Coronaviruses (CoVs) pose a serious global health threat to humans and animals. Four different genera of CoVs have been described: alphacoronaviruses (αCoVs), betacoronaviruses (βCoVs), gammacoronaviruses (γCoVs), and deltacoronaviruses (δCoVs) (1). Currently, seven main CoVs are known to infect humans: HCoV-NL63, HCoV-OC43, HCoV-HKU1, HCoV-229E, severe acute respiratory syndrome coronaviruses (SARS-CoV and SARS-CoV-2), and Middle East respiratory syndrome coronavirus (MERS-CoV) (2, 3). The hCoV strains cause the common cold and infect only the upper respiratory tract (URT), while SARS-CoV, SARS-CoV-2, and MERS-CoV also infect the lower respiratory tract (LRT), leading to severe complications, including death (4). MERS-CoV was first isolated in 2012 from the saliva of an elderly Saudi patient with severe acute pneumonia and renal failure (5). Since 2012, it has been detected in 27 countries, resulting in 2,622 laboratory-confirmed cases, including 950 deaths, with a mortality rate of up to 36.2% (1–5). MERS-CoV is a zoonotic pathogen that has several potential mechanisms of transmission (6). Transmission is likely to occur directly via contact with any infected patients or animals and indirectly, such as contact with camel waste through cleaning camel corrals or the consumption or use of camel urine, unpasteurized milks, and raw meats. Indirect transmission of MERS-CoV can also occur through contact with contaminated surfaces in hospitals, laboratory, public places, or homes (7). MERS-CoV primarily infects the respiratory tract in humans, predominantly infecting and replicating in the respiratory epithelium in the URT and LRT (8).

An effective MERS-CoV vaccine should protect humans and animals and prompt a long-lasting immune response, characterized by neutralizing antibodies (Nabs) and cellular immunity. Several experimental MERS-CoV vaccines are in development. The chimpanzee adenovirus developed at Oxford University, vector version 1 MERS-CoV (ChAdOx1-MERS-CoV) vaccine, is the furthest advanced, and a phase 1b trial has been successfully completed in healthy Middle Eastern adults (9–11).

Currently, no licensed MERS-CoV vaccines exist, representing a matter of great public health concern. The understanding of the acquired immune responses and their underlying mechanisms will facilitate the design of safe and effective vaccine platforms. Additionally, limited information is available on the T- and B-cell response and mucosal cytokine and chemokine production during MERS-CoV infection. This extensive review aims to provide a critical summary of potential protective mechanisms and the immunity elicited in the URT and LRT to assist in the design of a safe, effective, and protective vaccine regimen.

MERS-CoV is classified as a Group IV virus based on the Baltimore Classification System (BCS) (12). It is a positive-sense, linear single-stranded RNA (ssRNA) virus with an enveloped genome ranging from 26 to 32 kilobases. The virus particle is spherical and symmetric, ranging from 77 to 131 nm in size. It contains at least 11 predicted open reading frames (ORFs; ORFs-1a, -1b, -S, -3, -4a, -4b, -5, -E, -M, -8b, and -N) and 16 functional non-structural proteins (NSPs) (kb) (13, 14). The MERS-CoV genome encodes for four structural proteins, the nucleocapsid (N) protein, membrane (M) protein, envelope (E) protein, and spike (S) glycoprotein, and five accessory proteins (15–17) ( Figure 1 ).

The life cycle of MERS-CoV begins with the binding of the S glycoprotein to dipeptidyl peptidase-4 (DPP4), the host cell receptor, through the receptor-binding domain (RBD) on the S1 subunit of the S glycoprotein (19). This binding triggers a conformational change in the S2 subunit, which results in a close association of the viral particle and the cell membrane, facilitating membrane fusion and virus entry into the cytoplasm (20). Following the fusion of viral particles and cellular membranes, MERS-CoV RNA genomes are disassembled inside the target cells, releasing the N protein and genetic materials into the cytoplasm after the translation of ORF-1a and ORF-1b to pp1a and pp1ab, respectively, and the replication of genomic RNA. The replicated viral genome, N, and genomic RNA are assembled to form a helical N, which then cooperates with the S glycoprotein, M protein, and E protein to produce an aggregated virion (21). The viral structural proteins S, M, and E are then translated and use the secretory pathway system to transfer proteins across the endoplasmic reticulum–Golgi intermediate compartment (ERGIC) (22). N protein encapsulates viral genomes to form a mature virion after budding into the membranes of the ERGIC. Following assembly, the budded vesicles containing mature virions are transported to the host cell surface and released (23, 24). After releasing the new MERS-CoV progeny, the host innate immunity utilizes multiple strategies to detect and target viral particles (25, 26).

The main MERS-CoV receptor, DPP-4, is broadly expressed on human URT/LRT cells, including submucosa glands, nasal passages, pharynx, and sinuses, as well as in lungs, bronchi, bronchioles, and alveoli (19–29). Therefore, the host innate immune response at the site of infection is directly triggered during virus particle attachment, mainly through the S glycoprotein to its target cell receptors and entry into the appropriate cell. The primary effector cells of innate immunity are mainly antigen-presenting cells (APCs), such as macrophages and dendritic cells (DCs), which identify the virus components (27–29). The pattern recognition receptors (PRRs) in APCs play a key role and act as crucial mediators of host innate immunity, capable of identifying the pathogen-associated molecular pattern receptors (PAMPs) initiated by viral replication, which result in the rapid endorsement of distinct antiviral signaling pathways in response to the invasive infection (30–32). They are vital in recognition of structural components of MERS-CoV RNA particles (33). TLRs recruit two different adaptor molecules at the site of viral detection: toll/interleukin-1 receptor (TIR-1) domain-containing adapter-inducing interferon-β (TRIF) and myeloid differentiation primary response-88 (MyD-88). These intracellular adaptor proteins play a vital role in activating the mitogen-activated protein kinase (MAPK) and NF-κB pathways responsible for enhancing the production of pro-inflammatory cytokine markers ( Figure 2 ) (32, 35–40).

Type II IFNs (IFN-II), chiefly interferon-gamma (IFN-γ), also possess specific antiviral activity by signaling through the JAK/STAT pathway via the release of specific major histocompatibility complex (MHC) proteins to block virus distribution (41, 42). IFN-γ plays a critical role by stimulating CD8⁺ cytotoxic T cells and natural killer cells (NKCs) that rapidly eliminate virus particles (43). According to Mahallawi et al. (44), IFN-γ levels are significantly higher in MERS-CoV-infected patients than in healthy individuals. Thus, elevated IFN-γ is important for eliciting immune responses against MERS-CoV and preventing severe illness and death (45, 46). DCs and their cytokine expressions also play a key role in enhancing immunity via activating T cells after migrating from the peripheral tissues to the lymphoid tissue (47). Therefore, it is vital to fully understand the signaling of IFN-γ because of its significant implications in host immunity.

The emergence of MERS-CoV has highlighted the urgent need for the development of effective vaccines, which are crucial for halting the spread of infection (117, 118). Although many MERS-CoV vaccine candidates are being investigated, none are currently licensed for human use. Several approaches for developing and evaluating MERS-CoV vaccines have been identified. These include the use of recombinant viral vectors, such as chimpanzee adenoviruses, adeno-associated viruses, MVA, pox-viruses, and measles viruses that can express a full-length S glycoprotein or an extracellular S1 domain and have been experimentally engineered, modified, and tested in animal models (119). These recombinant viral vector vaccines have been shown to induce an anti-S glycoprotein antibody response in addition to CD4⁺ and CD8⁺ cytotoxic T-cell responses in examined animal models (120). Based on safety and strong immunogenicity results, recombinant viral vector vaccines, including replication-deficient chimpanzee simian adenovirus vectors (ChAds) developed at Oxford University, are considered a promising human vaccine platform (121). The ChAdOx1-MERS-CoV vaccine contains the RBD of the MERS-CoV S glycoprotein (proteins stabilized trimer) that has been developed and evaluated in dromedary camels and mice, displaying promising outcomes, including excellent immunogenicity (a high titer of anti-MERS-CoV Nabs and robust CD8⁺ cytotoxic T-cell responses) and safety when encoding either adenovirus-human DPP4 (AdV‐hDPP4) or Rift Valley Fever viral (RVFV) S glycoproteins (122–124). Another study by Munster et al. (125) revealed that a single dose of the ChAdOx1-MERS-CoV vaccine could safely generate high IgG antibody levels and inhibit virus replication in the respiratory tract, decreasing the disease severity and providing protective immune responses in rhesus macaques. Thus, the ChAdOx1-MERS-CoV vaccine is well-tolerated, safe, and able to provoke both humoral and cellular responses in addition to inducing potent Nabs in mice and camel models (126). Another viral vector vaccine is the recombinant modified vaccinia virus Ankara (MVA) expressing the full-length MERS-CoV S glycoprotein (MVA-MERS-CoV S), and it is a stabilized trimer protein. This vaccine generated a substantial Nabs response in vaccinated BALB/c mice injected intramuscularly (i.m.) or subcutaneously (s.c.). In animal models, the MVA-MERS-CoV S vaccine also induced a specific IFN-producing CD8⁺ cytotoxic T-cell response against MERS-CoV infection through both routes (i.m. and s.c.) (127, 128). Based on the positive results obtained in the preclinical animal experiments, two human phase 1a and 1b clinical trials [Folegatti et al. (129) and Alharbi et al. (130)] were conducted to test the ChAdOx1-MERS-CoV vaccine, in healthy adults, aged between 18 and 50 from the Middle East and the United Kingdom. A single dose from the ChAdOx1-MERS-CoV vaccine was able to enhance both cellular and humoral immune responses against MERS-CoV. Therefore, the vaccine was deemed safe, well-tolerated, and highly immunogenic at all examined doses and has been moved forward to phase 2 human clinical trials for further evaluation (130). The ChAdOx1-novel coronavirus-19 (ChAdOx1-nCoV-19) vaccine has been granted an emergency use authorization during the coronavirus disease 2019 (COVID-19) pandemic. The vaccine showed high efficacy against infection and a very high level of protection against disease severity, hospitalization, and death (131, 132).

Recently, scientists developed another vaccine platform that utilizes genetic material termed messenger RNA (mRNA), which is introduced into the cell to express a viral protein for triggering the immune system (133). mRNA vaccines are encoding for a specific protein (e.g., RBD of S glycoprotein of CoV) and direct cells to produce copies of a desired protein of interest (e.g., the RBD of S glycoprotein of CoV) on their cell surface, allowing immune cells to recognize them and develop rapid immunity that protects against invasive pathogens. Currently, three mRNA vaccines for protection against COVID-19, the disease caused by SARS-CoV-2 infection, are approved for emergency use [e.g., Moderna, Janssen (Johnson & Johnson), and Pfizer-BioNTech]. In clinical trials, these vaccines have shown over 90% efficacy in preventing COVID-19 disease-related hospitalization. Both ChAdOx1-nCoV-19 and mRNA vaccines exhibit safety and high immunogenicity and are well-tolerated, with adequate and manageable reactogenicity in tested individuals (131, 132).

The MERS-CoV-RBD S glycoprotein-based subunit vaccine (a stabilized trimer protein) is another option, which is very effective, well-tolerated, and safe and can stimulate robust immune responses (134). The i.m. immunization of mice with a SARS-CoV-RBD protein-based vaccine showed long-term protection and could prevent viral replication in the infected animal (135). The MERS-CoV-RBD-based subunit vaccine is considered another potential strategy for controlling, managing, and preventing MERS-CoV infection. Thus, the subunit vaccine was capable of strong immunogenicity and of inducing, in vaccinated mice, high titers of Nabs that inhibit and block the binding of virus to target receptors and prevent the virus replication. This is a positive advance toward the development of efficient and safe MERS-CoV vaccines.

A strong neutralizing mucosal IgA antibody response against the RBD and MERS-CoV S glycoproteins was elicited by administering the MERS-CoV-RBD-based subunit vaccine intranasally (i.n.) (136). The i.n. administration induced a sound immune response in mice and generated Nabs in immunized rabbits that reduce the severity and lethality of the disease. Thus, i.n. vaccination is important to consider when developing an effective vaccine candidate that can eradicate MERS-CoV infection.

Immunizations with vaccines including specific adjuvants result in high Nabs production. Administration of MERS-CoV S glycoprotein together with an adjuvant resulted in a strong immune response and high levels of Nabs in vaccinated mice. When tested in animals, both alum and microfluoridized adjuvant 59 (alum- and MF59-containing adjuvants) when combined with MERS-CoV subunit vaccine induced cell-mediated and antigen-specific antibodies’ responses and protective immunity (137). However, another adjuvant, glucopyranosyl lipid A (a synthetic TLR-4 agonist), must be used in conjunction with alum to produce a strong cellular Th-1 immune response. These adjuvant–vaccine combinations will improve the strength and effectiveness of the MERS-CoV vaccines under development. Consequently, using proper adjuvants will play a key role in enhancing immunogenicity and safety as well as accelerating the development of a safe, well-tolerated, and effective MERS-CoV vaccine (137, 138).

Vaccines are one of the most effective measures to combat infectious disease, and as such, the ability to rapidly develop MERS-CoV vaccines is critical to public health. The considerable progress in establishing and designing a variety of vaccine platforms targeting MERS-CoV will play a key role in managing the infection (139). The development of effective and safe MERS-CoV vaccines has progressed, and some vaccine candidates have now reached human studies. These vaccines are based on viral vector platforms (ChAdOx1 and modified vaccinia Ankara [MVA]) and deoxyribonucleic acid (DNA) platforms (GLS-5300) that incorporate the MERS-CoV S glycoprotein antigen (140). The morbidity and mortality rates of MERS might be significantly reduced by an effective MERS-CoV vaccine. In order to address future MERS-CoV outbreaks, policymakers could implement a variety of approaches, one of which could be as straightforward as reactively vaccinating healthcare providers who are at high risk to contracting MERS-CoV infection during outbreaks (140). Preventing transmission of respiratory pathogens including MERS-CoV in hospitals and other places is important and requires the implementation of standard precautions of infection control procedures and protocols such as environmental and administrative controls in addition to personal protective equipment (PPE) and safer work practices (141). Effective intervention strategies have been established and are being maintained by public health agency in South Korea to combat MERS-CoV infection. These strategies include large-scale epidemiological research, rapid lab diagnosis, isolation, mass quarantine, social distancing combined with acquaintance quarantine, and clinical categorization of severe patients and treatment with suitable medical therapies (142). Currently, numerous therapeutic options have been used, such as intravenous immunoglobulin (IVIG), convalescent plasma (CP), whole blood therapy, monoclonal antibodies, and the repurposing of clinically approved treatments (143). These MERS therapies are urgently required due to the prerequisite for an efficient therapeutic approach to effectively block MERS-CoV S glycoprotein-mediated cell attachment, entry, and membrane fusion. Antimicrobial peptides (AMPs) are another potential alternative therapeutic agent for treating MERS-CoV infection because of their ability to inhibit viral protein–protein interactions (143). The development of potent antiviral vaccinations able to induce strong immune responses has been greatly facilitated by the developments of nanotechnology platforms. It has been demonstrated that antigen-specific activation of the humoral and cell-mediated immune responses is induced by antigen delivery via nanoparticle-based vaccines (144). Several nanoparticle vaccines such as liposomes, chitosan, and microspheres–nanoparticles have been developed and evaluated, and they show strong immunological responses in animal models (144). Several studies by Khan et al. [(139, 144, 145)] have demonstrated that Nabs, viral protease inhibitors, and interferons are considered crucial therapeutic approaches for the management of MERS-CoV infection. It has been proposed that liposomes and nanoparticles are active and potent vaccine adjuvants when tested in animal models (mostly mice) for biomedical research and vaccine efficacy studies (139, 144, 145). The encapsulated antigens can be delivered by liposomes to the APCs’ cytoplasmic compartment, where they are able to activate the immune system through cell-mediated mechanisms. It has been demonstrated that the liposomes and nanoparticle vaccines can induce robust cellular-mediated (e.g., CD4⁺ T cells, CD8⁺ T cells, DCs, and NKCs) and humoral (antibody-mediated) responses and increase the production of MERS-CoV-specific antibody in combating viral replication in examined mice (139, 144, 145).

Exploring the human mucosal immune responses and immunological mechanisms during MERS-CoV infection and vaccination in the URT and LRT during MERS-CoV infection and vaccination is an important task. Thus, in the current intensive review, we summarized and simplified the published studies investigating this topic. Innate immune cells, mainly APCs, such as macrophages, B cells, and DCs, mediate the immune response by recognizing PAMPs initiated by viral replication intermediates. These interactions lead to the rapid activation of antiviral signaling pathways and cytokine and chemokine production in response to the infection. T and B cells, the main two arms of the adaptive immunity system, play an important role in fighting MERS-CoV infection, particularly CD4⁺ helper T cells that regulate CD8⁺ cytotoxic T-cell and B-cell functions. CD8⁺ cytotoxic T cells are effector cells that directly eliminate virus-infected cells.

Notably, the human NALT plays a crucial role in protection against several respiratory pathogens due to a wide range of mucosal immune effector cells (146, 147). However, few data are available on the immunopathogenesis and immune responses during MERS-CoV infection in URT tissues because of the few reported cases worldwide. Thus, an urgent need exists to explore the role of cell-mediated immunity and the mechanisms of pro-inflammatory cytokines, chemokines, and cytotoxic markers in the mucosal tissues, mainly the tonsils, to better understand the immune response during MERS-CoV infection and vaccination.

The effective, efficient innate and adaptive immune responses in human lungs can play a crucial role in the immune response, combatting the respiratory viral infection, and prevention of further disease complications. Nevertheless, local immunity in lung tissues makes it difficult to understand and properly evaluate the immune responses following MERS-CoV infection or the benefits of human vaccine trials.

Future studies of immune responses in the URT and LRT following infection and vaccination are a priority, leading to the assessment of new vaccine formulations, doses, and routes of administration (e.g., i.n.). Finally, understanding in depth the mechanisms of mucosal immune responses in both the URT and LRT following MERS-CoV infection or administration of MERS-CoV vaccines could provide valuable information for developing preventive methods and therapeutic vaccine candidates that are able to stop, control, and manage current MERS-CoV infections or the emerging and re-emerging of other human CoV infectious diseases.