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Research in the News: Xenotransplants - Using Animal Organs To Save Human Lives (Grades 9-12)

Xenotransplants: Using Animal Organs To Save Human Lives
by Bruce Agnew
(ARCHIVE: May 3, 1999)

When surgeon Joseph Murray performed the world's first successful human organ transplant in 1954-a kidney transplant between identical twins-he had no idea what he was beginning. Today, organ transplants no longer make news: about 20,000 Americans each year receive life-saving transplants of hearts, kidneys, livers, or lungs, from people who have signed organ-donor cards or whose relatives approve the donation. But at any given moment, about 50,000 people are getting sicker and sicker while they wait for such organs-and about 4,000 die each year, still waiting.

To address the shortage of human organs, many scientists and several biotechnology companies have been working on an answer that, at first glance, might seem like science fiction: use organs from animals. The procedure is called "xenotransplantation" (from the Greek "xeno" meaning "stranger"; the "x" is pronounced like a "z" as in Xerox). And some researchers believe they are on the verge of making xenotransplantation of whole organs work-although the attempts carried out so far have not been very encouraging.


AID patient, Jeff Getty, received a baboon bone marrow transplant in 1995.
AIDS patient Jeff Getty received a baboon bone marrow transplant in 1995.

Even if it turns out that animal organs can not be successfully transplanted, researchers also have ideas for transplanting animal cells for therapeutic effect. In fact, transplants of living animal cells into people are already are being tried-with apparent success in early experiments. For example, Suzanne Ildstad, director of the Institute for Cellular Therapeutics in Louisville, Kentucky studies bone-marrow transplantation. In 1995 she transplanted baboon bone-marrow into a man named Jeff Getty, who is infected with HIV and has AIDS. Bone marrow produces immune system cells. The hope was to replace Getty's crumbling immune system with an HIV-proof baboon immune system that could protect him from infection. Although the baboon cells functioned for only two weeks, Getty is still alive and the researchers learned a great deal.

If the potential benefits are huge, so are the barriers.

The human immune system-a complex network of defenses against disease organisms and other foreign substances that evolved over millions of years-fiercely resists even human-to-human transplants. When confronted with an organ from an animal as evolutionarily distant as, say, a pig, the human immune system reacts violently. In a response known as hyperacute rejection, antibodies that seem pre-primed to attack tissues from another species summon into action the so-called complement cascade, an array of proteins in the blood that attacks the internal walls of the transplant's blood vessels, rejecting the organ within hours or even minutes.


Microscopic sections of heart tissue from a rat-to-rat heart allotransplant (left) and a hamster to-rat heart xenotransplant (right). Examined 60 days after the transplant, the rat heart is healthy, while the hamster heart shows extensive damage. Courtesy
Microscopic sections of heart tissue from a rat-to-rat heart allotransplant (left) and a hamster to-rat heart xenotransplant (right). Examined 60 days after the transplant, the rat heart is healthy, while the hamster heart shows extensive damage. Courtesy A. J. Demetris, M.D., University of Pittsburgh Medical Center.

Even if hyperacute rejection can be tamped down, the human body mounts a more vigorous long-term attack on animal organs than it does against transplants of human organs. More blood cells, primarily B lymphocytes and natural killer cells, join the attack on the foreign tissue. Today, physicians can suppress many immune responses with drugs such as cyclosporine, FK506, and prednisone. These drugs are used in human-to-human transplants, known as allotransplants. In xenotransplants, heavier doses are required, and the patient's immune defenses against infectious organisms may be crippled.

This is exactly what happened when Thomas Starzl, of the University of Pittsburgh Medical Center, transplanted baboon livers into two patients with hepatitis in 1992 and 1993. Both patients died, not from a rejection response to the transplants but from runaway infections caused by microbes that are common in the environment and in the human body.

"There were probably some unusual rejection mechanisms that we haven't quite figured out," says John Fung, a member of Starzl's team. "But the real reason they died was from everyday bacterial and fungal infections, because their bodies were so immunosuppressed from the drugs."

The easiest way to deal with immune-system rejection of xenotransplants would be to sidestep them-to use organs from the animal that is the closest possible to human beings. That, of course, is the chimpanzee, whose genome is more than 98 percent identical with the human genome.

But chimpanzees are an endangered species. They are costly to raise, and they grow slowly to adulthood. Chimpanzees may also harbor unknown viruses that do them no harm but that might cause devastating diseases in humans-diseases that might be transmitted to other people. For example, researchers have strong evidence that HIV crossed into humans from chimps during the first half of this century. The term for such a species leap is zoonosis, and the term that is becoming accepted for an animal-to-human leap because of a xenotransplant is, naturally, xenozoonosis.



Too Much Like Us? Kanzi, a pigmy chimpanzee (Bonobo), has been taught to communicate with humans using lexigrams on a computer keyboard. Even if chimpanzees were not an endangered species, their close relationship to humans makes them an unlikely source f
Too Much Like Us? Kanzi, a pigmy chimpanzee (Bonobo), has been taught to communicate with humans using lexigrams on a computer keyboard. Even if chimpanzees were not an endangered species, their close relationship to humans makes them an unlikely source for xenotransplant organs.

Finally, the use of chimpanzees for xenotransplant organs would raise a fierce ethical storm. The question of whether humans have a moral right to take an animal's organs even to save a human life already concerns bioethicists and animal-rights advocates. Most bioethicists conclude, as did cell biologist Ernest Prentice, of the University of Nebraska Medical Center in Omaha, and his colleagues in a 1995 paper, that "pitting the life of a human being against the life of a baboon and to a much greater extent the life of a pig is effectively a 'no contest.'" But use of an endangered species might change the calculation.

Animal-rights advocates, however, oppose all xenotransplantation as "speciesism"-the contention, which they reject, that a human being has a higher moral value than an animal. Their argument would probably have its greatest public appeal in the case of chimpanzees, which may be just too much like us. Some researchers who study the cognitive abilities of chimpanzees say that they are capable of reasoning, learning language, and communicating with humans-not about philosophy, but certainly about wishes and perhaps about emotions.

For all these reasons, most xenotransplantation researchers agree that chimpanzees are not suitable organ donors. Researchers also appear to agree that other "higher" nonhuman primates such as baboons are out, too. Although organs from these animals are less likely than those of more distant species to set off hyperacute rejection, they, too, harbor microorganisms that might leap to humans easily and with dangerous consequences. And like chimpanzees, baboons are costly to raise and, in some cases, suffer from population decline.


Human and pig parts are similar, but not identical. But for transplants, the fit may be close enough.
Human and pig parts are similar, but not identical. But for transplants, the fit may be close enough.

Strange as it may sound, the animal that is emerging as the most likely source of transplantable organs is the pig. Pigs' organs are the right size. The animals are highly domesticated, they have large litters, and they grow quickly to maturity. They can be raised in sterile environments, which would reduce the likelihood of transmission of at least some pig diseases to humans. Many researchers, however, still worry about viruses that are unknown or that have become part of the animals' genome and cannot be dislodged.

Unfortunately, pig organs have molecular characteristics that make the human immune system react violently. But there may be ways around that, and researchers are exploring at least two quite different approaches.

Despite the obstacles, some xenotransplantation experiments involving humans are going on today-although not whole-organ transplants. By the end of 1998, says Amy Patterson, a scientist with the NIH Office of Recombinant DNA Activities, more than 200 people in the United States had received xenografts of animal cells or tissues. These experiments included implanting fetal pig neurons into the brains of people with Parkinson's disease, and using plastic-wrapped pig liver cells to cleanse the blood of people with liver failure, keeping them alive until a human donor liver can be found.

Researchers who would transplant whole organs have another big, unanswered question-how well will the animal organs will work in the human body? "Will the pig heart, for example, or the pig kidney function in a normal way in the human as it did in the pig?" asks Jeffrey Platt, of the Mayo Clinic in Rochester, Minn. So far, the signs have been "encouraging," he says, "but this is clearly an issue with which we need to grapple."


Xenotransplants: Better Luck with Animal Cells
Bruce Agnew
(ARCHIVE: December 3, 1998)

Rejection by the immune system still thwarts xenotransplantation of "vascularized" whole organs-hearts, kidneys, livers, and the like-whose internal blood vessels come under attack the moment the recipient's blood starts flowing through them. But researchers are faring better with xenotransplants of animal cells into humans. Experiments that are now under way or are planned for the near future include these:
  • Researchers at Diacrin Inc. in Charlestown, Mass., and Genzyme Tissue Repair in Cambridge, Mass., have implanted nerve cells (neurons) from fetal pigs into the brains of people who have Parkinson's disease or Huntington's disease. These are disabling and eventually fatal disorders resulting from the death of brain cells that produce chemicals known as neurotransmitters (dopamine in the case of Parkinson's disease, gamma-aminobutyric acid, or GABA, in Huntington's disease). The idea is that the fetal cells will develop and produce the missing neurotransmitter. The brain accepts transplants of foreign tissue more readily than do other parts of the body-possibly because the so-called blood-brain barrier, which blocks the passage of large molecules from the bloodstream into the brain and cerebrospinal fluid. Moreover, fetal cells do not produce as strong an immune reaction as do fully developed cells.
  • To treat insulin-dependent diabetes, scientists at Neocrin Co. in Irvine, Calif., and VivoRx Inc. in Santa Monica, Calif., have devised ways to wrap pig islets-cells of the pancreas that produce insulin-in a plastic material that shields the islets from immune-system cells and antibodies but permits nutrients to enter and insulin to exit. These "encapsulated" islets have functioned successfully in laboratory animals.
    Islet cell masses encapsulated in a protective polymer. Courtesy Dr. P. de Vos., Groningen U.
    Islet cell masses encapsulated in a protective polymer. Courtesy Dr. P. de Vos., Groningen U.
  • Researchers at Circe Biomedical Inc. in Lexington, Mass., have used encapsulated pig liver cells (hepatocytes) as temporary measures to extend the lives of people with liver failure until a human liver transplant can be found. Scientists at Nextran Inc. in Princeton, N.J., have used whole transgenic pig livers as similar temporary "bridges." The patient's blood is cleansed as it passes through the specially packaged hepatocytes or through the transgenic liver, which are maintained outside the patient's body.
  • Scientists at CytoTherapeutics Inc. in Providence, R.I., have used encapsulated calves' cells that produce natural pain-blocking substances to relieve the pain of cancer patients. The bovine adrenal chromaffin cells produce several opium-like chemicals that relieve pain (catecholamines, encephalins, and opioid peptides, or proteins). By early this year, more than 60 people had received implants of these encapsulated bovine cells.

How Xenotransplants Might Dodge Immune Defenses
Bruce Agnew
(ARCHIVE: December 3, 1998)

One way that scientists are trying to help the human immune system tolerate transplants of pig organs is to change the pig—through genetic engineering. Using existing laboratory techniques, several research teams are deleting specific pig genes or adding human genes to make pig cells seem, as John Fung, of the University of Pittsburgh Medical Center puts it, "less piggish" to the immune system. For example, Imutran, a biotechnology company in Cambridge, England, and Nextran Inc. in Princeton, N.J., have developed pigs that carry human genes that block activation of the complement system-and thus presumably will prevent hyperacute rejection. Animals that are genetically modified to carry genes from another species are called "transgenic" animals.

This pig has been engineered to look human—to the human immune system.
This pig has been engineered to look human—to the human immune system.

Other researchers are trying to modify a sugar molecule that appears on cell surfaces in most mammals-but not in humans and their close primate relatives. This molecule, galactose alpha-(1-3) galactose, is apparently the target for the "xenoreactive antibodies" that all adult humans have, says Jeffrey Platt, of the Mayo Clinic in Rochester, Minn. So researchers are trying to insert into pigs a human gene that will replace the pig molecule with a human sugar residue, fucosyl transferase. Whether the transgenic pigs will function normally after this switch is not yet known.

Suzanne Ildstad, director of the Institute for Cellular Therapeutics of the University of Louisville, and other researchers are taking a different approach. They are trying to alter the immune system of the transplant recipient so that the person will more easily tolerate a xeno—or, for that matter, human-transplant. Ildstad induces "tolerance" by giving the transplant recipient an infusion of specially purified bone-marrow cells from the donor. If the donor's marrow cells survive and function to produce mature blood cells, the patient's immune system becomes "chimeric." It includes some blood cells that belong to the patient and some that are produced from the donor's bone marrow. And in experiments with animals, Ildstad has found that the chimeric immune system accepts both same-species transplants and xenotransplants.

Ildstad has perfomed three human-to-human heart transplants using this technique, and she plans to try it with kidney transplants, too. In experiments with rats and mice, she has shown that inducing a chimeric immune system also gives xenotranpsplants a better chance of success.

Viruses Pose Problems for Xenotransplantation
Robert Taylor, Ph.D.
(ARCHIVE: December 3, 1998)

The use of animal organs, tissues, and cells for human transplantation is promising, says Amy Patterson, a scientist in the Office of Recombinant DNA Activities at the National Institutes of Health (NIH) in Bethesda, MD. If researchers can solve problems with immune system rejection of tissue from other species, animal organs may end the acute shortage of useable human organs and save human lives, she says. Unfortunately, animal organs may bring with them unwanted viruses and other infectious organisms, which could potentially harm not only the patient getting the animal organ, but other people as well. "We need to know more about these risks so we can carefully assess the transition from the research laboratory bench to human patients," says Patterson.

Unlikely Organ Donor. In the wild, baboons don't eat peaches. But at the University of Washington Regional Primate Research Center, this baboon sometimes get a treat.
Unlikely Organ Donor. In the wild, baboons don't eat peaches. But at the University of Washington Regional Primate Research Center, this baboon sometimes get a treat.

One way doctors can reduce risk is to screen animals for any known viruses and reject infected animals as donors. This is not always easy, however. For example, all pigs carry retroviruses in each cell's DNA. Last year, scientists at the Institute of Cancer Research in London showed that these pig retroviruses can infect human cells in laboratory culture. Whether these retroviruses could infect transplant recipients and what the effect might be are not known. It would be extremely difficult, if not impossible, to rid pigs of these retroviruses—and pigs genetically engineered to avoid provoking the human immune system are currently front-running candidates to be sources for xenografts.

Other unknowns face xenotransplantation researchers. Patterson notes that screening for viruses only takes you so far, because you can't screen for what you don't know, and animals sometimes silently harbor viruses that scientists have not yet discovered. Moreover, the kind of exposure that occurs with xenotransplantation is not like anything that occurs naturally, in that a xenograft is placed permanently inside the patient, whose immune system is often partially shut down to prevent rejection. Researchers aren't yet sure how animal viruses, known or unknown, might behave under these circumstances.

All the uncertainty gives policy makers reason to worry, and they are studying the problem. The Department of Health and Human Services (HHS) has issued guidelines to govern screening of donor animals, and long-term follow up of xenotransplant recipients. Researchers are studying the hundreds of people who have already received animal tissues for signs of viral infection. And HHS is forming a national advisory committee to study policy questions for many aspects of xenotransplantation, including the danger from animal viruses.

"There are many unanswered questions that concern all of us, and policy makers must find the right balance between the risks, and benefits," says Patterson. "The risk of introducing new viruses into the human population through xenotransplantation is not something that we can just dismiss."


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