key: cord-0884171-uhagk999 authors: Lobato Gómez, Maria; Huang, Xin; Alvarez, Derry; He, Wenshu; Baysal, Can; Zhu, Changfu; Armario‐Najera, Victoria; Blanco Perera, Amaya; Cerda Bennasser, Pedro; Saba‐Mayoral, Andera; Sobrino‐Mengual, Guillermo; Vargheese, Ashwin; Abranches, Rita; Abreu, Isabel Alexandra; Balamurugan, Shanmugaraj; Bock, Ralph; Buyel, Johannes.F.; da Cunha, Nicolau B.; Daniell, Henry; Faller, Roland; Folgado, André; Gowtham, Iyappan; Häkkinen, Suvi T.; Kumar, Shashi; Ramalingam, Sathish Kumar; Lacorte, Cristiano; Lomonossoff, George P.; Luís, Ines M.; Ma, Julian K.‐C.; McDonald, Karen. A.; Murad, Andre; Nandi, Somen; O’Keefe, Barry; Oksman‐Caldentey, Kirsi‐Marja; Parthiban, Subramanian; Paul, Mathew J.; Ponndorf, Daniel; Rech, Elibio; Rodrigues, Julio C. M.; Ruf, Stephanie; Schillberg, Stefan; Schwestka, Jennifer; Shah, Priya S.; Singh, Rahul; Stoger, Eva; Twyman, Richard M.; Varghese, Inchakalody P.; Vianna, Giovanni R.; Webster, Gina; Wilbers, Ruud H. P.; Capell, Teresa; Christou, Paul title: Contributions of the international plant science community to the fight against human infectious diseases – part 1: epidemic and pandemic diseases date: 2021-07-19 journal: Plant Biotechnol J DOI: 10.1111/pbi.13657 sha: 364aa1af52e197624d819876bc078d2e3524f99f doc_id: 884171 cord_uid: uhagk999 Infectious diseases, also known as transmissible or communicable diseases, are caused by pathogens or parasites that spread in communities by direct contact with infected individuals or contaminated materials, through droplets and aerosols, or via vectors such as insects. Such diseases cause ˜17% of all human deaths and their management and control places an immense burden on healthcare systems worldwide. Traditional approaches for the prevention and control of infectious diseases include vaccination programmes, hygiene measures and drugs that suppress the pathogen, treat the disease symptoms or attenuate aggressive reactions of the host immune system. The provision of vaccines and biologic drugs such as antibodies is hampered by the high cost and limited scalability of traditional manufacturing platforms based on microbial and animal cells, particularly in developing countries where infectious diseases are prevalent and poorly controlled. Molecular farming, which uses plants for protein expression, is a promising strategy to address the drawbacks of current manufacturing platforms. In this review article, we consider the potential of molecular farming to address healthcare demands for the most prevalent and important epidemic and pandemic diseases, focussing on recent outbreaks of high‐mortality coronavirus infections and diseases that disproportionately affect the developing world. In the first years of the 21st century, infectious diseases are still responsible for~17% of all human deaths (Vos et al., 2020) . The impact of infectious diseases as a proportion of all deaths has been falling decade on decade thanks to improvements in hygiene, vaccination and health care, but infectious diseases are still a major burden on national health systems. An infectious disease is defined as a transmissible disease caused by pathogens (viruses, bacteria or fungi) or parasites (both microbial and invertebrate, primarily endoparasites) but usually excludes infestations with arthropods such as ticks and lice, which typically act as ectoparasites. An epidemic disease is an infectious disease that may or may not be endemic in a population but spreads rapidly among communities of certain geographic areas (CDC, 2020b) . Epidemics can be contained using a combination of natural and technological factors (including therapy and vaccination) that prevent spreading to other regions. Currently, there are many epidemic diseases: cholera in Yemen (WHO, 2019), measles in Burundi (WHO, 2020g) , measles and Ebola in the Democratic Republic of the Congo (WHO, 2020b,c) , Ebola in Uganda (WHO, 2020e), measles in the Philippines, Kuala Koh, Samoa and New Zealand (Ministry of Health NZ, 2020) and dengue in parts of Southeast Asia and South America (WHO, 2017a) . The difference between an outbreak and an epidemic is often one of scale, but each is typified by a rapid increase in cases above the typical baseline incidence. The major difference between an endemic and epidemic disease is the unexpected nature of the epidemic, and each therefore requires different tactical and strategic approaches for control. A pandemic disease is an epidemic that spreads over multiple large regions or worldwide (CDC, 2020b) , and such diseases are more common today than in previous centuries because of the pervasive nature of global travel and trade (Morens et al., 2009) . Although the term pandemic is often associated with rapidly spreading diseases such as influenza and the current COVID-19 pandemic caused by severe acute respiratory syndrome-associated coronavirus 2 (SARS-CoV-2), which are transmitted by droplets or aerosols (CDC, 2020a; Morawska and Milton, 2020; WHO, 2020a) , it also applies to diseases such as HIV/AIDS caused by human immunodeficiency virus, which is transmitted more slowly via body fluids (WHO, 2020f) . This review article provides a critical assessment of the use of plant biotechnology as a means to tackle epidemic and pandemic diseases, focussing on the use of plants as bioreactors for the production of research reagents and pharmaceutical products including vaccines, antibodies and antivirals. The diseases covered by the article are summarized in Table 1 , with more details on the incidence, prevalence and burden associated with these diseases provided in Table S1 . Table 1 Classification of epidemic and pandemic diseases based on their epidemiology, showing the number of people affected in a specific time and place. The fatality rate was calculated by dividing the number of deaths by the total number of identified cases in the specific time and place. References are listed in Table S1 . Viral strains are underlined [1901] [1902] [1903] [1904] [1905] [1906] [1907] [1908] [1909] [1910] [1911] [1912] [1913] [1914] [1915] [1916] [1917] [1918] [1919] [1920] Why plants? Plant biotechnology has much to offer in the fight against infectious diseases, from the provision of emergency testing infrastructure (Webb et al., 2020) to the manufacture of smallmolecule drugs, recombinant antivirals, subunit vaccines, engineered viruses and virus-like particle (VLP) vaccines, therapeutic proteins, antibodies and diagnostic reagents (Capell et al., 2020; Daniell et al., 2016 Daniell et al., , 2019 Daniell et al., , 2021 McDonald and Holtz, 2020; Rosales-Mendoza, 2020; Tus e et al., 2020) . Although plants have been used as a platform for the production of pharmaceutical proteins for more than 30 years (Fischer and Buyel, 2020; Ma et al., 2003a) , their potential advantages in terms of scale and speed were highlighted by the slow response of traditional manufacturing platforms to epidemics of severe acute respiratory syndrome ( (Bradley and Bryan, 2019; Kobres et al., 2019) . Plants are still more often described as 'promising' or 'emerging' platforms rather than genuine alternatives, but their potential for the large-scale production of reagents and vaccines has been demonstrated in the context of COVID-19, particularly through the clinical testing of VLP-based vaccines (Ward et al., 2021a) . The ability of plants to produce pharmaceutical proteins has been demonstrated in hundreds of proof-of-principle studies and in a growing number of clinical trials, with a small number of products reaching the market as approved biologics or medical devices (Fischer and Buyel, 2020; Ma et al., 2003a; Ward et al., 2020) . Additional proteins have been expressed as diagnostics or research reagents, due to the shorter development times and lower regulatory burden (Tschofen et al., 2016) . This niche discipline, known as molecular farming, was initially promoted by citing three key advantages of plants over fermenter-based alternatives such as bacteria, yeast and mammalian cells: low cost, greater scalability and intrinsic safety (Mir-Artigues et al., 2019; Nandi et al., 2016) . The cultivation of plants in greenhouses (or even the field, where permitted) is much less expensive than fermenters and can be realized on a much larger scale. Plants are also intrinsically unable to support the replication of human viruses, effectively behaving as self-contained disposable bioreactors. However, the early development of plant-based pharmaceuticals was limited by four main drawbacks that reduced industrial confidence: low yields, high purification costs, regulatory barriers and plant-specific glycans. The second wave of molecular farming addressed these issues by increasing yields, optimizing downstream processing (Buyel et al., 2015; Peyret et al., 2019; Zischewski et al., 2015) for enhanced recovery and purification (Box 1), engaging with regulators to develop new guidelines and devising strategies to remove or modify plant glycans where this improved product functions, while also showing in multiple clinical trials that they pose no significant risk (Schroberer and Strasser, 2018) . Plant-based production systems now have the potential to compete with microbial and mammalian cells in fermenters, including the integration of pharmaceutical good manufacturing practice (GMP) at least for the downstream processing (DSP) steps Ma et al., 2015) . Furthermore, the ease of transporting seeds and expression constructs, combined with the inexpensive cultivation and increasing availability of disposable equipment and portable infrastructure, means that plants can be grown where needed to provide a local source of research reagents, and potentially also vaccines or drugs, even in developing country settings. The renaissance of molecular farming has led to three major platforms ( Figure 1 ): transient expression (mostly in Nicotiana benthamiana), transgenic plants (mostly tobacco and cereals, but also fruit and vegetable crops, legumes and oilseeds) and plant cell suspension cultures (mostly tobacco and rice), which can be extended to include other clonally propagated platforms in containment such as algae, moss, duckweed and plant organ cultures (e.g. hairy roots), which are thus covered by the same regulatory guidelines as cell cultures. These platforms have all been used to produce pharmaceutical proteins targeting infectious diseases because they have advantages for different disease types, which we explore in more detail when we consider the diseases in turn. Briefly, however, transient expression involves the infiltration of wild-type plants or plant cells with bacteria or their infection with viral vectors, leading to a burst of recombinant protein production. This allows protein recovery after a few days, and the entire platform is therefore extremely rapid and scalable. This is ideal for rapid responses in the face of emerging epidemic and pandemic diseases, and several companies have already invested in large-scale production facilities using N. The large-scale manufacturing of biopharmaceuticals is often more readily achievable using plants rather than fermenterbased systems, but this places additional pressure on the downstream processing (DSP) steps (Buyel et al., 2017) . The latter stages of DSP are more dependent on the product than the production system; hence, the same platform chromatography steps can be applied to antibodies produced in mammalian cells and plants . However, the early stages of DSP must deal with challenges specific to the recovery and purification of biopharmaceuticals from plant tissues, because most molecular farming products are retained within the plant cell or in the apoplast, with relatively few products secreted fully into the medium of cell suspension/hairy root cultures or into the hydroponic fluid in rhizosecretion platforms (Drake et al., 2009; Madeira et al., 2016a,b) . Cost-efficient conditioning and pre-processing steps have therefore been developed to address plantspecific challenges (product recovery from leaf or seed tissue, which results in a much higher burden of particles, fibres and host cell proteins than other systems), including precipitation, flocculation, optimized filter trains and membrane-based purification (Buyel and Fischer, 2014; Hassan et al., 2008; Menzel et al., 2016; Opdensteinen et al., 2019) . The DSP steps for whole plants and plant cell cultures have evolved to a similar process scale and level of professionalism as established for conventional host systems (Schillberg et al., 2019) . A framework has also been established to address process design and development, consisting of models for process steps (Buyel, 2016) , overall layout (Nandi et al., 2016) and costs McNulty et al., 2020; Walwyn et al., 2015) . Accordingly, manufacturing vaccines and therapeutics in plant-based systems is now a scalable and economically viable alternative to traditional production systems (Tus e et al., 2020). , 19, 1901-1920 benthamiana to develop vaccines against seasonal and pandemic influenza (Pillet et al., 2016 Shoji et al., 2011; Ward et al., 2020) , Ebola (Hiatt et al., 2015) , and most recently COVID-19 (Capell et al., 2020; Ward et al., 2021a) . The scalability and response time were succinctly demonstrated in a DARPA Blue Angel program that produced 10 million doses of influenza vaccine in one month (Lomonossoff and D'Aoust, 2016) . In the fight against COVID-19, transient expression has been successful for the development of diagnostic reagents and the components of assay kits (Capell et al., 2020) and also for the development of vaccines, with the Canadian government already placing orders for 76 million doses of the Medicago VLP vaccine (Ward et al., 2021a) . It takes longer to develop products when the proteins are expressed in transgenic plants, but this allows the continuous, large-scale production of proteins, which is ideal for slowly spreading or established pandemic diseases, as well as widely prevalent endemic diseases discussed in our sister article (He et al., 2021) , and where there is a large demand for biologics and insufficient capacity in the current supply chain. Tobacco is widely used to develop transgenic lines expressing pharmaceutical proteins, but leafy crops have the disadvantage of product instability during storage, meaning that immediate extraction and downstream purification is necessary unless the biomass can be frozen or dried (Hoelscher et al., 2018) . Freeze-dried leaves can be stored at ambient temperature for up to 3-4 years Herzog et al., 2017; Park et al., 2020; Su et al., 2015) , and seeds have been stored at ambient temperatures even longer without loss of protein activity, so both systems obviate the need for an expensive cold chain, which is especially valuable in remote areas in developing countries (Sabalza et al., 2013 ; (Huebbers and Buyel, 2021) , the latter either grown in containment or in the open field (bold text, thick arrows). The relative advantages and disadvantages of the three platforms are shown in terms of speed (the faster the better), scalability (the larger the better, generally inversely related to costs) and containment (the more contained the lesser the regulatory burden) with separate indicators for transgenic plants grown indoors and outdoors. Four additional minor or emerging platforms are also shown (regular text, thin arrows). Plant cell suspension cultures are usually transgenic cell lines, but transient expression is also possible (Sukenik et al., 2018) and has been realized in the form of plant cell packs for the high-throughput and highly automated testing of expression constructs with immediately scalable expression (Gengenbach et al., 2020; Rademacher et al., 2019) . Transgenic organ cultures such as hairy roots can be regarded as an extension of the cell suspension culture concept because the organ cultures are likewise grown in containment in bioreactors (Doran, 2013; Wongsamuth and Doran, 1997) . Variants on the theme of transgenic plants include transplastomic plants, where the transgene is inserted into the plastid genome rather than the nuclear genome (Bains et al., 2017; Berecz et al., 2017; Bock, 2015; Zhang et al., 2017) , and rhizosecretion, in which proteins are secreted by the roots of plants into the hydroponic medium, so that aggressive extraction methods are unnecessary (Drake et al., 2009; Madeira et al., 2016a,b) . The figure includes images from Biorender (https://biorender.com/). Stoger et al., 2005) . Furthermore, the use of any edible tissue for recombinant protein expression provides the option for oral delivery with zero Herzog et al., 2017; Park et al., 2020; Su et al., 2015; Tacket et al., 1998 Tacket et al., , 2000 or minimal processing (Nandi et al., 2005; Zavaleta et al., 2007) or topical application as a crude extract (Ramessar et al., 2008a) which eliminates up to 80% of the costs of production, as discussed in greater detail in our sister article (He et al., 2021) . The ability to use crude extracts also allows further cost savings by producing multiple proteins simultaneously within the same plants, as recently shown for two lectins and an HIV-specific antibody as the basis for a microbicidal cocktail to prevent HIV transmission (Vamvaka et al., 2018) . Finally, clonal systems such as cell suspension cultures are closest to traditional cell-based platforms in terms of GMP manufacturing and were therefore pioneers in the clinical development of plant-made pharmaceuticals. The first approved pharmaceutical product (taliglucerase alfa, a recombinant version of glucocerebrosidase indicated for Gaucher's disease) was manufactured in carrot cell suspension cultures (Tekoah et al., 2015) . Plant cells suffer similar limitations to other fermenter systems in terms of scalability (Santos et al., 2016) . Therefore, plant cells and similar systems with lower scalability are more suited to the production of pharmaceuticals for orphan diseases and others with relatively low prevalence, such as specific forms of cancer, although recent studies have shown how scalability can be increased by semi-continuous production (Macharoen et al., 2021) . Like transgenic plant tissues, plant cell pellets can be administered orally or crude extracts can be applied topically to reduce processing costs, so they may yet find use for the production of oral vaccines and other non-injected products. The cost implications of the different molecular farming platforms have been addressed in multiple techno-economic assessments (Alam et al., 2018; Corbin et al., 2020; McNulty et al., 2020; Mir-Artigues et al., 2019; Nandi et al., 2016; Schillberg et al., 2019) . In addition to the production of pharmaceutical proteins, plants can also be used to manufacture small-molecule drugs, including antivirals. Interest in antivirals derived from wild-type plants has increased following the discovery that medicinal plant extracts containing polyphenols, terpenes, cumarins and alkaloids often show antiviral properties (Daglia, 2012; Denaro et al., 2020) . Such molecules can inhibit viral entry, endosome and lysosome acidification (required for uncoating) or replication (Ben-Shabat et al., 2020; Musarra-Pizzo et al., 2019; Shin et al., 2010) . More than one third of the 185 antiviral drugs approved in the last 38 years are natural products or their derivatives (Newman and Cragg, 2020) . Indeed, COVID-19 has renewed interest in antiviral natural products, including heterocyclic molecules such as chloroquine, hydroxychloroquine, oseltamivir and dexamethasone ( Figure 2 ). Chloroquine (originally isolated from the bark of the cinchona tree, now produced synthetically) and its derivative hydroxychloroquine are antimalarial drugs that also inhibit the glycosylation of viral proteins (Savarino et al., 2004) . However, the efficacy and safety of these drugs for the treatment of COVID-19, though widely reported, has not been confirmed (Cortegiani et al., 2020) . Similarly, artemisinic acid derivatives (also widely used for the treatment of malaria, see our sister article in this issue, He et al., 2021) can be produced in plants as artemisinic acid (Fuentes et al., 2016 (Fuentes et al., , 2018 or artemisinin (Malhotra et al., 2016) and appear to offer potential for the treatment of COVID-19 (Gendrot et al., 2020) . Oseltamivir is a neuraminidase inhibitor derived from shikimic acid (originally extracted from plants, now produced in bacteria) that has been used to treat multiple viral diseases including most recently COVID-19 (Chhikara et al., 2020) . Dexamethasone, which is recommended for critically ill COVID-19 patients in a hospital setting (Liffey, 2020) , is also produced by chemical synthesis, but the corticosteroid backbone is found in many plant-derived steroids and could be used as an alternative source for largerscale production (Patel and Savjani, 2015) . Plant-derived small molecules have also been screened to find new products that inhibit the SARS-CoV-2 main protease, revealing the antiviral activity of luteolin-7-glucoside, demethoxycurcumin, apigenin-7-glucoside, oleuropein, curcumin, catechin and epicatechin gallate (Khaerunnisa et al., 2020) . Similarly, screening a library of 100 FDA-approved antiviral compounds and 1000 active components from Indian medicinal plants showed that anthraquinone rhein, ergosterol withanolide D, sterol lactone withaferin A, fluoroquinolone enoxacin and aloe-emodin can also bind to the protease (Kumar et al., 2020) . Coronaviruses are encapsulated single-stranded positive-sense RNA viruses that typically cause mild respiratory diseases such as the common cold. However, several novel strains of b coronavirus have emerged over the last 20 years that can trigger fatal acute respiratory infections, particularly in people with pre-existing health conditions. Major outbreaks occurred in 2002/2003 (severe acute respiratory syndrome-associated coronavirus, SARS-CoV), 2012 (Middle East respiratory syndrome-associated coronavirus, MERS-CoV) and most recently in 2019 (SARS-CoV-2) (Bradley and Bryan, 2019; Kobres et al., 2019; Park, 2020) . The latter was classified as a pandemic by the WHO on 11 March 2020 (WHO Director-General, 2020) and has thus far infected more than 180 million people worldwide causing~3.9 million deaths (Johns Hopkins University of Medicine, 2021) although the recent approval of several vaccines is now providing hope that the disease can at last be brought under control (Hooker and Palumbo, 2020) . The three most lethal b coronaviruses and the properties of the associated diseases are compared in Table 2 . Molecular farming played a negligible role in the fight against SARS and MERS because these epidemics, while serious, did not reach the pandemic status of COVID-19, and the technology was in any case not ready for a large-scale response. Nevertheless, the N-terminal ectodomain of the SARS-CoV spike (S) protein was expressed in tobacco, lettuce and tomato and was in some cases proven to be immunogenic (Li and Chye, 2009; Li et al., 2006; Pogrebnyak et al., 2005) . Furthermore, the SARS-CoV membrane (M) protein and nucleocapsid (N) protein were produced by transient expression in N. benthamiana, again providing evidence of immunogenicity (Demurtas et al., 2016; Zheng et al., 2009) . The yield of the N protein was 79 mg/kg fresh leaf biomass (Zheng et al., 2009) . The outbreak of COVID-19 resulted in a much more significant reaction from the molecular farming community, in part reflecting the rapid spread of the disease and the need for urgent responses, and in part reflecting the profound growth of plantbased transient expression as a large-scale vaccine manufacturing [1901] [1902] [1903] [1904] [1905] [1906] [1907] [1908] [1909] [1910] [1911] [1912] [1913] [1914] [1915] [1916] [1917] [1918] [1919] [1920] platform in the 18 years since SARS (Capell et al., 2020; Rosales-Mendoza, 2020) . From the outset, molecular farming was acknowledged as a potential response platform and attracted a substantial amount of investment. This was true especially for the production of research-grade reagents and vaccine candidates, but also for the development of therapeutics, including antibodies against the virus and the hyperactive immune response linked to the most severe and often fatal symptoms of COVID-19. Because research-grade reagents do not need regulatory clearance or clinical testing, many current academic and commercial researchers in the molecular farming community (including the authors of this article) stepped up following the outbreak of COVID-19 in order to use their technology to produce SARS-CoV-2 proteins, antibodies for their detection and PCR control reagents. These products can also double as clinical-grade products (vaccine candidates and therapeutics) if produced under GMP conditions. Perhaps the most important target of molecular farming in the context of COVID-19 is the SARS-CoV-2 trimeric S protein and derivatives such as the 223-residue S B receptor-binding domain (RBD). The full S protein is 1255 amino acids in length (~180 kDa), which is cleaved into the receptor-binding S1 subunit (~110 kDa) and the fusion-promoting S2 subunit (~70 kDa). The S protein contains 22 sites for N-linked glycans (19 of which have been experimentally confirmed), 13 in the S1 subunit and low levels of O-linked glycosylation (Ram ırez Hern andez et al., 2021), which increase its molecular weight. The RBD has a molecular weight of~35 kDa. These proteins can be developed as research reagents and diagnostics for the detection of serum antibodies, but also as vaccine candidates and even therapeutics. The S protein has been produced in mammalian cells with a yield of 2 mg/ml whereas the much smaller RBD is expressed at higher levels, up to 25 mg/ml (Amanat et al., 2020; Zhao et al., 2020) . Many groups are now producing variants of this heavily glycosylated protein in plant cell suspension cultures or whole plants by transient expression or in transgenic lines (Makatsa et al., 2020; authors' unpublished data) . Differences in the glycan profiles of S protein variants produced in plants may affect the immunogenicity of different vaccines, contributing to differences in efficacy. Another key protein used in COVID-19 research is angiotensinconverting enzyme 2 (ACE2), which is the major SARS-CoV-2 receptor found on pulmonary epithelial cells among others (Hoffmann et al., 2020; Wrapp et al., 2020) . The natural function of ACE2 is the regulation of blood pressure and cardiovascular homeostasis, which is achieved via the proteolytic degradation of the pro-inflammatory and vasoconstrictive peptide angiotensin II (Ang1-8) to Ang1-7 (Anguiano et al., 2017) . Elevated levels of angiotensin II are pathogenic, so a soluble version of ACE2 (sACE2) is currently in development as a cardiovascular drug and has completed phase I and II trials (Haschke et al., 2013; Khan et al., 2017) . The outbreak of SARS-CoV-2 provided impetus for the repurposing of this protein, which was shown to inhibit SARS-CoV-2 infection of human cells and organoids in vitro and is now undergoing clinical testing (Monteil et al., 2020) . Like the SARS-CoV-2 S protein, human ACE2 is heavily glycosylated, with seven N-linked glycosylation sites and a single O-linked glycosylation site (Shajahan et al., 2020) . One unique aspect of molecular farming is the distinct glycan profile of plant cell lines compared to mammalian cells (Schoberer and Strasser, 2018) , allowing the production of S protein and ACE2 variants as different glycoforms that may differ in terms of stability, immunogenicity and efficacy (Sol a and Griebenow, 2010) . The absence of ACE2 glycosylation has been shown to impair the uptake of SARS-CoV-2 by human cells, with a small impact on the binding affinity . However, a full-length oral ACE2 expressed in lettuce chloroplasts (thus lacking glycans) accumulates to a 10-fold higher concentration in the lungs than in plasma, leading to a reduction in right ventricular hypertrophy, total pulmonary resistance index, right ventricle systolic pressure and pulmonary artery remodelling in hypertensive animals . For COVID-19 patients, it is important to deliver ACE2 to lung tissues because SARS-CoV-2 binds to receptors there and causes significant lung damage. In addition, CTB-ACE2 with efficient binding to both GM1 and ACE2 can effectively block binding of the S protein and viral entry into human cells, especially via oral epithelial cells that are enriched with both receptors . Another advantage of molecular farming in the response to COVID-19 is the speed and scalability of systems based on transient expression in whole plants, which will help to address the massive demand for research reagents, and could ultimately be used to produce vaccines and therapeutics on a sufficient scale for global distribution (Capell et al., 2020; Tus e et al., 2020) . This advantage may also be critical in the future, if variants of SARS-CoV-2 evolve to render current vaccine products less effective. Industrial-scale production will be required for SARS-CoV-2 proteins used as vaccine antigens, for sACE2 as a therapeutic and for broadly neutralizing antibodies that may eventually take the place of convalescent serum which is currently being used to treat critically ill patients (Wang et al., 2021) . Similarly, testing the population for immunity will require billions of serology tests worldwide. Periodic retesting may also become necessary as SARS-CoV-2 is already showing signs of becoming an endemic disease, and pathogenic coronaviruses may elicit less than 3 years of immunity in some individuals (Long et al., 2020; Payne et al., 2016) . The scalability of production is therefore a key consideration. Currently, recombinant SARS-CoV-2 S1 antigen prices fall within the range US$4-25/µg and at least 300 ng of purified antigen is needed for serological tests based on the enzyme-linked immunosorbent assay (ELISA). One billion tests would therefore cost US$1.2 billion for the antigen alone unless economies of scale can be harnessed. Commercial-scale production facilities based on transient expression are currently operated by iBio in Bryan, Texas, USA (Holtz et al., 2015) , Medicago in Quebec, Canada, and Raleigh-Durham, North Carolina, USA (Lomonossoff and D'Aoust, 2016) and Kentucky Bioprocessing in Owensboro, Kentucky, USA (Pogue et al., 2010) . All of these facilities are currently being used to produce COVID-19 reagents and vaccine candidates for clinical testing, including subunit vaccines and VLPs (Capell et al., 2020) . Medicago has recently published the successful results of phase I trials (Ward et al., 2021a) and is currently conducting phase III trials, with 76 million doses already ordered by the Canadian government. Researchers at UC Davis are testing variations of the SARS-CoV-2 S protein and ACE2-Fc fusion proteins in mammalian cells and plant expression systems to compare titre and structures, allowing the immunological analysis of the recombinant glycoproteins combined with molecular dynamics simulations to predict product stability and relative binding affinity (Bernardi et al., 2020) . Monoclonal antibodies against SARS-CoV-2 proteins have also been produced by transient expression in N. benthamiana (Rattanapisit et al., 2020) , and the US company Novici Biotech (Vacaville, CA, USA) has not only produced one such antibody (CR3022) by transient expression but has also donated batches to BEI Resources (Manassas, VA, USA) for distribution at shipping cost only. Transient expression has also been used to produce the antiviral lectin griffithsin (Fuqua et al., 2015; Hahn et al., 2015) , which was shown to act synergistically against SARS-CoV-2 (Cai et al., 2020) . Whereas transient expression allows rapid production, ultimate scalability requires transgenic plants because stable lines can be scaled indefinitely for the long-term production of proteins in greenhouses or (in some jurisdictions) even in the open field. Other groups, including the authors of this article, are using transgenic systems to produce antiviral lectins in transgenic plants, including rice (Vamvaka et al., 2016a (Vamvaka et al., ,b, 2018 and soybean seeds (O'Keefe et al., 2015) . The potential of ACE2/Ang1-7 to rebalance the severely disrupted renin-angiotensin axis suggests a potential benefit in more severely ill patients with acute respiratory distress syndrome, with or without COVID-19, where low ACE2 and Ang(1-7) have been linked to poor prognosis. The NHLBI SMARTT program has already facilitated toxicology, pharmacokinetic and regulatory studies for ACE2/Ang1-7 expressed in chloroplasts (Figure 3) . Briefly, oral dose range finding studies of CTB-ACE2/CTB-Ang(1-7) in healthy male and female Sprague Dawley rats revealed no significant toxicity, and the few mild clinical/laboratory abnormalities were confined to the high-dose group . CTB-ACE2/Ang1-7 in pharmacokinetic studies was also delivered in a dose-dependent manner. Clinical studies of CTB-ACE2/Ang1-7 are now underway to determine the safety, tolerability and pharmacodynamics of oral ACE2/Ang1-7 in healthy volunteers (phase 1a) and patients with COVID-19 (phase 1b). Furthermore, a 2-week treatment (phase 2) is being evaluated for the ability to improve clinical outcomes in patients admitted to a non-ICU hospital setting and in patients with COVID-19 who are triaged to home quarantine, evaluating the median time to release from quarantine using established criteria. Influenza is a contagious viral infection transmitted by sneezing and coughing. It is caused mainly by influenza viruses A and B, which induce symptoms of fever, myalgia, headache, malaise and the typical signs of upper respiratory infections (coughing, sore throat, congestion). Symptoms typically last 5-10 days but longer in children, the elderly and the immunocompromised. Influenza is recorded in 5-10% of adults and 20-30% of children every year, with both seasonal and epidemic/pandemic patterns. Seasonal influenza occurs in temperate regions, but there is no clear seasonal pattern elsewhere (Moghadami, 2017) . Influenza virus undergoes antigenic drift caused by point mutations but also antigenic shift caused by the recombination of the segmented genome when multiple strains infect the same individual. This leads to rapid changes in the genetic makeup of strains circulating in the human population and new vaccines must therefore be prepared every year (WHO, 2020h). The influenza antigens included in the vaccines are selected based on global surveillance, and decisions are made at least 6 months before the next season to allow time for vaccine manufacturing and approval. Recommendations are proposed by WHO and regional medical regulators for trivalent or quadrivalent [1901] [1902] [1903] [1904] [1905] [1906] [1907] [1908] [1909] [1910] [1911] [1912] [1913] [1914] [1915] [1916] [1917] [1918] [1919] [1920] formulations including A/H1N1 and A/H3N2 strains, as well as one or two B strains thought most likely to become prevalent in the next season. The viruses are then adapted for propagation in eggs and are produced separately. The long gap between the selection of antigens and the availability of vaccines means that inaccurate predictions can limit the efficacy of the next seasonal vaccine due to the emergence of an unanticipated strain, as occurred between 2010 and 2014 when the effectiveness of the US vaccine dropped from 60% to 19%. Similarly, pandemic strains of influenza emerge occasionally due to zoonotic transmission, as most recently seen in the 2009 swine flu pandemic. The seasonal vaccine offered no immunity against this strain, leading to the emergency manufacture of a new vaccine that included the H1N1/09 antigen. Plants are promising as a platform for the manufacture of influenza vaccines due to their scalability and the rapid production facilitated by transient expression. Whereas 6 months or more is needed to prepare sufficient quantities of egg-derived vaccine to meet global demand, the same can be achieved in plants within a few weeks (Shoji et al., 2012) , as proven in the abovementioned DARPA Blue Angel program that produced 10 million doses in one month (Lomonossoff and D'Aoust, 2016) . For this reason, although some influenza antigens have been produced in transgenic plants (Ceballo et al., 2017; Firsov et al., 2015; Lee et al., 2015) , most have been transiently expressed in N. benthamiana (Hodgins et al., 2017; 2019a,b; Landry et al., 2014; Shoji et al., 2009a,b; Shoji et al., 2013 Shoji et al., , 2015 Table S1 ) including all vaccine candidates intended for commercial development. Several products indicated for seasonal and pandemic influenza have already reached late-stage clinical development, including vaccines against novel influenza strains and quadrivalent vaccines against seasonal variants (Chichester et al., 2012; Cummings et al., 2014) . The candidates have all been based on the hemagglutinin protein (HA), primarily from H1N1 or H5N1 strains of Influenza A virus. Various formats have been tested, including monomeric and trimeric HA subunits, but the most popular approach is the presentation of HA on the surface of VLPs. Typical VLPs require a viral coat protein component to form the core of the particle, and influenza vaccines based on tobacco mosaic virus have been developed using this principle by Fraunhofer CMB/iBio (Shoji et al., 2011 (Shoji et al., , 2012 . These systems can achieve high product yields: for example, vaccines against strains H3N2, H5N1 and H1N1 have been produced at yields of 50-200 mg/kg fresh leaf biomass (Shoji et al., 2008 (Shoji et al., , 2011 . However, HA can assemble in planta and bud from the membrane to form independent enveloped VLPs even in the absence of viral coat protein components (D'Aoust et al., 2008) and the particles were found to be immunogenic and protective in mouse challenge studies (D'Aoust et al., 2010) . This unexpected discovery provided the foundation for the development of multiple vaccine candidates based on carrier-free VLPs by Medicago, including a proof-of-concept vaccine against a newly emerged H7N9 strain (Pillet et al., 2015) and a quadrivalent vaccine with HA derived from strains A/California/07/2009 H1N1 (A/H1N1 Cal), A/Victoria/361/11 H3N2 (A/H3N2 Vic), B/Brisbane/ 60/08 (B/Bris, Victoria lineage) and B/Wisconsin/1/10 (B/Wis, Yamagata lineage), which has reached phase III clinical development (Pillet et al., 2016 Ward et al., 2020) . The two phase III trials involved a total of 22 930 subjects (Ward et al., 2020) . The first study of 10 160 adults during the 2017/2018 northern hemisphere influenza season was a placebo-controlled randomized trial that revealed an absolute vaccine efficacy of 35.1%, which was lower than the primary endpoint of the study (70% efficacy) but better than the performance of the standard quadrivalent vaccine in the same year, particularly when comparing the response against the H3N2 strain. The second study of 12,794 adults aged 65 or more during the 2018/2019 northern hemisphere influenza season was a direct comparison of the plant-derived and egg-derived vaccines, showing the former had an 8.8% higher efficacy despite the lower antibody response. A third phase III trial was recently completed successfully using VLPs [1901] [1902] [1903] [1904] [1905] [1906] [1907] [1908] [1909] [1910] [1911] [1912] [1913] [1914] [1915] [1916] [1917] [1918] [1919] [1920] 1200 healthy adults aged 18-49 years to test lot-to-lot consistency and to confirm safety and immunogenicity (Ward et al., 2021b) . Overall, the influenza VLPs have been shown to interact with macrophages similarly to the native virus, which may explain their superior efficacy compared to killed vaccines adapted in eggs (Makarkov et al., 2017 (Makarkov et al., , 2019 . At the cellular level, the VLPs were shown to present trimeric HA that interacted directly with dendritic cells in humans and mice, promoting the release of proinflammatory cytokines and the activation of antigen-specific Tcell responses (Won et al., 2018) . The strong immunogenicity of HA-based VLPs has led to a wealth of clinical data concerning the specific immune response to these vaccine candidates and has, as a by-product, helped to address one of the early contentious aspects of molecular farming the impact of plant glycans. The clinical testing of the H5N1 influenza vaccine is pertinent because the phase I/II trials specifically measured the human antibody response to N-linked glycans present on the VLP surface. In the phase I trial, seven of 48 subjects (14.6%) already produced such antibodies and in the extended phase I/II trial of the same product, the frequency of seropositive subjects before vaccination was 19.2% . A total of 280 of 349 subjects received either one or two intramuscular doses of vaccine, including 40 subjects with pre-existing plant allergies. Subjects were monitored for 6 months after vaccination, and 34% developed transient IgG responses to glycans. Some subjects developed IgE responses but not to the glycoepitope containing xylose and fucose, which is specific to plants, and there was no evidence of allergy or hypersensitivity Ward et al., 2014) . Similar results were reported in phase I/II trials of the quadrivalent influenza vaccine. Only two of 30 subjects tested positive for IgE against the glycoepitope during the study, and one subject with pre-existing IgE actually lost the IgE response following vaccination, most probably reflecting background exposure to environmental plant carbohydrates. Approximately 24 000 people have now received one or two doses of the plantderived VLP vaccine without the induction or worsening of clinical allergies, the development of pathological IgE responses or the long-term elicitation of glycan-specific IgG. The development of influenza vaccines produced by transient expression is therefore one of the key niches of molecular farming that show unambiguous advantages over all other current manufacturing platforms, and this is reflected by the keen interest and investment in the platform by the US and Canadian governments. Ebola haemorrhagic fever in humans is caused by four of the six known species of Ebolavirus, with Zaire ebolavirus causing the most severe symptoms and the greatest number of fatalities. The first known outbreak was in 1976 in Sudan, although the cause was not known until several months later when a second outbreak occurred in Zaire (now the Democratic Republic of the Congo). The virus spreads through contact with body fluids and is thought to transfer from fruit bats to primates (including humans) and some domestic animals. There have been six major outbreaks in the last decade, some of which are current, and the fatality rate for infected individuals is~50% on average, with a maximum of 90% (WHO, 2020d). Work on vaccine development was intermittent until the recent outbreaks brought the disease to global attention, particularly the threat of wider spreading due to international travel, but it has been challenging to complete vaccine trials due to the disease tailing off before programmes can be mounted, leaving a shortage of recruits (Chappell and Watterson, 2017) . Three vaccines have progressed to efficacy trials after successful phase I safety evaluation, two of which were based on adenovirus vectors expressing the Zaire ebolavirus glycoprotein 1 (ChAd3-ZEBOV and Ad26-EBOV/MVA-EBOV) and one based on recombinant vesicular stomatitis virus (rVSV-EBOV). The adenovirus vaccines are efficacious in non-human primates, although Ad26-EBOV/MVA-EBOV requires a modified vaccinia Ankara booster dose. The rVSV-EBOV vaccine was also shown to be effective in humans in a delayed deployment efficacy trial conducted in Guinea at the tail end of the 2014/2015 outbreak (Chappell and Watterson, 2017) and was administered to more than 300 000 enrollees in the subsequent 2018 outbreak in the Democratic Republic of the Congo, resulting in 80% of vaccine recipients resisting the disease and the remainder showing only mild symptoms (Maxmen, 2020) . Given the success of the rVSV-EBOV vaccine and the restriction of vesicular stomatitis virus to mammalian cells, molecular farming has not been used to independently develop any Ebola vaccine candidates. A chimeric protein containing two epitopes from the Zaire ebolavirus glycoprotein 1 fused to the nontoxic B component of the enterotoxigenic Escherichia coli (ETEC) heatlabile toxin (LTB) was expressed in tobacco (14.7 µg/kg fresh leaf biomass) and was immunogenic in BALB/c mice, producing IgA and IgG responses following oral immunization (R ıos-Huerta et al., 2017), but this was not developed any further perhaps because the yields were too low for an economically viable process. However, plants have been used to produce monoclonal antibodies against the virus which can help with the treatment of patients who have already contracted the disease (Olinger et al., 2012; Zeitlin et al., 2011) . Single monoclonal antibodies and cocktails of two or three different types have been produced in N. benthamiana and transplastomic lettuce leaves, achieving the neutralization of Ebola virus in pre-clinical tests (Fulton et al., 2015; Lai et al., 2012; Lin et al., 2018; Phoolcharoen et al., 2011) . The light and heavy chains of monoclonal antibody 6D8 were produced with yields of up to 0.5 g/kg by transient expression (Phoolcharoen et al., 2011) . A cocktail of three monoclonal antibodies known as ZMapp (c13C6, c2G4 and c4G7) was also transiently expressed in tobacco leaves (0.5 g/kg) and, for each antibody, the full-size tetrameric IgG complex containing two heavy and two light chains retained its virus-binding activity (Qiu et al., 2014) . It is important to note that the three antibodies were expressed separately and the purified products were subsequently mixedthe simultaneous expression of multiple antibodies in the same plant is likely to result in hybrid immunoglobulin assembly. In another study, three anti-Ebola virus mouse/human chimeric monoclonal antibodies (c13C6, h-13F6 and c6D8) produced in tobacco completely protected two infected animals in pre-clinical tests (Olinger et al., 2012) . ZMapp was subsequently approved under the animal efficacy rule, which allows temporary use in humans based on animal data if clinical studies would be impossible or unethical. This was deemed to be the case in the 2014-2016 Ebola outbreak in West Africa, in which seven patients were treated with~9 g of the cocktail and five survived (Qiu et al., 2014) . Conventional clinical development continued in parallel, but as in previous vaccine studies it was not possible to collect sufficient data to achieve statistical significance because the number of patients declined as the epidemic wound down (PREVAIL II Writing Group et al., 2016) . In 2020, the FDA approved Inmazeb for the treatment of Zaire ebolavirus infection in adults and children, a combination of three monoclonal , 19, 1901-1920 antibodies (atoltivimab, maftivimab and odesivimab) produced in CHO cells (Markham, 2021) . The lectin CV-N has also shown animal efficacy against Ebola virus (Barrientos et al., 2003) . The mosquito-transmitted Zika virus was discovered in East Africa in 1947, and sporadic individual infections in humans were reported from 1954, but the first epidemic did not occur until 2007, when 185 cases were recorded in the Yap Islands of Micronesia (Gubler et al., 2017) . A series of outbreaks in 2013-2014 affected~9000 people across Oceania, followed by a major epidemic in 2015-2016 in Brazil, spreading to the rest of the Americas and affecting up to 35 000 people, garnering international attention and a WHO classification as a Public Health Emergency of International Concern. Although direct fatalities from the disease are unknown, mother-to-child transmission during pregnancy can cause microcephaly and other brain malformations in the foetus (Rasmussen et al., 2016) . Several countries that have experienced Zika outbreaks have also reported increases in the prevalence of Guillain-Barr e syndrome, which causes muscle weakness and in some cases breathing difficulties and cardiovascular complications. The properties of Zika fever, Ebola fever and non-seasonal influenza as epidemic diseases are compared in Table 3 . A number of Zika virus vaccine candidates are currently under development, many based on previously approved platforms and designs against dengue and other infectious diseases (Tripp and Ross, 2016) . For example, the Zika envelope protein (ZE3) is a safe and efficacious vaccine candidate, producing VLPs that elicit robust anti-ZE3 antibody titres and neutralize the virus efficiently without an adjuvant (Diamos et al., 2020b) . The transient expression of ZE3 in N. benthamiana achieved yields of up to 160 mg/kg fresh leaf biomass, suggesting this could be an effective response strategy to further outbreaks (Yang et al., 2018) . As discussed for Ebola, transient expression has also been used to produce single monoclonal antibodies and cocktails of two or three different types against Zika virus. The yield was up to 1.5 g/kg fresh leaf biomass, and the purified antibodies retained their ability to recognize the Zika virus envelope protein and neutralize the virus (Diamos et al., 2020a) . HIV is a retrovirus that is transmitted through sexual intercourse or contact with infected blood. The virus targets cells of the immune system (CD4 + T cells, macrophages and dendritic cells) and therefore leads to an acquired immunodeficiency syndrome (AIDS) that renders the patient susceptible to opportunistic infections, which are generally the direct cause of death (Bowen et al., 2016; Buchacz et al., 2016; ) . Although there is no vaccine or cure, HIV loads can be controlled by antiretroviral drugs, particularly highly active antiretroviral therapy (HAART) involving multiple drugs with different targets. Accordingly, the population living with HIV is steadily increasing and was nearly 38 million in 2018, with eastern and southern Africa the worst affected regions (UNAIDS, 2020). HIV is a global disease, but its effects are disproportionately felt in poorer regions without access to drugs or preventatives, so molecular farming in transgenic plants is a particularly suitable approach given the potential for large-scale inexpensive production and the use of crops that can be grown locally in developing countries. Several HIV proteins have been expressed in plants as potential vaccine candidates, including the gp140 envelope protein in N. benthamiana at 21.5 mg/kg fresh leaf biomass, which was well tolerated and immunogenic in rabbits (Margolin et al., 2019 (Margolin et al., , 2020 . HIV coat protein genes have also been transiently expressed in N. glutinosa and N. benthamiana, with yields of 814.2 and 462.6 µg/kg fresh leaf biomass, respectively (Ataie Kachoie et al., 2018). The p24 capsid protein (and a fusion of p24 with the negative regulatory protein Nef) was expressed in transplastomic tobacco and tomato plants to levels of up to 40% of total protein and proved to be immunogenic following subcutaneous and oral administration in experimental animals (Gonzalez-Rabade et al., 2011; McCabe et al., 2008; Zhou et al., 2008) . HIV-specific antibodies have been expressed in transgenic rice (Vamvaka et al., 2016c) , tobacco (Niemer et al., 2014) and maize (Sabalza et al., 2012) and have shown promising neutralizing activity in vitro, suggesting they could be used as microbicidal formulations (Ramessar et al., Table 3 Differences between H5N1, Ebola and Zika (modified from Park and Wi, 2016) . R 0 is the basic reproduction number, the expected number of cases directly generated by one case in a population where all individuals are susceptible to the disease 2008b). An HIV polyepitope has also been expressed in lettuce (Govea-Alonso et al., 2013) . Antiviral lectins such as cyanovirin-N and griffithsin transiently expressed in N. benthamiana (Habibi et al., 2018) or stably expressed in soybean (O'Keefe et al., 2015) , rice (Vamvaka et al., 2016a,b) and transplastomic tobacco (Elghabi et al., 2011; Hoelscher et al., 2018) have also proven effective. The benefits of the soybean system are expanded in Box 2. Vamvaka et al. (2018) expressed the HIV-neutralizing monoclonal antibody 2G12 and two lectins (cyanovirin-N and griffithsin) in the same transgenic rice line, providing an inexpensive and scalable strategy for the provision of microbicidal cocktails. The high mutation rate of HIV means that single components are ineffective due to the evolution of escape mutants, but combinations of three or more components targeting different viral epitopes can help to prevent viral spreading. The rice system is advantageous because typical molecular farming products must be purified to homogeneity, and this would abolish the advantage of the triple transgenic lines. However, the generally regarded as safe (GRAS) status of rice and other cereals means that microbicides could be prepared from crude extracts (essentially ground seeds) allowing the development of effective microbicide cocktails that can be stored and transported as dry seed without a cold chain and then prepared as a microbicide in a local facility (Vamvaka et al., 2018) . As a model for this approach, transgenic rice expressing recombinant proteins is already grown in the field in locations where there are no rice crops or compatible wild species, such as the Ventria facilities in the USA and US Virgin Islands (APHIS, 2018), and other companies grow seed-based crops in containment for the same purposes (Fischer and Buyel, 2020) . Transgenic tobacco plants expressing 2G12 were developed during the EU-funded Pharma-Planta project, which resulted in a successful phase I clinical trial . In this case, the production platform and regulatory aspects were adjusted during the study as the regulations concerning GMP requirements changed during the project, resulting in the accreditation of a GMP facility and the successful production of clinical-grade plant-derived 2G12 for intravaginal testing in healthy female subjects Sack et al., 2015) . As stated above, griffithsin has also been produced by transient expression (Fuqua et al., 2015; Hahn et al., 2015) and the economic benefits of this approach have been discussed (Alam et al., 2018) . HPV is a sexually transmitted virus that is harmless in~90% of cases but in a minority of infected persons causes warts that increase the risk of cancer of the anus, vulva, vagina, penis and oropharynx (IARC, 2020) . More than 200 HPV genotypes have been grouped according to the viral genome structure and tropism to human epithelial tissues (Garbuglia, 2014) . Twelve high-risk types (HPV16, 18, 31, 33, 35, 39, 45, 51, 52, 56, 58 and 59) are classified as carcinogenic to humans, leading to 570 000 cases of cervical cancer and 311 000 deaths in 2018 (IARC, 2020) . HPV is combatted by a combination of preventative vaccination and screening (Arbyn et al., 2020) . Several vaccines have been developed, mostly targeting oncoproteins E6 and E7 (Chabeda et al., 2018; Hung et al., 2008; Ma et al., 2010; Moniz et al., 2003) by aiming to deliver the E6 and E7 antigens in to APCs in order to activate CD8 + cytotoxic T cells or CD4 + helper T cells . Bivalent and quadrivalent HPV vaccines containing HPV16 and HPV18 antigens protect na€ ıve individuals with high efficacy and are therefore administered preferentially to school-age girls (Arbyn et al., 2020) . The current VLP-based HPV vaccines -Cervarix (GlaxoSmithKline) and Gardasil (Merck)are highly effective but expensive to produce because they are manufactured in insect and yeast cells, respectively (Wang and Roden, 2013) . They also require a cold chain and must be delivered by intramuscular injection (Ma et al., 2013) . Several plant-based systems have therefore been explored, including transient expression in N. benthamiana, and transgenic tobacco, potato, Arabidopsis and tomato plants. The primary targets have been the L1 and L2 capsid proteins (Buck et al., 2013) and the E6 and E7 oncoproteins (De La Rosa et al., 2009; Franconi et al., 2002; Massa et al., 2007; Morgenfeld et al., 2009) . The L1 and L2 proteins were produced as VLPs in transgenic tobacco and potato (Biemelt et al., 2003; Varsani et al., 2003) . Codon optimization of the HPV sequence and the introduction of a tobacco mosaic virus translational enhancer increased the L1 yields to 20 mg/kg fresh potato tuber, and all the VLPs were immunogenic in mice (Biemelt et al., 2003) and Box 2. The production of lectins in soybean seeds2 Cyanovirin-N is a lectin isolated from the cyanobacterium Nostoc ellipsosporum, and it has been shown to inactivate SIV and HIV by establishing multiple weak interactions with the surface envelope glycoprotein (gp120) thus blocking membrane fusion (Boyd et al., 1997; Tsai et al., 2003; ) . In the context of molecular farming, it is important to note that bacterial systems are uneconomical for the production of this protein because high yields of functional protein are difficult to achieve given the dependence on multiple disulfide bonds (Lofti et al., 2018) . Transgenic plants offer a scalable alternative (O'Keefe et al., 2015) . Soybean seeds are particularly attractive due to their endogenous protein content of 40% compared to 8-10% for cereals (Stoger et al., 2005; Vianna et al., 2011b) . In soybean seeds, the protein storage vacuoles (PSVs) are involved in the accumulation of~70% of all seed proteins (Shimada et al., 2018; Tan et al., 2019; ) making them ideal for the accumulation of recombinant proteins (Cunha et al., ,b, 2013 (Cunha et al., , 2014a (Cunha et al., ,b, 2019 (Cunha et al., , 2020 Jolliffe et al., 2005; Rech et al., 2014; Tan et al., 2019; Vianna et al., 2011a,b; Wakasa and Takaiwa, 2013) . Multiple recombinant proteins have therefore been expressed in soybean PSVs, including proinsulin (Cunha et al., 2010) , human growth hormone , coagulation factor IX , 2014b ), cyanovirin-N (O'Keefe et al., 2015 , antibodies (Vianna et al., 2011a,b) and tumour antigens (Rech et al., 2014) . The proteins remained stable and active after 7 years of seed storage at room temperature (Cunha et al., 2011a,b; O'Keefe et al., 2015; Rech et al., 2014; Vianna et al., 2011a) . Cyanovirin-N was expressed in soybean using the b-conglycinin promoter to restrict expression to the seeds and a signal peptide to target the PSVs, resulting in the detection of the protein specifically in the seeds 4 weeks after pollination, with peak expression after 8 weeks (O'Keefe et al., 2015) . The final concentration of pure cyanovirin-N in the seeds was 3% of total soluble protein (350 g/kg dry seed biomass), and no recombinant protein was detected in the seed oil. , 19, 1901-1920 rabbits (Varsani et al., 2003) in the presence of adjuvants (Biemelt et al., 2003; Varsani et al., 2003; Warzecha et al., 2003) . Transient expression in N. benthamiana (Liu et al., 2005) and expression in transgenic Arabidopsis (Kohl et al., 2007) and transplastomic tomato (De La Rosa et al., 2009) did not improve efficacy or yields. However, a codon-optimized HPV-16 L1 protein was produced by transient expression in N. benthamiana with a yield of 550 mg/kg fresh leaf biomass (Regnard et al., 2010) , and in tobacco plastids with yields of 887 mg/kg (Maclean et al., 2007) and 3 g/kg fresh leaf biomass, the latter equivalent to 24% total soluble protein (Fern andez-San Mill an et al., 2008) . In other transplastomic plants, the yield was~1.5% of the total soluble protein (Lenzi et al., 2008; Waheed et al., 2011) . The L2 protein has only been expressed as an L1-L2 fusion and the yields were no higher than reported above for L1 ( Ce rovsk a et al., 2008 ( Ce rovsk a et al., , 2012 Chabeda et al., 2019; Lamprecht et al., 2016; Mati c et al., 2012) . The E7 protein was produced by transient expression in N. benthamiana using potato virus X vectors, with yields of 3-4 g/kg fresh leaf biomass (Franconi et al., 2002) . E7 was also expressed as a fusion to the PVX coat protein, increasing the stability and immunogenicity of the product compared to native E7 by allowing the assembly of multivalent structures (Morgenfeld et al., 2009) . E7 was also expressed as a fusion to the bacterial enzyme lichenase, improving its stability and facilitating purification, leading to yields of~100 mg/kg fresh leaf biomass . Viral hepatitis is an inflammation of the liver caused by one of five related viruses named hepatitis viruses A-E (Jefferies et al., 2018) . Transmission depends on the type of virus, but it is mainly through sexual contact (HBV), contaminated blood (HCV) or contaminated food and water caused by inadequate sanitation (HAV and HEV). Almost one third of the global population has been infected by either HBV or HCV (WHO, 2012), and 1.34 million people died as a result in 2015 (WHO, 2017b). The highest prevalence of hepatitis is in sub-Saharan Africa for HAV and HBV (Jefferies et al., 2018) , the Eastern Mediterranean Region and Europe for HCV (WHO, 2017b), whereas HEV is more common in Asia and the rest of Africa (Razavi, 2020) . HDV only infects individuals already infected with HBV because it requires HBV for replication (Razavi, 2020) . Effective vaccines are available against HAV and HBV, but not HCV or HDV (Duncan et al., 2020; Ogholikhan and Schwarz, 2016) , and the current HEV vaccine is only licenced for use in China but has not been approved by the FDA (Ogholikhan and Schwarz, 2016) . Lectins have also shown activity against HCV, including griffithsin administered by subcutaneous injection (Meuleman et al., 2011; Takebe et al., 2013) . The HBV surface antigen (HBsAg) was the first vaccine produced in tobacco and was antigenically and physically similar to the HBsAg spherical particles derived from human serum and recombinant yeast (Mason et al., 1992) . Several further subunit vaccines have since been expressed in plants, including the core antigens of HCV (HCcAg) and HBV (HBcAg) as well as antibodies against HBsAg (Hern andez-Vel azquez et al., 2015; Huang et al., 2006; Mohammadzaeh et al., 2015) . Tobacco has been used as the expression host in most studies (L opez et al., 2008; Nemchinov et al., 2000; Rukavtsova et al., 2007; Zhou et al., 2006) but also fruits and vegetables such as tomato (Lou et al., 2007; Ma et al., 2003b) , banana (Elkholy et al., 2009) (Imani et al., 2002) and potato (Thanavala et al., 2005) , and cereals such as rice (Qian et al., 2008) . Two studies have led directly to human clinical trials involving oral vaccines in edible vegetable tissues. Three human volunteers were fed with transgenic lettuce leaves expressing HBsAg (first 200 g, then another 150 g within 2 months). The yield of HBsAg in the lettuce leaves was 1-5 µg/kg fresh tissue. Two weeks after the second dose, HBsAg-specific antibody levels > 10 IU/L were detected in sera from two of three volunteers, which is the accepted minimum protective level against HBV (Kapusta et al., 1999) . In the second study, 33 human volunteers previously immunized with the licenced HBV vaccine (with current antibody titres ≤115 IU/L) were fed with transgenic potato tubers containing HBsAg at a concentration of 8.5 AE 2.1 mg/kg fresh biomass. The volunteers ingested 100-110 g of raw tuber in two doses (days 0 and 28) or three doses (days 0, 14 and 28), causing the antibody titres to increase up to 56-fold after three doses in 10 of 16 volunteers and up to 33-fold after two doses in 9 of 17 volunteers (Thanavala et al., 2005) . Several pre-clinical studies have demonstrated immune responses in mice against plantderived antigens of HAV (Chung et al., 2011 (Chung et al., , 2014 , HBV (Dobrica et al., 2018; Huang et al., 2006) , HCV (Nemchinov et al., 2000) and HEV (Zhou et al., 2006) . Interestingly, as well as its role as a vaccine candidate, HBcAg is also regarded as a model protein for the testing of molecular farming strategies to increase yields. It has therefore been produced by transient expression (Mechtcheriakova et al., 2006) and has also been directed to accumulate in the plastids (Zhou et al., 2006) , vacuole (Hayden et al., 2012) and endoplasmic reticulum (Chung et al., 2014; Mohammadzadeh et al., 2015) of transgenic plants. In the latter case, low proteolytic activity and the presence of chaperones to promote folding resulted in higher levels of accumulation (Tremblay et al., 2010) . However, the highest reported accumulation of HBcAg was in transgenic tobacco when the construct was driven by the cauliflower mosaic virus 35S promoter (CaMV35S) and nos terminator, without a signal peptide, resulting in a yield of 110-250 g/kg fresh biomass (Pyrski et al., 2017) . The HBcAg protein from this experiment induced an immune response in mice, with a 2-5 times more effective response at a dose of 2 9 10 µg rather than 2 9 1 µg (Pyrski et al., 2017) . As discussed elsewhere in this article, the high stability of the HBV core antigen has been exploited by using it as a fusion partner for less stable antigens, allowing the development of chimeric VLPs displaying proteins from other viruses (Peyret et al., 2015) . The future of molecular farming for epidemic and pandemic diseases Scientific advances drive the potential contributions of the international plant science community in the fight against infectious diseases, but this alone is insufficient to guarantee success. As with product development, technology platform development and implementation are highly reliant on acceptability, accessibility, engagement and capacity, particularly if the involvement of low-to-middle-income countries (LMICs) is envisaged (Ma et al., 2013) . In the case of epidemic or pandemic diseases, the involvement of LMIC partners would be a key component of any sustainable long-term action. One example is the long-term collaboration between Bharathiar University (Coimbatore, India) and St. George's University (London, UK), which has been supported by the government-funded UK-India [1901] [1902] [1903] [1904] [1905] [1906] [1907] [1908] [1909] [1910] [1911] [1912] [1913] [1914] [1915] [1916] [1917] [1918] [1919] [1920] Education and Research Initiative since 2007. Through a series of relatively small awards, these two universities established a collaboration targeting two important infectious diseases (Chikungunya and dengue), promoting exchange visits by project leaders and graduate students and four 2-day workshops on molecular farming with sponsorships for graduate scientists from across India to attend. From an Indian national perspective, through the UKIERI-funded workshops, more than 300 graduate scientists were introduced to molecular farming and were able to engage regularly with national experts from research organizations, industry and government regulators, to plan the development path for plant molecular farming in India. The key outputs thus far have been knowledge dissemination and human capacity building across India, which must now be followed up with further investment into plant-based manufacturing (Murad et al., 2020) . On a broader scale, molecular farming must overcome the barriers of industry inertia and regulatory nonalignment that currently prevent its widespread commercial uptake and coordinated international large-scale deployment for vaccine and biologics manufacturing. Molecular farming is a disruptive technology that subverts industry norms, in which biopharmaceutical production is an entirely cleanroom-based process with all biological materials, equipment and reagents, and thus the entire upstream and downstream process, meeting the requirements of GMP. In contrast, the upstream portion of molecular farming often utilizes whole plants grown in indoor facilities under controlled conditions using quality-controlled raw materials and reagents or, depending on the product, under good agricultural and collection practices (GACP) rather than GMP. The downstream process, beginning after the plant homogenization/extraction step and extending through the production of final drug product, would need to meet GMP requirements. The regulation of plant-made pharmaceuticals in the United States and Europe, as well as considerations during public health emergencies, has been recently reviewed by Tus e et al., (2020) illustrating the need to streamline and unify regulatory procedures globally. These elements must be addressed before molecular farming can become a mainstream technology platform and the world can benefit from its capacity for rapid, large-scale and lower cost production (Nandi et al., 2016) , which appears to offer the only realistic approach for global coordinated high-volume vaccine and biologics manufacturing when faced with an emerging disease such as COVID-19. The emergency regulations adopted by the FDA and EMA to facilitate COVID-19 drug development could also help to facilitate this transition by providing a framework in which effective solutions are prioritized over the rigorous enforcement of regulations designed to govern nonemergency drug development . If these barriers can be overcome, molecular farming offers hope to billions of people around the world suffering from endemic, epidemic and pandemic diseases. The authors declare no conflicts of interest. PC and TC conceived the topic. All authors contributed sections to this article based on their expertise and experience, provided comments and recommendations on the combined draft and approved the final version. Technoeconomic modeling of plant-based griffithsin manufacturing A serological assay to detect SARS-CoV-2 seroconversion in humans Circulating ACE2 in cardiovascular and kidney diseases PMPI NEPA decision summary. Online 2020) Estimates of incidence and mortality of cervical cancer in 2018: a worldwide analysis Expression of Human Immunodeficiency Virus type 1 (HIV-1) coat protein genes in plants using cotton leaf curl Multan betasatellite-based vector Plastid molecular pharming II. Production of biopharmaceuticals by plastid transformation Cyanovirin-N binds to the viral surface glycoprotein, GP1,2 and inhibits infectivity of Ebola virus Antiviral effect of phytochemicals from medicinal plants: applications and drug delivery strategies Plastid molecular pharming I. production of oral vaccines via plastid transformation Development and simulation of fully glycosylated molecular models of ACE2-Fc fusion proteins and their interaction with the SARS-CoV-2 spike protein binding domain Production of human papillomavirus type 16 virus-like particles in transgenic plants Engineering plastid genomes: methods, tools, and applications in basic research and biotechnology HIVassociated opportunistic CNS infections: pathophysiology, diagnosis and treatment Discovery of cyanovirin-N, a novel human immunodeficiency virus-inactivating protein that binds viral surface envelope glycoprotein gp120: potential applications to microbicide development Emerging respiratory infections: the infectious disease pathology of SARS, MERS, pandemic influenza, and Legionella Incidence of AIDS-defining opportunistic infections in a multicohort analysis of HIV-infected persons in the United States and Canada The papillomavirus major capsid protein L1 Numeric simulation can be used to predict heat transfer during the blanching of leaves and intact plants Extraction, purification and characterization of the plant-produced HPV16 subunit vaccine candidate E7 GGG Predictive models for transient protein expression in tobacco (Nicotiana tabacum L.) can optimize process time, yield, and downstream costs Flocculation increases the efficacy of depth filtration during the downstream processing of recombinant pharmaceutical proteins produced in tobacco Extraction and downstream processing of plant-derived recombinant proteins Very-large-scale production of antibodies in plants: the biologization of manufacturing Griffithsin with a broad-spectrum antiviral activity by binding glycans in viral glycoprotein exhibits strong synergistic effect in combination with a pancoronavirus fusion inhibitor targeting SARS-CoV-2 spike S2 subunit Potential applications of plant biotechnology against SARS-CoV-2 Coronavirus (COVID-19) frequently asked questions High accumulation in tobacco seeds of hemagglutinin antigen from avian (H5N1) influenza Transient expression of HPV16 E7 peptide (aa 44-60) and HPV16 L2 peptide (aa 108-120) on chimeric potyvirus-like particles using Potato virus X-based vector Transient expression of human papillomavirus type 16 L2 epitope fused to N-and C-terminus of coat protein of Potato Virus X in plants Therapeutic vaccines for high-risk HPV-associated diseases Substitution of human papillomavirus type 16 L2 neutralizing epitopes into L1 surface loops: The effect on virus-like particle assembly and immunogenicity Fighting ebola: a window for vaccine re-evaluation? Corona virus SARS-CoV-2 disease COVID-19: infection, prevention and clinical advances of the prospective chemical drug therapeutics Safety and immunogenicity of a plant-produced recombinant hemagglutinin-based influenza vaccine (HAI-05) derived from A/ Indonesia/05/2005 (H5N1) influenza virus: a phase 1 randomized, doubleblind, placebo-controlled, dose-escalation study in healthy adults Expression of a recombinant chimeric protein of hepatitis A virus VP1-Fc using a replicating vector based on Beet curly top virus in tobacco leaves and its immunogenicity in mice Expression of a functional recombinant chimeric protein of human hepatitis A virus VP1 and an Fc antibody fragment in transgenic tomato plants Lettuce-produced hepatitis C virus E1E2 heterodimer triggers immune responses in mice and antibody production after oral vaccination Technoeconomic analysis of semicontinuous bioreactor production of biopharmaceuticals in transgenic rice cell suspension cultures A systematic review on the efficacy and safety of chloroquine for the treatment of COVID-19 The Authors Safety and immunogenicity of a plantproduced recombinant monomer hemagglutinin-based influenza vaccine derived from influenza A (H1N1) pdm09 virus: a phase 1 dose-escalation study in healthy adults Short communication: correct targeting of proinsulin in protein storage vacuoles of transgenic soybean seeds Plant genetic engineering: basic concepts and strategies for boosting the accumulation of recombinant proteins in crops Basic aspects for choosing crops for recombinant production of therapeutic and industrial molecules Expression of functional recombinant human growth hormone in transgenic soybean seeds Accumulation of functional recombinant human coagulation factor IX in transgenic soybean seeds Expression and characterisation of recombinant molecules in transgenic soybean Recombinant biosynthesis of functional human growth hormone and coagulation factor IX in transgenic soybean seeds Molecular farming of human cytokines and blood products from plants: challenges in biosynthesis and detection of plant-produced recombinant proteins The production of hemagglutinin-based virus-like particles in plants: a rapid, efficient and safe response to pandemic influenza Influenza virus-like particles produced by transient expression in Nicotiana benthamiana induce a protective immune response against a lethal viral challenge in mice Polyphenols as antimicrobial agents Vaccination via chloroplast genetics: affordable protein drugs for the prevention and treatment of inherited or infectious human diseases Green giant -a tiny chloroplast genome with mighty power to produce high-value proteins: history and phylogeny Plant cell-made protein antigens for induction of Oral tolerance Investigational new drug enabling angiotensin oral delivery studies to attenuate pulmonary hypertension An HPV 16 L1-based chimeric human papilloma virus-like particles containing a string of epitopes produced in plants is able to elicit humoral and cytotoxic T-cell activity in mice Antigen production in plant to tackle infectious diseases flare up: the case of SARS Antiviral activity of plants and their isolated bioactive compounds: an update High level production of monoclonal antibodies using an optimized plant expression system Codelivery of improved immune complex and virus-like particle vaccines containing Zika virus envelope domain III synergistically enhances immunogenicity Oral administration of a chimeric Hepatitis B Virus S/ preS1 antigen produced in lettuce triggers infection neutralizing antibodies in mice Therapeutically important proteins from in vitro plant tissue culture systems Development of rhizosecretion as a production system for recombinant proteins from hydroponic cultivated tobacco Hepatitis C virus vaccine: challenges and prospects. Vaccines Optimization of the expression of the HIV fusion inhibitor cyanovirin-N from the tobacco plastid genome Expression of hepatitis B surface Antigen (HBsAg) gene in transgenic banana Human papillomavirus L1 protein expressed in tobacco chloroplasts self-assembles into virus-like particles that are highly immunogenic High-yield expression of M2e peptide of avian influenza virus H5N1 in transgenic duckweed plants Molecular farming -the slope of enlightenment GMP issues for recombinant plant-derived pharmaceutical proteins Plant-derived human papillomavirus 16 E7 oncoprotein induces immune response and specific tumor protection Plastid transformation and its application in metabolic engineering A new synthetic biology approach allows transfer of an entire metabolic pathway from a medicinal plant to a biomass crop Purification of monoclonal antibody against Ebola GP1 protein expressed in Nicotiana benthamiana Improving the large scale purification of the HIV microbicide, griffithsin Human papillomavirus in head neck cancer Antimalarial artemisinin-based combination therapies (ACT) and COVID-19 in Africa: in vitro inhibition of SARS-CoV-2 replication by mefloquine-artesunate Immunogenicity of chloroplast-derived HIV-1 p24 and a p24-Nef fusion protein following subcutaneous and oral administration in mice The Authors Immunogenic properties of a lettuce-derived C4(V3)6 multiepitopic HIV protein History and emergence of zika virus Gene-silencing suppressors for high-level production of the HIV-1 entry inhibitor griffithsin in Nicotiana benthamiana A novel and fully scalable Agrobacterium spray-based process for manufacturing cellulases and other cost-sensitive proteins in plants Pharmacokinetics and pharmacodynamics of recombinant human angiotensin-converting enzyme 2 in healthy human subjects Considerations for extraction of monoclonal antibodies targeted to different subcellular compartments in transgenic tobacco plants Production of highly concentrated, heat-stable hepatitis B surface antigen in maize Contributions of the international plant science community to the fight against infectious diseases in humans -part 2: affordable drugs in edible plants for endemic and re-emerging diseases Tobacco seeds as efficient production platform for a biologically active anti-HBsAg monoclonal antibody Oral tolerance induction in hemophilia B dogs fed with transplastomic lettuce The emergence of antibody therapies for Ebola A plant-derived VLP influenza vaccine elicits a balanced immune response even in very old mice with co-morbidities Prime-pull vaccination with a plant-derived virus-like particle influenza vaccine elicits a broad immune response and protects aged mice from death and frailty after challenge A single intramuscular dose of a plant-made virus-like particle vaccine elicits a balanced humoral and cellular response and protects young and aged mice from influenza H1N1 virus challenge despite a modest/absent humoral response High-level expression of the HIV entry inhibitor griffithsin from the plastid genome and retention of biological activity in dried tobacco leaves SARS-CoV-2 Cell entry depends on ACE2 and TMPRSS2 and is blocked by a clinically proven protease inhibitor Commercial-scale biotherapeutics manufacturing facility for plant-made pharmaceuticals Covid vaccines: will drug companies make bumper profits? BBC News Online 18-12-2020 Rapid, high-level production of hepatitis B core antigen in plant leaf and its immunogenicity in mice On the verge of the market -plant factories for the automated and standardized production of biopharmaceuticals Therapeutic human papillomavirus vaccines: Current clinical trials and future directions The integration of a major hepatitis B virus gene into cell-cycle synchronized carrot cell suspension cultures and its expression in regenerated carrot plants Update on global epidemiology of viral hepatitis and preventive strategies Pathways for protein transport to seed storage vacuoles A plant-derived edible vaccine against hepatitis B virus Potential inhibitor of COVID-19 main protease (M pro) from several medicinal plant compounds by molecular docking study A pilot clinical trial of recombinant human angiotensinconverting enzyme 2 in acute respiratory distress syndrome A systematic review and evaluation of Zika virus forecasting and prediction research during a public health emergency of international concern Expression of HPV-11 L1 protein in transgenic Arabidopsis thaliana and Nicotiana tabacum In silico identification of potent FDA approved drugs against Coronavirus COVID-19 main protease: a drug repurposing approach Robust production of virus-like particles and monoclonal antibodies with geminiviral replicon vectors in lettuce Production of human papillomavirus pseudovirions in plants and their use in pseudovirion-based neutralisation assays in mammalian cells Influenza virus-like particle vaccines made in Nicotiana benthamiana elicit durable, poly-functional and cross-reactive T cell responses to influenza HA antigens Oral immunization of haemaggulutinin H5 expressed in plant endoplasmic reticulum with adjuvant saponin protects mice against highly pathogenic avian influenza A virus infection Translational fusion of chloroplast-expressed human papillomavirus type 16 L1 capsid protein enhances antigen accumulation in transplastomic tobacco Use of GFP to investigate expression of plantderived vaccines Accumulation of recombinant SARS-CoV spike protein in plant cytosol and chloroplasts indicate potential ª 2021 The Authors Important to use dexamethasone only for serious COVID cases: WHO. Reuters Health News An effective way of producing fully assembled antibody in transgenic tobacco plants by linking heavy and light chains via a self-cleaving 2A peptide Expression of human papillomavirus type 16 L1 protein in transgenic tobacco plants An update of the recombinant protein expression systems of Cyanovirin-N and challenges of preclinical development Plant-produced biopharmaceuticals: a case of technical developments driving clinical deployment Clinical and immunological assessment of asymptomatic SARS-CoV-2 infections Expression of the Hepatitis A virus empty capsids in suspension cells and transgenic tobacco plants Expression of the human hepatitis B virus large surface antigen gene in transgenic tomato plants HPV and therapeutic vaccines: where are we in 2010? Curr Realising the value of plant molecular pharming to benefit the poor in developing countries and emerging economies The production of recombinant pharmaceutical proteins in plants Regulatory approval and a first-in-human phase I clinical trial of a monoclonal antibody produced in transgenic tobacco plants Expression of ORF2 partial gene of hepatitis E virus in tomatoes and immunoactivity of expression products Production of recombinant butyrylcholinesterase from transgenic rice cell suspension cultures in a pilot-scale bioreactor Optimization of human papillomavirus type 16 (HPV-16) L1 expression in plants: Comparison of the suitability of different HPV-16 L1 gene variants and different cellcompartment localization High-yield production of a human monoclonal IgG by rhizosecretion in hydroponic tobacco cultures Rhizosecretion improves the production of Cyanovirin-N in Nicotiana tabacum through simplified downstream processing Plant-made virus-like particles bearing influenza hemagglutinin (HA) recapitulate early interactions of native influenza virions with human monocytes/macrophages Plant-derived virus-like particle vaccines drive cross-presentation of influenza A hemagglutinin peptides by human monocyte-derived macrophages SARS-CoV-2 antigens expressed in plants detect antibody responses in COVID-19 patients Compartmentalized metabolic engineering for artemisinin biosynthesis and effective malaria treatment by oral delivery of plant cells Production and immunogenicity of soluble plant-produced HIV-1 subtype C envelope gp140 immunogens Co-expression of human calreticulin significantly improves the production of HIV gp140 and other viral glycoproteins in plants REGN-EB3: first approval Expression of hepatitis B surface antigen in transgenic plants Anti-cancer activity of plant-produced HPV16 E7 vaccine Comparative analysis of recombinant human papillomavirus 8L1 production in plants by a variety of expression systems and purification methods For Ebola in the Democratic Republic of the Congo, the end will have to wait Plastid transformation of high-biomass tobacco variety Maryland Mammoth for production of human immunodeficiency virus type 1 (HIV-1) p24 antigen From farm to finger prick -a perspective on how plants can help in the fight against COVID-19 Techno-economic analysis of a plant-based platform for manufacturing antimicrobial proteins for food safety Assembled HBcAg particles were first produced by transient expression: The use of viral vectors to produce hepatitis B virus core particles in plants Optimized blanching reduces the host cell protein content and substantially enhances the recovery and stability of two plant-derived malaria vaccine candidates Griffithsin has antiviral activity against hepatitis C virus A simplified techno-economic model for the molecular pharming of antibodies A narrative review of influenza: a seasonal and pandemic disease. Iran Heterologous expression of hepatitis C virus core protein in oil seeds of Brassica napus L HPV DNA vaccines Inhibition of SARS-CoV-2 infections in engineered human tissues using clinical-grade soluble human ACE2 The Authors It is time to address airborne transmission of coronavirus disease 2019 (COVID-19) What is a pandemic? Potato virus X coat protein fusion to human papillomavirus 16 E7 oncoprotein enhance antigen stability and accumulation in tobacco chloroplast Molecular pharming for low-and middle-income countries The antimicrobial and antiviral activity of polyphenols from almond (Prunus dulcis L.) skin Techno-economic analysis of a transient plant-based platform for monoclonal antibody production Process development and economic evaluation of recombinant human lactoferrin expressed in rice grain Development of a plant-derived subunit vaccine candidate against hepatitis C virus Natural products as sources of new drugs over the nearly four decades from 01/1981 to 09/2019 The human anti-HIV antibodies 2F5, 2G12, and PG9 differ in their susceptibility to proteolytic degradation: down-regulation of endogenous serine and cysteine proteinase activities could improve antibody production in plant-based expression platforms Engineering soya bean seeds as a scalable platform to produce cyanovirin-N, a non-ARV microbicide against HIV Delayed treatment of Ebola virus infection with plant-derived monoclonal antibodies provides protection in rhesus macaques Oral delivery of novel human IGF-1 bioencapsulated in lettuce cells promotes musculoskeletal cell proliferation, differentiation and diabetic fracture healing Epidemiology, virology, and clinical features of severe acute respiratory syndrome -coronavirus-2 (SARS-CoV-2 Coronavirus Disease-19) Systematic review of plant steroids as potential anti-inflammatory agents: current status and future perspectives Persistence of antibodies against middle east respiratory syndrome coronavirus Tandem fusion of hepatitis B core antigen allows assembly of virus-like particles in bacteria and plants with enhanced capacity to accommodate foreign proteins A plant-derived quadrivalent virus like particle influenza vaccine induces cross-reactive antibody and T cell response in healthy adults Immunogenicity and safety of a quadrivalent plant-derived virus like particle influenza vaccine candidate-two randomized phase II clinical trials in 18 to 49 and ≥50 years old adults Plant-derived H7 VLP vaccine elicits protective immune response against H7N9 influenza virus in mice and ferrets Severe acute respiratory syndrome (SARS) S protein production in plants: development of recombinant vaccine Production of pharmaceutical-grade recombinant aprotinin and a monoclonal antibody product using plant-based transient expression systems A randomized, controlled trial of ZMapp for Ebola virus infection HBcAg produced in transgenic tobacco triggers Th1 and Th2 response when intramuscularly delivered Immunogenicity of recombinant hepatitis B virus surface antigen fused with preS1 epitopes expressed in rice seeds Reversion of advanced Ebola virus disease in nonhuman primates with ZMapp Plant cell packs: a scalable platform for recombinant protein production and metabolic engineering Molecular pharming in cereal crops Cost-effective production of a vaginal protein microbicide to prevent HIV transmission The role of the SARS-CoV-2 S-protein glycosylation in the interaction of SARS-CoV-2/ACE2 and immunological responses Zika virus and birth defects: reviewing the evidence for causality Rapid production of SARS-CoV-2 receptor binding domain (RBD) and spike specific monoclonal antibody CR3022 in Nicotiana benthamiana Global epidemiology of viral hepatitis Recombinant proteins in plants High level protein expression in plants through the use of a novel autonomously replicating geminivirus shuttle vector Expression of an immunogenic LTB-based chimeric protein targeting Zaire ebolavirus epitopes from GP1 in plant cells 2020) Will plant-made biopharmaceuticals play a role in the fight against COVID-19? Expert Opin The Authors Tissue specific expression of hepatitis B virus surface antigen in transgenic plant cells and tissue culture Functional characterization of the recombinant HIV-neutralizing monoclonal antibody 2F5 produced in maize seeds Seeds as a production system for molecular pharming applications: status and prospects From gene to harvest: insights into upstream process development for the GMP production of a monoclonal antibody in transgenic tobacco plants Putting the spotlight back on plant suspension cultures Anti-HIV effects of chloroquine Critical analysis of the commercial potential of plants for the production of recombinant proteins Plant glyco-biotechnology Comprehensive characterization of N-and Oglycosylation of SARS-CoV-2 human receptor angiotensin converting enzyme 2 Plant vacuoles Broad-spectrum antiviral effect of Agrimonia pilosa extract on influenza viruses Plant-derived hemagglutinin protects ferrets against challenge infection with the A/Indonesia/05/05 strain of avian influenza Plant expressed HA as a seasonal influenza vaccine candidate Plant-based rapid production of recombinant subunit hemagglutinin vaccines targeting H1N1 and H5N1 influenza Immunogenicity of hemagglutinin from A/Bar-headed Goose/ Qinghai/1A/05 and A/Anhui/1/05 strains of H5N1 influenza viruses produced in Nicotiana benthamiana plants A plant-based system for rapid production of influenza vaccine antigens A plant-produced H1N1 trimeric hemagglutinin protects mice from a lethal influenza virus challenge Immunogenicity of H1N1 influenza virus-like particles produced in Nicotiana benthamiana Glycosylation of therapeutic proteins: an effective strategy to optimize efficacy Sowing the seeds of success: pharmaceutical proteins from plants Low cost industrial production of coagulation factor IX bioencapsulated in lettuce cells for oral tolerance induction in hemophilia B Transient recombinant protein production in glycoengineered Nicotiana benthamiana cell suspension culture Immunogenicity in humans of a recombinant bacterialantigen delivered in transgenic potato Human immune responses to a novel norwalk virus vaccine delivered in transgenic potatoes Antiviral lectins from red and blue-green algae show potent in vitro and in vivo activity against hepatitis C virus Large-scale production of pharmaceutical proteins in plant cell culture: the protalix experience Immunogenicity in humans of an edible vaccine for hepatitis B Tobacco, a highly efficient green bioreactor for production of therapeutic proteins Development of a Zika vaccine Cyanovirin-N gel as a topical microbicide prevents rectal transmission of SHIV89.6P in macaques Plant molecular farming: much more than medicines The emergency response capacity of plant-based biopharmaceutical manufacturing: what it is and what it could be Cyanovirin-N produced in rice endosperm offers effective pre-exposure prophylaxis against HIV-1BaLinfection in vitro Unexpected synergistic HIV neutralization by a triple microbicide produced in rice endosperm Rice endosperm produces an underglycosylated and potent form of the HIV-neutralizing monoclonal antibody 2G12 Expression of human papillomavirus type 16 major capsid protein in transgenic Nicotiana tabacum cv Expression and accumulation of heterologous molecules in the protein storage vacuoles of soybean seeds Soybeans as bioreactors for biopharmaceuticals and industrial proteins Global burden of 369 diseases and injuries in 204 countries and territories, 1990-2019: a systematic analysis for the Global Burden of Disease Study Transplastomic expression of a modified human papillomavirus L1 protein leading to the assembly of capsomeres in tobacco: ª 2021 The Authors a step towards cost-effective second-generation vaccines Seed storage proteins Techno-economic analysis of horseradish peroxidase production using a transient expression system in Nicotiana benthamiana Convalescent plasma may be a possible treatment for COVID-19: A systematic review Virus-like particles for the prevention of human papillomavirus-associated malignancies Phase 1 randomized trial of a plant-derived viruslike particle vaccine for COVID-19 Human antibody response to N-glycans present on plant-made influenza virus-like particle (VLP) vaccines. Vaccine Efficacy, immunogenicity, and safety of a plantderived, quadrivalent, virus-like particle influenza vaccine in adults (18-64 years) and older adults (≥ 65 years): two multicentre, randomised phase 3 trials Phase III: Randomized observer-blind trial to evaluate lot-to-lot consistency of a new plant-derived quadrivalent virus like particle influenza vaccine in adults 18-49 years of age Oral immunogenicity of human papillomavirus-like particles expressed in Potato Agtech infrastructure for pandemic preparedness (2019) Cholera situation in Yemen Deaths from Democratic Republic of the Congo measles outbreak Top 6000 6c WHO (2020d) Ebola virus disease WHO Director-General (2020) Opening remarks at the media briefing on COVID-19 -22 Characterization of the innate stimulatory capacity of plantderived virus-like particles bearing influenza hemagglutinin Production of monoclonal antibodies by tobacco hairy roots Cryo-EM structure of the 2019-nCoV spike in the prefusion conformation High expression of ACE2 receptor of 2019-nCoV on the epithelial cells of oral mucosa Current state in the development of candidate therapeutic HPV vaccines Plant-produced Zika virus envelope protein elicits neutralizing immune responses that correlate with protective immunity against Zika virus in mice Inhibition of SARS-CoV-2 viral entry upon blocking N-and Oglycan elaboration Efficacy of rice-based oral rehydration solution containing recombinant human lactoferrin and lysozyme in Peruvian children with acute diarrhea Enhanced potency of a fucose-free monoclonal antibody being developed as an Ebola virus immunoprotectant Expression and functional evaluation of biopharmaceuticals made in plant chloroplasts Long-term efficacy of a hepatitis E vaccine Serological diagnostic kit of SARS-CoV-2 antibodies using CHO-expressed full-length SARS-CoV-2 S1 proteins Boosted expression of the SARS-CoV nucleocapsid protein in tobacco and its immunogenicity in mice High-level expression of human immunodeficiency virus antigens from the tobacco and tomato plastid genomes A truncated hepatitis E virus ORF2 protein expressed in tobacco plastids is immunogenic in mice Overcoming low yields of plantmade antibodies by a protein engineering approach The authors would like to thank the Spanish Ministry of Economy, Industry and Competitiveness (project AGL2017-85377-R), the Spanish Ministry of Science, Innovation and Universities (projects RTI2018-097613-B-I00 and PGC2018-097655-B-I00), the EU Horizon 2020 project Pharma-Factory (774078) and the Generalitat de Catalunya (Grups Consolidats 2017-SGR828), Ag encia Additional supporting information may be found online in the Supporting Information section at the end of the article.Table S1 Classification of epidemic and pandemic diseases based on their epidemiology