For mRNA Vaccines, COVID-19 Is Just the Beginning
Easy to manufacture and update, these new vaccines may be a powerful tool against emerging variants and other infectious diseases.
Even the experts were startled by the remarkable success of the two first-of-their-kind messenger RNA (mRNA) vaccines developed by Moderna and Pfizer/BioNTech against COVID-19.
鈥淚f you had told me before that there would be 95% effectiveness for these vaccines, I鈥檇 have said you were dreaming,鈥 says , a professor in Molecular Microbiology and Immunology. Their adaptability for infectious threats beyond COVID, too, is something vaccine researchers have dreamed of.
mRNA vaccines exploit the system our cells use to make proteins. Our cells make proteins based on information in our DNA: Each gene codes for a particular protein. That genetic information is essential, but cells can鈥檛 do anything with it until mRNA molecules translate it into instructions for making specific proteins. That鈥檚 what mRNA vaccines deliver: ready-made mRNA instructions for making a specific protein. In the case of these new COVID-19 vaccines, the instructions are for making the 鈥渟pike鈥 (S) protein found on the surface of the SARS-CoV-2 virus.
Vaccines that deliver the S protein stimulate the same protective antibody response as exposure to the actual virus. But mRNA vaccines provoke an especially robust immune response, Pekosz notes, because our own bodies make the protein. 鈥淲hen our cells express a foreign protein, that is a trigger for different types of immune cells to be recruited and contribute to the response,鈥 he says. This includes both antibody-secreting B cells and the T cells that hunt and kill infected cells.
But can that protection stand up to new variants of the virus鈥攕uch as the now-widespread 鈥淯K variant,鈥 which is ?
鈥淪o far, it looks like the mutations that are in the spike protein in these different variants are not going to let the virus escape the vaccine,鈥 says , a senior scholar at the . But this could change鈥攑articularly as SARS-CoV-2 continues to spread throughout the world, with each new host creating opportunities for mutation. If these mutations notably alter the protein鈥檚 structure, new variants could elude the antibodies elicited by vaccines for other variants.
Fortunately, mRNA vaccines are well-suited for keeping up with sudden changes in the viral landscape. The mRNA itself is manufactured via a standardized process in which the core ingredient is a DNA sequence encoding a specific viral protein. This means vaccine makers can update the vaccine to fend off new strains by simply tweaking the 鈥渞ecipe鈥 to encode a new protein.
鈥淚f this virus becomes endemic, it might be that new vaccine variants will need to be rolled out to match the variants that take root,鈥 Gronvall says, pointing to seasonal flu shots as a parallel.
For his part, Pekosz sees potential in this approach for fending off the highly variable influenza virus. to develop 鈥渦niversal鈥 flu vaccines based on mRNAs that train the immune system to fight diverse strains of seasonal or pandemic flu.
The extra immune firepower mRNA vaccines provide could also yield more durable protection. 鈥淲e could probably generate a flu vaccine that could theoretically protect us for five years instead of just one,鈥 Pekosz says. Indeed, he believes the COVID-19 vaccine effort鈥檚 success heralds a bright future in the fight against other pathogens.
鈥淚f it鈥檚 on the outside of a virus, then this technology makes it really easy to swap that sequence in and generate an immune response [against it],鈥 says Pekosz.
Michael Eisenstein is a science writer whose work has appeared in Nature, SEED, Wired Science, and , among other publications.
