UCLA-led study reveals the mechanism that helps malaria parasites take over human red blood cells
3D imaging by California NanoSystems Institute could lead to new targeted therapeutics
Meghan Steele Horan | Aug 27, 2018
In the study, published today in Nature, researchers reveal the atomic structure of the Plasmodium translocon of exported proteins, or PTEX, the protein complex that transports these malaria proteins into the red blood cell. The research also provides the first direct evidence of the proteins moving through PTEX.
“For many years, scientists hypothesized that PTEX was responsible for transporting these malaria proteins,” said Z. Hong Zhou, a professor of microbiology, immunology and molecular genetics and director of the Electron Imaging Center for Nanomachines at the California NanoSystems Institute at UCLA, who led the study. “We just never knew how it worked, until now.”
Malaria is an infectious disease transmitted to people through the bites of infected mosquitos. It affects more than 200 million people annually, causing nearly a half-million deaths each year.
When a human is bitten, Plasmodium parasites invade human red blood cells and take a part of the red blood cell membrane to build a protective compartment, or vacuole, around itself.
“Normal red blood cells are too simple to provide enough nutrients to support the actively growing parasites,” said Chi-Min Ho, a UCLA graduate student and first author of the study. “Each parasite is essentially living in an empty warehouse and has to produce hundreds of malaria ‘effector’ proteins to remodel the red blood cell into a home.”
PTEX acts as a gatekeeper; without it, effector proteins become trapped in the vacuole. Ho and her colleagues wanted to learn exactly how PTEX is involved in transporting the proteins out into the red blood cell.
To find out, the Washington University researchers first grew malarial parasites in human blood in a laboratory. At UCLA, Ho extracted PTEX from the parasites, and rapidly froze them at 190 degrees below zero Celsius. From there, she took images of the PTEX particles using a method called cryoelectron microscopy, or cryoEM. In the technique, scientists use an electron microscope to hit the subject — in this case, PTEX particles — with an electron beam, and capture the resulting 2D images with a specialized camera.
Ho then used computer algorithms to combine the 2D images into high-resolution 3D models, giving the team the first-ever view of the entire shape of PTEX at an atomic level. They discovered that PTEX is made up of three proteins that act like a molecular machine.
“The first PTEX protein is the engine that powers transport; it unfolds the parasite proteins and threads them through the remaining two PTEX proteins,” said Pascal Egea, a research scientist at the David Geffen School of Medicine at UCLA who co-led the study. “The middle protein is like an adapter that connects the engine to the last protein, which is shaped like a funnel, allowing passage to the red blood cell.”
In looking closely at the 3D models, the team made an even more exciting discovery.
“When we harvested the parasites, they were right at the point of their lifecycle where they were actively transporting the effector proteins out into the red blood cell,” Ho said. “We were delighted to find unfolded proteins trapped inside PTEX. This provided us with direct proof that PTEX is directly responsible for exporting effector proteins.”
With the ongoing race against the rise of drug-resistant malaria parasites, the scientists hope that their findings could help drive the development of urgently needed new drugs that target PTEX and prevent it from functioning properly.
For Zhou, finding new treatments for malaria is a very personal mission.
“My mom almost died of malaria when I was a child,” he said. “It’s very gratifying that our research could lead to new lifesaving treatments for malaria.”
The study’s other authors are Josh Beck and Daniel Goldberg of Washington University and Mason Lai and Yanxiang Cui of UCLA. Zhou and Egea are also members of the UCLA Molecular Biology Institute. The research was supported by the National Institutes of Health, the Ruth L. Kirschstein National Research Service Award, the National Science Foundation and the Alexander and Renée Kolin Endowment at UCLA.