At present, the target of most of the SARS-CoV-2 (Covid-19) vaccine development worldwide is the spike protein (S) or, more specifically, the receptor-binding domain (RBD) of the virus (1). According to The World Health Organization, almost all of these vaccines will be delivered parentally by intramuscular injection (2). The goal is to achieve broadly neutralizing IgG antibody production in response to a systemic viremia and contribute to the mucosal immune defense. However, questions remain about the relative impact that IgG makes to the mucosal response, whether or not it can provide durable immunity, especially in the aging population, and to what degree it contributes to the immunopathology of antibody-dependent enhancement (ADE).
Despite the reliance on the intramuscular approach, mucosal administration of vaccines has been highly successful from ancient through modern times (3). The late Norwegian immunologist, Per Brandtzaeg, was a strong advocate for the intranasal administration of vaccines because of the regional effect that it has on the upper airways with the production of both systemic and mucosal IgA and systemic IgG immunoglobulins (4). He was also highly critical of the surgical removal of the adenoids and tonsils in children, in part, due to impaired responses to vaccines (5). Perhaps the pediatric population is being spared the ravages of the current pandemic due to the protective nature of the adenoids and tonsils.
The tonsils and adenoids are part of the mucosal immune system known as Waldeyer’s ring or the nasal associated lymphoid tissue (NALT). This organized mucosal associated lymphatic tissue lies below the lamina propria of the nasal mucosa and is the primary inductive site for the secretory immune system (6). It is in this region where all the molecular and cellular conditions are available for the production of secretory IgA (S-IgA) by plasma cells and memory-type IgA+ B cells independently of the bone marrow (7).
Plasma B cells produce both monomeric (sIgA) and polymeric (pIgA) multimers, dimers, tetramers and pentamers (8). This multivalency results in greater avidity for viral peptides than IgG (9) and prevents the infiltration of pathogens known as immune exclusion (10). The pIgA is actively transported across the cell membrane from the basolateral to the apical surface of the secretory epithelium by the secretory component (SC) of polymeric-immunoglobulin receptor (pIgR) as a secretory (SIgA) complex. As the SIgA reaches the surface of the uninfected cell, SC separates from the SIgA where both elements diffuse into the mucus layer and provide specific protective mechanisms (11). In vitro, free SC binds to IL-8 and inhibits IL-8-mediated recruitment of neutrophils to prevent neutrophil extracellular traps in the airways (see below) (12, 13). If a cell has become infected by a virus, pIgA complex is absorbed through the basal membrane by the pIgR where it is then internalized into the endoplasmic reticulum leading to the intracellular neutralization of newly formed viral proteins which are then eliminated through the apical surface into the intestinal or airway lumen (14).
The expression of the peripheral node addressin (PNAd) by the high-walled endothelial venules of the NALT accounts for the trafficking of B and T lymphocytes to the salivary, parotid and submaxillary gland lymph nodes (15, 16) where plasma B cells then migrate to the salivary and parotid glands to express IgA that offers protection against bacterial pathogens produced in the oral cavity as well as inhaled airborne virions (17). The PNAd derived from NALT also promotes a mucosal and systemic humoral response that includes that includes the lungs (18) and the genital mucosa (19).
Given that PNAd is expressed by the HEV in the NALT and bronchial associated lymphatic tissues, its role in cellular immunity in response to vaccination is paramount since up to 80% of lymphocytes in human tonsils are CD8+ memory cells (20). On the other hand, naïve T cells were excluded from the mucosal-associated tissue in mice that were challenged with influenza virus that suggested a mechanism of immune tolerance in the upper airway. The activation of CD8+ cells by intranasal boosting with a recombinant vaccinia virus encoding the spike protein of the SARS-CoV in mice resulted in pathogen clearance from a lethal challenge of the virus (21). However, in Covid-19 patients, lymphopenia is the hallmark of disease progression (22) and in particular, CD8+ and natural killer cells (NK) decreased with progression of the disease (23). Not only does the innate immune response fail to protect against Covid-19, but it may be the underlying cause of the increased morbidity and mortality (24).
A large body of literature has demonstrated that protection of the lungs is afforded by nasal administration of a variety of viral and bacterial vaccines (25–27). While there are concerns about the durability of IgG antibodies to Covid-19 (28), IgA antibodies to influenza generated by the diffuse NALT lining the nasal passages lasted for the life of the animal (29).
The Covid-19 infection epitomizes a mucosal disease process. Close contact, aerosol droplets, and fomites facilitate the transmission of the virus where it comes into contact with the oronasal and conjunctival mucosa. Here, the spike protein of the virus binds to the angiotensin-converting enzyme-2 (ACE2) receptor of the target cells capable of replicating the virus (30). The nasal epithelium has the highest concentration of ACE2, and the alveoli have the lowest (31). These findings reflect that the most robust replication of the virus likely takes place in the nose and little or none in the alveoli (32). Furthermore, the epithelial cells lining the salivary gland ducts that are rich in the expression of ACE2 actively produce virions (33) that are spread through aerosol droplets (34) that may be inhaled or aspirated into the lung. (31, 35) However, since IgA seroconversion occurs two days after the onset of infection, and is detected earlier than IgM or IgG in Covid-19 patients (36), its presence in the saliva not only provides the basis for point-of-care diagnostic testing (37) but further supports the use of the intranasal administration of a vaccine in order to neutralize the virus at its source—the upper airway.
However, despite the presence of antigen presenting cells in the nasal and oral mucosa, SARS-CoV-1 was able to evade this innate immune response in Rhesus macaques (RM), and within two days post infection (dpi) had breached the upper respiratory epithelium where it infected the underlying mucosal dendritic cells and macrophages that subsequently migrated from Waldeyer’s ring to draining lymph nodes and into the lungs where they formed dense clusters around the alveoli (38). The sequestration of virus in intracellular vesicles of the macrophages demonstrates the critical role that these antigen presenting cells (APC) play in the dissemination of the virus to the lung and systemic compartment especially since viral shedding of Covid-19 in the pharynx precedes viral replication in the lungs (39).
While pre-existing immunity is considered beneficial, there is great concern that the accelerated pace to develop a vaccine against SARS-CoV-2 will result in a detrimental immune response, i.e., an antibody-dependent enhancement (ADE) of the infection (40). Particularly disturbing is the fact that as a result of prior exposure to the “common cold coronavirus” (CCC), T cell reactivity to SARS-CoV-2 antigen peptide pools is in the 20–50% range in unexposed blood donors from across the globe (41). In fact, one study showed that 90% of the human race tested positive for three of the four CCCs (42). A recent study showed that 35% of seronegative Covid-19 healthy donors had cross-reactive CD4+ T cells to the S protein probably acquired from previous infections with human coronaviruses (43). The presence of durable cross-reactive T cell memory responses would play a role in amplifying an anamnestic B cell response against those common antigens (44, 45). Thus, prior sensitization to conserved epitopes could lead to the production of non- neutralizing or sub-neutralizing binding antibodies, principally of the IgG isotype, and form antigen-antibody complexes. These immune complexes (IC) act as molecular bridges between a virus and immune cells (46) expressing either a complement receptor, IgG Fc receptor (FcγR) on the surface and neonatal Fc receptor (FcRn) (47) intracellularly. The FcγR can function as a mimic for the ACE2 receptor that is not expressed on all immune cells and allows for neutralizing antibodies to gain access to the reproductive machinery of those cells (48). Ultimately, the ratio of activating versus inhibitory FcγRs will determine the severity of the disease based on the subtype of IgG that it binds and the subsequent signaling cascades it produces (49). When the IC binds to an activating FcγR on APCs it also results in the production of proinflammatory cytokines and chemokines that lead to lung and other organ injury (50, 51). This hypercytokinemia causes an increased transudate and production of hyaluronan in the alveoli that absorbs up to 1,000 times its molecular weight with water resulting in the severe acute respiratory syndrome (SARS) and death (52). Even though ADE is primarily associated with IgG antibodies, the phenomenon has also been observed with IgA antibodies in HIV infection (53, 54). However, other than HIV, IgA has not been identified with ADE in any other viral infection.
Two recent studies confirmed that fully neutralizing IgG antibodies led to disease enhancement. One study showed that monoclonal antibodies targeting the MERS-CoV RBD caused a conformational change in the spike protein that blocked viral entry into cells expressing its cognate receptor, dipeptidyl peptidase 4 and directed its entry into FcγR expressing cells (55). In the second study, an IM vaccination that produced an anti-spike IgG (S-IgG) and an intravenous administration of S-IgG monoclonal antibodies correlated with acute lung injury during a SARS-CoV infection of RM (56). Although the anti-S-IgG reduced the expression of viral RNA in the lungs, it led to a massive accumulation of monocyte/macrophages within 2 dpi that caused significant diffuse alveolar damage. An antibody directed against the FcγR reduced the production of IL-8 and MCP1 by wound-healing macrophages suggesting that the mechanism of acute lung injury was mediated by the anti-S-IgG antibody.
It is not known if the expression of neonatal Fc receptor (FcRn) in the endothelial, airway and gastrointestinal tissues (57) plays a role in IgG mediated enhancement of SARS-CoV-2. Coronaviruses as well as other viruses that form immune complexes with IgG antibodies are transcytosed through the plasma membrane and transported intracellularly by the FcRn into the endosomal system (58). Both the IgG antibody (59) and the mouse hepatitis virus, a prototypic member of the CoV family (60), depend on the same Rab GTPases in the endosomal system for the recycling of IgG and for the proteolytic processing of their fusion proteins respectively. This escorted means of endocytosis of the virus could be the underlying mechanism of the endovascular events observed late in the infection (61). Of particular note, 82% of the cases of Kawasaki-like disease in children in France had IgG antibodies for SARS-CoV-2 (62).
Although the induction of a mucosal response by systemic immunization remains poorly understood (63), the use of an appropriate adjuvant could change the outcome and lead to the expression of IgA (64). Nevertheless, the intranasal administration of a vaccine is inherently associated with an IgA response. An additional benefit of IgA is based on its non-inflammatory effects since neither the secreted, monomeric form (sIgA) found in serum nor the secretory, polymeric form (S-IgA) found in mucosal secretions activate any of the three complement pathways (65, 66). And, when bound to the antigen, IgA blocks the binding of IgG and IgM and thus prevents the complement-mediated inflammatory effects associated with these isotypes (67). Furthermore, all forms of the IgA antibody, serum and secretory, monoclonal and polyclonal, interfered with complement-dependent phagocytosis by neutrophils mediated by IgG antibodies (66). This would be beneficial in limiting the recruitment of neutrophils to the lungs and the inflammasomes associated with viral infections (68).
In the context of a coronavirus vaccine, two separate studies compared the efficacy of an intramuscular versus a mucosal route. The first study used a recombinant adeno-associated virus (rAAV)-based RBD (RBD-rAAV) vaccine to the SARS-CoV spike protein (69) and the second studied three adenovirus-based vaccine candidates against MERS-CoV (70). In both studies, the intranasal route was superior to the IM route in terms of a systemic and local humoral response, and both had a stronger systemic and pulmonary CTL response. However, neither the IM nor intranasal administration of the SARS-CoV RBD-rAAV vaccine produced any ADE which the authors attributed to the properties of the adenovirus vector and its specificity for the particular epitope within the RBD. But perhaps most importantly, only the intranasal and subligual administration of the MERS-CoV full-length spike protein induced IgA antibodies that were found in the broncholaveolar lavage fluid. Thus far, only one paper has clearly substantiated the validity of previous articles that support the nasal administration of a Covid-19 vaccine (71) although a number of academic and biopharma entities have announced their successes with press releases.
While IgA is the most highly expressed antibody in the body, its production by the mucosal-associated lymphatic tissue declines with age. This decline is one aspect of a condition known as immunosenescence that is particularly relevant in the current pandemic caused by Covid-19 in which the elderly are the most vulnerable population. However, a study in mice showed that the aging process affects the NALT to a lesser degree than the gastrointestinal associated lymphatic tissue (72). This suggests that all of the necessary immunocompetent cells are maintained in the nasal mucosa to mount an effective immune response. However, the need still remains to determine an appropriate adjuvant for mucosal administration (73) of a Covid-19 vaccine especially one that would avoid a Th17 response that contributes to the eosinophilic infiltration in the lungs (74).
If seen only from an immunological perspective, the IM administration of a vaccine is not without its drawbacks (75). There is a significant concern about the lack of availability of vials, needles, and syringes to meet the global demand. Then, there is the need for trained personnel to administer the vaccine intramuscularly that can result in as many as five needle-stick injuries per 100 injections worldwide (76). Also, there may be poor compliance due to the anticipated pain at the injection site and concerns about the arms race mentality that may have flattened the traditional trajectory required for a safe and effective vaccine. And, lastly, there is a significant concern for the reuse of needles and syringes in developing countries that can lead to blood-borne viral infections and for the proper disposal of this medical waste in these countries.
Regulatory agencies worldwide should require a comparison of the parenteral administration with mucosal delivery and accelerate the approval of the appropriate adjuvants, particularly for the aging population. If successful, mucosal delivery will play a protective role in preventing the invasion of the virus early in the infectious process and prevent the viremia to which an IgG response is also generated. Mucosal delivery also represents a more cost-effective and efficient means of delivering a vaccine in the time of a pandemic. And ultimately, there is less likelihood of an immunopathological immune response known as ADE that is invariably associated with IgG.
Author Contributions
The author confirms being the sole contributor of this work and has approved it for publication.
Conflict of Interest
CT is the Founder and President of Immugen Pharma LLC.
References
1. Premkumar L, Segovia-Chumbez B, Jadi R., Martinez DR, Raut R, Markmann A, et al. The receptor binding domain of the viral spike protein is an immunodominant and highly specific target of antibodies in SARS-CoV-2 patients. Sci Immunol (2020) 5(48):eabc8413. doi: 10.1126/sciimmunol.abc8413
2. Available at: https://www.who.int/publications/m/item/draft-landscape-of-covid-19-candidate-vaccines.
3. Hellfritzsch M, Scherließ R. Mucosal Vaccination via the Respiratory Tract. Pharmaceutics (2019) 11(8):375. doi: 10.3390/pharmaceutics11080375\
4. Brandtzaeg P. Potential of nasopharynx-associated lymphoid tissue for vaccine responses in the airways. Am J Respir Crit Care Med (2011) 183(12):1595–604. doi: 10.1164/rccm.201011-1783OC
5. Ogra PL. Effect of tonsillectomy and adenoidectomy on nasopharyngeal antibody response to poliovirus. N Engl J Med (1971) 284(2):59–64. doi: 10.1056/NEJM197101142840201
6. Shikina T, Hiroi T, Iwatani K, Jang MH, Fukuyama S, Tamura M, et al. IgA class switch occurs in the organized nasopharynx- and gut-associated lymphoid tissue, but not in the diffuse lamina propria of airways and gut. J Immunol (2004) 172(10):6259–64. doi: 10.4049/jimmunol.172.10.6259
7. Jahnsen FL, Gran E, Haye R, Brandtzaeg P. Human nasal mucosa contains antigen-presenting cells of strikingly different functional phenotypes. Am J Respir Cell Mol Biol (2004) 30(1):31–7. doi: 10.1165/rcmb.2002-0230OC
8. Kumar N, Arthur CP, Ciferri C, Matsumoto ML. Structure of the secretory immunoglobulin A core. Sci (New York NY) (2020) 367(6481):1008–14. doi: 10.1126/science.aaz5807
9. Muramatsu M, Yoshida R, Yokoyama A, Miyamoto H, Kajihara M, Maruyama J, et al. Comparison of antiviral activity between IgA and IgG specific to influenza virus hemagglutinin: increased potential of IgA for heterosubtypic immunity. PLoS One (2014) 9(1):e85582. doi: 10.1371/journal.pone.0085582
10. Yan H, Lamm ME, Björling E, Huang YT. Multiple functions of immunoglobulin A in mucosal defense against viruses: an in vitro measles virus model. J Virol (2002) 76(21):10972–9. doi: 10.1128/jvi.76.21.10972-10979.2002
11. Rogier EW, Frantz AL, Bruno ME, Kaetzel CS. Secretory IgA is Concentrated in the Outer Layer of Colonic Mucus along with Gut Bacteria. Pathogens (2014) 3(2):390–403. doi: 10.3390/pathogens3020390
12. Marshall LJ, Perks B, Ferkol T, Shute JK. IL-8 released constitutively by primary bronchial epithelial cells in culture forms an inactive complex with secretory component. J Immunol (2001) 167(5):2816–23. doi: 10.4049/jimmunol.167.5.2816
13. Zuo Y, Yalavarthi S, Shi H, Gockman K, Zuo M, Madison JA, et al. Neutrophil extracellular traps in COVID-19. JCI Insight (2020) 5(11):e138999. doi: 10.1172/jci.insight.138999
14. Mazanec MB, Kaetzel CS, Lamm ME, Fletcher D, Nedrud JG. Intracellular neutralization of virus by immunoglobulin A antibodies. Proc Natl Acad Sci U S A (1992) 89(15):6901–5. doi: 10.1073/pnas.89.15.6901
15. Csencsits KL, Jutila MA, Pascual DW. Nasal-associated lymphoid tissue: phenotypic and functional evidence for the primary role of peripheral node addressin in naive lymphocyte adhesion to high endothelial venules in a mucosal site. J Immunol (Baltimore Md 1950) (1999) 163(3):1382–9.
16. Csencsits KL, Jutila MA, Pascual DW. Mucosal addressin expression and binding-interactions with naive lymphocytes vary among the cranial, oral, and nasal-associated lymphoid tissues. Eur J Immunol (2002) 32(11):3029–39. doi: 10.1002/1521-4141(200211)32:11<3029::AID-IMMU3029>3.0.CO;2-9
17. Brandtzaeg P. Secretory immunity with special reference to the oral cavity. J Oral Microbiol (2013) 5. doi: 10.3402/jom.v5i0.20401
18. Xu B, Wagner N, Pham LN, Magno V, Shan Z, Butcher EC, et al. Lymphocyte homing to bronchus-associated lymphoid tissue (BALT) is mediated by L-selectin/PNAd, alpha4beta1 integrin/VCAM-1, and LFA-1 adhesion pathways. J Exp Med (2003) 197(10):1255–67. doi: 10.1084/jem.20010685
19. VanCott TC, Kaminski RW, Mascola JR, Kalyanaraman VS, Wassef NM, Alving CR, et al. HIV-1 neutralizing antibodies in the genital and respiratory tracts of mice intranasally immunized with oligomeric gp160. J Immunol (Baltimore Md 1950) (1998) 160(4):2000–12.
20. Pizzolla A, Wang Z, Groom JR, Kedzierska K, Brooks AG, Reading PC, et al. Nasal-associated lymphoid tissues (NALTs) support the recall but not priming of influenza virus-specific cytotoxic T cells. Proc Natl Acad Sci U S A (2017) 114(20):5225–30. doi: 10.1073/pnas.1620194114
21. Channappanavar R, Fett C, Zhao J, Meyerholz DK, Perlman S. Virus-specific memory CD8 T cells provide substantial protection from lethal severe acute respiratory syndrome coronavirus infection. J Virol (2014) 88(19):11034–44. doi: 10.1128/JVI.01505-14
22. Cao X. COVID-19: immunopathology and its implications for therapy. Nat Rev Immunol (2020) 20(5):269–70. doi: 10.1038/s41577-020-0308-3
23. Jiang Y, Wei X, Guan J, Qin S, Wang Z, Lu H, et al. COVID-19 pneumonia: CD8+ T and NK cells are decreased in number but compensatory increased in cytotoxic potential. Clin Immunol (Orlando Fla) (2020) 218:108516. doi: 10.1016/j.clim.2020.108516
24. Lucas C, Wong P, Klein J, Castro T, Silva J, Sundaram M, et al. Longitudinal analyses reveal immunological misfiring in severe COVID-19. Nature (2020) 584(7821):463–9. doi: 10.1038/s41586-020-2588-y
25. Sealy R, Jones BG, Surman SL, Hurwitz JL. Robust IgA and IgG-producing antibody forming cells in the diffuse-NALT and lungs of Sendai virus-vaccinated cotton rats associate with rapid protection against human parainfluenza virus-type 1. Vaccine (2010) 28(41):6749–56.
26. Terauchi Y, Sano K, Ainai A, Saito S, Taga Y, Ogawa-Goto K, et al. IgA polymerization contributes to efficient virus neutralization on human upper respiratory mucosa after intranasal inactivated influenza vaccine administration. Hum vaccines Immunother (2018) 14(6):1351–61. doi: 10.1080/21645515.2018.1438791
27. Lowell GH, Kaminski RW, Grate S, Hunt RE, Charney C, Zimmer S, et al. Intranasal and intramuscular proteosome-staphylococcal enterotoxin B (SEB) toxoid vaccines: immunogenicity and efficacy against lethal SEB intoxication in mice. Infect Immun (1996) 64(5):1706–13. doi: 10.1128/IAI.64.5.1706-1713.1996
28. Liu A, Wang W, Zhao X, Zhou X, Yang D, Lu M, Lv Y, et al. Disappearance of antibodies to SARS-CoV-2 in a -COVID-19 patient after recovery. Clin Microbiol Infect (2020) S1198–743X(20)30411-0. doi: 10.1016/j.cmi.2020.07.009
29. Liang B, Hyland L, Hou S. Nasal-associated lymphoid tissue is a site of long-term virus-specific antibody production following respiratory virus infection of mice. J Virol (2001) 75(11):5416–20. doi: 10.1128/JVI.75.11.5416-5420.2001
30. Walls AC, Park YJ, Tortorici MA, Wall A, McGuire AT, Veesler D. Structure, Function, and Antigenicity of the SARS-CoV-2 Spike Glycoprotein. Cell (2020) 181(2):281–292.e6. doi: 10.1016/j.cell.2020.02.058
31. Hou YJ, Okuda K, Edwards CE, Martinez DR, Asakura T, Dinnon KH. SARS-CoV-2 Reverse Genetics Reveals a Variable Infection Gradient in the Respiratory Tract. Cell (2020) 182(2):426–46.e14. doi: 10.1016/j.cell.2020.05.042
32. Sims AC, Baric RS, Yount B, Burkett SE, Collins PL, Pickles RJ. Severe acute respiratory syndrome coronavirus infection of human ciliated airway epithelia: role of ciliated cells in viral spread in the conducting airways of the lungs. J Virol (2005) 79(24):15511–24. doi: 10.1128/JVI.79.24.15511-15524.2005
33. Liu L, Wei Q, Alvarez X, Wang H, Du Y, Zhu H, et al. Epithelial cells lining salivary gland ducts are early target cells of severe acute respiratory syndrome coronavirus infection in the upper respiratory tracts of rhesus macaques. J Virol (2011) 85(8):4025–30. doi: 10.1128/JVI.02292-10
34. Isho B, Abe KT, Zuo M, Jamal AJ, Rathod B, Samavarchi-Tehrani P. Mucosal versus systemic antibody responses to SARS-CoV-2 antigens in COVID-19 patients. medRxiv (2020). doi: 10.1101/2020.08.01.20166553
35. Yu HQ, Sun BQ, Fang ZF, Zhao JC, Liu XY, Li YM, et al. Distinct features of SARS-CoV-2-specific IgA response in COVID-19 patients. Eur Respir J (2020) 56(2):2001526. doi: 10.1183/13993003.01526-2020
36. Ma H, Zeng W, He H, Zhao D, Jiang D, Zhou P, et al. Serum IgA, IgM, and IgG responses in COVID-19. Cell Mol Immunol (2020) 17(7):773–5. doi: 10.1038/s41423-020-0474-z
37. Varadhachary A, Chatterjee D, Garza J, Garr RP, Foley C, Letkeman AF, et al. Salivary anti-SARS-CoV-2 IgA as an accessible biomarker of mucosal immunity against COVID-19. medRxiv preprint server Health Sci (2020). doi: 10.1101/2020.08.07.20170258
38. Liu L, Wei Q, Nishiura K, Peng J, Wang H, Midkiff C, et al. Spatiotemporal interplay of severe acute respiratory syndrome coronavirus and respiratory mucosal cells drives viral dissemination in rhesus macaques. Mucosal Immunol (2016) 9(4):1089–101. doi: 10.1038/mi.2015.127
39. Wölfel R, Corman VM, Guggemos W, Seilmaier M, Zange S, Müller MA, et al. Virological assessment of hospitalized patients with COVID-2019. Nature (2020) 581(7809):465–9. doi: 10.1038/s41586-020-2196-x
40. Iwasaki A, Yang Y. The potential danger of suboptimal antibody responses in COVID-19. Nat Rev Immunol (2020) 20(6):339–41. doi: 10.1038/s41577-020-0321-6
41. Sette A, Crotty S. Pre-existing immunity to SARS-CoV-2: the knowns and unknowns. Nat Rev Immunol (2020), 1–2. doi: 10.1038/s41577-020-0389-z
42. Gorse GJ, Patel GB, Vitale JN, O’Connor TZ. Prevalence of antibodies to four human coronaviruses is lower in nasal secretions than in serum. Clin Vaccine Immunol CVI (2010) 17(12):1875–80. doi: 10.1128/CVI.00278-10
43. Braun J, Loyal L, Frentsch M, Wendisch D, Georg P, Kurth F, et al. SARS-CoV-2-reactive T cells in healthy donors and patients with COVID-19. Nature (2020). doi: 10.1038/s41586-020-2598-9
44. Eroshenko N, Gill T, Keaveney MK, Church GM, Trevejo JM, Rajaniemi H. Implications of antibody-dependent enhancement of infection for SARS-CoV-2 countermeasures. Nat Biotechnol (2020) 38(7):789–91. doi: 10.1038/s41587-020-0577-1
45. Mitchison NA. T-cell-B-cell cooperation. Nat Rev Immunol (2004) 4(4):308–12. doi: 10.1038/nri1334
46. Taylor A, Foo SS, Bruzzone R, Dinh LV, King NJ, Mahalingam S. Fc receptors in antibody-dependent enhancement of viral infections. Immunol Rev (2015) 268(1):340–64. doi: 10.1111/imr.12367
47. Pyzik M, Sand K, Hubbard JJ, Andersen JT, Sandlie I, Blumberg RS. The Neonatal Fc Receptor (FcRn): A Misnomer? Front Immunol (2019) 10:1540. doi: 10.3389/fimmu.2019.01540
48. Smatti MK, Al Thani AA, Yassine HM. Viral-Induced Enhanced Disease Illness. Front Microbiol (2018) 9:2991. doi: 10.3389/fmicb.2018.02991
49. Jaume M, Yip MS, Cheung CY, Leung HL, Li PH, Kien F, et al. Anti-severe acute respiratory syndrome coronavirus spike antibodies trigger infection of human immune cells via a pH- and cysteine protease-independent FcγR pathway. J Virol (2011) 85(20):10582–97. doi: 10.1128/JVI.00671-11
50. Yip MS, Leung NH, Cheung CY, Li PH, Lee HH, Daëron M, et al. Antibody-dependent infection of human macrophages by severe acute respiratory syndrome coronavirus. Virol J (2014) 11:82. doi: 10.1186/1743-422X-11-82
51. Yasui F, Kai C, Kitabatake M, Inoue S, Yoneda M, Yokochi S, et al. Prior immunization with severe acute respiratory syndrome (SARS)-associated coronavirus (SARS-CoV) nucleocapsid protein causes severe pneumonia in mice infected with SARS-CoV. J Immunol (2008) 181(9):6337–48. doi: 10.4049/jimmunol.181.9.6337
52. Bell TJ, Brand OJ, Morgan DJ, Salek-Ardakani S, Jagger C, Fujimori, et al. Defective lung function following influenza virus is due to prolonged, reversible hyaluronan synthesis. Matrix Biol (2019) 80:14–28. doi: 10.1016/j.matbio.2018.06.006
53. Janoff EN, Wahl SM, Thomas K, Smith PD. Modulation of human immunodeficiency virus type 1 infection of human monocytes by IgA. J Infect Dis (1995) 172(3):855–8. doi: 10.1093/infdis/172.3.855
54. Kozlowski PA, Black KP, Shen L, Jackson S. High prevalence of serum IgA HIV-1 infection-enhancing antibodies in HIV-infected persons. Masking by IgG. J Immunol (Baltimore Md 1950) (1995) 154(11):6163–73.
55. Wan Y, Shang J, Sun S, Tai W, Chen J, Geng Q, et al. Molecular Mechanism for Antibody-Dependent Enhancement of Coronavirus Entry. J Virol (2020) 94(5):e02015–19. doi: 10.1128/JVI.02015-19
56. Liu L, Wei Q, Lin Q, Fang J, Wang H, Kwo H, et al. Anti-spike IgG causes severe acute lung injury by skewing macrophage responses during acute SARS-CoV infection. JCI Insight (2019) 4(4):e123158. doi: 10.1172/jci.insight.123158
57. Latvala S, Jacobsen B, Otteneder MB, Herrmann A, Kronenberg S. Distribution of FcRn Across Species and Tissues. J Histochem Cytochem (2017) 65(6):321–33. doi: 10.1369/0022155417705095
58. Tzaban S, Massol RH, Yen E, Hamman W, Frank SR, Lapierre LA, et al. The recycling and transcytotic pathways for IgG transport by FcRn are distinct and display an inherent polarity. J Cell Biol (2009) 185(4):673–84. doi: 10.1083/jcb.200809122
59. Ward ES, Martinez C, Vaccaro C, Zhou J, Tang Q, Ober RJ. From sorting endosomes to exocytosis: association of Rab4 and Rab11 GTPases with the Fc receptor, FcRn, during recycling. Mol Biol Cell (2005) 16(4):2028–38. doi: 10.1091/mbc.e04-08-0735
60. Burkard C, Verheije MH, Wicht O, van Kasteren S II, van Kuppeveld FJ, Haagmans BL, et al. Coronavirus cell entry occurs through the endo-/lysosomal pathway in a proteolysis-dependent manner. PLoS Pathog (2014) 10(11):e1004502. doi: 10.1371/journal.ppat.1004502
61. Labò N, Ohnuki H, Tosato G. Vasculopathy and Coagulopathy Associated with SARS-CoV-2 Infection. Cells (2020) 9(7):1583. doi: 10.3390/cells9071583
62. Moreira A. Kawasaki disease linked to COVID-19 in children. Nat Rev Immunol (2020) 20(7):407. doi: 10.1038/s41577-020-0350-1
63. Su F, Patel GB, Hu S, Chen W. Induction of mucosal immunity through systemic immunization: Phantom or reality? Hum Vaccines Immunother (2016) 12(4):1070–9. doi: 10.1080/21645515.2015.1114195
64. Clements JD, Freytag LC. Parenteral Vaccination Can Be an Effective Means of Inducing Protective Mucosal Responses. Clin Vaccine Immunol CVI (2016) 23(6):438–41. doi: 10.1128/CVI.00214-16
65. Russell MW, Sibley DA, Nikolova EB, Tomana M, Mestecky J. IgA antibody as a non-inflammatory regulator of immunity. Biochem Soc Trans (1997) 25(2):466–70. doi: 10.1042/bst0250466
66. Nikolova EB, Tomana M, Russell MW. All forms of human IgA antibodies bound to antigen interfere with complement (C3) fixation induced by IgG or by antigen alone. Scand J Immunol (1994) 39(3):275–80. doi: 10.1111/j.1365-3083.1994.tb03371.x
67. Mestecky J, Russell MW, Elson CO. Perspectives on mucosal vaccines: is mucosal tolerance a barrier? J Immunol (2007) 179(9):5633–8. doi: 10.4049/jimmunol.179.9.5633
68. Yap JKY, Moriyama M, Iwasaki A. Inflammasomes and Pyroptosis as Therapeutic Targets for COVID-19. J Immunol (2020) 205(2):307–12. doi: 10.4049/jimmunol.2000513
69. Du L, Zhao G, Lin Y, Sui H, Chan C, Ma S, et al. Intranasal vaccination of recombinant adeno-associated virus encoding receptor-binding domain of severe acute respiratory syndrome coronavirus (SARS-CoV) spike protein induces strong mucosal immune responses and provides long-term protection against SARS-CoV infection. J Immunol (2008) 180(2):948–56. doi: 10.4049/jimmunol.180.2.948
70. Kim MH, Kim HJ, Chang J. Superior immune responses induced by intranasal immunization with recombinant adenovirus-based vaccine expressing full-length Spike protein of Middle East respiratory syndrome coronavirus. PLoS One (2019) 14(7):e0220196. doi: 10.1371/journal.pone.0220196
71. Hassan AO, Case JB, Winkler ES, Thackray LB, Kafai NM, Bailey AL, et al. A SARS-CoV-2 Infection Model in Mice Demonstrates Protection by Neutralizing Antibodies. Cell (2020) 182(3):744–53.e4. doi: 10.1016/j.cell.2020.06.011
72. Fujihashi K, Sato S, Kiyono H. Mucosal adjuvants for vaccines to control upper respiratory infections in the elderly. Exp Gerontol (2014) 54:21–6. doi: 10.1016/j.exger.2014.01.006
73. Sasaki E, Asanuma H, Momose H, Furuhata K, Mizukami T, Hamaguchi I. Immunogenicity and Toxicity of Different Adjuvants Can Be Characterized by Profiling Lung Biomarker Genes After Nasal Immunization. Front Immunol (2020) 11(2171).
74. Hotez PJ, Bottazzi ME, Corry DB. The potential role of Th17 immune responses in coronavirus immunopathology and vaccine-induced immune enhancement. Microbes Infect (2020) 22(4-5):165–7. doi: 10.1016/j.micinf.2020.04.005
75. Mitragotri S. Immunization without needles. Nat Rev Immunol (2005) 5(12):905–16. doi: 10.1038/nri1728
76. World Health Organization. State of the World’s Vaccines and Immunization. Geneva: World Health Organization (1996). Available at: https://apps.who.int/iris/bitstream/handle/10665/44169/9789241563864_eng.pdf?sequence=1.
Keywords: vaccine, mucosal, IgA, IgG, antibody-dependent enhancement, Covid-19, intramuscular
Citation: Travis CR (2020) As Plain as the Nose on Your Face: The Case for A Nasal (Mucosal) Route of Vaccine Administration for Covid-19 Disease Prevention. Front. Immunol. 11:591897. doi: 10.3389/fimmu.2020.591897
Received: 05 August 2020; Accepted: 17 September 2020;
Published: 30 September 2020.
Edited by:
Anke Huckriede, University Medical Center Groningen, NetherlandsReviewed by:
Kohtaro Fujihashi, University of Alabama at Birmingham, United StatesNils Yngve Lycke, University of Gothenburg, Sweden
Copyright © 2020 Travis. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Craig R. Travis, Y3J0QGltbXVnZW4uY29t