A COVID-19 vaccine has passed its first human trial. But is it the frontrunner?

Moderna Therapeutics has just entered phase two of its clinical trials. Here's how mRNA vaccines work and what the latest developments mean.

Sunday, May 31, 2020,
By Nsikan Akpan
Photograph by Model at atomic resolution in by Visual Science

A promising coronavirus vaccine candidate cleared a key hurdle this week, when Moderna Therapeutics entered phase two of clinical trials. The move signals that the company’s mRNA vaccine has passed its initial safety checks and has met an important milestone in bringing this drug closer to the public and commercial markets.

After almost five months of global deaths and economic shutdowns wrought by the COVID-19 pandemic, people are anxiously awaiting a glimmer of hope for a return to normal routines. This partly explains the recent frenzy over results from Moderna and its frontrunner candidate, which moved from the company’s lab in Cambridge, Massachusetts, to human trials in a record-setting 63 days.

On May 18, the biotech company had announced preliminary findings that healthy subjects had responded to its mRNA vaccine by producing “neutralising antibodies.” Antibodies are the key sentinels made by the immune system to prevent infection by the coronavirus. Experts were quick to point out that the results applied to only eight people out of 45 in the trial, which is being conducted by the U.S. National Institute of Allergy and Infectious Diseases. The company has not released sufficient information to gauge whether the phase one subjects had protective immune responses, which is widely considered by immunologists to involve more than simply producing antibodies.

But the details that Moderna did present, paired with the latest announcement, suggest that the company may be on its way to achieving something unprecedented: licensing the first mRNA vaccine for human use.

Pharmacist Michael Witte (left) gives Rebecca Sirull a shot in the first phase of a clinical trial for a potential vaccine for COVID-19 on March 16, 2020. Sirull is the third patient to receive the shot in the study at the Kaiser Permanente Washington Health Research Institute in Seattle, one of three sites participating in the phase one trial.

Photograph by Ted S. Warren, AP Photo

“The results are exciting, because they've got phase one data showing that the vaccine is safe, which is a big deal,” says Ali Salem, a drug developer and professor at the University of Iowa’s College of Pharmacy who is not involved in the Moderna trial.

The phase two trial will involve an estimated 600 participants spread across 10 sites and eight states. Those sites began screening for subjects last week, and if they qualify based on physical exams, some will receive immunisations starting this coming Monday. After this story initially published, Moderna confirmed via press release that the first participants in each age group of the trial—adults below and above age 55—have received doses of the company's candidate.

“Our principal investigators would easily say that these studies are the most important that they’ve done in their lifetimes,” says Jaime Farra, a marketing director at the Alliance for Multispecialty Research, which is running a site in Newton, Kansas.

How mRNA vaccines emerged

Whenever a germ infects a body, our immune systems scramble to recognise and mount a response. Traditional vaccines take advantage of that response by injecting whole but inactive viruses, or their whole proteins, into our bodies, triggering an immune reaction. These vaccines take time to develop, in part because scientists must grow and inactivate an entire germ or its proteins in a specific way.

Messenger RNA is genetic material made of nucleic acid—the same stuff as our DNA—that travels throughout our cells, giving final instructions on which proteins to build to form the body’s cellular architecture. In the early 1990s, scientists wondered what would happen if they manufactured pieces of viral DNA and mRNA and then injected them into human cells or lab animals. The hope was that the cells would take in the genetic snippets, make viral proteins, and trigger an immune response.

In theory, this method would allow scientists to make vaccines faster; instead of weeks, a candidate could be ready to test in hours or days. These vaccine candidates would also be more flexible and durable against germs that tend to evolve through mutation, such as coronaviruses, influenza, and HIV. This could help lead to a universal vaccine that would work against multiple strains of a virus, says Margaret Liu, chairman of the board for the International Society of Vaccines.

Thirty years ago, Liu was among the first wave of lab researchers to try to use DNA and mRNA vaccines; her early results with a universal DNA vaccine for influenza were the first to show protection and showed the most promise—at least in mice. Overall, the early days of DNA vaccines and mRNA vaccines showed repeated success in animal models, which is known as the “pre-clinical” stage of drug development, but then couldn’t generate potent immune responses in humans.

“People thought, well, it must be because humans are bigger,” Liu says. But that hypothesis lost support after successful DNA vaccines were developed for horses, fish, and California condors.

Meanwhile, mRNA vaccines struggled with weakened stability. Once inside the body, the mRNA from a vaccine breaks down faster than DNA, which also limits the immune potency. Additionally, mRNA can aggravate immune cells, causing adverse reactions. For years, these challenges sidelined mRNA vaccines and relegated DNA vaccines to veterinary medicine.

The pivot in progress

The narrative began to shift in 2005, when scientists at the University of Pennsylvania introduced slight chemical modifications to mRNA vaccines. These changes added durability and made the vaccines safer, causing fewer adverse immune responses.

“A lot of people started to look at mRNA as a therapeutic strategy for a variety of diseases,” the University of Iowa’s Salem says. One of these offshoots would become “ModeRNA Therapeutics,” now known as Moderna, a company created in 2010 after Harvard researcher Derrick Rossi used modified mRNA to reprogram stem cells in a bid to treat cardiovascular disease.

Over the years, the company also came to rely on a popular tool for drug delivery called lipid nanoparticles. By packing genetic material inside a slippery pod made of oily lipids, these particles could more easily slide mRNA into cells, where it could go to work. With safer mRNA technology and better drug delivery, the company was able to expand its portfolio and pursue remedies for cancer and a range of infectious diseases, including the flu. But the major turning point arrived with the mosquito-borne Zika virus.

Dozens of crown-like spikes (red), which give coronaviruses their name, protrude from the surface of the virus and enable infection of a human cell.

Photograph by Model at atomic resolution in by Visual Science

After Zika emerged in 2015, laboratories rushed to find a suitable vaccine. Justin Richner, now an assistant professor at the University of Illinois at Chicago, was part of a multi-university effort to conduct early research on mRNA vaccine candidates made by Moderna Therapeutics. Richner says the team honed the mRNA codes, which led one of Moderna’s Zika vaccines into early human trials in 2016—where it stalled.

Safety first

Moderna Therapeutics did not respond to multiple requests from National Geographic for an interview. But the company’s corporate updates, which are not peer-reviewed, can yield clues about their progress with the COVID-19 vaccine. For example, while Moderna’s May 18 announcement didn’t provide hard numbers about how many antibodies were present in humans or mice after immunisation. But it did reveal that the first phase of its COVID-19 trial has apparently achieved its primary goal to determine the safest drug dosage.

“When you do a first-in-humans clinical trial, the utmost important information to get out is whether the vaccine is safe,” says Maria Elena Bottazzi, associate dean at Baylor College of Medicine's National School of Tropical Medicine, who is not involved in the Moderna trial.

She adds that a better sign of success for Moderna may be something that hasn’t yet been addressed by the company’s statements: T-cells. Antibodies are only one branch of an immune response. T-cells are another. Both can form lasting protection on their own, but T-cells help make antibodies emerge. That matters because DNA and mRNA vaccines are better geared toward triggering T-cells, Bottazzi says, but assessing such a response is laborious and typically reserved for later phases of human trials.

Still, Moderna could have a long way to go. Phase two subjects are slated to be monitored for at least 15 months, though if early signs look good, the vaccine candidate could progress to its final stages later this year.

Regardless of whether Moderna succeeds, the world will need multiple versions to beat the pandemic. Globally, more than a hundred COVID-19 vaccine candidate trials are underway, and so far, multiple companies are reporting promising peer-reviewed results. Numerous bets are ultimately an advantage, because if any single vaccine candidate fails, the others remain to offer continued hope, Bottazzi says.

A human cell (greenish brown) is heavily infected with SARS-CoV-2 virus particles (pink) isolated from a human patient. This image was captured and colour-enhanced at the NIAID Integrated Research Facility in Fort Detrick, Maryland. A vaccine would prevent the virus from replicating and taking over the host’s cells.

Photograph by Colorized scanning electron micrograph by National Institute of Allergy and Infectious Diseases, NIH
Editor's note: The story has been updated with the news that Moderna has confirmed the start of its phase two trial. The story was originally published on May 29.
Read More