How Genetic Engineering Could Save the Coral Reefs
Underwater world with corals and tropical fish.
Coral reefs are usually relegated to bit player status in television and movies, providing splashes of background color for "Shark Week," "Finding Nemo," and other marine-based entertainment.
In real life, the reefs are an absolutely crucial component of the ecosystem for both oceans and land, rivaling only the rain forests in their biological complexity. They provide shelter and sustenance for up to a quarter of all marine life, oxygenate the water, help protect coastlines from erosion, and support thousands of tourism jobs and businesses.
Genetic engineering could help scientists rebuild the reefs that have been lost, and turn those still alive into a souped-up version that can withstand warmer and even more acidic waters.
But the warming of the world's oceans -- exacerbated by an El Nino event that occurred between 2014 and 2016 -- has been putting the world's reefs under tremendous pressure. Their vibrant colors are being replaced by sepulchral whites and tans.
That's the result of bleaching -- a phenomenon that occurs when the warming waters impact the efficiency of the algae that live within the corals in a symbiotic relationship, providing nourishment via photosynthesis and eliminating waste products. The corals will often "shuffle" their resident algae, reacting in much the same way a landlord does with a non-performing tenant -- evicting them in the hopes of finding a better resident. But when better-performing algae does not appear, the corals become malnourished, eventually becoming deprived of their color and then their lives.
The situation is dire: Two-thirds of Australia's Great Barrier Reef have undergone a bleaching event in recent years, and it's believed up to half of that reef has died.
Moreover, hard corals are the ocean's redwood trees. They take centuries to grow, meaning it could take centuries or more to replace them.
Recent developments in genetic engineering -- and an accidental discovery by researchers at a Florida aquarium -- provide opportunities for scientists to potentially rebuild a large proportion of the reefs that have been lost, and perhaps turn those still alive into a souped-up version that can withstand warmer and even more acidic waters. But many questions have yet to be answered about both the biological impact on the world's oceans, and the ethics of reengineering the linchpin of its ecosystem.
How did we get here?
Coral bleaching was a regular event in the oceans even before they began to warm. As a result, natural selection weeds out the weaker species, says Rachel Levin, an American-born scientist who has performed much of her graduate work in Australia. But the current water warming trend is happening at a much higher rate than it ever has in nature, and neither the coral nor the algae can keep up.
"There is a big concern about giving one variant a huge fitness advantage, have it take over and impact the natural variation that is critical in changing environments."
In a widely-read paper published last year in the journal Frontiers in Microbiology, Levin and her colleagues put forth a fairly radical notion for preserving the coral reefs: Genetically modify their resident algae.
Levin says the focus on algae is a pragmatic decision. Unlike coral, they reproduce extremely rapidly. In theory, a modified version could quickly inhabit and stabilize a reef. About 70 percent of algae -- all part of the genus symbiodinium -- are host generalists. That means they will insert themselves into any species of coral.
In recent years, work on mapping the genomes of both algae and coral has been progressing rapidly. Scientists at Stanford University have recently been manipulating coral genomes using larvae manipulated with the CRISPR/Cas9 technology, although the experimentation has mostly been limited to its fluorescence.
Genetically modifying the coral reefs could seem like a straightforward proposition, but complications are on the horizon. Levin notes that as many as 20 different species of algae can reside within a single coral, so selecting the best ones to tweak may pose a challenge.
"The entire genus is made up of thousands of subspecies, all very genetically distinct variants. There is a huge genetic diversity, and there is a big concern about giving one variant a huge fitness advantage, have it take over and impact the natural variation that is critical in changing environments," Levin says.
Genetic modifications to an algae's thermal tolerance also poses the risk of what Levin calls an "off-target effect." That means a change to one part of the genome could lead to changes in other genes, such as those regulating growth, reproduction, or other elements crucial to its relationship with coral.
Phillip Cleves, a postdoctoral researcher at Stanford who has participated in the CRISPR/Cas9 work, says that future research will focus on studying the genes in coral that regulate the relationship with the algae. But he is so concerned about the ethical issues of genetically manipulating coral to adapt to a changing climate that he declined to discuss it in detail. And most coral species have not yet had their genomes fully mapped, he notes, suggesting that such work could still take years.
An Alternative: Coral Micro-fragmentation
In the meantime, there is another technique for coral preservation led by David Vaughan, senior scientist and program manager at the Mote Marine Laboratory and Aquarium in Sarasota, Florida.
Vaughan's research team has been experimenting in the past decade with hard coral regeneration. Their work had been slow and painstaking, since growing larvae into a coral the size of a quarter takes three years.
The micro-fragmenting process in some ways raises fewer ethical questions than genetically altering the species.
But then, one day in 2006, Vaughan accidentally broke off a tiny piece of coral in the research aquarium. That fragment grew to the size of a quarter in three months, apparently the result of the coral's ability to rapidly regenerate when injured. Further research found that breaking coral in this manner -- even to the size of a single polyp -- led to rapid growth in more than two-dozen species.
Mote is using this process, known as micro-fragmentation, to grow large numbers of coral rapidly, often fusing them on top of larger pieces of dead coral. These coral heads are then planted in the Florida Keys, which has experienced bleaching events over 12 of the last 14 years. The process has sped up almost exponentially; Mote has planted some 36,000 pieces of coral to date, but Vaughan says it's on track to plant 35,000 more pieces this year alone. That sum represents between 20 to 30 acres of restored reef. Mote is on track to plant another 100,000 pieces next year.
This rapid reproduction technique in some ways allows Mote scientists to control for the swift changes in ocean temperature, acidification and other factors. For example, using surviving pieces of coral from areas that have undergone bleaching events means these hardier strains will propagate much faster than nature allows.
Vaughan recently visited the Yucatan Peninsula to work with Mexican researchers who are going to embark on a micro-fragmenting initiative of their own.
The micro-fragmenting process in some ways raises fewer ethical questions than genetically altering the species, although Levin notes that this could also lead to fewer varieties of corals on the ocean floor -- a potential flattening of the colorful backdrops seen in television and movies.
But Vaughan has few qualms, saying this is an ecological imperative. He suggests that micro-fragmentation could serve as a stopgap until genomic technologies further advance.
"We have to use the technology at hand," he says. "This is a lot like responding when a forest burns down. We don't ask questions. We plant trees."
The upcoming vaccine is changing the way we look at treating one of the country’s deadliest cancers.
Last week, researchers at the University of Oxford announced that they have received funding to create a brand new way of preventing ovarian cancer: A vaccine. The vaccine, known as OvarianVax, will teach the immune system to recognize and destroy mutated cells—one of the earliest indicators of ovarian cancer.
Understanding Ovarian Cancer
Despite advancements in medical research and treatment protocols over the last few decades, ovarian cancer still poses a significant threat to women’s health. In the United States alone, more than 12,0000 women die of ovarian cancer each year, and only about half of women diagnosed with ovarian cancer survive five or more years past diagnosis. Unlike cervical cancer, there is no routine screening for ovarian cancer, so it often goes undetected until it has reached advanced stages. Additionally, the primary symptoms of ovarian cancer—frequent urination, bloating, loss of appetite, and abdominal pain—can often be mistaken for other non-cancerous conditions, delaying treatment.
An American woman has roughly a one percent chance of developing ovarian cancer throughout her lifetime. However, these odds increase significantly if she has inherited mutations in the BRCA1 or BRCA2 genes. Women who carry these mutations face a 46% lifetime risk for ovarian and breast cancers.
An Unlikely Solution
To address this escalating health concern, the organization Cancer Research UK has invested £600,000 over the next three years in research aimed at creating a vaccine, which would destroy cancerous cells before they have a chance to develop any further.
Researchers at the University of Oxford are at the forefront of this initiative. With funding from Cancer Research UK, scientists will use tissue samples from the ovaries and fallopian tubes of patients currently battling ovarian cancer. Using these samples, University of Oxford scientists will create a vaccine to recognize certain proteins on the surface of ovarian cancer cells known as tumor-associated antigens. The vaccine will then train that person’s immune system to recognize the cancer markers and destroy them.
The next step
Once developed, the vaccine will first be tested in patients with the disease, to see if their ovarian tumors will shrink or disappear. Then, the vaccine will be tested in women with the BRCA1 or BRCA2 mutations as well as women in the general population without genetic mutations, to see whether the vaccine can prevent the cancer altogether.
While the vaccine still has “a long way to go,” according to Professor Ahmed Ahmed, Director of Oxford University’s ovarian cancer cell laboratory, he is “optimistic” about the results.
“We need better strategies to prevent ovarian cancer,” said Ahmed in a press release from the University of Oxford. “Currently, women with BRCA1/2 mutations are offered surgery which prevents cancer but robs them of the chance to have children afterward.
Teaching the immune system to recognize the very early signs of cancer is a tough challenge. But we now have highly sophisticated tools which give us real insights into how the immune system recognizes ovarian cancer. OvarianVax could offer the solution.”
How sharing, hearing, and remembering positive stories can help shape our brains for the better
Across cultures and through millennia, human beings have always told stories. Whether it’s a group of boy scouts around a campfire sharing ghost stories or the paleolithic Cro-Magnons etching pictures of bison on cave walls, researchers believe that storytelling has been universal to human beings since the development of language.
But storytelling was more than just a way for our ancestors to pass the time. Researchers believe that storytelling served an important evolutionary purpose, helping humans learn empathy, share important information (such as where predators were or what berries were safe to eat), as well as strengthen social bonds. Quite literally, storytelling has made it possible for the human race to survive.
Today, neuroscientists are discovering that storytelling is just as important now as it was millions of years ago. Particularly in sharing positive stories, humans can more easily form relational bonds, develop a more flexible perspective, and actually grow new brain circuitry that helps us survive. Here’s how.
How sharing stories positively impacts the brain
When human beings share stories, it increases the levels of certain neurochemicals in the brain, neuroscientists have found. In a 2021 study published in Proceedings of the National Academy of Sciences (PNAS), Swedish researchers found that simply hearing a story could make hospitalized children feel better, compared to other hospitalized children who played a riddle game for the same amount of time. In their research, children in the intensive care unit who heard stories for just 30 minutes had higher levels of oxytocin, a hormone that promotes positive feelings and is linked to relaxation, trust, social connectedness, and overall psychological stability. Furthermore, the same children showed lower levels of cortisol, a hormone associated with stress. Afterward, the group of children who heard stories tended to describe their hospital experiences more positively, and even reported lower levels of pain.
Annie Brewster, MD, knows the positive effect of storytelling from personal experience. An assistant professor at Harvard Medical School and the author of The Healing Power of Storytelling: Using Personal Narrative to Navigate Illness, Trauma, and Loss, Brewster started sharing her personal experience with chronic illness after being diagnosed with multiple sclerosis in 2001. In doing so, Brewster says it has enabled her to accept her diagnosis and integrate it into her identity. Brewster believes so much in the power of hearing and sharing stories that in 2013 she founded Health Story Collaborative, a forum for others to share their mental and physical health challenges.“I wanted to hear stories of people who had found ways to move forward in positive ways, in spite of health challenges,” Brewster said. In doing so, Brewster believes people with chronic conditions can “move closer to self-acceptance and self-love.”
While hearing and sharing positive stories has been shown to increase oxytocin and other “feel good” chemicals, simply remembering a positive story has an effect on our brains as well. Mark Hoelterhoff, PhD, a lecturer in clinical psychology at the University of Edinburgh, recalling and “savoring” a positive story, thought, or feedback “begins to create new brain circuitry—a new neural network that’s geared toward looking for the positive,” he says. Over time, other research shows, savoring positive stories or thoughts can literally change the shape of your brain, hard-wiring someone to see things in a more positive light.How stories can change your behavior
In 2009, Paul Zak, PhD, a neuroscientist and professor at Claremont Graduate University, set out to measure how storytelling can actually change human behavior for the better. In his study, Zak wanted to measure the behavioral effects of oxytocin, and did this by showing test subjects two short video clips designed to elicit an emotional response.
In the first video they showed the study participants, a father spoke to the camera about his two-year-old son, Ben, who had been diagnosed with terminal brain cancer. The father told the audience that he struggled to connect with and enjoy Ben, as Ben had only a few months left to live. In the end, the father finds the strength to stay emotionally connected to his son until he dies.
The second video clip, however, was much less emotional. In that clip, the same father and son are shown spending the day at the zoo. Ben is only suggested to have cancer (he is bald from chemotherapy and referred to as a ‘miracle’, but the cancer isn’t mentioned directly). The second story lacked the dramatic narrative arc of the first video.
Zak’s team took blood before and after the participants watched one of the two videos and found that the first story increased the viewers’ cortisol and oxytocin, suggesting that they felt distress over the boy’s diagnosis and empathy toward the boy and his father. The second narrative, however, didn’t increase oxytocin or cortisol at all.
But Zak took the experiment a step further. After the movie clips, his team gave the study participants a chance to share money with a stranger in the lab. The participants who had an increase in cortisol and oxytocin were more likely to donate money generously. The participants who had increased cortisol and oxytocin were also more likely to donate money to a charity that works with children who are ill. Zak also found that the amount of oxytocin that was released was correlated with how much money people felt comfortable giving—in other words, the more oxytocin that was released, the more generous they felt, and the more money they donated.
How storytelling strengthens our bond with others
Sharing, hearing, and remembering stories can be a powerful tool for social change–not only in the way it changes our brain and our behavior, but also because it can positively affect our relationships with other people
Emotional stimulation from telling stories, writes Zak, is the foundation for empathy, and empathy strengthens our relationships with other people. “By knowing someone’s story—where they come from, what they do, and who you might know in common—relationships with strangers are formed.”
But why are these relationships important for humanity? Because human beings can use storytelling to build empathy and form relationships, it enables them to “engage in the kinds of large-scale cooperation that builds massive bridges and sends humans into space,” says Zak.
Storytelling, Zak found, and the oxytocin release that follows, also makes people more sensitive to social cues. This sensitivity not only motivates us to form relationships, but also to engage with other people and offer help, particularly if the other person seems to need help.
But as Zak found in his experiments, the type of storytelling matters when it comes to affecting relationships. Where Zak found that storytelling with a dramatic arc helps release oxytocin and cortisol, enabling people to feel more empathic and generous, other researchers have found that sharing happy stories allows for greater closeness between individuals and speakers. A group of Chinese researchers found that, compared to emotionally-neutral stories, happy stories were more “emotionally contagious.” Test subjects who heard happy stories had greater activation in certain areas of their brains, experienced more significant, positive changes in their mood, and felt a greater sense of closeness between themselves and the speaker.
“This finding suggests that when individuals are happy, they become less self-focused and then feel more intimate with others,” the authors of the study wrote. “Therefore, sharing happiness could strengthen interpersonal bonding.” The researchers went on to say that this could lead to developing better social networks, receiving more social support, and leading more successful social lives.
Since the start of the COVID pandemic, social isolation, loneliness, and resulting mental health issues have only gotten worse. In light of this, it’s safe to say that hearing, sharing, and remembering stories isn’t just something we can do for entertainment. Storytelling has always been central to the human experience, and now more than ever it’s become something crucial for our survival.
Want to know how you can reap the benefits of hearing happy stories? Keep an eye out for Upworthy’s first book, GOOD PEOPLE: Stories from the Best of Humanity, published by National Geographic/Disney, available on September 3, 2024. GOOD PEOPLE is a much-needed trove of life-affirming stories told straight from the heart. Handpicked from Upworthy’s community, these 101 stories speak to the breadth, depth, and beauty of the human experience, reminding us we have a lot more in common than we realize.