The system can be integrated with the cloning of large candidate libraries, allowing a throughput of >1,000 samples per week, and protein is produced 3 days after infiltration. The translatability of cell pack data to intact plants was successfully demonstrated for three mAbs and several other proteins, including a toxin . Therefore, cell packs allow the rapid and automated screening of product candidates such as vaccines and diagnostic reagents. In addition to recombinant proteins, the technology can, in principle, also be used to produce virus-like particles based on plant viruses, which further broadens its applicability for screening and product evaluation but, to our knowledge, according results had not been published as of September 2020. In the future, plant cell packs could be combined with a recently developed method for rapid gene transfer to plant cells using carbon nanotubes . Such a combination would not be dependent on bacteria for cloning or gene transfer to plant cells , thereby reducing the overall duration of the process by an additional 2–3 days . For the rapid screening of even larger numbers of candidates, cost-efficient cell-free lysates based on plant cells have been developed and are commercially available in a ready-to-use kit format. Proteins can be synthesized in ~24 h, potentially in 384-well plates, and the yields expressed as recombinant protein mass per volume of cell lysate can reach 3 mg ml−1 . Given costs of ~€1,160 ml−1 according to the manufacturer LenioBio , this translates to ~€400 mg−1 protein, an order of magnitude less expensive than the SP6 system ,4×4 grow table which achieves 0.1 mg ml−1 at a cost of ~€360 ml−1 based on the company’s claims.
Protocol duration and necessary labor are comparable between the two systems and so are the proteins used to demonstrate high expression, e.g., luciferase. However, the scalability of the plantcell lysates is currently limited to several hundred milliliters, and transferability to intact plants has yet to be demonstrated, i.e., information about how well product accumulation in lysates correlates with that in plant tissues. Such correlations can then form the basis to scale-up lysate-based production to good manufacturing practice -compliant manufacturing in plants using existing facilities. Therefore, the cell packs are currently the most appealing screening system due to their favorable balance of speed, throughput, and translatability to whole plants for large-scale production. In any pandemic, the pathogen genome has to be sequenced, made publically available, and freely disseminated in the global scientific community to accelerate therapeutic and vaccine development. Once sequence information is available, a high priority is the rapid development, synthesis, and distribution of DNA sequences coding for individual viral open reading frames. These reagents are not only important for screening subunit vaccine targets but also as enabling tools for research into the structure, function, stability, and detection of the virus . Because many viral pathogens mutate over time, the sequencing of clinical virus samples is equally important to enable the development of countermeasures to keep pace with virus evolution .
To ensure the broadest impact, the gene constructs must be codon optimized for expression in a variety of hosts ; cloned into plasmids with appropriate promoters, purification tags, and watermark sequences to identify them as synthetic and so that their origin can be verified ; and made widely available at minimal cost to researchers around the world. Not-for-profit plasmid repositories, such as Addgene and DNASU, in cooperation with global academic and industry contributors, play an important role in providing and sharing these reagents. However, the availability of codon-optimized genes for plants and the corresponding expression systems is often limited . For example, there were 41,247 mammalian, 16,560 bacterial, and 4,721 yeast expression vectors in the Addgene collection as of August 2020, but only 1,821 for plants, none of which contained SARS-CoV-2 proteins. Sharing plant-optimized SARS-CoV-2 synthetic biology resources among the academic and industry research community working on PMPs would further accelerate the response to this pandemic disease. Screening and process development can also be expedited by using modeling tools to identify relevant parameter combinations for experimental testing. For example, initial attempts have been made to establish correlations between genetic elements or protein structures and product accumulation in plants . Similarly, heuristic and model-based predictions can be used to optimize downstream processing unit operations including chromatography . Because protein accumulation often depends on multiple parameters, it is typically more challenging to model than chromatography and probably needs to rely on data-driven rather than mechanistic models. Based on results obtained for antibody production, a combination of descriptive and mechanistic models can reduce the number of experiments and thus the development time by 75% , which is a substantial gain when trying to counteract a global pandemic such as COVID-19.
These models are particularly useful if combined with the high-throughput experiments described above. Techno-economic assessment computeraided design tools, based on engineering process models, can be used to design and size process equipment, solve material and energy balances, generate process flow sheets, establish scheduling, and identify process bottlenecks. TEA models have been developed and are publicly available for a variety of plant-based bio-manufacturing facilities, including whole plant and plant cell bioreactor processes for production of mAbs , antiviral lectins , therapeutics , and antimicrobial peptides . These tools are particularly useful for the development of new processes because they can indicate which areas would benefit most from focused research and development efforts to increase throughput, reduce process mass intensity, and minimize overall production costs.The rapid production of protein-based countermeasures for SARS-CoV-2 will most likely, at least initially, require bio-manufacturing processes based on transient expression rather than stable transgenic lines. Options include the transient transfection of mammalian cells , baculovirus-infected insect cell expression systems , cell-free expression systems for in vitro transcription and translation , and transient expression in plants . The longer term production of these countermeasures may rely on mammalian or plant cell lines and/or transgenic plants, in which the expression cassette has been stably integrated into the host genome, but these will take months or even years to develop, optimize, and scale-up. Among the available transient expression systems, only plants can be scaled-up to meet the demand for COVID-19 countermeasures without the need for extensive supply chains and/or complex and expensive infrastructure, thus ensuring low production costs . These manufacturing processes typically use Nicotiana benthamiana as the production host and each plant can be regarded as a biodegradable, single-use bioreactor . The plants are grown either in greenhouses or indoors, either hydroponically or in a growth substrate, often in multiple layers to minimize the facility footprint, and under artificial lighting such as LEDs. In North America,cannabis drying system large-scale commercial PMP facilities have been built in Bryan, TX , Owensboro, KY , Durham, NC , and Quebec, Canada . The plants are grown from seed until they reach 4–6 weeks of age before transient expression, which is typically achieved by infiltration using recombinant A. tumefaciens carrying the expression cassette or by the introduction of a viral expression vector such as tobacco mosaic virus , for example, the GENEWARE platform . For transient expression by infiltration with A. tumefaciens, the plants are turned upside down and the aerial portions are submerged in the bacterial suspension. A moderate vacuum is applied for a few minutes, and when it is released, the bacteria are drawn into the interstitial spaces within the leaves. The plants are removed from the suspension and moved to an incubation room/chamber for 5–7 days for recombinant protein production. A recent adaptation of this process replaces vacuum infiltration with the aerial application of the A. tumefaciens suspension mixed with a surfactant. The reduced surface tension of the carrier solution allows the bacteria to enter the stomata, achieving a similar effect to agroinfiltration . This agrospray strategy can be applied anywhere, thus removing the need for vacuum infiltrators and associated equipment .
For transient expression using viral vectors, the viral suspension is mixed with an abrasive for application to the leaves using a pressurized spray, and the plants are incubated for 6–12 days as the recombinant protein is produced. Large scale production facilities have an inventory of plants at various stages of growth and they are processed in batches. Depending on the batch size , the vacuum infiltration throughput, and the target protein production kinetics, the infiltration/ incubation process time is 5–8 days. The inoculation/incubation process is slightly longer at 6–13 days. The overall batch time from seeding to harvest is 33–55 days depending on the optimal plant age, transient expression method, and target protein production kinetics . Importantly, plant growth can be de-coupled from infiltration, so that the plants are kept at the ready for instant use, which reduces the effective first-reaction batch time from gene to product to ~10–15 days if a platform downstream process is available . The time between batches can be reduced even further to match the longest unit operation in the upstream or downstream process. The number of plants available under normal operational scenarios is limited to avoid expenditure, but more plants can be seeded and made available in the event of a pandemic emergency. This would allow various urgent manufacturing scenarios to be realized, for example, the provision of a vaccine candidate or other prophylactic to first-line response staff.The speed of transient expression in plants allows the rapid adaptation of a product even when the process has already reached manufacturing scale. For example, decisions about the nature of the recombinant protein product can be made as little as 2 weeks before harvest because the cultivation of bacteria takes less than 7 days and the post-infiltration incubation of plants takes ~5–7 days. By using large-scale cryo-stocks of ready-to-use A. tumefaciens, the decision can be delayed until the day of infiltration and thus 5–7 days before harvesting the biomass . This flexibility is desirable in an early pandemic scenario because the latest information on improved drug properties can be channeled directly into production, for example, to produce gram quantities of protein that are required for safety assessment, pre-clinical and clinical testing, or even compassionate use if the fatality rate of a disease is high . Although infiltration is typically a discontinuous process requiring stainless-steel equipment due to the vacuum that must be applied to plants submerged in the bacterial suspension, most other steps in the production of PMPs can be designed for continuous operation, incorporating single-use equipment and thus complying with the proposed concept for bio-facilities of the future . Accordingly, continuous harvesting and extraction can be carried out using appropriate equipment such as screw presses , whereas continuous filtration and chromatography can take advantage of the same equipment successfully used with microbial and mammalian cell cultures . Therefore, plant-based production platforms can benefit from the same >4-fold increase in space-time yield that can be achieved by continuous processing with conventional cell-based systems . As a consequence, a larger amount of product can be delivered earlier, which can help to prevent the disease from spreading once a vaccine becomes available. In addition to conventional chromatography, several generic purification strategies have been developed to rapidly isolate products from crude plant extracts in a cost-effective manner . Due to their generic nature, these strategies typically require little optimization and can immediately be applied to products meeting the necessary requirements, which reduces the time needed to respond to a new disease. For example, purification by ultrafiltration/diafiltration is attractive for both small and large molecules because they can be separated from plant host cell proteins , which are typically 100–450 kDa in size, under gentle conditions such as neutral pH to ensure efficient recovery . This technique can also be used for simultaneous volume reduction and optional buffer exchange, reducing the overall process time and ensuring compatibility with subsequent chromatography steps. HCP removal triggered by increasing the temperature and/ or reducing the pH is mostly limited to stable proteins such as antibodies, and especially, the former method may require extended product characterization to ensure the function of products, such as vaccine candidates, is not compromised . The fusion of purification tags to a protein product can be tempting to accelerate process development when time is pressing during an ongoing pandemic. These tags can stabilize target proteins in planta while also facilitating purification by affinity chromatography or non-chromatographic methods such as aqueous two-phase systems . On the downside, such tags may trigger unwanted aggregation or immune responses that can reduce product activity or even safety .