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. 2020 Nov 6;16(12):3011–3022. doi: 10.1080/21645515.2020.1825896

Recent advances in vaccine and immunotherapy for COVID-19

Ali A Rabaan a,, Shamsah H Al-Ahmed b, Ranjit Sah c, Jaffar A Al-Tawfiq d,e,f, Ayman M Al-Qaaneh g,h, Lamiaa H Al-Jamea i, Alexander Woodman i, Manaf Al-Qahtani j,k, Shafiul Haque l, Harapan Harapan m,n,o, D Katterine Bonilla-Aldana p,q, Pavan Kumar r, Kuldeep Dhama s, Alfonso J Rodriguez-Morales f,t,
PMCID: PMC7651183  PMID: 33156739

ABSTRACT

The COVID-19 pandemic caused by SARS-CoV-2 has resulted in millions of cases and hundreds of thousands of deaths. Beyond there being no available antiviral therapy, stimulating protective immunity by vaccines is the best option for managing future infections. Development of a vaccine for a novel virus is a challenging effort that may take several years to accomplish. This mini-review summarizes the immunopathological responses to SARS-CoV-2 infection and discusses advances in the development of vaccines and immunotherapeutics for COVID-19.

KEYWORDS: SARS-CoV-2, COVID-19, vaccine, immunotherapeutics, pandemic

Introduction

The 2019 coronavirus disease (COVID-19) was first reported in late December 2019 in Wuhan; China has now become a global pandemic. The virus causing COVID-19 is the Severe acute respiratory coronavirus syndrome 2 (SARS-CoV-2) that belongs to the coronaviridae family of viruses. The characteristic feature of coronavirus is the presence of club-like extensions on the surface made of glycosylated trimers of S protein. The coronaviruses are roughly 80–120 nm in diameter.1 COVID-19 resulting from the new SARS-CoV-2 infection has now become a global health concern. The incubation time of the virus is about 2–10 days, and it is transmitted through aerosol from human-to-human and also through contaminated inanimate objects and hands.2 The virus can remain infective on the surfaces of objects for up to 9 days at room temperature. However, the viral survival declines with temperatures above 30°C. It can be efficiently inactivated by surface disinfection procedures with 62–71% ethanol, 0.5% hydrogen peroxide or 0.1% sodium hypochlorite within 1 minute.2

First described in China, SARS-CoV-2 has been reported in essentially all countries worldwide, with more than 15 million infected subjects and more than a half-million deaths. Owing to the global spread, WHO declared COVID-19 as a pandemic on 11 March 2020.3

Since the first report of the genomic sequence of the SARS-CoV-2 has come, researchers, clinicians, and pharmaceutical companies have devoted all their resources and research toward developing therapeutic modalities and vaccines for SARS-CoV-2.

Most of the data on antiviral therapy is based on the clinical and preclinical studies on other related viruses such as SARS-CoV, Middle East coronavirus respiratory syndrome (MERS-CoV) and non-coronavirus (Ebola). This narrative mini-review summarizes epidemiology, pathogenesis, immune responses, vaccine development issues, and immunotherapy for COVID-19 and provides an update on recent advances for vaccine and immunotherapy.

Pathogenesis

The SARS-CoV-2 resembles the SARS-CoV in several aspects. Homology modeling revealed that both the viruses employ similar receptor-binding domains to attach to the host cells with subtle differences in particular amino acid residues.4 The coronaviruses have spike proteins that are glycoproteins and consist of two subunits: S1 and S2. The S1 and S2 proteins are the most important structural proteins of the virus. The spikes on the surface of the SARS-CoV-2 are homotrimers of S proteins that establish attachments with the host cell receptors.5 The structural and the non-structural proteins (nsps) in co-ordination carry out the CoV pathogenesis and decide the virulence.6

The virus entry

Coronaviruses enter into the host cells by using the viral S protein.7 SARS-CoV-2 enters into the host cell by the interaction of its S protein with the host receptor “ACE2” present in most of the human cell types.8 The viral RNA is transferred into the host cell cytoplasm as soon as it enters the host cell. The viral genome translates its two polyproteins and structural proteins. These proteins enable the viral genome to replicate inside the host cell.9 The nascent viral glycoprotein envelope is processed in the endoplasmic reticulum or Golgi membrane. Then, the genomic RNA and the nucleocapsid proteins fuse to form the nucleocapsid. The newly formed viral particles then fuse with the vesicles in the intermediate reticulum-Golgi endoplasmic compartment (ERGIC) followed by the fusion of these virus-containing vesicles with the plasma membrane that leads to the virus release.7

Antigen presentation

To date, there are no reported studies on the immune mechanism of SARS-CoV-2 infection. However, the studies on the immune mechanisms of the related viruses like SARS-CoV and MERS give much insight into the immune mechanism of the virus.10 Upon entry into the host, the virus presents its antigens to the antigen-presenting cells (APCs) of the host mediating the antiviral mechanism of the host immune system.

Humoral and cellular immunity

Antigen presentation by the APCs results in the activation of the cell-mediated and the humoral immunity of the host governed by T cells and B cells, respectively. The antibody response (levels of IgM and IgG) to SARS-CoV follows a characteristic pattern.11 The IgM antibody levels reach undetectable levels by the end of 12th week of infection, but the IgG remains for more extended periods.12

SARS-CoV infection induces concomitant activation of T cell and B cell-mediated immune responses. Upon SARS-CoV infection, B cell responses are first observed against the nucleocapsid (N) protein followed by responses to S protein which is seen within 4–8 days after the onset of symptoms.13,14 Neutralizing antibody responses for the S protein begins by 2nd week. Many patients develop the neutralizing antibody responses by 3rd week.15,16 Since viral titers are observed to peak earlier for SARS-CoV-2 as compared to SARS-CoV, the antibody responses may also be elicited earlier.17,18 It has been observed that a subset of infected patients do not develop long-lasting antibody responses to SARS-CoV-2. However, it is not clear whether these patients are more susceptible for re-infection.19,20

It has been documented that the population of CD4 and CD8 T cells significantly falls in the patients infected with SARS-CoV-2.21 It was seen that the antibody-secreting cells (ASCs) in the blood of a SARS-CoV-2-infected patient increased from day 7 (1.48%) to a peak level on day 8 (6.91%). Similarly, the cTFH cells increased from 1.98% on day 7 to 3.25% on day 8. The cTFH cells peaked on 9th day (4.4.6%). This observation indicates that both humoral and cell-mediated immunity comes into play in response to SARS-CoV-2 infection.22

An accumulation of mononuclear cells suspected to be monocytes and T cells was observed in the lungs of a COVID-19 patient along with decreased systemic levels of hyperactive T cells.21 Lymphopenia and decreased levels of peripheral T cells indicate that the T cells are migrated toward the lungs from the systemic circulation to the site of infection (primarily lungs) to counteract the viral infection.23–26 Increased exhaustion and reduced functional diversity of T cells may be predictive of severe disease progression.27 It has been seen that the patients recovered from SARS-CoV developed coronavirus-specific memory T cells, seen up to 2 years after recovery.28,29 It is quite evident from these reports that T cell-mediated immunity plays an important role in controlling infection. However, several vaccine agents designed against SARS-CoV resulted in immunopathology due to TH2 cell-mediated infiltration of eosinophils.30,31 The vaccinated mice showed increased immunopathology than protection against SARS-CoV infection.32 Therefore, further extensive studies are needed to evaluate the protective versus damaging T cell responses, which is essential for designing vaccines for the coronavirus.33 However, it is very important to investigate whether T cell-mediated responses are solely responsible for infection control in humans. This will provide impetus to the vaccine development process.

Cytokine storm

Acute respiratory distress syndrome (ARDS) is the most common pathology seen in patients infected with SARS-CoV-2, SARS-CoV, and MERS.21,34 A hyperinflammatory condition associated with hypercytokinaemia is often observed in COVID-19 patients.34 This hyperinflammatory condition is related to multiple organ failure.35 The cytokine surge seen in COVID-19 patients results due to increased levels of the proinflammatory cytokines such as IFN-a, IFN-g, IL-1b, IL-6, IL-12, IL-18, IL-33, TNF-a, TGFb and chemokines such as CCL2, CCL3, CCL5, CXCL8, CXCL9, CXCL10, among others, by the cells of immunity system.34,36 This cytokine storm may be followed by multiple organ failure and ARDS resulting in the death of the patients infected with SARS-COV-2 as seen in SARS-CoV and MERS-CoV infection.21

Evasion of the host immune response

As the SARS-CoV-2 is very new to the researchers, not much data are available on the immunopathological mechanisms and the tricks of the novel virus to escape the host immune response. However, data from the studies on the previously known coronaviruses like SARS-CoV and MERS can be utilized to speculate the possible mechanisms this new SARS-CoV-2 virus may employ to deceive the host immune system. The pattern recognition receptors (PRRs) can identify the evolutionarily preserved microbial structures called pathogen-associated molecular patterns (PAMPs). As a defense mechanism against the host cells, these viruses (SARS-CoV and MERS-CoV) may develop modified membranes derived from host cell components such as developing double-membrane vesicles that lack or have altered pathogen-associated molecular patterns (PAMPs) hence unrecognizable by the host cell pattern recognition receptors (PRRs). This facilitates viral replication without their RNA being recognized by the host cell.37 Another mechanism seen in MERS infection can be thought of being utilized by the SARS-CoV-2 virus to escape the host immunity. It has been recognized with MERS infection that the expression of genes related to antigen presentation is downregulated upon infection, facilitating the virus evade the first checkpoint of host immunity.38 Research studies have evidenced the fact that nsp can suppress the innate immune response of the host.6

Need for vaccine development

Although remdesivir is available in developed countries as a specific antiviral drug that has been shown to be effective in reducing symptoms and accelerating recovery from COVID-19 disease, it is not affordable in most parts of the world and is in limited supply, such that much of the world awaits an inexpensive and effective antiviral drug. The treatment for COVID-19 relies on the management of the symptoms focused on the symptomatic management of the patients which include controlling secondary infections by the administration of broad-spectrum antibiotics, ventilation, and fluid control.11,34

COVID-19 vaccine development platforms and challenges in COVID-19 vaccine development

The public health threat of COVID-19 will remain until a potential and effective vaccine is developed.39 Several companies have taken the initiative of developing the vaccine against COVID-19 targeting the SARS-CoV2 virus continuously circulating in the human population.40

Various strategies such as live-attenuated virus, viral proteins, viral nucleic acid, virus-like particle, peptide, viral vector (replicating and non-replicating), and recombinant protein approaches are being used for vaccine development against SARS-CoV-2. These strategies have their own associated advantages and disadvantages.5,41 Viral antigen-based and nucleic acid-based vaccines are safer, but the immunogenic potential of these vaccines is less. The nucleic acid-based vaccines are the fastest to enter into phase 1 clinical trial, but to date, there is no nucleic acid-based vaccine licensed to be used in humans. Since safety is a concern with a live-attenuated virus, it is risky for the vulnerable older population.41 Nucleic acid-based platforms provide wider options for antigen manipulation. Therefore, vaccines based on nucleic acid approaches might be considered as one of the important approaches for the development of a vaccine for SARS-CoV2.42

Viral vector-based platforms offer advantages such as high level of protein expression, stability, and induction of strong immune response. Since vaccines based on recombinant proteins are already licensed for several other diseases, the existing large-scale production capacity can be utilized for the production of vaccines for SARS-CoV-2.42 It is possible that some platforms may be more appropriate for a specific group of population such as the aged, children, pregnant women or immunocompromised patients.

Since our knowledge about the immune responses to the vaccines is not entirely established, different strategies should be tried for designing a vaccine for COVID-19. Only advances and comprehensive research can answer this question about selecting the best approach for vaccine development for COVID-19. Distinctive challenges for SARS-CoV-2 vaccine development include clinical recruitment, defining a correlate of protection, and proving efficacy, especially when there is public pressure to release a vaccine for general use. Despite the development of novel platforms for vaccine development, there are several underlying challenges in SARS-CoV-2 vaccine development.

Although the viral S protein is a potential immunogen, it is essential to evaluate the optimal immune response elicited by the antigen. It is still a matter of debate whether the full S protein or only the receptor-binding domain is suitable for achieving optimal immune response.33 Previous experience with SARS and MERS vaccine candidates has raised concerns about the exacerbating lung disease, either directly or due to antibody-dependent enhancement (ADE). This adverse effect may be associated with Th2 response. Production of sub-optimal levels of antibody or antibody of low quality can result in the phenomenon of ADE that promotes the disease pathology. This warrants consideration of ADE in the evaluation of safety of the emerging candidate vaccines for SARS-CoV-2. Therefore, testing of the vaccine candidates for safety in suitable animal models and constant safety monitoring in clinical trials is quintessential. It is premature to define a good animal model for COVID-19.33

Another major challenge in SARS-CoV-2 vaccine development is establishment of correlates of protection. Experience with SARS and MERS vaccines may be utilized to establish correlates of protection. However, they are still not established. The duration of protection and whether a single dose of the vaccine is sufficient to elicit the required immune response is uncertain.33

Vaccine development is a long process and involves large sample sizes for conducting research; it may take years to establish a vaccine. Since it is associated with high costs and failure rates, the developers take extra precaution and follow a strict sequence of steps involving multiple rounds of data analysis and strict checks at manufacturing levels. Developing a vaccine in an outbreak scenario requires a new strategy of executing multiple steps in parallel even before confirmation of the outcome of another step.33

The other challenge is faced at the commercial production of clinical trial materials. For the novel platforms, large-scale production has never been done before. So, it will require large-scale production (identification, technology transfer, and manufacturing process) without the knowledge of the viability of the vaccine candidate. It is not certain whether these novel platforms are scalable and if it is possible to produce sufficient quantities using the existing capacity.33

Performing clinical trials during a pandemic is associated with the additional challenge of choosing trial sites as it is difficult to predict where and when outbreaks will occur. So, if multiple vaccines are ready, countries should not be crowded with multiple clinical trials. In a pandemic situation where the mortality rates are high, people may not consent for randomized controlled trials with placebo.43 One way to tackle this problem is utilizing a single-shared control group for testing several vaccines simultaneously. In this approach, more people will receive an active vaccine.44 Although this approach is advantageous, it is associated with statistical complexities. Developers may try to avoid direct comparative analysis of their vaccine candidates with others.

Finally, there will be a surge of demand for the vaccines globally. Hence, serological studies will be needed to establish which populations are at higher risks so that they can be prioritized for the vaccine allocation.33

Advances in vaccine development for COVID-19

Several companies, research laboratories and universities are researching to come up with a vaccine for COVID-19. According to WHO, as of August 25, 2020, there are 31 vaccines in the clinical evaluation phase (Table 1) and 142 vaccines in the preclinical evaluation phase (according to the WHO draft, August 25, 2020) (Table 2).45 Out of the 31 candidate vaccines in clinical trial phase, 7 have reached phase 3, 3 have reached phase 2 clinical trials, and the rest are in phase 1 or phase1/2. Of the seven candidate vaccines in phase 3, ChAdOx1-S is a single dose intramuscular non-replicating viral vector vaccine expressing the SARS-CoV-2 spike protein. Other three are inactivated double dose intramuscular SARS-CoV-2 vaccines. LNP-encapsulated mRNA and 3 LNP-mRNAs are double dose intramuscular RNA vaccines. Ad26COVS1 is a double dose intramuscular non-replicating viral vector vaccine (Table 1). Three vaccine candidates listed in Table 1 are in phase 2 clinical trial. Adenovirus Type 5 Vector is a single dose intramuscular non-replicating viral vector vaccine. Adjuvanted recombinant protein (RBD-Dimer) is a double or triple dose intramuscular protein subunit vaccine. The other vaccine candidate in phase 2 clinical trial is a double dose intramuscular mRNA vaccine (Table 1).

Table 1.

List of 31 candidate vaccines in different clinical trial phases.45.

  Clinical Stage
COVID-19 Vaccine developer/manufacturer Vaccine platform Type of candidate vaccine Number of doses Timing of doses Route of Administration Phase 1 Phase 1/2 Phase 2 Phase 3
University of Oxford/AstraZeneca Non-Replicating Viral Vector ChAdOx1-S 1   IM   PACTR202006922165132 2020–001072-15 2020–001228-32 ISRCTN89951424 NCT04516746
Sinovac Inactivated Inactivated 2 0, 14 days IM   NCT04383574
NCT04352608 		  NCT04456595
669/UN6.KEP/EC/2020
Wuhan Institute of Biological Products/Sinopharm Inactivated Inactivated 2 0,14 or 0,21 days IM   ChiCTR2000031809   ChiCTR2000034780
Beijing Institute of Biological Products/Sinopharm Inactivated Inactivated 2 0,14 or 0,21 days IM   ChiCTR2000032459   ChiCTR2000034780
Moderna/NIAID RNA LNP-encapsulated mRNA 2 0, 28 days IM NCT04283461
Interim Report		   NCT04405076 NCT04470427
BioNTech/Fosun Pharma/Pfizer RNA 3 LNP-mRNAs 2 0, 28 days IM   2020–001038-36
ChiCTR2000034825
Study Report		   NCT04368728
CanSino Biological Inc./Beijing Institute of Biotechnology Non-Replicating Viral Vector Adenovirus Type 5 Vector 1   IM ChiCTR2000030906
Study Report		   ChiCTR2000031781
Study Report		  
Anhui Zhifei Longcom Biopharmaceutical/Institute of Microbiology, Chinese Academy of Sciences Protein Subunit Adjuvanted recombinant protein (RBD-Dimer) 2 or 3 0, 28 or 0, 28, 56
days		 IM NCT04445194   NCT04466085  
Curevac RNA mRNA 2 0, 28 days IM NCT04449276   NCT04515147  
Institute of Medical Biology, Chinese Academy of Medical Sciences Inactivated Inactivated 2 0, 28 days IM NCT04412538 NCT04470609    
Inovio Pharmaceuticals/International Vaccine Institute DNA DNA plasmid vaccine with electroporation 2 0, 28 days ID   NCT04447781
NCT04336410 		   
Osaka University/AnGes/Takara Bio DNA DNA plasmid vaccine + Adjuvant 2 0, 14 days IM   NCT04463472    
Cadila Healthcare Limited DNA DNA plasmid vaccine 3 0, 28, 56 days ID   CTRI/2020/07/026352    
Genexine Consortium DNA DNA Vaccine (GX-19) 2 0, 28 days IM   NCT04445389    
Bharat Biotech Inactivated Whole-Virion Inactivated 2 0, 14 days IM   NCT04471519    
Janssen Pharmaceutical Companies Non-Replicating Viral Vector Ad26COVS1 2 0, 56 days IM   NCT04436276   NCT04505722
(not yet recruiting)
Novavax Protein Subunit Full length recombinant SARS CoV- 2 glycoprotein nanoparticle vaccine adjuvanted with Matrix M 2 0, 21 days IM   NCT04368988    
Kentucky Bioprocessing, Inc Protein Subunit RBD-based 2 0, 21 days IM   NCT04473690    
Arcturus/Duke-NUS RNA mRNA     IM   NCT04480957    
Gamaleya Research Institute Non-Replicating Viral Vector Adeno-based 1   IM NCT04436471
NCT04437875 		     
ReiThera/LEUKOCARE/Univercells Non-Replicating Viral Vector Replication defective Simian Adenovirus (GRAd) encoding S 1   IM 2020–002835-31      
Clover Biopharmaceuticals Inc./GSK/Dynavax Protein Subunit Native like Trimeric subunit Spike Protein vaccine 2 0, 21 days IM NCT04405908      
Vaxine Pty Ltd/Medytox Protein Subunit Recombinant spike protein with
Advax™ adjuvant		 1   IM NCT04453852      
University of Queensland/CSL/Seqirus Protein Subunit Molecular clamp stabilized Spike protein with MF59 adjuvant 2 0, 28 days IM ACTRN12620000674932p      
Medigen Vaccine Biologics Corporation/NIAID/Dynavax Protein Subunit S-2P protein + CpG 1018 2 0, 28 days IM NCT04487210      
Instituto Finlay de Vacunas, Cuba Protein Subunit RBD + Adjuvant 2 0, 28 days IM IFV/COR/04      
Institute Pasteur/Themis/Univ. of Pittsburg CVR/Merck Sharp & Dohme Replicating Viral Vector Measles-vector based 1 or 2 0, 28 days IM NCT04497298      
Imperial College London RNA LNP-nCoVsaRNA 2   IM ISRCTN17072692      
People’s Liberation Army (PLA) Academy of Military Sciences/Walvax Biotech. RNA mRNA 2 0, 14 or 0, 28
days		 IM ChiCTR2000034112      
Medicago Inc. VLP Plant-derived VLP adjuvanted with GSK or Dynavax adjs. 2 0, 21 days IM NCT04450004      
FBRI SRC VB VECTOR, Rospotrebnadzor, Koltsovo Protein Subunit Peptide 2 0, 21 days IM TBD      
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Abbreviations: IM = Intra muscular’

Table 2.

List of 142 candidate vaccines in preclinical evaluation phase.45.

Platform Type of candidate vaccine Developer Same platform for non-Coronavirus candidates
DNA DNA, engineered vaccine inserts compatible with multiple delivery systems DIOSynVax Ltd / University of Cambridge  
DNA DNA vaccine Ege University  
DNA DNA plasmid vaccine RBD&N Scancell/University of Nottingham/ Nottingham Trent University  
DNA DNA plasmid vaccine S,S1,S2,RBD &N National Research Centre, Egypt  
DNA DNA with electroporation Karolinska Institute / Cobra Biologics
(OPENCORONA Project)		  
DNA DNA with electroporation Chula Vaccine Research Center  
DNA DNA Takis/Applied DNA Sciences/Evvivax  
DNA Plasmid DNA, Needle-Free Delivery Immunomic Therapeutics, Inc./EpiVax, Inc./PharmaJet SARS
DNA DNA vaccine BioNet Asia  
DNA msDNA vaccine Mediphage Bioceuticals/University of Waterloo  
DNA DNA vaccine Entos Pharmaceuticals  
DNA bacTRL-Spike Symvivo  
Inactivated Inactivated + alum KM Biologics JE, Zika
Inactivated Inactivated Selcuk University  
Inactivated Inactivated Erciyes University  
Inactivated Inactivated whole virus National Research Centre, Egypt  
Inactivated Inactivated Beijing Minhai Biotechnology Co., Ltd.  
Inactivated TBD Osaka University/ BIKEN/ NIBIOHN  
Inactivated Inactivated + CpG 1018 Sinovac/Dynavax  
Inactivated Inactivated + CpG 1018 Valneva/Dynavax  
Inactivated Inactivated Research Institute for Biological Safety Problems, Rep of Kazakhstan  
Live Attenuated Virus Codon deoptimized live attenuated vaccines Mehmet Ali Aydinlar University / Acıbadem Labmed Health Services
A.S.		  
Live Attenuated Virus Codon deoptimized live attenuated vaccines Codagenix/Serum Institute of India HAV, InfA, ZIKV, FMD, SIV, RSV, DENV
Live Attenuated Virus Codon deoptimized live attenuated vaccines Indian Immunologicals Ltd/Griffith University  
Non-Replicating Viral Vector Sendai virus vector ID Pharma  
Non-Replicating Viral Vector Adenovirus-based Ankara University  
Non-Replicating Viral Vector Adeno-associated virus vector (AAVCOVID) Massachusetts Eye and Ear/Massachusetts General Hospital/AveXis  
Non-Replicating Viral Vector MVA encoded VLP GeoVax/BravoVax LASV, EBOV, MARV, HIV
Non-replicating viral vector MVA-S encoded DZIF – German Center for Infection Research/IDT Biologika GmbH Many
Non-replicating viral vector MVA-S IDIBAPS-Hospital Clinic, Spain  
Non-Replicating Viral Vector adenovirus-based NasoVAX expressing
SARS2-CoV spike protein		 Altimmune influenza
Non-Replicating Viral Vector Adeno5-based Erciyes University  
Non-Replicating Viral Vector 2nd Gen E2b- Ad5 Spike, RBD, Nucleocapsid
Subcutaneous&Oral		 ImmunityBio, Inc. & NantKwest, Inc. flu, Chik, Zika, EBOV, LASV,
HIV/SIV,Cancer
Non-Replicating Viral Vector Ad5 S (GREVAX™ platform) Greffex MERS
Non-Replicating Viral Vector Oral Ad5 S Stabilitech Biopharma Ltd Zika, VZV, HSV-2 and Norovirus
Non-Replicating Viral Vector adenovirus-based + HLA-matched peptides Valo Therapeutics Ltd  
Non-Replicating Viral Vector Oral Vaccine platform Vaxart InfA, CHIKV, LASV, NORV; EBOV, RVF, HBV, VEE
Non-Replicating Viral Vector MVA expressing structural proteins Centro Nacional Biotecnología (CNB-CSIC), Spain Multiple candidates
Non-Replicating Viral Vector Dendritic cell-based vaccine University of Manitoba  
Non-Replicating Viral Vector parainfluenza virus 5 (PIV5)-based vaccine
expressing the spike protein		 University of Georgia/University of Iowa MERS
Non-Replicating Viral Vector Recombinant deactivated rabies virus
containing S1		 Bharat Biotech/Thomas Jefferson University HeV, NiV, EBOV, LASSA, CCHFV, MERS
Non-Replicating Viral Vector Influenza A H1N1 vector National Research Centre, Egypt  
Non-Replicating Viral Vector Inactivated Flu-based SARS-CoV2 vaccine +
Adjuvant		 National Center for Genetic Engineering and Biotechnology (BIOTEC)
/GPO, Thailand		  
Protein Subunit RBD protein (baculovirus production) + FAR-
Squalene adjuvant		 Farmacológicos Veterinarios SAC (FARVET SAC) / Universidad Peruana
Cayetano Heredia (UPCH)		  
Protein Subunit Protein Subunit Research Institute for Biological Safety Problems, Rep of Kazakhstan  
Protein Subunit RBD-protein Mynvax  
Protein Subunit Recombinant S protein Izmir Biomedicine and Genome Center  
Protein Subunit Peptide + novel adjuvant Bogazici University  
Protein Subunit S subunit intranasal liposomal formulation
with GLA/3M052 adjs.		 University of Virginia  
Protein Subunit S-Protein (Subunit) + Adjuvant, E coli based
Expression		 Helix Biogen Consult, Ogbomoso & Trinity Immonoefficient Laboratory,
Ogbomoso, Oyo State, Nigeria.		  
Protein Subunit Protein Subunit S,N,M&S1 protein National Research Centre, Egypt  
Protein Subunit Protein Subunit University of San Martin and CONICET, Argentina  
Protein Subunit RBD protein fused with Fc of IgG + Adj. Chulalongkorn University/GPO, Thailand  
Protein Subunit Capsid-like Particle AdaptVac (PREVENT-nCoV consortium)  
Protein Subunit Drosophila S2 insect cell expression system
VLPs		 ExpreS2ion  
Protein Subunit Peptide antigens formulated in LNP IMV Inc  
Protein Subunit S protein WRAIR/USAMRIID  
Protein Subunit S protein +Adjuvant National Institute of Infectious Disease, Japan/Shionogi/UMN Pharma Influenza
Protein Subunit VLP-recombinant protein + Adjuvant Osaka University/ BIKEN/ National Institutes of Biomedical Innovation,
Japan		  
Protein Subunit microneedle arrays S1 subunit Univ. of Pittsburgh MERS
Protein Subunit Peptide Vaxil Bio  
Protein Subunit Adjuvanted protein subunit (RBD) Biological E Ltd  
Protein Subunit Peptide Flow Pharma Inc Ebola, Marburg, HIV, Zika, Influenza, HPV therapeutic vaccine, BreastCA
vaccine
Protein Subunit S protein AJ Vaccines  
Protein Subunit Ii-Key peptide Generex/EpiVax Influenza, HIV, SARS-CoV
Protein Subunit S protein EpiVax/Univ. of Georgia H7N9
Protein Subunit Protein Subunit EPV-CoV-19 EpiVax  
Protein Subunit S protein (baculovirus production) Sanofi Pasteur/GSK Influenza, SARS-CoV
Protein Subunit gp-96 backbone Heat Biologics/Univ. Of Miami NSCLC, HIV, malaria, Zika
Protein Subunit Subunit vaccine FBRI SRC VB VECTOR, Rospotrebnadzor, Koltsovo  
Protein Subunit S1 or RBD protein Baylor College of Medicine SARS
Protein Subunit Subunit protein, plant produced iBio/CC-Pharming  
Protein Subunit Recombinant protein, nanoparticles (based
on S-protein and other epitopes)		 Saint-Petersburg scientific research institute of vaccines and serums  
Protein Subunit COVID-19 XWG-03
truncated S (spike) proteins		 Innovax/Xiamen Univ./GSK HPV
Protein Subunit Adjuvanted microsphere peptide VIDO-InterVac, University of Saskatchewan  
Protein Subunit Synthetic Long Peptide Vaccine candidate for
S and M proteins		 OncoGen  
Protein Subunit Oral E. coli-based protein expression system
of S and N proteins		 MIGAL Galilee Research Institute  
Protein Subunit Nanoparticle vaccine LakePharma, Inc.  
Protein Subunit Plant-based subunit
(RBD-Fc + Adjuvant)		 Baiya Phytopharm/ Chula Vaccine Research Center  
Protein Subunit OMV-based vaccine Quadram Institute Biosciences Flu A, plague
Protein Subunit OMV-based vaccine BiOMViS Srl/Univ. of Trento  
Protein subunit structurally modified spherical particles of
the tobacco mosaic virus (TMV)		 Lomonosov Moscow State University rubella, rotavirus
Protein Subunit Spike-based University of Alberta Hepatitis C
Protein Subunit Recombinant S1-Fc fusion protein AnyGo Technology  
Protein Subunit Recombinant protein Yisheng Biopharma  
Protein Subunit Recombinant S protein in IC-BEVS Vabiotech  
Protein Subunit Orally delivered, heat stable subunit Applied Biotechnology Institute, Inc.  
Protein Subunit Peptides derived from Spike protein Axon Neuroscience SE  
Protein Subunit Protein Subunit MOGAM Institute for Biomedical Research, GC Pharma  
Protein Subunit RBD-based Neovii/Tel Aviv University  
Protein Subunit Outer Membrane Vesicle (OMV)-subunit Intravacc/Epivax  
Protein Subunit Outer Membrane Vesicle(OMV)-peptide Intravacc/Epivax  
Protein Subunit Spike-based (epitope screening) ImmunoPrecise/LiteVax BV  
Replicating Bacteria Vector Oral Salmonella enteritidis (3934Vac) based
protein expression system of RBD		 Farmacológicos Veterinarios SAC (FARVET SAC) / Universidad Peruana
Cayetano Heredia (UPCH)		  
Replicating Viral Vector YF17D Vector KU Leuven  
Replicating Viral Vector Measles Vector Cadila Healthcare Limited  
Replicating Viral Vector Measles Vector FBRI SRC VB VECTOR, Rospotrebnadzor, Koltsovo  
Replicating Viral Vector Measles Virus (S, N targets) DZIF – German Center for Infection Research/CanVirex AG Zika, H7N9, CHIKV
Replicating Viral Vector Horsepox vector expressing S protein Tonix Pharma/Southern Research Smallpox, monkeypox
Replicating Viral Vector Live viral vectored vaccine based on attenuated influenza virus backbone (intranasal) BiOCAD and IEM Influenza
Replicating Viral Vector Recombinant vaccine based on Influenza A virus, for the prevention of COVID-19 (intranasal) FBRI SRC VB VECTOR, Rospotrebnadzor, Koltsovo Influenza
Replicating Viral Vector Attenuated Influenza expressing
an antigenic portion of the Spike protein		 Fundação Oswaldo Cruz and Instituto Buntantan Influenza
Replicating Viral Vector Influenza vector expressing RBD University of Hong Kong  
Replicating Viral Vector Replication-competent VSV chimeric virus
technology (VSVΔG) delivering the SARS-CoV- 2 Spike (S) glycoprotein.		 IAVI/Merck Ebola, Marburg, Lassa
Replicating Viral Vector Replicating VSV vector-based DC-targeting University of Manitoba  
Replicating Viral Vector VSV-S University of Western Ontario HIV, MERS
Replicating Viral Vector VSV-S Aurobindo  
Replicating Viral Vector VSV vector FBRI SRC VB VECTOR, Rospotrebnadzor, Koltsovo  
Replicating Viral Vector VSV-S Israel Institute for Biological Research/Weizmann Institute of Science  
Replicating Viral Vector M2-deficient single replication (M2SR)
influenza vector		 UW–Madison/FluGen/Bharat Biotech influenza
Replicating Viral Vector Newcastle disease virus vector (NDV-SARS-
CoV-2/Spike)		 Intravacc/ Wageningen Bioveterinary Research/Utrecht Univ.  
Replicating Viral Vector Avian paramyxovirus vector (APMV) The Lancaster University, UK  
RNA Self-amplifying RNA Gennova  
RNA mRNA Selcuk University  
RNA LNP-mRNA Translate Bio/Sanofi Pasteur  
RNA LNP-mRNA CanSino Biologics/Precision NanoSystems  
RNA LNP-encapsulated mRNA cocktail encoding
VLP		 Fudan University/ Shanghai JiaoTong University/RNACure Biopharma  
RNA LNP-encapsulated mRNA encoding RBD Fudan University/ Shanghai JiaoTong University/RNACure Biopharma  
RNA Replicating Defective SARS-CoV-2 derived
RNAs		 Centro Nacional Biotecnología (CNB-CSIC), Spain  
RNA LNP-encapsulated mRNA University of Tokyo/ Daiichi-Sankyo MERS
RNA Liposome-encapsulated mRNA BIOCAD  
RNA Several mRNA candidates RNAimmune, Inc.  
RNA mRNA FBRI SRC VB VECTOR, Rospotrebnadzor, Koltsovo  
RNA mRNA China CDC/Tongji University/Stermina  
RNA LNP-mRNA Chula Vaccine Research Center/University of Pennsylvania  
RNA mRNA in an intranasal delivery system eTheRNA  
RNA mRNA Greenlight Biosciences  
RNA mRNA IDIBAPS-Hospital Clinic, Spain  
VLP VLP Bezmialem Vakif University  
VLP VLP Middle East Technical University  
VLP Enveloped Virus-Like Particle (eVLP) VBI Vaccines Inc. CMV, GBM, Zika
VLP S protein integrated in HIV VLPs IrsiCaixa AIDS Research/IRTA-CReSA/Barcelona Supercomputing
Centre/Grifols		  
VLP VLP + Adjuvant Mahidol University/ The Government Pharmaceutical Organization
(GPO)/Siriraj Hospital		  
VLP Virus-like particles, lentivirus and
baculovirus vehicles		 Navarrabiomed, Oncoimmunology group  
VLP Virus-like particle, based on RBD displayed
on virus-like particles		 Saiba GmbH  
VLP ADDomerTM multiepitope display Imophoron Ltd and Bristol University’s Max Planck Centre  
VLP Unknown Doherty Institute  
VLP VLP OSIVAX  
VLP eVLP ARTES Biotechnology malaria
VLP VLPs peptides/whole virus Univ. of Sao Paulo  
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After the vaccine is developed

It is not the only challenge to come up with an effective vaccine for COVID-19 in a short period but the most significant problem would be getting enough doses of the vaccine to be supplied to the countries globally. There is a risk that the more affluent countries can monopolize on the supply of COVID-19 vaccines globally in a similar way that happened with the flu pandemic. Therefore, along with focusing on the vaccine development, we should focus on containing the spread of the virus. Economically weak countries as in Africa would face problems in accessing vaccines, as happened with anti-HIV drugs. Due to the high rates of HIV drugs, several poor people died in Africa not being able to afford it. Therefore, there should be a fair distribution of the vaccines if any company succeeds in the race of developing a vaccine for COVID-19.

Convalescent plasma therapy

Convalescent plasma therapy is an old concept of separating serum from the blood of a patient who has recovered from infection and injecting it to another infected patient. The convalescent plasma contains the antibodies for the infectious pathogen which neutralizes the pathogen in the new recipient patient. This therapy can be useful in treating COVID-19 patients.

The evidence coming from studies that reported the use of convalescent plasma therapy in treating past coronavirus infections such as SARS and MERS compelled the researchers to apply this therapy on COVID-19 patients.46–49 Recent studies have highlighted the beneficial effects of convalescent plasma therapy in critically ill COVID-19 patients.50 Among the five critically ill COVID-19 patients who were administered convalescent plasma, three patients were discharged upon recovery, and two patients are in the incubation period of 37 days.50 This treatment modality is associated with some disadvantages. Convalescent plasma therapy increases the risk of serum related disease and antibody-dependent enhancement of infection. There is always the risk of transmission of other infectious diseases through the serum and the additional risk associated with convalescent plasma therapy is the chances of developing infection from another viral strain due to antibodies against one form of coronavirus.51 All published studies on clinical trials with convalescent plasma did not include a negative-control group needed to judge the efficacy of the intervention. Therefore, the need of the hour is the identification of the human monoclonal antibody for a common antigenic determinant/epitope of SARS CoV-2 to prevent COVID-19.

Monoclonal antibody therapy

Human monoclonal antibodies such as 80 R, m396, and S230.15 specific for the S1 domain of the SARS CoV have been reported to be effective in neutralizing the SARS-CoV infections by inhibiting their binding to the ACE receptors on the host cells.52 Another study reported that the monoclonal antibody CR3014 reduced the rate of replication of SARS-CoV genome and inhibited viral shedding, thus wholly prevented the virus-induced lung pathology. This antibody also works on the principle of inhibiting the binding of SARS-CoV by reducing the affinity of the S1 domain of the virus for the ACE receptor on the host cells.53

Since the receptor-binding domain of SARS-CoV-2 differs significantly from the SARS-CoV virus, the monoclonal antibodies (as m396, CR3014) targeting the S1 domain of SARS-CoV may not be effective in neutralizing the novel SARS-CoV-2. A recent study highlighted that the human monoclonal antibody CR3022 completely neutralizes both SARS-CoV and SARS-CoV-2. Therefore, these monoclonal antibodies can be considered for use in the prevention and treatment of COVID-19.54 Another study reported that the human monoclonal antibody 47D11 neutralizes SARS-CoV-2 by binding to the conserved sequence on the receptor-binding domain of the S1B protein. These antibodies can slow down the viral infection and can impart immunity in the uninfected persons.55 The receptor-binding domain is the best target to develop monoclonal antibody treatment to manage or prevent SARS-CoV-2 infections.

Takeda Pharmaceutical Company based in Japan is in the process of preparing a monoclonal antibody mixture, TAK-888 from the serum of recovered COVID-19 patients to come up with a new treatment strategy for COVID-19. Another pharmaceutical company, Vir Pharmaceuticals, USA, is testing antibodies isolated from recovered SARS patients to neutralize SARS-CoV-2. This company has also collaborated with a China-based company, WuXi Biologics, to develop a serum-based therapy to tackle SARS-CoV-2 infection in critically ill patients.56

A limitation to the use of convalescent plasma and MAbs is that they might benefit hospitalized patients but will not be generally useful for the population.

Conclusion

Several companies have initiated the development of antiviral and vaccines for COVID-19. Different approaches have been undertaken to develop an effective vaccine for COVID-19 such as attenuated virus, viral proteins, viral nucleic acid, virus-like particle, peptide, viral vector (replicating and non-replicating), and recombinant proteins. However, the most significant challenge post-vaccine development will be the fair distribution of the vaccines globally. Convalescent plasma therapy and monoclonal antibody therapy are also being tested and can be the potential therapeutic modality for the management and prevention of COVID-19. However, they might benefit only the hospitalized patients and will not be generally useful for the population.

Disclosure of potential conflicts of interest

No potential conflicts of interest were disclosed.

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