Wednesday, May 14, 2025

B-GRADE HORROR MOVIE

Wily parasite kills human cells and wears their remains as disguise

University of California - Davis

The single-celled parasite Entamoeba histolytica infects 50 million people each year, killing nearly 70,000. Usually, this wily, shape-shifting amoeba causes nothing worse than diarrhea. But sometimes it triggers severe, even fatal disease by chewing ulcers in the colon, liquefying parts of the liver and invading the brain and lungs.

“It can kill anything you throw at it, any kind of human cell,” said Katherine Ralston, an associate professor in the Department of Microbiology and Molecular Genetics. E. histolytica can even evade the immune system – and it can kill the white blood cells that are supposed to fight it.

Scientists have struggled to understand how it does this. But in a new paper published in the May issue of Trends in Parasitology, Ralston and her lab lay out a plan for finally tackling it, using genetic tools to tease apart the function of its proteins and genes.

“All parasites are understudied, but E. histolytica is especially enigmatic,” said Ralston. Building the tools for studying it has taken years. But along the way she has uncovered surprises that may set the stage for improved treatments.

Finding the murder weapon of a microscopic killer

E. histolytica enters the colon after a person ingests contaminated food or water, generally in developing countries with poor water sanitation. In the United States, it is most commonly seen in people who recently took trips overseas, or who immigrated from other countries.

Its species name, histolytica, means “tissue-dissolving” — because it creates festering pockets of liquefied tissue, called abscesses, in the organs it infects. As it rampages through a person’s organs, it doesn’t neatly eat the cells that it kills; instead, it leaves the wounded cells to spill out their contents while it hurries on to kill other cells.

Ralston started studying this fearsome little beast in 2011, during a postdoctoral fellowship at the University of Virginia. Back then, people believed that it killed cells by injecting them with a poison. But as she watched it through a microscope, she saw something very different.

E. histolytica was actually taking bites out of human cells. Peering through the microscope, “You could see little parts of the human cell being broken off,” she said. Those ingested cell fragments, shining fluorescent green under her microscope, accumulated inside the amoeba.

Her report that the parasite kills cells through this process, called “trogocytosis,” was published in the journal Nature in 2014. “This was important,” she said. “To devise new therapies or vaccines, you really need to know how E. histolytica damages tissue.”

Ralston discovered, in 2022, that after the amoeba ingests parts of human cells, it becomes resistant to a major component of the human immune system — a class of molecules called “complement proteins” that finds and kills invading cells.

In a new paper, posted to bioRxiv in October 2024, Ralston and graduate students Maura Ruyechan and Wesley Huang found that the amoeba gains this resistance by ingesting proteins from the outer membranes of human cells and placing them on its own outer surface. Two of these human proteins, called CD46 and CD55, prevent complement proteins from latching onto the amoeba’s surface.

In essence, the amoebae are killing human cells and then donning their protein uniforms as a disguise, allowing them to evade the human immune system.

Building tools for scientific discovery

With other pathogens, like HIV and salmonella, scientists made rapid progress by identifying many genes, then running high-throughput experiments to knock those genes out individually to find ones that are crucial for causing disease. But that has been difficult with E. histolytica.

Its genome, sequenced in 2005, is five times larger than that of salmonella and 2,500 times larger than that of HIV. Analyzing it required years of advances in bioinformatics. But a 2013 study finally showed something promising: E. histolytica uses a cellular process called “RNA inhibition” (RNAi) as a volume knob, to control the expression of its genes.

“We thought we could turn this into a tool for understanding its genome,” Ralston said. In 2021 she, Ruyechan, Huang and six UC Davis colleagues published a paper demonstrating one such tool that they developed. Their “RNAi library” allows them to inhibit the expression, individually, of each one of the parasite’s 8,734 known genes.

In their newest paper, published as the cover story this month in Trends in Parasitology, Ralston, Huang and Ruyechan present a plan for using this RNAi system to quickly identify genes that are required for the amoeba to do crucial things, like biting human cells or stealing their proteins.

They advocate for combining this with the gene-editing tool CRISPR. Using this approach, they could label proteins with fluorescent markers, to watch them interact under a microscope; or delete small parts of genes and proteins, to find the specific parts that are crucial and could be targeted with drugs.

“We now see a light at the end of the tunnel, and we think this could be achievable,” said Huang, who is advocating for the research community to develop CRISPR for use in the amoeba.

From basic research to medical breakthroughs

The story of E. histolytica illustrates the value of basic research — and how it contributes to medical breakthroughs many years down the road.

It took years for researchers to learn how to grow this parasite in the lab and years more for Ralston to discover how it bites human cells and coopts their proteins to escape the immune system. Even after its genome was sequenced, Ralston and other scientists needed time to develop experimental tools for picking it apart. This lays the foundation for identifying genes or proteins that can be targeted with vaccines or new drugs.

“Science is a process of building,” Ralston said. “You have to build one tool upon another, until you’re finally ready to discover new treatments.”

Ralston’s work has been funded by the National Institutes of Health and received support from the American Society for Microbiology, Pew Charitable Trusts, the Hellman Foundation, and the Hartwell Foundation. This research has utilized several UC Davis research core facilities, including the Light Microscopy Imaging Facility, the Bioinformatics Core Facility, and the Center for Molecular and Genomic Imaging.

Additional authors of the 2021 paper presenting the RNAi library include: Akhila Bettadapur, Rene Suleiman, Hannah Miller and Tammie Tam (UC Davis College of Biological Sciences); Samuel Hunter and Matthew Settles (UC Davis Genome Center); and Charles Barbieri (SeqMatic LLC, Fremont, CA).

Journal

Trends in Parasitology

DOI

10.1016/j.pt.2025.03.010

Method of Research

Experimental study

Subject of Research

Cells

Article Title

Work with me here: variations in genome content and emerging genetic tools in Entamoeba histolytica

POSTMODERN ALCHEMY

Liquid metal tin is the key to sustainable desalination!

Researchers have developed a solar-powered method that uses liquid tin to purify water and recover valuable metals from seawater brine

Institute of Science Tokyo

Liquid metal tin-based desalination to recover metallic elements — image:
Researchers develop a solar energy-powered desalination system using liquid metal tin to recover valuable metallic elements from seawater
view more
Credit: Masatoshi Kondo from Institute of Science Tokyo, Japan

Water scarcity remains one of the most pressing global challenges, affecting over two billion people worldwide. With population growth and climate change further exacerbating this problem, scientists are turning to seawater desalination as a promising solution to satisfy the ever-increasing demand for freshwater.

However, current desalination plants discharge massive amounts of brine as waste— approximately 141.5 million cubic meters daily. This solution typically contains concentrated metallic elements. Additionally, existing methods for recovering metals from brine are quite energy-intensive and generate other types of hazardous waste.

In order to address these challenges, a research team led by Associate Professor Masatoshi Kondo from Institute of Science Tokyo (Science Tokyo), Japan, has developed an innovative approach using liquid metal tin to simultaneously purify water and recover valuable metals. Their paper was made available online on February 26, 2025, and was published in Volume 15, Issue 1 of the journal Water Reuse on March 01, 2025. The study demonstrates how this technology can transform desalination brine from an environmental liability into a valuable resource. This work was co-authored by doctoral student Toranosuke Horikawa, then-bachelor student Mahiro Masuda, and Assistant Professor Minho Oh, from Science Tokyo.

The proposed strategy is centered around spraying brine onto the surface of liquid tin heated to 300 °C. Upon contact, freshwater is instantly evaporated and thus distilled from the brine, while valuable elements such as sodium, magnesium, calcium, and potassium remain in the tin. “The main energy source for this type of seawater desalination can be concentrated solar power, since heat is the main energy source required for this desalination process. Unlike conventional methods, large consumption of electricity is not necessary, enabling the development of a sustainable process,” explains Dr. Kondo, highlighting the technology’s use of easily accessible and renewable energy.

After minerals are dissolved into the liquid tin, a slow cooling process allows different metal elements to precipitate at specific temperatures, enabling their separate recovery. Through laboratory experiments, the researchers found that potassium begins to precipitate first, followed by sodium, calcium, and finally magnesium, enabling targeted recovery of each resource.

Another important approach that sets it apart is its versatility and efficiency. “The proposed technology for the collection and recovery of metallic elements from seawater desalination brine can also be used to distill groundwater polluted with arsenic without consuming large amounts of energy or producing waste,” notes Dr. Kondo. Groundwater contamination with arsenic is a widespread problem affecting drinking water for millions of people in regions like South Asia, particularly affecting Bangladesh, India, Vietnam, and nearby countries.

Worth noting, this innovative technology aligns with multiple sustainable development goals, providing a pathway to secure both freshwater and metal resources without generating secondary waste or significant carbon emissions. Additionally, liquid metal tin, which has been considered as a challenge due to its reactivity in nuclear fusion reactors, has been utilized to efficiently recover valuable seawater-based resources. Overall, this liquid tin-based approach offers a promising solution that transforms environmental challenges into valuable opportunities, potentially revolutionizing water treatment and desalination practices worldwide.

***

Reference

Authors: Toranosuke Horikawa1, Mahiro Masuda1, Minho Oh2, and Masatoshi Kondo3

Title: Liquid metal technology for collection of metal resources from seawater desalination brine and polluted groundwater

Journal: Water Reuse

DOI: 10.2166/wrd.2025.100

Affiliations:

1School of Engineering, Department of Mechanical Engineering, Graduate Major in Nuclear Engineering, Institute of Science Tokyo, Japan

2Department of Materials Science and Engineering, Institute of Science Tokyo, Japan

3Institute of Integrated Research, Laboratory for Zero-Carbon Energy, Institute of Science Tokyo, Japan

About Institute of Science Tokyo (Science Tokyo)

Institute of Science Tokyo (Science Tokyo) was established on October 1, 2024, following the merger between Tokyo Medical and Dental University (TMDU) and Tokyo Institute of Technology (Tokyo Tech), with the mission of “Advancing science and human wellbeing to create value for and with society.”

About Associate Professor Masatoshi Kondo from Institute of Science Tokyo (Science Tokyo), Japan

Dr. Masatoshi Kondo is an Associate Professor at the Institute of Integrated Research at Science Tokyo, Japan. His research interests include liquid metals, nuclear fusion reactors, molten salts, and fast breeder reactors. He is affiliated with academic societies such as Japan Society of Plasma Science and Nuclear Fusion Research and Atomic Energy Society of Japan. He is also an honorable awardee of multiple commendations such as Marine Tech Grand Prix 2022, Asahi Yukuzai Award. He has published numerous articles with more than 2,000 citations.

Funding information

This paper is partially based on results obtained from a project, JPNP20004, subsidized by the New Energy and Industrial Technology Development Organization (NEDO). This work was supported by JST SPRING, Japan Grant Number JPMJSP2106 and JPMJSP2180.