Citation
- Authors: Guo, S.. et al.
- Year: 2023
- Journal: Cell Discov 9 79
- Applications: in vitro / DNA / FectoPRO
- Cell type: Expi293F
Description: Human embryonic kidney Fibroblast
Known as: Expi 293-F, Expi, HEK-293 Expi
Method
The first chain of DNA was synthesized using mRNA as the template with a 5’ RACE label in the end. With the help of 5’ RACE label, cDNA was amplified and then the variable (V) region of antibodies was amplified by nested PCR. The V region of both heavy and light chain were then linked respectively with human IgG1 skeleton as DNA fragment for mAb production.
1.6 μg DNA fragments were mixed with FectoPRO and added into 1×10^6 Expi293F cells per mL. Three days after transfection, cells were centrifuged and the supernatants containing the secreted mAbs were collected.
Abstract
Vaccination with different vaccines has been implemented globally to counter the continuous COVID-19 pandemic. However, the vaccine-elicited antibodies have reduced efficiency against the highly mutated Omicron sub-variants. Previously, we developed a protein subunit COVID-19 vaccine called ZF2001, based on the dimeric receptor-binding domain (RBD). This vaccine has been administered using different dosing intervals in real-world setting. Some individuals received three doses of ZF2001, with a one-month interval between each dose, due to urgent clinical requirements. Others had an extended dosing interval of up to five months between the second and third dose, a standard vaccination regimen for the protein subunit vaccine against hepatitis B. In this study, we profile B cell responses in individuals who received three doses of ZF2001, and compared those with long or short dosing intervals. We observed that the long-interval group exhibited higher and broader serologic antibody responses. These responses were associated with the increased size and evolution of vaccine-elicited B-cell receptor repertoires, characterized by the elevation of expanded clonotypes and somatic hypermutations. Both groups of individuals generated substantial amounts of broadly neutralizing antibodies (bnAbs) against various SARS-CoV-2 variants, including Omicron sub-variants such as XBB. These bnAbs target four antigenic sites within the RBD. To determine the vulnerable site of SARS-CoV-2, we employed cryo-electron microscopy to identify the epitopes of highly potent bnAbs that targeted two major sites. Our findings provide immunological insights into the B cell responses elicited by RBD-based vaccine, and suggest that a vaccination regimen of prolonging time interval should be used in practice.