COVID-19 vaccine development: milestones, lessons and prospects

Abstract

With the constantly mutating of SARS-CoV-2 and the emergence of Variants of Concern (VOC), the implementation of vaccination is critically important. Existing SARS-CoV-2 vaccines mainly include inactivated, live attenuated, viral vector, protein subunit, RNA, DNA, and virus-like particle (VLP) vaccines. Viral vector vaccines, protein subunit vaccines, and mRNA vaccines may induce additional cellular or humoral immune regulations, including Th cell responses and germinal center responses, and form relevant memory cells, greatly improving their efficiency. However, some viral vector or mRNA vaccines may be associated with complications like thrombocytopenia and myocarditis, raising concerns about the safety of these COVID-19 vaccines. Here, we systemically assess the safety and efficacy of COVID-19 vaccines, including the possible complications and different effects on pregnant women, the elderly, people with immune diseases and acquired immunodeficiency syndrome (AIDS), transplant recipients, and cancer patients. Based on the current analysis, governments and relevant agencies are recommended to continue to advance the vaccine immunization process. Simultaneously, special attention should be paid to the health status of the vaccines, timely treatment of complications, vaccine development, and ensuring the lives and health of patients. In addition, available measures such as mix-and-match vaccination, developing new vaccines like nanoparticle vaccines, and optimizing immune adjuvant to improve vaccine safety and efficacy could be considered.

Fig. 1

The milestones of COVID-19 vaccine development. With the maturity of vaccine platforms, more and more COVID-19 vaccines have entered clinical trials and been approved for emergency use in many countries. However, the appearance of VOCs has brought great challenges to existing COVID-19 vaccines. By changing the administration route, the protection provided by vaccines can be enhanced, and more vaccination strategies are applied to cope with VOCs. In addition, more vaccine development methods are applied, such as developing polyvalent vaccines and improving adjuvant and delivery systems. These enormous changes form a milestone in the COVID-19 vaccine progress compared with post-years

Fig. 2

Vaccine-induced Th1 cell response. Some COVID-19 vaccines would induce Th1 cell responses. After recognition of the AP-MHC class II complex and T-cell receptor (TCR), CD4⁺ T cells distributed in peripheral lymphoid organs can differentiate into Th1 cells, which secrete various cytokines, such as interleukin 2 (IL-2), and simultaneously upregulate the expression of related receptors (IL-2R). Through IL-2 and IL-2R, T-cell proliferation and CD8⁺ T-cell activation are promoted, CD8⁺ T-cell can differentiate into cytotoxic T lymphocytes (CTLs) through the activation, producing perforin and other cytokines, which may improve the efficacy of vaccines

Fig. 3

Vaccine-induced germinal center response. Some COVID-19 vaccines would induce a germinal center response. Upon the interaction of T cells and B cells, some activated Th cells move to the lymphatic follicles and then differentiate into Tfh cells. Activated B cells proliferate and divide in lymphatic follicles to form the germinal center. With the help of Tfh cells, high-frequency point mutations occur in the variable region of the antibody gene of GC B cells, and antibody category transformation occurs, finally forming memory B cells and plasma cells, which can produce high-affinity antibodies

Fig. 4

Vaccine-induced memory cell response. In the Th1 and GC B-cell processes, antigen-specific memory T cells and memory B cells are usually formed. Unlike initial T-cell activation, the activation of memory T cells no longer depends on antigen-presenting cells and can induce a stronger immune response. Most memory B cells enter the blood to participate in recycling and are rapidly activated to produce potent antibodies upon encountering the same antigen

Fig. 5

A timeline of critical events in the COVID-19 vaccine development progress. WHO has approved the emergency use of ten vaccines (including three India vaccines, COVISHIELD, COVAXIN, and COVOVAX). Vaccination plays a critical role in protecting people from SARS-CoV-2 infections. However, the appearance of VOCs brought big challenges to the efficacy of approved COVID-19 vaccines. These events were summarized and displayed in the form of a timeline

Fig. 6

A timeline of the preclinical and clinical trials of approved COVID-19 vaccines. Preclinical and clinical trials play important roles in evaluating the safety and protective efficacy of COVID-19 vaccines. The information of preclinical to clinical trials of several WHO-approved COVID-19 vaccines are provided in the form of a timeline, and partial Phase III clinical trials’ data were also displayed to show the total efficacy

Fig. 7

A systemic illustration of the mutation in the S protein of VOCs. VOCs were designated by WHO because of the enhanced infectivity or immune escape ability (or with both), the specific mutations in the S protein of VOC Alpha to Omicron are displayed, and the mutations related to enhanced immune escape ability were marked in green color, while the mutation related to decreased immune escape ability was marked into orange color

Fig. 8

A summary of some possible complications induced by COVID-19 vaccines. The possible complications induced by COVID-19 vaccines mainly include the following categories: (1) coagulation dysfunction, such as thrombocytopenia; (2) heart diseases, such as myocarditis; (3) immune diseases, such as allergic reactions, autoimmune hepatitis, and autoimmune thyroid diseases; (4) nervous system diseases, such as facial paralysis and functional neurological disorders; (5) lymphatic system diseases; and (6) other diseases, such as Rowell’s syndrome, macular rash, and chilblain-like lesions

Fig. 9

Effect of vaccination in different populations. COVID-19 vaccines are still effective for pregnant women, patients with autoimmune diseases, and controlled HIV-infected patients, and the overall efficacy can maintain about 80–90%, while the 30% neutralization reduction occurs in older people. Moreover, the overall neutralizing activity of COVID-19 vaccines in solid organ transplant recipients, cancer patients, and uncontrolled AIDS patients is significantly reduced