Nanoparticle vaccine for COVID-19
Stanford University
"Our
goal is to make a single-shot vaccine that does not require a cold-chain for
storage or transport. If we're successful at doing it well, it should be cheap
too," said Kim, who is the Virginia and D. K. Ludwig Professor of
Biochemistry. "The target population for our vaccine is low- and
middle-income countries."
Their vaccine, detailed in a paper published Jan. 5 in ACS Central Science, contains nanoparticles studded with the same proteins that comprise the virus's distinctive surface spikes.
In addition to being the reason why these are
called coronaviruses -- corona is Latin for "crown" -- these spikes
facilitate infection by fusing to a host cell and creating a passageway for the
viral genome to enter and hijack the cell's machinery to produce more viruses.
The spikes can also be used as antigens, which means their presence in the body
is what can trigger an immune response.
Nanoparticle vaccines balance the effectiveness of viral-based vaccines with the safety and ease-of-production of subunit vaccines.
Vaccines that use viruses to deliver the antigen are often more effective than vaccines that contain only isolated parts of a virus. However, they can take longer to produce, need to be refrigerated and are more likely to cause side effects.
Nucleic acid vaccines
-- like the Pfizer and Moderna mRNA vaccines that have recently been authorized
for emergency use by the FDA -- are even faster to produce than nanoparticle
vaccines but they are expensive to manufacture and may require multiple doses.
Initial tests in mice suggest that the Stanford nanoparticle vaccine could
produce COVID-19 immunity after just one dose.
The researchers are also hopeful that it could be stored at room temperature and are investigating whether it could be shipped and stored in a freeze-dried, powder form.
By comparison, the vaccines that are farthest along in development
in the United States all need to be stored at cold temperatures, ranging from
approximately 8 to -70 degrees Celsius (46 to -94 degrees Fahrenheit).
"This
is really early stage and there is still lots of work to be done," said
Abigail Powell, a former postdoctoral scholar in the Kim lab and lead author of
the paper. "But we think it is a solid starting point for what could be a
single-dose vaccine regimen that doesn't rely on using a virus to generate
protective antibodies following vaccination."
The
researchers are continuing to improve and fine-tune their vaccine candidate,
with the intention of moving it closer to initial clinical trials in humans.
Spikes
and nanoparticles
The
spike protein from SARS-CoV-2 is quite large, so scientists often formulate
abridged versions that are simpler to make and easier to use. After closely
examining the spike, Kim and his team chose to remove a section near the
bottom.
To complete their vaccine, they combined this shortened spike with nanoparticles of ferritin -- an iron-containing protein -- which has been previously tested in humans. Before the pandemic, Powell had been working with these nanoparticles to develop an Ebola vaccine.
Together with scientists at the SLAC
National Accelerator Laboratory, the researchers used cryo-electron microscopy
to get a 3D image of the spike ferritin nanoparticles in order to confirm that
they had the proper structure.
For the mouse tests, the researchers compared their shortened spike nanoparticles to four other potentially useful variations: nanoparticles with full spikes, full spikes or partial spikes without nanoparticles, and a vaccine containing just the section of the spike that binds to cells during infection.
Testing the
effectiveness of these vaccines against actual SARS-CoV-2 virus would have
required the work to be done in a Biosafety Level 3 lab, so the researchers
instead used a safer pseudo-coronavirus that was modified to carry SARS-CoV-2's
spikes.
The
researchers determined the potential effectiveness of each vaccine by
monitoring levels of neutralizing antibodies. Antibodies are blood proteins
produced in response to antigens; neutralizing antibodies are the specific
subset of antibodies that actually act to prevent the virus from invading a
host cell.
After a single dose, the two nanoparticle vaccine candidates both resulted in neutralizing antibody levels at least twice as high as those seen in people who have had COVID-19, and the shortened spike nanoparticle vaccine produced a significantly higher neutralizing response than the binding spike or the full spike (non-nanoparticle) vaccines.
After a second dose, mice that had received
the shortened spike nanoparticle vaccine had the highest levels of neutralizing
antibodies.
Looking
back at this project, Powell estimates that the time from inception to the
first mouse studies was about four weeks. "Everybody had a lot of time and
energy to devote to the same scientific problem," she said. "It is a
very unique scenario. I don't really expect I'll ever encounter that in my
career again."
"What's
happened in the past year is really fantastic, in terms of science coming to
the fore and being able to produce multiple different vaccines that look like
they're showing efficacy against this virus," said Kim, who is senior
author of the paper. "It normally takes a decade to make a vaccine, if
you're even successful. This is unprecedented."
Vaccine
access
Although the team's new vaccine is intended specifically for populations that may have more difficulty accessing other SARS-CoV-2 vaccines, it is possible, given the rapid progress of other vaccine candidates, that it will not be needed to address the current pandemic.
In that case, the researchers are prepared to pivot
again and pursue a more universal coronavirus vaccine to immunize against
SARS-CoV-1, MERS, SARS-CoV-2 and future coronaviruses that are not yet known.
"Vaccines are one of the most profound achievements of biomedical research. They are an incredibly cost-effective way to protect people against disease and save lives," said Kim.
"This coronavirus vaccine is part of work we're
already doing -- developing vaccines that are historically difficult or
impossible to develop, like an HIV vaccine -- and I'm glad that we're in a
situation where we could potentially bring something to bear if the world needs
it."
This work was funded by MCHRI, the Damon Runyon Cancer Research Foundation, the National Institutes of Health, the Virginia and D. K. Ludwig Fund for Cancer Research and Chan Zuckerberg Biohub.
