A decellularized small porcine liver.
Jennifer Cisneros was 18 years old, commuting to college from her family's home outside Annapolis, Maryland, when she came down with what she thought was the flu. Over the following weeks, however, her fatigue and nausea worsened, and her weight began to plummet. Alarmed, her mother took her to see a pediatrician. "When I came back with the urine cup, it was orange," Cisneros recalls. "He was like, 'Oh, my God. I've got to send you for blood work.'"
"Eventually, we'll be better off than with a human organ."
Further tests showed that her kidneys were failing, and at Johns Hopkins Hospital, a biopsy revealed the cause: Goodpasture syndrome (GPS), a rare autoimmune disease that attacks the kidneys or lungs. Cisneros was put on dialysis to filter out the waste products that her body could no longer process, and given chemotherapy and steroids to suppress her haywire immune system.
The treatment drove her GPS into remission, but her kidneys were beyond saving. At 19, Cisneros received a transplant, with her mother as donor. Soon, she'd recovered enough to return to school; she did some traveling, and even took up skydiving and parasailing. Then, after less than two years, rejection set in, and the kidney had to be removed.
She went back on dialysis until she was 26, when a stranger learned of her plight and volunteered to donate. That kidney lasted four years, but gave out after a viral infection. Since 2015, Cisneros—now 32, and working as an office administrator between thrice-weekly blood-filtering sessions—has been waiting for a replacement.
She's got plenty of company. About 116,000 people in the United States currently need organ transplants, but fewer than 35,000 organs become available every year. On average, 20 people on the waiting list die each day. And despite repeated campaigns to boost donorship, the gap shows no sign of narrowing.
"This is going to revolutionize medicine, in ways we probably can't yet appreciate."
For decades, doctors and scientists have envisioned a radical solution to the shortage: harvesting other species for spare parts. Xenotransplantation, as the practice is known, could provide an unlimited supply of lifesaving organs for patients like Cisneros. Those organs, moreover, could be altered by genetic engineering or other methods to reduce the danger of rejection—and thus to eliminate the need for immunosuppressive drugs, whose potential side effects include infections, diabetes, and cancer. "Eventually, we'll be better off than with a human organ," says David Cooper, MD, PhD, co-director of the xenotransplant program at the University of Alabama School of Medicine. "This is going to revolutionize medicine, in ways we probably can't yet appreciate."
Recently, progress toward that revolution has accelerated sharply. The cascade of advances began in April 2016, when researchers at the National Heart, Lung, and Blood Institute (NHLBI) reported keeping pig hearts beating in the abdomens of five baboons for a record-breaking mean of 433 days, with one lasting more than two-and-a-half years. Then a team at Emory University announced that a pig kidney sustained a rhesus monkey for 435 days before being rejected, nearly doubling the previous record. At the University of Munich, in Germany, researchers doubled the record for a life-sustaining pig heart transplant in a baboon (replacing the animal's own heart) to 90 days. Investigators at the Salk Institute and the University of California, Davis, declared that they'd grown tissue in pig embryos using human stem cells—a first step toward cultivating personalized replacement organs. The list goes on.
Such breakthroughs, along with a surge of cash from biotech investors, have propelled a wave of bullish media coverage. Yet this isn't the first time that xenotransplantation has been touted as the next big thing. Twenty years ago, the field seemed poised to overcome its final hurdles, only to encounter a setback from which it is just now recovering.
Which raises a question: Is the current excitement justified? Or is the hype again outrunning the science?
A History of Setbacks
The idea behind xenotransplantation dates back at least as far as the 17th century, when French physician Jean-Baptiste Denys tapped the veins of sheep and cows to perform the first documented human blood transfusions. (The practice was banned after two of the four patients died, probably from an immune reaction.) In the 19th century, surgeons began transplanting corneas from pigs and other animals into humans, and using skin xenografts to aid in wound healing; despite claims of miraculous cures, medical historians believe those efforts were mostly futile. In the 1920s and '30s, thousands of men sought renewed vigor through testicular implants from monkeys or goats, but the fad collapsed after studies showed the effects to be imaginary.
Research shut down when scientists discovered a virus in pig DNA that could infect human cells.
After the first successful human organ transplant in 1954—of a kidney, passed between identical twin sisters—the limited supply of donor organs brought a resurgence of interest in animal sources. Attention focused on nonhuman primates, our species' closest evolutionary relatives. At Tulane University, surgeon Keith Reemstma performed the first chimpanzee-to-human kidney transplants in 1963 and '64. Although one of the 13 patients lived for nine months, the rest died within a few weeks due to organ rejection or infections. Other surgeons attempted liver and heart xenotransplants, with similar results. Even the advent of the first immunosuppressant drug, cyclosporine, in 1983, did little to improve survival rates.
In the 1980s, Cooper—a pioneering heart transplant surgeon who'd embraced the dream of xenotransplantation—began arguing that apes and monkeys might not be the best donor animals after all. "First of all, there's not enough of them," he explains. "They breed in ones and twos, and take years to grow to full size. Even then, their hearts aren't big enough for a 70-kg. patient." Pigs, he suggested, would be a more practical alternative. But when he tried transplanting pig organs into nonhuman primates (as surrogates for human recipients), they were rejected within minutes.
In 1992, Cooper's team identified a sugar on the surface of porcine cells, called alpha-1,3-galactose (a-gal), as the main target for the immune system's attack. By then, the first genetically modified pigs had appeared, and biotech companies—led by the Swiss-based pharma giant Novartis—began pouring millions of dollars into developing one whose organs could elude or resist the human body's defenses.
Disaster struck five years later, when scientists reported that a virus whose genetic code was written into pig DNA could infect human cells in lab experiments. Although there was no evidence that the virus, known as PERV (for porcine endogenous retrovirus) could cause disease in people, the discovery stirred fears that xenotransplants might unleash a deadly epidemic. Facing scrutiny from government regulators and protests from anti-GMO and animal-rights activists, Novartis "pulled out completely," Cooper recalls. "They slaughtered all their pigs and closed down their research facility." Competitors soon followed suit.
The riddles surrounding animal-to-human transplants are far from fully solved.
A New Chapter – With New Questions
Yet xenotransplantation's visionaries labored on, aided by advances in genetic engineering and immunosuppression, as well as in the scientific understanding of rejection. In 2003, a team led by Cooper's longtime colleague David Sachs, at Harvard Medical School, developed a pig lacking the gene for a-gal; over the next few years, other scientists knocked out genes expressing two more problematic sugars. In 2013, Muhammad Mohiuddin, then chief of the transplantation section at the NHLBI, further modified a group of triple-knockout pigs, adding genes that code for two human proteins: one that shields cells from attack by an immune mechanism known as the complement system; another that prevents harmful coagulation. (It was those pigs whose hearts recently broke survival records when transplanted into baboon bellies. Mohiuddin has since become director of xenoheart transplantation at the University of Maryland's new Center for Cardiac Xenotransplantation Research.) And in August 2017, researchers at Harvard Medical School, led by George Church and Luhan Yang, announced that they'd used CRISPR-cas9—an ultra-efficient new gene-editing technique—to disable 62 PERV genes in fetal pig cells, from which they then created cloned embryos. Of the 37 piglets born from this experiment, none showed any trace of the virus.
Still, the riddles surrounding animal-to-human transplants are far from fully solved. One open question is what further genetic manipulations will be necessary to eliminate all rejection. "No one is so naïve as to think, 'Oh, we know all the genes—let's put them in and we are done,'" biologist Sean Stevens, another leading researcher, told the The New York Times. "It's an iterative process, and no one that I know can say whether we will do two, or five, or 100 iterations." Adding traits can be dangerous as well; pigs engineered to express multiple anticoagulation proteins, for example, often die of bleeding disorders. "We're still finding out how many you can do, and what levels are acceptable," says Cooper.
Another question is whether PERV really needs to be disabled. Cooper and some of his colleagues note that pig tissue has long been used for various purposes, such as artificial heart valves and wound-repair products, without incident; requiring the virus to be eliminated, they argue, will unnecessarily slow progress toward creating viable xenotransplant organs and the animals that can provide them. Others disagree. "You cannot do anything with pig organs if you do not remove them," insists bioethicist Jeantine Lunshof, who works with Church and Yang at Harvard. "The risk is simply too big."
"We've removed the cells, so we don't have to worry about latent viruses."
Meanwhile, over the past decade, other approaches to xenotransplantation have emerged. One is interspecies blastocyst complementation, which could produce organs genetically identical to the recipient's tissues. In this method, genes that produce a particular organ are knocked out in the donor animal's embryo. The embryo is then injected with pluripotent stem cells made from the tissue of the intended recipient. The stem cells move in to fill the void, creating a functioning organ. This technique has been used to create mouse pancreases in rats, which were then successfully transplanted into mice. But the human-pig "chimeras" recently created by scientists were destroyed after 28 days, and no one plans to bring such an embryo to term anytime soon. "The problem is that cells don't stay put; they move around," explains Father Kevin FitzGerald, a bioethicist at Georgetown University. "If human cells wind up in a pig's brain, that leads to a really interesting conundrum. What if it's self-aware? Are you going to kill it?"
Much further along, and less ethically fraught, is a technique in which decellularized pig organs act as a scaffold for human cells. A Minnesota-based company called Miromatrix Medical is working with Mayo Clinic researchers to develop this method. First, a mild detergent is pumped through the organ, washing away all cellular material. The remaining structure, composed mainly of collagen, is placed in a bioreactor, where it's seeded with human cells. In theory, each type of cell that normally populates the organ will migrate to its proper place (a process that naturally occurs during fetal development, though it remains poorly understood). One potential advantage of this system is that it doesn't require genetically modified pigs; nor will the animals have to be raised under controlled conditions to avoid exposure to transmissible pathogens. Instead, the organs can be collected from ordinary slaughterhouses.
Recellularized livers in bioreactors
(Courtesy of Miromatrix)
"We've removed the cells, so we don't have to worry about latent viruses," explains CEO Jeff Ross, who describes his future product as a bioengineered human organ rather than a xeno-organ. That makes PERV a nonissue. To shorten the pathway to approval by the Food and Drug Administration, the replacement cells will initially come from human organs not suitable for transplant. But eventually, they'll be taken from the recipient (as in blastocyst complementation), which should eliminate the need for immunosuppression.
Clinical trials in xenotransplantation may begin as early as 2020.
Miromatrix plans to offer livers first, followed by kidneys, hearts, and eventually lungs and pancreases. The company recently succeeded in seeding several decellularized pig livers with human and porcine endothelial cells, which flocked obediently to the blood vessels. Transplanted into young pigs, the organs showed unimpaired circulation, with no sign of clotting. The next step is to feed all four liver cell types back into decellularized livers, and see if the transplanted organs will keep recipient pigs alive.
Ross hopes to launch clinical trials by 2020, and several other groups (including Cooper's, which plans to start with kidneys) envision a similar timeline. Investors seem to share their confidence. The biggest backer of xenotransplantation efforts is United Therapeutics, whose founder and co-CEO, Martine Rothblatt, has a daughter with a lung condition that may someday require a transplant; since 2011, the biotech firm has poured at least $100 million into companies pursuing such technologies, while supporting research by Cooper, Mohiuddin, and other leaders in the field. Church and Yang, at Harvard, have formed their own company, eGenesis, bringing in a reported $40 million in funding; Miromatrix has raised a comparable amount.
It's impossible to predict who will win the xenotransplantation race, or whether some new obstacle will stop the competition in its tracks. But Jennifer Cisneros is rooting for all the contestants. "These technologies could save my life," she says. If she hasn't found another kidney before trials begin, she has just one request: "Sign me up."
The test tubes contain tiny DNA/enzyme-based circuits, which comprise TRUMPET, a new type of electronic device, smaller than a cell.
While a computer gives these inputs in binary code or "bits," such as a 0 or 1, biocomputing uses DNA strands as inputs, whether double or single-stranded, and often uses fluorescent RNA as an output.
Adamala’s research focuses on developing such biocomputing systems using DNA, RNA, proteins, and lipids. Using these molecules in the biocomputing systems allows the latter to be biocompatible with the human body, resulting in a natural healing process. In a recent Nature Communications study, Adamala and her team created a new biocomputing platform called TRUMPET (Transcriptional RNA Universal Multi-Purpose GatE PlaTform) which acts like a DNA-powered computer chip. “These biological systems can heal if you design them correctly,” adds Adamala. “So you can imagine a computer that will eventually heal itself.”
The basics of biocomputing
Biocomputing and regular computing have many similarities. Like regular computing, biocomputing works by running information through a series of gates, usually logic gates. A logic gate works as a fork in the road for an electronic circuit. The input will travel one way or another, giving two different outputs. An example logic gate is the AND gate, which has two inputs (A and B) and two different results. If both A and B are 1, the AND gate output will be 1. If only A is 1 and B is 0, the output will be 0 and vice versa. If both A and B are 0, the result will be 0. While a computer gives these inputs in binary code or "bits," such as a 0 or 1, biocomputing uses DNA strands as inputs, whether double or single-stranded, and often uses fluorescent RNA as an output. In this case, the DNA enters the logic gate as a single or double strand.
If the DNA is double-stranded, the system “digests” the DNA or destroys it, which results in non-fluorescence or “0” output. Conversely, if the DNA is single-stranded, it won’t be digested and instead will be copied by several enzymes in the biocomputing system, resulting in fluorescent RNA or a “1” output. And the output for this type of binary system can be expanded beyond fluorescence or not. For example, a “1” output might be the production of the enzyme insulin, while a “0” may be that no insulin is produced. “This kind of synergy between biology and computation is the essence of biocomputing,” says Stephanie Forrest, a professor and the director of the Biodesign Center for Biocomputing, Security and Society at Arizona State University.
Biocomputing circles are made of DNA, RNA, proteins and even bacteria.
Evgeny Katz
The TRUMPET’s promise
Depending on whether the biocomputing system is placed directly inside a cell within the human body, or run in a test-tube, different environmental factors play a role. When an output is produced inside a cell, the cell's natural processes can amplify this output (for example, a specific protein or DNA strand), creating a solid signal. However, these cells can also be very leaky. “You want the cells to do the thing you ask them to do before they finish whatever their businesses, which is to grow, replicate, metabolize,” Adamala explains. “However, often the gate may be triggered without the right inputs, creating a false positive signal. So that's why natural logic gates are often leaky." While biocomputing outside a cell in a test tube can allow for tighter control over the logic gates, the outputs or signals cannot be amplified by a cell and are less potent.
TRUMPET, which is smaller than a cell, taps into both cellular and non-cellular biocomputing benefits. “At its core, it is a nonliving logic gate system,” Adamala states, “It's a DNA-based logic gate system. But because we use enzymes, and the readout is enzymatic [where an enzyme replicates the fluorescent RNA], we end up with signal amplification." This readout means that the output from the TRUMPET system, a fluorescent RNA strand, can be replicated by nearby enzymes in the platform, making the light signal stronger. "So it combines the best of both worlds,” Adamala adds.
These organic-based systems could detect cancer cells or low insulin levels inside a patient’s body.
The TRUMPET biocomputing process is relatively straightforward. “If the DNA [input] shows up as single-stranded, it will not be digested [by the logic gate], and you get this nice fluorescent output as the RNA is made from the single-stranded DNA, and that's a 1,” Adamala explains. "And if the DNA input is double-stranded, it gets digested by the enzymes in the logic gate, and there is no RNA created from the DNA, so there is no fluorescence, and the output is 0." On the story's leading image above, if the tube is "lit" with a purple color, that is a binary 1 signal for computing. If it's "off" it is a 0.
While still in research, TRUMPET and other biocomputing systems promise significant benefits to personalized healthcare and medicine. These organic-based systems could detect cancer cells or low insulin levels inside a patient’s body. The study’s lead author and graduate student Judee Sharon is already beginning to research TRUMPET's ability for earlier cancer diagnoses. Because the inputs for TRUMPET are single or double-stranded DNA, any mutated or cancerous DNA could theoretically be detected from the platform through the biocomputing process. Theoretically, devices like TRUMPET could be used to detect cancer and other diseases earlier.
Adamala sees TRUMPET not only as a detection system but also as a potential cancer drug delivery system. “Ideally, you would like the drug only to turn on when it senses the presence of a cancer cell. And that's how we use the logic gates, which work in response to inputs like cancerous DNA. Then the output can be the production of a small molecule or the release of a small molecule that can then go and kill what needs killing, in this case, a cancer cell. So we would like to develop applications that use this technology to control the logic gate response of a drug’s delivery to a cell.”
Although platforms like TRUMPET are making progress, a lot more work must be done before they can be used commercially. “The process of translating mechanisms and architecture from biology to computing and vice versa is still an art rather than a science,” says Forrest. “It requires deep computer science and biology knowledge,” she adds. “Some people have compared interdisciplinary science to fusion restaurants—not all combinations are successful, but when they are, the results are remarkable.”
Crickets are low on fat, high on protein, and can be farmed sustainably. They are also crunchy.
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Further reading:
More info on Bicky Nguyen
https://yseali.fulbright.edu.vn/en/faculty/bicky-n...
The environmental footprint of beef production
https://www.earthsave.org/environment.htm
https://www.watercalculator.org/news/articles/beef-king-big-water-footprints/
https://www.frontiersin.org/articles/10.3389/fsufs.2019.00005/full
https://ourworldindata.org/carbon-footprint-food-methane
Insect farming as a source of sustainable protein
https://www.insectgourmet.com/insect-farming-growing-bugs-for-protein/
https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/insect-farming
Cricket flour is taking the world by storm
https://www.cricketflours.com/
https://talk-commerce.com/blog/what-brands-use-cricket-flour-and-why/
