Scientists Are Growing an Edible Cholera Vaccine in Rice
The world's attention has been focused on the coronavirus crisis but Yemen, Bangladesh and many others countries in Asia and Africa are also in the grips of another pandemic: cholera. The current cholera pandemic first emerged in the 1970s and has devastated many communities in low-income countries. Each year, cholera is responsible for an estimated 1.3 million to 4 million cases and 21,000 to 143,000 deaths worldwide.
Immunologist Hiroshi Kiyono and his team at the University of Tokyo hope they can be part of the solution: They're making a cholera vaccine out of rice.
"It is much less expensive than a traditional vaccine, by a long shot."
Cholera is caused by eating food or drinking water that's contaminated by the feces of a person infected with the cholera bacteria, Vibrio cholerae. The bacteria produces the cholera toxin in the intestines, leading to vomiting, diarrhea and severe dehydration. Cholera can kill within hours of infection if it if's not treated quickly.
Current cholera vaccines are mainly oral. The most common oral are given in two doses and are made out of animal or insect cells that are infected with killed or weakened cholera bacteria. Dukoral also includes cells infected with CTB, a non-harmful part of the cholera toxin. Scientists grow cells containing the cholera bacteria and the CTB in bioreactors, large tanks in which conditions can be carefully controlled.
These cholera vaccines offer moderate protection but it wears off relatively quickly. Cold storage can also be an issue. The most common oral vaccines can be stored at room temperature but only for 14 days.
"Current vaccines confer around 60% efficacy over five years post-vaccination," says Lucy Breakwell, who leads the U.S. Centers for Disease Control and Prevention's cholera work within Global Immunization Division. Given the limited protection, refrigeration issue, and the fact that current oral vaccines require two disease, delivery of cholera vaccines in a campaign or emergency setting can be challenging. "There is a need to develop and test new vaccines to improve public health response to cholera outbreaks."
A New Kind of Vaccine
Kiyono and scientists at Tokyo University are creating a new, plant-based cholera vaccine dubbed MucoRice-CTB. The researchers genetically modify rice so that it contains CTB, a non-harmful part of the cholera toxin. The rice is crushed into a powder, mixed with saline solution and then drunk. The digestive tract is lined with mucosal membranes which contain the mucosal immune system. The mucosal immune system gets trained to recognize the cholera toxin as the rice passes through the intestines.
The cholera toxin has two main parts: the A subunit, which is harmful, and the B subunit, also known as CTB, which is nontoxic but allows the cholera bacteria to attach to gut cells. By inducing CTB-specific antibodies, "we might be able to block the binding of the vaccine toxin to gut cells, leading to the prevention of the toxin causing diarrhea," Kiyono says.
Kiyono studies the immune responses that occur at mucosal membranes across the body. He chose to focus on cholera because he wanted to replicate the way traditional vaccines work to get mucosal membranes in the digestive tract to produce an immune response. The difference is that his team is creating a food-based vaccine to induce this immune response. They are also solely focusing on getting the vaccine to induce antibodies for the cholera toxin. Since the cholera toxin is responsible for bacteria sticking to gut cells, the hope is that they can stop this process by producing antibodies for the cholera toxin. Current cholera vaccines target the cholera bacteria or both the bacteria and the toxin.
David Pascual, an expert in infectious diseases and immunology at the University of Florida, thinks that the MucoRice vaccine has huge promise. "I truly believe that the development of a food-based vaccine can be effective. CTB has a natural affinity for sampling cells in the gut to adhere, be processed, and then stimulate our immune system, he says. "In addition to vaccinating the gut, MucoRice has the potential to touch other mucosal surfaces in the mouth, which can help generate an immune response locally in the mouth and distally in the gut."
Cost Effectiveness
Kiyono says the MucoRice vaccine is much cheaper to produce than a traditional vaccine. Current vaccines need expensive bioreactors to grow cell cultures under very controlled, sterile conditions. This makes them expensive to manufacture, as different types of cell cultures need to be grown in separate buildings to avoid any chance of contamination. MucoRice doesn't require such an expensive manufacturing process because the rice plants themselves act as bioreactors.
The MucoRice vaccine also doesn't require the high cost of cold storage. It can be stored at room temperature for up to three years unlike traditional vaccines. "Plant-based vaccine development platforms present an exciting tool to reduce vaccine manufacturing costs, expand vaccine shelf life, and remove refrigeration requirements, all of which are factors that can limit vaccine supply and accessibility," Breakwell says.
Kathleen Hefferon, a microbiologist at Cornell University agrees. "It is much less expensive than a traditional vaccine, by a long shot," she says. "The fact that it is made in rice means the vaccine can be stored for long periods on the shelf, without losing its activity."
A plant-based vaccine may even be able to address vaccine hesitancy, which has become a growing problem in recent years. Hefferon suggests that "using well-known food plants may serve to reduce the anxiety of some vaccine hesitant people."
Challenges of Plant Vaccines
Despite their advantages, no plant-based vaccines have been commercialized for human use. There are a number of reasons for this, ranging from the potential for too much variation in plants to the lack of facilities large enough to grow crops that comply with good manufacturing practices. Several plant vaccines for diseases like HIV and COVID-19 are in development, but they're still in early stages.
In developing the MucoRice vaccine, scientists at the University of Tokyo have tried to overcome some of the problems with plant vaccines. They've created a closed facility where they can grow rice plants directly in nutrient-rich water rather than soil. This ensures they can grow crops all year round in a space that satisfies regulations. There's also less chance for variation since the environment is tightly controlled.
Clinical Trials and Beyond
After successfully growing rice plants containing the vaccine, the team carried out their first clinical trial. It was completed early this year. Thirty participants received a placebo and 30 received the vaccine. They were all Japanese men between the ages of 20 and 40 years old. 60 percent produced antibodies against the cholera toxin with no side effects. It was a promising result. However, there are still some issues Kiyono's team need to address.
The vaccine may not provide enough protection on its own. The antigen in any vaccine is the substance it contains to induce an immune response. For the MucoRice vaccine, the antigen is not the cholera bacteria itself but the cholera toxin the bacteria produces.
"The development of the antigen in rice is innovative," says David Sack, a professor at John Hopkins University and expert in cholera vaccine development. "But antibodies against only the toxin have not been very protective. The major protective antigen is thought to be the LPS." LPS, or lipopolysaccharide, is a component of the outer wall of the cholera bacteria that plays an important role in eliciting an immune response.
The Japanese team is considering getting the rice to also express the O antigen, a core part of the LPS. Further investigation and clinical trials will look into improving the vaccine's efficacy.
Beyond cholera, Kiyono hopes that the vaccine platform could one day be used to make cost-effective vaccines for other pathogens, such as norovirus or coronavirus.
"We believe the MucoRice system may become a new generation of vaccine production, storage, and delivery system."
Could Your Probiotic Be Making You Sicker?
Mindy D. had suffered from constipation for years when her gastroenterologist advised her, at 38, to take a popular over-the-counter probiotic. Over the next two years, she experimented with different dosages, sometimes taking it three times a day. But she kept getting sicker—sometimes so ill she couldn't work.
"We shouldn't just presume probiotics are safe."
Her symptoms improved only after she traveled from Long Island to Georgia to see Satish S. C. Rao, a gastroenterologist at Augusta University. "The key thing was taking her off probiotics and treating her with antibiotics," he says.
That solution sounds bizarre, if, like many, you believe that antibiotics are bad and probiotics good. Millions of Americans take probiotics—live bacteria deemed useful—assuming there can be only positive effects. The truth is that you really don't know how any probiotic will affect you. To quote the American Gastroenterological Association Center for Gut Microbiome Research and Education, "It remains unclear what strains of bacteria at what dose by what route of administration are safe and effective for which patients."
"We shouldn't just presume probiotics are safe," says Purna Kashyap, a gastroenterologist from the Mayo Clinic, in Rochester, Minnesota, and a member of the Center's scientific advisory board. Neither the U.S. Food and Drug Administration or the European Food Safety Authority have approved probiotics as a medical treatment. Things can go very wrong in the ill: Among patients with severe acute pancreatitis, one study found that a dose of probiotics increased the chance of death. Even randomized controlled trials of probiotics rarely report harms adequately and the effect over the long-term has not been studied.
Many people pick up a product at a drug store or health store without ever telling a doctor. Doctors are fans, too: in a 2017 survey of healthcare providers at Stanford, more than 60 percent of the respondents said they prescribed probiotics. Many did so inconsistently, leaving the choice of which probiotic up to the patient. Healthy people take them for a range of unproven benefits, including protection from infections or heart disease or to sharpen their brains.
It's fine—unless it isn't. "Probiotics are capable of altering the microbiome in unpredictable ways," explains Leo Galland, an internist in New York who specializes in difficult digestions. "I've had patients who got gas and bloating, constipation or diarrhea from probiotics."
Your Microbiome Is Unique
The booming probiotic market has fed on excitement about the new science of the microbiome, the genetic material of all the microbes that live in our bodies and on our skin. Microbes make up 1 to 3 percent of every human being's body mass—you carry trillions of them, including more than a hundred species and thousands of strains. To identify a microbe, you need to know the genus, species and strain. For example, in Lactobacillus rhamnosus GG, the ingredient in the OTC probiotic Culturelle, Lactobacillus is the genus, rhamnosus is the species and GG is the strain designation.
Variations in your microbiome could help explain why you put on weight or suffer from Crohn's or depression. Each of us has our own unique mix.
A decade ago, the U.S. National Institute of Health (NIH) launched the Microbiome Project to establish a baseline description of health. Scientists sequenced the DNA in more than 2,200 strains, still a small fraction of the whole.
Within a couple of years, we had evidence that our microbiomes are distinctive. Another team used the NIH data set to look into the idea of microbial "fingerprints." A classic computer science algorithm allowed it to assign individuals "codes" defined by DNA sequences of their microbes—no human DNA required. Using information solely from the guts, "Eighty percent of individuals could still be uniquely identified up to a year later," they wrote.
That distinctiveness makes a difference when we try to change our mix by swallowing bacteria considered "pro." Even in healthy people, the reactions to probiotics vary widely, according to a study in Cell in September. The team examined the intestines of healthy volunteers who had taken a cocktail of eleven strains of probiotics for the experiment. Which took up residence in the intestinal lining? The answer depended on the person. Led by Eran Segal and colleagues at the Weizmann Institute of Science, in Rehovot, Israel, the authors concluded that effective supplements would have to be personalized.
Patients with "brain fog" improved dramatically when they were taken off their probiotics and given antibiotics as well.
To truly customize a probiotic, however, we'd have to know the state of an individual's gut microbiome, identify danger signs and link them to symptoms, isolate relevant strains of probiotics that might be needed, and get them into the gut lining effectively. Commercial tests are still at step one. Several companies claim to assess your microbiome based on a stool sample—but the Weizmann team has also shown that the differences between our gut linings aren't apparent from our stool. Galland has explored testing his patients looking for ways to help. "I've concluded that uBiome, American Gut Project, and others don't yield useful information," he observes.
Can A Probiotic Make Your Brain Foggy?
Besides taking her probiotic, Mindy D. had cut out gluten and upped her vegetables and fruits. But soon after she ate her seemingly healthy meals, she would begin to feel dizzy and sometimes even slurred her words, as if she were drunk. "It was such an intense feeling," she said.
A slender 5 ft. 2 inches, she dropped 20 pounds, becoming unhealthily thin. She traveled to see specialists in Minnesota and Connecticut and took two month-long medical leaves before she found Rao in Georgia.
In June, Rao created a stir when he and his coauthors reported that a cluster of his patients with "brain fog"—the "intense feeling" Mindy D. described—improved dramatically when they were taken off their probiotics and given antibiotics as well.
His idea was that lactobacilli and other bacteria colonized their small intestines, rather than making it to the colon as intended—a condition known as "small intestinal bacteria overgrowth" (SIB0) that some gastroenterologists treat with antibiotics. In this group, he argues, the small intestine produced the brain fog symptoms as a consequence of D-lactic acidosis, a phenomenon usually associated with damaged intestines. "If you have brain fogginess along with gas and bloating, please don't take probiotics," Rao says.
The paper prompted a rebuttal at the end of September from Eamonn Quigley, a gastroenterologist at Houston Methodist, who criticized the methodology in detail. Kashyap, of the Mayo Clinic, is skeptical as well. "People were picked for their brain fogginess and they were taking probiotics. Probiotics could be an innocent bystander," he says.
"It's hard for me to imagine the mechanism of say, Culturelle, causing SIB0," says Shira Doron, a specialist in infectious diseases and associate professor at Tufts University School of Medicine who studies probiotics. "The vast majority of people will never suffer a side effect from a probiotic. But probiotics are a live organism so they have a unique set of potential risks that other supplements don't have. They can give you a severe infection in very rare circumstances."
The larger point is that probiotics should be used under a doctor's care. In April, a panel of 14 experts on behalf of the European Society for Primary Care Gastroenterology concluded that "specific probiotics are beneficial in certain lower GI problems." That does not mean any over-the-counter probiotic is likely to help you because it helped your cousin.
"Even your doctor may be going by anecdotal experience, rather than hard science."
Both Galland and Rao use probiotics in their practice, but carefully. "We advise caution against excessive and indiscriminate use of probiotics especially without a well-defined medical indication, and particularly in patients with gastrointestinal dysmotility," when the muscles of the digestive system don't work normally, Rao's team wrote.
"Because there are so many studies out there that are poorly done, that aren't looking at side effects, the science is murky. Even your doctor may be going by anecdotal experience, rather than hard science," Doron adds. Your doctor may tell you that many of his patients report a great experience with probiotics. As Doron points out, however, with disorders like irritable bowel syndrome, the most common gastrointestinal diagnosis, the placebo effect is very strong. Many patients could "respond to anything if they believe it works," she says.
Advances Bring First True Hope to Spinal Cord Injury Patients
Seven years ago, mountain biking near his home in Whitefish, Montana, Jeff Marquis felt confident enough to try for a jump he usually avoided. But he hesitated just a bit as he was going over. Instead of catching air, Marquis crashed.
Researchers' major new insight is that recovery is still possible, even years after an injury.
After 18 days on a ventilator in intensive care and two-and-a-half months in a rehabilitation hospital, Marquis was able to move his arms and wrists, but not his fingers or anything below his chest. Still, he was determined to remain as independent as possible. "I wasn't real interested in having people take care of me," says Marquis, now 35. So, he dedicated the energy he formerly spent biking, kayaking, and snowboarding toward recovering his own mobility.
For generations, those like Marquis with severe spinal cord injuries dreamt of standing and walking again – with no realistic hope of achieving these dreams. But now, a handful of people with such injuries, including Marquis, have stood on their own and begun to learn to take steps again. "I'm always trying to improve the situation but I'm happy with where I'm at," Marquis says.
The recovery Marquis and a few of his fellow patients have achieved proves that our decades-old understanding of the spinal cord was wrong. Researchers' major new insight is that recovery is still possible, even years after an injury. Only a few thousand nerve cells actually die when the spinal cord is injured. The other neurons still have the ability to generate signals and movement on their own, says Susan Harkema, co-principal investigator at the Kentucky Spinal Cord Injury Research Center, where Marquis is being treated.
"The spinal cord has much more responsibility for executing movement than we thought before," Harkema says. "Successful movement can happen without those connections from the brain." Nerve cell circuits remaining after the injury can control movement, she says, but leaving people sitting in a wheelchair doesn't activate those sensory circuits. "When you sit down, you lose all the sensory information. The whole circuitry starts discombobulating."
Harkema and others use a two-pronged approach – both physical rehabilitation and electrical stimulation – to get those spinal cord circuits back into a functioning state. Several research groups are still honing this approach, but a few patients have already taken steps under their own power, and others, like Marquis, can now stand unassisted – both of which were merely fantasies for spinal cord injury patients just five years ago.
"This really does represent a leap forward in terms of how we think about the capacity of the spinal cord to be repaired after injury," says Susan Howley, executive vice president for research for the Christopher & Dana Reeve Foundation, which supports research for spinal cord injuries.
Jeff Marquis biking on a rock before his accident.
This new biological understanding suggests the need for a wholesale change in how people are treated after a spinal cord injury, Howley says. But today, most insurance companies cover just 30-40 outpatient rehabilitation sessions per year, whether you've sprained your ankle or severed your spinal cord. To deliver the kind of therapy that really makes a difference for spinal cord injury patients requires "60-80-90 or 150 sessions," she says, adding that she thinks insurance companies will more than make up for the cost of those therapy sessions if spinal cord injury patients are healthier. Early evidence suggests that getting people back on their feet helps prevent medical problems common among paralyzed people, including urinary tract infections, which can require costly hospital stays.
"Exercise and the ability to fully bear one's own weight are as crucial for people who live with paralysis as they are for able-bodied people," Howley notes, adding that the Reeve Foundation is now trying to expand the network of facilities available in local communities to offer this essential rehabilitation.
"Providing the right kind of training every day to people could really improve their opportunity to recover," Harkema says.
It's not entirely clear yet how far someone could progress with rehabilitation alone, Harkema says, but probably the best results for someone with a severe injury will also require so-called epidural electrical stimulation. This device, implanted in the lower back for a cost of about $30,000, sends an electrical current at varying frequencies and intensities to the spinal cord. Several separate teams of researchers have now shown that epidural stimulation can help restore sensation and movement to people who have been paralyzed for years.
Epidural stimulation boosts the electrical signal that is generated below the point of injury, says Daniel Lu, an associate professor and vice chair of neurosurgery at the UCLA School of Medicine. Before a spinal cord injury, he says, a neuron might send a message at a volume of 10 but after injury, that volume might drop to a two or three. The epidural stimulation potentially trains the neuron to respond to the lower volume, Lu says.
Lu has used such stimulators to improve hand function – "essentially what defines us" – in two patients with spinal cord injuries. Both increased their grip strength so they now can lift a cup to drink by themselves, which they couldn't do before. He's also used non-invasive stimulation to help restore bladder function, which he says many spinal cord injury patients care about as much as walking again.
A closeup of the stimulator.
Not everyone will benefit from these treatments. People whose injury was caused by a cut to the spinal cord, as with a knife or bullet, probably can't be helped, Lu says, adding that they account for less than 5 percent of spinal cord injuries.
The current challenge Lu says is not how to stimulate the spinal cord, but where to stimulate it and the frequency of stimulation that will be most effective for each patient. Right now, doctors use an off-the-shelf stimulator that is used to treat pain and is not optimized for spinal cord patients, Harkema says.
Swiss researchers have shown impressive results from intermittent rather than continuous epidural stimulation. These pulses better reflect the way the brain sends its messages, according to Gregoire Courtine, the senior author on a pair of papers published Nov. 1 in Nature and Nature Neuroscience. He showed that he could get people up and moving within just a few days of turning on the stimulation. Three of his patients are walking again with only a walker or minimal assistance, and they also gained voluntary leg movements even when the stimulator was off. Continuous stimulation, this research shows, actually interferes with the patients' perception of limb position, and thus makes it harder for them to relearn to walk.
Even short of walking, proper physical rehabilitation and electrical stimulation can transform the quality of life of people with spinal cord injury, Howley and Harkema say. Patients don't need to be able to reach the top shelf or run a marathon to feel like they've been "cured" from their paralysis. Instead, recovering bowel, bladder and sexual functions, the ability to regulate their temperature and blood pressure, and reducing the breakdown of skin that can lead to a life-threatening infection can all be transformative – and all appear to improve with the combination of rehabilitation and electrical stimulation.
Howley cites a video of one of Harkema's patients, Stefanie Putnam, who was passing out five to six times a day because her blood pressure was so low. She couldn't be left alone, which meant she had no independence. After several months of rehabilitation and stimulation, she can now sit up for long periods, be left alone, and even, she says gleefully, cook her own dinner. "Every time I watch it, it brings me to tears," Howley says of the video. "She's able to resume her normal life activity. It's mind-boggling."
The work also suggests a transformation in the care of people immediately after injury. They should be allowed to stand and start taking steps as soon as possible, even if they cannot do it under their own power, Harkema says. Research is also likely to show that quickly implanting a stimulator after an injury will make a difference, she says.
There may be medications that can help immediately after an injury, too. One drug currently being studied, called riluzole, has already been approved for ALS and might help limit the damage of a spinal cord injury, Howley says. But testing its effectiveness has been a slow process, she says, because it needs to be given within 12 hours of the initial injury and not enough people get to the testing sites in time.
Stem cell therapy also offers promise for spinal cord injury patients, Howley says – but not the treatments currently provided by commercial stem cell clinics both in the U.S. and overseas, which she says are a sham. Instead, she is carefully following research by a California-based company called Asterias Biotherapeutics, which announced plans Nov. 8 to merge with a company called BioTime.
Asterias and a predecessor company have been treating people since 2010 in an effort to regrow nerves in the spinal cord. All those treated have safely tolerated the cells, but not everyone has seen a huge improvement, says Edward Wirth, who has led the trial work and is Asterias' chief medical director. He says he thinks he knows what's held back those who didn't improve much, and hopes to address those issues in the next 3- to 4-year-long trial, which he's now discussing with the U.S. Food and Drug Administration.
So far, he says, some patients have had an almost complete return of movement in their hands and arms, but little improvement in their legs. The stem cells seem to stimulate tissue repair and regeneration, he says, but only around the level of the injury in the spinal cord and a bit below. The legs, he says, are too far away to benefit.
Wirth says he thinks a combination of treatments – stem cells, electrical stimulation, rehabilitation, and improved care immediately after an injury – will likely produce the best results.
While there's still a long way to go to scale these advances to help the majority of the 300,000 spinal cord injury patients in the U.S., they now have something that's long been elusive: hope.
"Two or three decades ago there was no hope at all," Howley says. "We've come a long way."