding influenza A virus hemagglutinin (HA) and matrix protein 1 (M1) were cloned with the Drosophila BiP signal sequence in plasmid vectors containing a blasticidin and a neomycin resistance gene, respectively. After Trichoplusia ni BTI-TN-5B1-4 (High Five) cells were co-transfected with a pair of constructed plasmid vectors, stably transformed cells were established via incubation with blasticidin and G418. Western blot analyses showed that recombinant High Five cells secreted HA and M1 proteins into the culture supernatant. Immunoprecipitation of the culture supernatant with an anti-HA antibody and transmission electron microscopy suggested that secreted HA and M1 proteins were in a particulate structure with a morphology similar to that of an influenza virus. Hemagglutination assay indicated that expressed HA molecules retained hemagglutination activity. In a shake-flask culture, recombinant cells achieved a high HA yield (≈ 10 μg/ml) comparable to the yields obtained using the baculovirus-insect cell system. Recombinant insect cells may serve as excellent platforms for the efficient production of influenza VLPs for use as safe and effective vaccines and diagnostic antigens.