Abstract
Recombinant adenoviral (Ad) vectors are highly efficient gene transfer vectors widely used in vaccine development and immunotherapy. To promote the industrial application of Ad vectors, studies focusing on reducing the cost of manufacturing, shortening the preclinical research period, and improving the quality of products are needed. Here, we describe a highly efficient and economical process for producing Ad vector in a novel, single-use bioreactor system suitable for clinical trials. A mini-bioreactor was used for parameter optimization and development of medium replacement protocols for Ad5-GFP production before scale-up. HEK293 cell culture and virus infection were monitored in a disposable AmProtein Current Perfusion Bioreactor and Bioflo310 bioreactor using optimized parameters and medium replacement protocols. The total cell number increased from 2.0 × 109 to 3.2 × 1010 after 6 days of culture. The total number of viral particles obtained in a single batch was 1.2 × 1015. These results demonstrate the efficiency and suitability of this system for Ad vector production for research and GMP applications.
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Introduction
Recombinant adenovirus (Ad) vectors are highly efficient gene transfer vectors widely used in vaccine development and immunotherapy. Gendicine, an Ad-based gene therapy that delivers wild-type p53 for the treatment of head and neck squamous cell carcinoma, was the first Ad-based therapy approved by the State Food and Drug Administration (SFDA) in China (Guan et al. 2006; Zhang et al. 2018). The application of Ad vectors continues to expand worldwide due to several advantages over other vectors, including ease of vector construction, efficiency of the manufacturing process, and high vector stability (Lusky 2005; Sharon and Kamen 2018). To promote the industrial application of Ad vectors, future studies should focus on reducing the cost of manufacturing, shortening the preclinical research period, and improving product quality.
The HEK293 cell line is widely used to produce Ad vectors. There are several culture systems available for manufacturing including roller bottles, cell factories, cell cubes, and bioreactors (Kamen and Henry 2004; Lusky 2005). Of these systems, bioreactors hold many advantages over the others. AmProtein (Hangzhou, China) has developed a novel disposable bioreactor system that includes a miniature bioreactor for parameter evaluation before scale-up to a disposable perfusion bioreactor (AmProtein Current Perfusion Bioreactor [ACPB]) (Sun et al. 2013; Hui 2007; Qian et al. 2008; Li et al. 2009).
This bioreactor system provides good nutrient distribution and excellent oxygen transfer without gas bubbles and shearing forces, and is especially suitable for anchorage-dependent cell culture and virus production.
The production of Ad vectors in bioreactors has been extensively studied. Most research has focused on physicochemical operating conditions, including important parameters such as pH, dissolved oxygen (DO) concentration, multiplicity of infection (MOI), temperature, and medium replacement strategies (Iyer et al. 1999; Jardon and Garnier 2003; Liu et al. 2009; Schoofs et al. 1998; Shen et al. 2012; Singh 1999; Sun et al. 2013; Hui 2007; Qian et al. 2008). The key to establishing a highly efficient productive system for Ad vectors is a detailed understanding of Ad biology, including the kinetics of replication in HEK293 cells and characteristics of cell metabolism during infection.
In this study, we describe a rapid process for Ad vector production from HEK293 cells cultured in a disposable bioreactor system. We also describe optimal parameters for Ad vector production. The purpose of this study is to reduce the duration of preclinical research and the cost of manufacturing for clinical trials and applications under good manufacturing practice (GMP) conditions.
Material and methods
Cell lines and Ad vector
HEK293 cells were purchased from American Type Culture Collection (ATCC; CL-1573) and cultured at 37 °C, 5% CO2 in Dulbecco’s Modified Eagle’s medium (DMEM; Gibco, USA) supplemented with 10% fetal bovine serum (FBS; Gibco, USA) and 3.0 g/L NaHCO3. The Ad.MAX™ system (SignaGen Laboratories Inc., USA) was used to generate a ΔE1/ΔE3 Ad5 vector expressing green fluorescence protein (GFP) under the control of the CMV promoter (Ad5-GFP) (Cote et al. 1997). We performed plaque purification to obtain clonal Ad (Green and Wold 1979). In brief, the viral stocks (102, 103, 104, 105 IU/mL) in 0.2 mL were applied to HEK293 cells grown in 6-well plate (Corning, USA). After 2 h post-infection at 37 °C, the inocula were removed and the plaque assays were performed using an agar overlay on HEK293 cells. Seventy-two hours post-infection, well-separated virus plaque was picked with sterile pipette. The agar plugs were transferred to microfuge tubes containing 0.5 mL DMEM. We picked five plaques and selected one plaque as the pre-master virus seed for further amplification. The remaining stocks were stored at − 70 °C.
The cells often grow inside the carrier, not on the surface (Fig. 1d). Trypsin (Gibco, USA) digestion can easily detach the cells for scale up seeding without damage to the cells’ viability. In brief, we washed the cell carrier contained in the mini-bioreactor and removed the cells by trypsinization (37 °C, 10 min). We routinely removed 85% cells into the medium. A master cell bank (8 × 106 cells/mL, 1.5 mL/vial, 143 vials) and working cell bank (6.5 × 106 cells/mL, 1.5 mL/vial, 303 vials) were generated by passage and propagation of HEK293 cells from T75 flasks to the mini-bioreactor (Table 1).
Mini-bioreactor culture of HEK293 cells
The mini-bioreactor system (AmProtein Inc., China) contains a self-rotating incubator and a 100-mL vessel packed with 0.6 g of polymer fiber carrier (Fig. 1). The available area for cell growth in 0.6 g of polymer fiber carrier is 960 cm2. Different densities of HEK293 cells (0.3 × 107, 0.6 × 107, 0.9 × 107, 1.2 × 107) were seeded in the mini-bioreactors and incubated in the self-rotating incubator (37 °C, 5% CO2, 45 rpm) to determine the optimal cell density for infection. Each cell density was tested in triplicate. The medium was changed at 24-h intervals. The concentration of glucose in the medium was assessed at 24-h intervals using a glucose assay kit (Sigma, USA). Cells were counted by crystal violet staining. The relationship between cell density and glucose consumption rate (GCR) was analyzed.
Optimization of viral yield in the mini-bioreactor
To determine the effect of MOI on Ad vector yields in this system, HEK293 cells cultured in mini-bioreactor vessels were infected with Ad vectors at different MOIs (MOI = 1, 10, 20, or 50). To determine the effect of temperature on Ad vector production, HEK293 cells cultured in mini-bioreactor vessels were infected with Ad vectors (MOI = 20) at different temperatures (32, 33, 34, 35, 36, or 37 °C). The cell-free supernatants were removed at 24-h intervals. Intracellular virus samples were collected at 96 h post-infection (hpi). Cells underwent three freeze-thaw cycles followed by centrifugation at 700×g for 5 min. Supernatants were stored at − 70 °C. The infectious viral particle units (IU) and total viral particles (VP) were measured.
In order to develop the most suitable medium supplementation scheme allowing for the earlier release of viral particles to the supernatant, we designed four different protocols for post-infection medium supplementation in mini-bioreactors. Lactalbumin hydrolysate (LH, GIBCO, Life Technologies, USA) was used as the medium supplement.
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Protocol 1 (P1): Inoculate Ad in DMEM and incubate for 2 h, then supplement with 10% FBS, and change the medium at 24-h intervals. Harvest supernatants from 48 to 96 hpi at 24-h intervals.
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Protocol 2 (P2): Inoculate Ad in DMEM for 2 h, then supplement with glucose (2 g/L), and change the medium at 24-h intervals. Harvest supernatants from 48 to 96 hpi at 24-h intervals.
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Protocol 3 (P3): Inoculate Ad in DMEM for 2 h, then supplement with 10% FBS, incubate for 24 h, and then replace the medium with DMEM supplemented with glucose (2 g/L) at 24-h intervals. Harvest supernatants from 48 to 96 hpi at 24-h intervals.
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Protocol 4 (P4): Inoculate Ad in DMEM for 2 h, then supplement with 10% FBS, incubate for 24 h, and then replace the medium with DMEM supplemented with different concentrations of LH (0.1, 0.25, 0.5, 1% [w/v]) and glucose (2 g/L) at 24-h intervals. Harvest supernatants from 48 to 96 hpi at 24-h intervals.
Each protocol was tested in triplicate, and the viral titers in the harvested supernatants determined. HiVeg™ peptone (HiMedia Lab, India) was also tested, but the results were not worth pursuing (data not shown).
Analysis of Ad vector
IUs produced from the Ad vector were detected by rapid TCID50 assay [19] using a QuickTiter™ Adenovirus Titer Immunoassay Kit (Cell BioLabs, USA). Briefly, HEK293 cells were seeded at a density of 4 × 104 cells/100 μL onto 96-well plates. A series of 1:10 vector dilutions (105–1012) was added to each of 10 replicate wells for each dilution. The supernatant was discarded at 4 days post-infection, and the monolayers were fixed with 75% acetone. The cell monolayers were then incubated with anti-hexon mAb for 1 h at 37 °C, followed by a goat anti-mouse horseradish peroxidase conjugated secondary antibody for 1 h at 37 °C. Positive cells were counted and viral titers calculated.
Total viral particle (VP) determination was performed by a quick, high-performance liquid chromatography (HPLC) method as described by Whitfield et al. (2009). In brief, supernatants were filtered through a 0.45-μm filter. An aliquot of the filtered supernatant was then analyzed on a Dionex DX500 Chromatography System (Dionex Corp., Sunnyvale, CA) using an anion exchange Bio-Monolith QA HPLC column (Agilent technologies; Santa Clara, CA). Analysis of UV data was performed using Chromeleon 6.80 (Dionex) and PeakSimple 3.85 (SRI Instruments, Torrance, CA).
Virus production in ACPB and NBS-Bioflo310 bioreactors
The ACPB system is a disposable bioreactor developed by Amprotein based on the world patent (Hui 2007). An illustration of the ACPB system is shown in Fig. 2. Phosphate-buffered saline (PBS; 10 mM, 6 L) was pumped into the disposable perfusion column (with 150 g polymer fiber carriers) and plastic bioreactor bag overnight, and then was replaced by 5 L DMEM. A total of 2.25 × 109 cells from 20 mini-bioreactors (0.9 × 108 cells × 150 g/0.6 g = 2.25 × 109) were transferred into the perfusion column by feed bottle and incubated for 2 h without rocking. The physical parameters were set on the ACPB prior to rocking (temperature 37 °C; rocking rate 50 rpm; pH 7.2–7.4; DO 50%–70%; circulation rate 150 mL/min). The 5-L medium was replaced at 24-h intervals, and the glucose levels were consistently maintained above 1.2 mg/mL. After 5 days of culture, the cells were removed with polymer fiber carriers and divided into six parts. The concentration of the six parts and the total number of cells were determined using crystal violet staining (Fig. 3a).
Ad5 vector propagation
After 5 days of culture, the ACPB was washed twice with PBS. Ad vector (MOI = 20) in 4 L fresh DMEM without FBS was pumped into the perfusion column and incubated for 2 h, and an additional 5 L DMEM was pumped into the plastic bioreactor bag. The operating conditions for Ad vector propagation were set based on the results of the mini-bioreactor cultures: temperature of 33 °C, vibrating rate of 50 rpm, pH of 7.2–7.4, and DO of 55%. The circulation rate was maintained at 120 mL/min. During the process, 5 L of the supernatant was harvested at 48 and 72 hpi and the remaining 10 L was harvested at 96 hpi, for 20 L in total. The media was replaced with 5 L PBS, and the infected cells remaining on the polymer fiber carrier were subjected to three free-thaw cycles.
Bioflo310 is a bioreactor similar to ACPB that uses nonwoven polymer fiber paper as a cell carrier. It differs from ACPB in its structure (non-disposable) and operating procedures. During virus production, 4.5 L of medium was changed at 24-h intervals. The 4.5-L supernatants were harvested at 48, 72, and 96 hpi (13.5 L in total). The media was replaced with 4 L PBS, and the infected cells remaining on the polymer fiber carrier were subjected to three free-thaw cycles. We used the same set of parameters and culture strategies for both the NBS-bioflo310 and ACPB to produce Ad5 vector.
Quality control of the Ad5 vector
To further improve the quality of the product, we tested specific activity, i.e., the ratio of infectious virus particle units to the total number of virus particles (IU/VP). Currently, the Chinese SFDA requires that the specific activity of recombinant Ad clinical products must be greater than 3.3%, which is 3.3 times higher than the 1% quality requirement stipulated in 1998. Residual BSA was detected using standard ELISA methods with a BSA-ELISA kit (Cygnus, USA).
To fully characterize the Ad5 product, a number of physical, chemical, and biological tests were also employed according to established guidelines and Chinese Phamacopoeia (2015), including Replication Competent Adenovirus (RCA) testing, sterility testing, endotoxin testing, and Adeno-associate virus (AAV) detection. RCA testing: The test samples were used to infect A549 cells. Four passages were performed and cells were regularly observed to detect cytopathic effect (CPE). Positive and negative controls were included to validate the assay. Sterility testing: Membrane-filter procedure was used in the test. After filtration, the membrane was incubated in two types of media (Soybean Casein Digest Broth, Fluid Thioglycollate Medium) for 14 days with intermittent observations during the testing period to detect evidence of microbial contamination. Endotoxin testing: The test samples were combined with Limulus amebocyte lysate reagent (FUJIFILM, US) and measuring the resulting proportional reaction by gel-clot. AAV detection: Viral DNA of the test samples were isolated using TRIzol reagent (Invitrogen, USA) according to the manufacturer’s instructions. AAV was detected by PCR method using a pair of universal primers, forward primer 5′ AAC TGG ACC AAT GAA AAC TTT CC 3′ and reverse primer 5′ AAA AAG TCT TTG ACT TCC TGC TT 3′. Positive and negative controls are included to validate the assay.
Results
Cell bank and virus seed generation and analysis
A master cell bank (8 × 106 cells/mL, 1.5 mL/vial, 143 vials) and working cell bank (6.5 × 106 cells/mL, 1.5 mL/vial, 303 vials) were generated. HEK293 cells were cultured over 20 passages to test their stability. The seed-train cultures were amplified using the different flasks and vessels listed in Table 1. The master seeds (460 vials, 6.31 × 109 IU/mL, 1 mL/vial) and working seeds of Ad vector (600 vials, 6.31 × 109 IU/mL, 1 mL/vial) were generated and analyzed (data not shown).
Cell culture in mini-bioreactor vessels
The GCR was determined based on the glucose concentration in fresh medium and the residual glucose concentration in the mini-bioreactor, measured at 24-h intervals. Cell growth and GCR profiles for HEK293 cells from the mini-bioreactor culture vessels are presented in Fig. 3a. Cell growth and GCR were positively correlated. The total cell number increased from 0.9 × 107 to 0.9 × 108 cells after 5 days of culture. The maximum GCR in the 30 mL system was 2.96 mg/mL between 96 and 120 h of culture. The maximum GCR was reached at different time points in accordance with the variation in cell seeding densities in the mini-bioreactor vessels (Fig. 3b). The seeding density of 0.9 × 107 cells per 0.6 g disk was considered to be the most appropriate for the culture time because the GCR was highly similar to the rate with the seeding density of 1.2 × 107 cells and reached the maximum value earlier than the other two density conditions.
Optimization of viral yield in a mini-bioreactor
We determined that the optimal seeding density was 0.9 × 107 cells per 0.6 g disk, and the optimal incubation time was 5 days. Next, we investigated the effects of different MOIs (MOI = 1, 10, 20, and 50) on virus production in the mini-bioreactor. Following the infection with the Ad5 vector at 37 °C, supernatants were harvested at 24-h intervals and the viral titers determined by performing immunochemistry on HEK293 cells infected with Ad5 (Fig. 4a). Viral titers peaked at 96 hpi at MOIs of 1, 10, and 20, with lower titers obtained with MOIs of 1 and 10. At a MOI of 50, viral titers peaked at 72 hpi (Fig. 4b). Based on these results, we established that a MOI of 20 was the most appropriate MOI for this system.
The effects of temperature on virus production in the mini-bioreactor was also investigated. Supernatants were harvested at 24-h intervals and combined together from different harvest time (48, 72, and 96 hpi), and the viral titers (IU and VP) determined. We found that the viral titers were highest when the incubation temperature was 35 °C. The total harvest yield reached 1.0 × 108 IU at a temperature of 35 °C (Fig. 4c).
Effects of different medium supplements and culture strategies on viral yields
To determine the most suitable medium supplementation for virus production, we tested four conditions: P1 (FBS), P2, P3, and P4 (LH). P4 contained four subgroups (LH 0.1, 0.25, 0.5, and 1% [w/v]). The Ad was inoculated in the mini-bioreactors at an MOI of 20 and a temperature of 35 °C. The supernatants from the mini-bioreactors were harvested at 48, 72, and 96 hpi, and the viral titers were determined. The results of the viral yield revealed that P1, P2, and P4 (0.25% LH and 0.5% LH) produced a higher titer than the other conditions, with the viral titers reaching 10.2, 9.6, 9.7, and 9.7 log10IU/mL, respectively. P4 (0.25% LH) and P4 (0.5% LH) exhibited no differences in viral yield, indicating that P4 (0.25% LH) may be the most suitable strategy in terms of the practical manufacturing of the Ad vector (Fig. 5).
ACPB and NBS-Bioflo310 culture
HEK293 cells from 10 mini-bioreactors (2.25 × 109 total cells) were seeded in the first ACPB culture run (ACPB-0). The cells were maintained under quiescent conditions for 2 h to allow for attachment. Approximately 97% of the seed cells attached during the 2-h quiescent period. The medium was replaced (5 L) at 24-h intervals, and the glucose levels were consistently maintained above 1.5 mg/mL. After 6 days of culture, the total number of HEK293 cells was determined to be 2.8 × 1010 by crystal violet staining of the fiber carriers obtained from the ACPB. The cell density at different positions was analyzed and suggested an even distribution pattern throughout the perfusion column (Fig. 6a).
The second run (ACPB-1) used the P1 strategy as described above. The GCR at 24 h and the viral titer at 48, 72, and 96 hpi were evaluated. The maximum viral titer reached was 10.2 log10IU/mL (Fig. 6b). The total volume of the harvested supernatant was 20 L, and the mean virus titer was 8.0 × 109 IU/mL with a total yield of 4.2 × 1015 VP.
The next three runs (ACPB-2, 3, and 4) used the P4 (0.25% LH) strategy as described above. The GCR at 24 h and the viral titer at 48, 72, and 96 hpi were evaluated. The maximum viral titer reached was 9.8 log10IU/mL (8.8 × 109 IU/mL; Fig. 6c). The total volume of the harvested supernatant was 20 L, and the mean virus titer was 7.3 × 109 IU/mL, with a total yield of 2.5 × 1015 VP.
The final run was conducted on an NBS-Bioflo310 and used the P4 (0.25% LH) strategy. The GCR at 24 h and the viral titer at 48, 72, and 96 hpi were evaluated. The maximum viral titer reached 10.0 log10IU/mL (1 × 1010 IU/mL; Fig. 6d). The total volume of the harvested supernatant was 13.5 L, and the mean virus titer was 8.1 × 109 IU/mL, with a total yield of 1.8 × 1015 VP.
The total yields (VP) harvested from supernatants (extracellular) and cell lysates (intracellular) were calculated. Approximately 40–60% of Ad5 vector remained in HEK293 cells (data not shown). Residual bovine serum albumin in supernatants harvested in 48, 72, and 96 hpi from the ACPB and NBS-Bioflo310 was measured. The results show a large decrease in BSA using the P4 (0.25% LH) supplementation strategy compared with P1 strategy (Table 2).
The specific activity of Ad5 vector harvested from the ACPB and Bioflo310 was calculated. The results show that the specific activity of Ad5 from the ACPB-2/P4 and Bioflo310/P4 is higher than from ACPB-1/P1 (Table 3). The specific activity of Ad5 from cell lysates is much lower than that from supernatants. The Ad5 product was fully characterized by a number of chemical and biological tests (Table 4). The results indicated that the quality of Ad5 was in compliance with GMP standard.
Discussion
Although the production of Ad has been investigated in a number of publications and reviewed (Bewig and Schmidt 2000; Whitfield et al. 2009), it remains challenging to significantly improve product yields to reduce the cost of goods and maintain economic viability. Maximization of virus particle yields and stability of active vector during the course of production will certainly rely on a better understanding of key replication mechanisms and kinetic parameters (Maranga et al. 2005; Nadeau et al. 2000; Petiot et al. 2011; Siegwart et al. 1999). A suitable medium replacement strategy is a crucial factor for successful manufacturing of Ad vectors. Medium is the main cost of production and also has an important influence on downstream processes and the quality of final products. During the initial 0–24 hpi in a bioreactor, Ad5 titers are below 106 IU and are barely amplified. The 24-h infection period allows for entry of the Ad into 293 cells and for expression of GFP; however, no secondary infection occurs within the 24-h post-infection period. During this period, cells infected with virus consume more nutrients in the medium. The decrease in productive infection at a high cell density is called the “cell density effect” (Kamen and Henry 2004; Nadeau and Kamen 2003). In order to maintain cell viability and overcome nutrient limitations and the cell density effect, we used DMEM supplemented with 10% FBS for the first 24 h post-infection and then replaced the medium with DMEM supplemented with 0.25% (w/v) LH and glucose (2 mg/mL) at 24-h intervals. This approach provided the cells with a sufficient nutrient stock for the subsequent 72 h for virus production. The advantages of this protocol are its low cost, high yield, and lower levels of residual serum.
The mini-bioreactor is a new tool for cell culture, which is characterized by small size and ease of operation. The mini-bioreactor offers a very rapid process to create cell banks and virus seeds. The ACPB system provides a high oxygen transfer efficiency and reduces the shearing force of bubbles, which makes it very suitable for virus culture. In the ACPB, the bioreactor bag and perfusion column are constructed with pre-sterilized plastic. This design eliminates the need for cleaning and sterilization, and, therefore, shortens the implementation time to conform to GMP. Additionally, the ACPB can be scaled up to 300 L with a larger perfusion column and bioreactor bag.
It is well documented that the MOI is a key factor in Ad vector infection. When cells are infected at an MOI greater than 20, a synchronous infection occurs (Nadeau and Kamen 2003). Since cells are not accessible during the culture period, an indirect method for estimating cell density in this system was developed. In this study, GCR was used as an indirect indicator to estimate cell growth and density in mini-bioreactors to study the relationship between cell density and GCR. The results showed that GCR is a reliable estimation of cell density growth in this model system (Meuwly et al. 2006; Yang and Butler 2000). It has been reported that temperature significantly affects cell metabolism, with extended viability being favored at low temperatures. The effect of temperature on viral production is significant. In this study, we found that maximum viral production occurred at 35 °C, which is consistent with previous studies (Jardon and Garnier 2003).
Specific activity of recombinant Ad is a very crucial factor that may affect whether the Ad5 vector-related products can progress to clinic trial. According to SFDA standards, the specific activity of recombinant Ad clinical products should be greater than 3.3%. The bioactivity of Ad5 vectors can be affected by the purity of the harvest and the downstream purification process. In our study, the increase in specific activity may be attributable to using a relatively “serum-free” strategy and discarding the intracellular virus.
In summary, we established a novel model system and suitable culture strategy for Ad5 vector production. This model system offers a rapid and economical process to produce GMP-level Ad5 products, which may shorten the research period leading to clinic trial.
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Acknowledgments
We would like to thank AmProtein (Hangzhou, China) for their assistance with ACPB photos. We also thank the native English speaking scientists of Elixigen Company (Huntington Beach, California) for editing our manuscript.
Funding
This work was supported by the State Project of Essential Drug Research and Development (grant number 2015ZX09101044) and the Science & Technology Key Program of Zhejiang, China (grant number 2014C03039).
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Chen, KD., Wu, XX., Yu, DS. et al. Process optimization for the rapid production of adenoviral vectors for clinical trials in a disposable bioreactor system. Appl Microbiol Biotechnol 102, 6469–6477 (2018). https://doi.org/10.1007/s00253-018-9091-5
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DOI: https://doi.org/10.1007/s00253-018-9091-5