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New way to target an old foe: malaria

Engineered liver tissue developed at MIT could help scientists test new drugs and vaccines.
<i>Plasmodium vivax</i> (red sphere) grows in engineered liver tissue developed by MIT researchers to study malaria. The blue spheres represent the nuclei of cells that make up the microscale liver tissue.
Caption:
<i>Plasmodium vivax</i> (red sphere) grows in engineered liver tissue developed by MIT researchers to study malaria. The blue spheres represent the nuclei of cells that make up the microscale liver tissue.
Credits:
Image: Sandra March/Bhatia Lab, MIT

Although malaria has been eradicated in many countries, including the United States, it still infects more than 200 million people worldwide, killing nearly a million every year. In regions where malaria is endemic, people rely on preventive measures such as mosquito netting and insecticides. Existing drugs can help, but the malaria parasite is becoming resistant to many of them. 

Scientists working to develop new drugs and vaccines hope to target the parasite in the earliest stages of an infection, when it quietly reproduces itself in the human liver.

In a major step toward that goal, a team led by MIT researchers has now developed a way to grow liver tissue that can support the liver stage of the life cycle of the two most common species of malaria, Plasmodium falciparum and Plasmodium vivax. This system could be used to test drugs and vaccines against both species, says Sangeeta Bhatia, the John and Dorothy Wilson Professor of Health Sciences and Technology and Electrical Engineering and Computer Science at MIT.

Bhatia is the senior author of a paper describing the liver-tissue system in the July 17 issue of the journal Cell Host & Microbe. The paper’s lead author is Sandra March, a research scientist in Bhatia’s lab, and scientists from the Broad Institute, Sanaria Inc. and the University of Lisbon also contributed to the research.

Reproducing infection

The malaria life cycle has several stages. Once the parasite infects a human victim, through a mosquito bite, it takes up residence in the liver. The parasite spends about a week in the liver, producing tens of thousands of copies that eventually burst free to infect blood cells. After this initial infection, P. vivax can lurk for weeks, months or even years, reactivating to cause another malaria bout.

So far, researchers have been able to grow P. falciparum in human blood and, to a certain extent, in its liver stages, but they have not been able to reliably grow P. vivax in either stage. P. falciparum has the highest malaria mortality rate, but P. vivax can cause debilitating, long-term infections. To eradicate malaria, drugs and vaccines that target both species will probably be needed, Bhatia says.

Bhatia — who is also a senior associate member of the Broad Institute and a member of MIT’s Koch Institute for Integrative Cancer Research and Institute for Medical Engineering and Science — has previously created micropatterned surfaces on which liver tissue can be grown, surrounded by supportive cells. These engineered cells survive for up to six weeks and mimic most of the functions of liver cells in the body, including drug metabolism and production of liver proteins. 

Using unique, frozen samples of P. falciparum obtained in collaboration with Stephen L. Hoffman and his team at Sanaria, the researchers infected healthy liver cells and observed the development of liver-stage parasites using an automated imaging system designed in collaboration with Anne Carpenter’s group at the Broad Institute. This system allows them to quickly evaluate not only how much infection has occurred, but also the effects of potential drugs. They can also measure how weakened forms of the parasites, which could be used as vaccines, perform in the liver.

To test the system’s usefulness, the researchers studied a P. falciparum vaccine that is now in clinical trials. For a weakened, or attenuated, parasite to succeed as a vaccine, it must infect the liver and progress enough to raise an immune response, but then arrest and not reach the blood stage. The researchers showed that the vaccine now in trials does follow that trajectory.

The new system could also be used for larger-scale drug studies than previously possible, Bhatia says. Researchers now use liver cancer cells grown in the lab to study P. falciparum infection, but those cells have deficient drug metabolism and keep growing instead of providing a quiet home for the parasite to persist.

Seeking P. vivax

Obtaining enough P. vivax samples to test the system took several years, but the team eventually acquired samples, flown in from Thailand, India and South America. Using these samples, they were able to grow P. vivax in liver tissue and show that it produces small persistent parasites that appear to be dormant forms called hypnozoites.

“We don’t want to call them hypnozoites yet, because nobody has a gold-standard marker for them, but we have persistent small forms that live for three weeks. So we are optimistic and doing more to wake them up again. Reactivation would be the ultimate confirmation,” Bhatia says.

Technologies that permit high-throughput screening of drugs against hypnozoites would be “a tremendous advance of global-health importance,” says Kevin Baird, vice director of the Eijkman Oxford Clinical Research Unit in Indonesia. “This paper shows the formation of what are very likely hypnozoites, but demonstration of their maturation (and therefore likely utility in screening chemotherapeutics) remains to be achieved in this system or anywhere else.”

The researchers are now working on confirming that the P. vivax they grew in the liver tissue really did create hypnozoites. Once this is confirmed, they plan to start testing some candidate drugs, now in development, against P. vivax.

The research was funded by the Bill and Melinda Gates Foundation, Medicines for Malaria Venture, the National Institute of Allergy and Infectious Disease, the National Institutes of Health and the Howard Hughes Medical Institute.

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