Scientists want the salamander's secret: how they regenerate tissue
All organisms have the capacity to repair or regenerate tissue damage. None can do it better than salamanders or newts, which can regenerate an entire severed limb.
That feat has amazed and delighted man from the dawn of time and led to endless attempts to understand how it happens – and whether we can control it for our own purposes. An exciting new clue toward that understanding has come from a surprising source: research on the decline of cells, called cellular senescence.
Senescence is the last stage in the life of a cell. Whereas some cells simply break up or wither and die off, others transition into a zombie-like state where they can no longer divide. In this liminal phase, the cell still pumps out many different molecules that can affect its neighbors and cause low grade inflammation. Senescence is associated with many of the declining biological functions that characterize aging, such as inflammation and genomic instability.
Oddly enough, newts are one of the few species that do not accumulate senescent cells as they age, according to research over several years by Maximina Yun. A research group leader at the Center for Regenerative Therapies Dresden and the Max Planck Institute of Molecular and Cell Biology and Genetics, in Dresden, Germany, Yun discovered that senescent cells were induced at some stages of regeneration of the salamander limb, “and then, as the regeneration progresses, they disappeared, they were eliminated by the immune system,” she says. “They were present at particular times and then they disappeared.”
Senescent cells added to the edges of the wound helped the healthy muscle cells to “dedifferentiate,” essentially turning back the developmental clock of those cells into more primitive states.
Previous research on senescence in aging had suggested, logically enough, that applying those cells to the stump of a newly severed salamander limb would slow or even stop its regeneration. But Yun stood that idea on its head. She theorized that senescent cells might also play a role in newt limb regeneration, and she tested it by both adding and removing senescent cells from her animals. It turned out she was right, as the newt limbs grew back faster than normal when more senescent cells were included.
Senescent cells added to the edges of the wound helped the healthy muscle cells to “dedifferentiate,” essentially turning back the developmental clock of those cells into more primitive states, which could then be turned into progenitors, a cell type in between stem cells and specialized cells, needed to regrow the muscle tissue of the missing limb. “We think that this ability to dedifferentiate is intrinsically a big part of why salamanders can regenerate all these very complex structures, which other organisms cannot,” she explains.
Yun sees regeneration as a two part problem. First, the cells must be able to sense that their neighbors from the lost limb are not there anymore. Second, they need to be able to produce the intermediary progenitors for regeneration, , to form what is missing. “Molecularly, that must be encoded like a 3D map,” she says, otherwise the new tissue might grow back as a blob, or liver, or fin instead of a limb.
Wound healing
Another recent study, this time at the Mayo Clinic, provides evidence supporting the role of senescent cells in regeneration. Looking closely at molecules that send information between cells in the wound of a mouse, the researchers found that senescent cells appeared near the start of the healing process and then disappeared as healing progressed. In contrast, persistent senescent cells were the hallmark of a chronic wound that did not heal properly. The function and significance of senescence cells depended on both the timing and the context of their environment.
The paper suggests that senescent cells are not all the same. That has become clearer as researchers have been able to identify protein markers on the surface of some senescent cells. The patterns of these proteins differ for some senescent cells compared to others. In biology, such physical differences suggest functional differences, so it is becoming increasingly likely there are subsets of senescent cells with differing functions that have not yet been identified.
There are disagreements within the research community as to whether newts have acquired their regenerative capacity through a unique evolutionary change, or if other animals, including humans, retain this capacity buried somewhere in their genes.
Scientists initially thought that senescent cells couldn’t play a role in regeneration because they could no longer reproduce, says Anthony Atala, a practicing surgeon and bioengineer who leads the Wake Forest Institute for Regenerative Medicine in North Carolina. But Yun’s study points in the other direction. “What this paper shows clearly is that these cells have the potential to be involved in tissue regeneration [in newts]. The question becomes, will these cells be able to do the same in humans.”
As our knowledge of senescent cells increases, Atala thinks we need to embrace a new analogy to help understand them: humans in retirement. They “have acquired a lot of wisdom throughout their whole life and they can help younger people and mentor them to grow to their full potential. We're seeing the same thing with these cells,” he says. They are no longer putting energy into their own reproduction, but the signaling molecules they secrete “can help other cells around them to regenerate.”
There are disagreements within the research community as to whether newts have acquired their regenerative capacity through a unique evolutionary change, or if other animals, including humans, retain this capacity buried somewhere in their genes. If so, it seems that our genes are unable to express this ability, perhaps as part of a tradeoff in acquiring other traits. It is a fertile area of research.
Dedifferentiation is likely to become an important process in the field of regenerative medicine. One extreme example: a lab has been able to turn back the clock and reprogram adult male skin cells into female eggs, a potential milestone in reproductive health. It will be more difficult to control just how far back one wishes to go in the cell's dedifferentiation – part way or all the way back into a stem cell – and then direct it down a different developmental pathway. Yun is optimistic we can learn these tricks from newts.
Senolytics
A growing field of research is using drugs called senolytics to remove senescent cells and slow or even reverse disease of aging.
“Senolytics are great, but senolytics target different types of senescence,” Yun says. “If senescent cells have positive effects in the context of regeneration, of wound healing, then maybe at the beginning of the regeneration process, you may not want to take them out for a little while.”
“If you look at pretty much all biological systems, too little or too much of something can be bad, you have to be in that central zone” and at the proper time, says Atala. “That's true for proteins, sugars, and the drugs that you take. I think the same thing is true for these cells. Why would they be different?”
Our growing understanding that senescence is not a single thing but a variety of things likely means that effective senolytic drugs will not resemble a single sledge hammer but more a carefully manipulated scalpel where some types of senescent cells are removed while others are added. Combinations and timing could be crucial, meaning the difference between regenerating healthy tissue, a scar, or worse.
BREAKING: The First U.S. Test to Detect If a Person Has Potential Immunity to COVID-19 Was Just Developed
While testing for COVID-19 ramps up around the country, there's another kind of testing that will prove equally important to combating the pandemic: one that can detect whether someone has already been infected.
"The idea is that this assay can be established anywhere in the world following these steps."
Why is this important? As former FDA commissioner Scott Gottlieb wrote in today's Wall Street Journal: "If a sizable portion of a local community has some protection, authorities can be more confident in relying less on invasive measures. Once deployed, serological tests are cheap, straightforward, and easy to scale."
Now, a microbiology lab at the Icahn School of Medicine at Mount Sinai, led by Dr. Florian Krammer, has just announced the development of this serological test. Leapsmag spoke with Daniel Stadlbauer, a post-doctoral fellow in the lab who helped lead the work.
Is yours the first serological test available?
They did something similar in South Korea. In the U.S., it's the first of these tests.
How close are we to rolling this test out to the public?
Last week, we started this process and we finished the protocol today. Mount Sinai is trying to roll this out in the next few days in the clinic to see which patients have been infected with coronavirus recently or have been infected at all.
The protocol we uploaded today can be used as a template for other research labs or hospitals to follow the steps we provided and they should then be able to set up the antibody test. The idea is that this assay can be established anywhere in the world following these steps.
Are there any bottlenecks to getting this rolled out – supply chain or regulation obstacles?
There are no regulations that say you can't do it. Research labs and hospitals for sure can do it. I'm not aware of supply chain issues because you need basic lab equipment and materials, but I don't think those are in short supply right now.
How does the test work?
People coming to the hospital who are suspected to have infection with coronavirus, their blood gets taken routinely. This blood can be used for our test, too. The test will tell you if this person has antibodies against coronavirus. You can also test the blood of people who are not currently sick to see if this person was infected, say, a month ago. If there are antibodies in the blood, you can say this person is probably immune to getting it again.
It will be essential workers who need to be tested first, like nurses, firefighters, and doctors. It will be great to know that they would not put themselves or others at risk by going back to work because they cannot spread the disease.
"People probably cannot get reinfected once they mount a good immune response and have good antibody levels."
How soon after infection does the test detect if you have antibodies?
Usually after 7 days of infection.
How long do the antibodies last to confer immunity?
Those studies need to be done – right now it's unclear. People probably cannot get reinfected once they mount a good immune response and have good antibody levels. How long those level last still needs to be investigated. But they won't get reinfected in the next, I would say, six months.
How accurate is the test?
Very accurate. The advantage – which is bad for us but good for the test – is that humans have no baseline immunity to this coronavirus. It means that when you have not been infected, you have pretty much no antibodies, which is why it can spread so easily. But once you have antibodies in your blood, we can detect them and it's a clear difference between antibodies or no antibodies.
Where should hospitals and labs go for more information on how to build their own tests from your work?
They should check out our lab website to find the detailed protocol to download.
If I am a person who just wants to take this test to find out if I've already been infected, what should I do?
It will be done soon in the clinical setting. I don't know yet how widely it will be available. The more research labs and hospitals that set up this testing, the more people who can be tested in the future.
Kira Peikoff was the editor-in-chief of Leaps.org from 2017 to 2021. As a journalist, her work has appeared in The New York Times, Newsweek, Nautilus, Popular Mechanics, The New York Academy of Sciences, and other outlets. She is also the author of four suspense novels that explore controversial issues arising from scientific innovation: Living Proof, No Time to Die, Die Again Tomorrow, and Mother Knows Best. Peikoff holds a B.A. in Journalism from New York University and an M.S. in Bioethics from Columbia University. She lives in New Jersey with her husband and two young sons. Follow her on Twitter @KiraPeikoff.
Blood Donated from Recovered Coronavirus Patients May Soon Yield a Stopgap Treatment
In October 1918, Lieutenant L.W. McGuire of the United States Navy sent a report to the American Journal of Public Health detailing a promising therapy that had already saved the lives of a number of officers suffering from pneumonia complications due to the Spanish influenza outbreak.
"These antibodies then become essentially drugs."
McGuire described how transfusions of blood from recovered patients – an idea which had first been trialed during a polio epidemic in 1916 – had led to rapid recovery in a series of severe pneumonia cases at a Naval Hospital in Massachusetts. "It is believed the serum has a decided influence in shortening the course of the disease, and lowering the mortality," he wrote.
Now more than a century on, this treatment – long forgotten in the western world - is once again coming to the fore during the current COVID-19 pandemic. With fatalities continuing to rise, and no vaccine expected for many months, experts are urging medical centers across the U.S. and Europe to initiate collaborations between critical care and transfusion services to offer this as an emergency treatment for those who need it most.
As of March 20, there are more than 90,000 individuals globally who have recovered from the disease. Some scientists believe that the blood of many of these people contains high levels of neutralizing antibodies that can kill the virus.
"These antibodies then become essentially drugs," said Arturo Casadevall, professor of Molecular Microbiology & Immunology at John Hopkins Bloomberg School of Public Health, who is currently co-ordinating a clinical trial of convalescent serum for COVID-19 involving 20 institutions across the US.
"We're talking about preparing a therapy right out of the serum of those that have recovered. It could also be used in patients who are already sick, but have not progressed to respiratory failure, to treat them before they enter intensive care units. That will provide a lot of support because there's a limited number of respirators and resources."
The first conclusive data on how the blood of recovered patients can help tackle COVID-19 is set to come out of China, where it was also used as an emergency treatment during the SARS and MERS outbreaks. On February 9, a severely ill patient in Wuhan was treated with convalescent serum and since then, hospitals across China have used the therapy on a total of 245 patients, with 91 reportedly showing an improvement in symptoms.
In China alone, more than 58,000 patients have now recovered from COVID-19. Casadevall said that last week the country shipped 90 tons of serum and plasma from these patients to Italy – the center of the pandemic in Europe – for emergency use.
Some of the first people to be treated are likely to be doctors and nurses in hospitals who are most at risk of exposure.
A current challenge, however, is that the blood donation from the recovered patients must be precisely timed in order to maximize the number of antibodies a future patient receives. Doctors in China say that obtaining the necessary blood samples at the right time is one of the major barriers to applying the treatment on a larger scale.
"It's difficult to get the donations," said Dr. Yuan Shi of Chongqing Medical University. "When patients have recovered from the disease, we would like to collect their blood two to four weeks afterwards. We try our best to call back the patients, but it's sometimes difficult to get them to come back within that time period."
Because of such hurdles, Japan's largest drugmaker, Takeda Pharmaceuticals, is now working to turn neutralizing antibodies from recovered COVID-19 patients into a standardized drug product. They hope to launch a clinical trial for this in the next few months.
In the U.S., Casadevall hopes blood transfusions from recovered patients can become clinically available as a therapy within the next four weeks, once regulatory approval has been received. Some of the first people to be treated are likely to be doctors and nurses in hospitals who are most at risk of exposure, to provide a protective boost in their immunity.
"A lot of healthcare workers in the U.S. have already been asked to quarantine, and you can imagine what effect that's going to have on the healthcare system," he said. "It can't take large numbers of people staying home; there's not the capacity."
But not all medical experts are convinced it's the way to go, especially when it comes to the most severe cases of COVID-19. "There's no knowing whether that treatment would be useful or not," warned Dr. Andrew Freedman, head of Cardiff University's School of Medicine in the U.K.
"There are going to be better things available in a few months, but we are facing, 'What do you do now?'"
However, Casadevall says that the treatment is not envisioned as a panacea to treating coronavirus, but simply a temporary measure which could give doctors some options until stronger options such as vaccines or new drugs are available.
"This is a stopgap option," he said. "There are going to be better things available in a few months, but we are facing, 'What do you do now?' The only thing we can offer severely ill people at the moment is respiratory support and oxygen, and we don't have anything to prevent those exposed from going on and getting ill."