Molecules Swing Electrolytes across Membranes to Kill Cancer Cells
Singapore, May 23, 2019 – Researchers from Singapore have designed the world’s first ‘molecular swing’ to transport electrolytes across cell membranes. In a recent paper1, the scientists from NanoBio Lab
(NBL) and Institute of Bioengineering and Nanotechnology of the Agency for Science, Technology and Research (A*STAR) demonstrated that their new mechanism transported potassium ions 27% faster than gramicidin A, a naturally occurring highly active
peptide transporter. When applied to brain tumor cells, this increase in speed inhibited cancer cells faster than potassium channel blocking drugs like quinidine. This suggests that the molecular swings could be potent anti-cancer agents.
According to Dr. Huaqiang Zeng, NBL Team Leader and Principal Research Scientist, “We are delighted that our unconventional molecular swing design functioned successfully. Its ability to efficiently and selectively transport potassium ions better
than a natural transporter encouraged us to investigate its possible use in cancer chemotherapy.”
Said Professor Jackie Y. Ying, A*STAR Senior Fellow and head of NBL, “We hope that our promising results will motivate others to create different types of motional channels for transmembrane transport that may lead to practical medical benefits
in the future. This field of research has the potential to revolutionize medicine with more effective anti-cancer drugs and antibiotics.”
Electrolytes are electrically charged chemicals and minerals, which play an important role in the body. They help to maintain key body functions, such as regulating the osmotic pressure in cells, stimulating muscles to contract and transmitting nerve
signals. One essential electrolyte is the potassium ion, which helps to regulate blood pressure and maintain a normal heart rhythm.
In order for our organs to function properly, we need an appropriate balance of electrolytes in our body. Typically, electrolytes move in and out of cells via carriers or channels. Carrier molecules facilitate ion transport by undergoing dramatic conformational
changes, while channel molecules penetrate membranes to form pathways for ions to travel easily. Recently, researchers have been trying to replicate real-world macroscopic functions at the microscopic level using molecules. These developments in artificial
molecular machines inspired the research team to design a new type of ion transport mechanism based on swing motion.
The molecular swing anchors itself firmly to a cell’s lipid membrane via two cholesterol groups. Its other parts include one linear hydrazide segment that acts as the beam, one flexible oligoethylene glycol chain as the rope, and one crown ether
as the seat. The crown ether binds to a potassium or sodium ion, and transports it across the membrane when there is a difference in ion concentration between the interior and exterior of the cell.
As potassium ions move out of the cells, the over-accumulation of positively charged ions outside the cells depolarizes their neurons. This causes the neurons to become less capable or even incapable of transmitting signals, leading to cell death. The
researchers showed that molecular swings precipitated this killing process in brain cancer cells more rapidly than anti-cancer drugs that block potassium channels to hinder ion transfer.
The researchers are currently optimizing the structure of the molecular swing to enhance its anticancer activity. They are also testing other novel ion transport mechanisms.
- Huaqiang Zeng, Changliang Ren, Feng Chen, Ruijian Ye, Yong Siang Ong, Hongfang Lu, Su Seong Lee and Jackie Y. Ying, “Molecular Swings as Extremely Active Ion Transporters,” Angewandte Chemie International Edition, (2019) DOI: 10.1002/anie.201901833.
Images (Credit: NanoBio Lab, A*STAR):
Clockwise from top left: The NBL research team who designed the molecular swing comprises Dr. Changliang Ren, Dr. Feng Chen, Dr. Hongfang Lu, Dr. Huaqiang Zeng and Prof. Jackie Y. Ying.
Illustration of potassium ions being transported across a cell membrane by the molecular swing.
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About NanoBio Lab (www.nbl.a-star.edu.sg)
NanoBio Lab is a multidisciplinary lab-incubator that is committed to improving lives through scientific discovery and technological innovation. Using nanotechnology, we create new materials and systems with unique functions and enhanced properties for
advanced applications. We work closely with hospitals and industry to shape the future of medicine, food safety, environmental monitoring and energy. Our research focus includes high-precision drug delivery vehicles, biocompatible materials for cell
culture and medical use, portable detection kits for infectious diseases and food pathogens, intelligent sensors for environmental pollutants and food fraud, organs-on-chip for toxicology testing, advanced water purification membranes and innovative
energy storage solutions. Our vision is to improve the world through nanotechnology. Under the direction of renowned nanotechnology researcher, Professor Jackie Y. Ying, the NanoBio Lab works at the intersection of chemistry, materials science, engineering,
and medicine to develop new nanocomposites, biomaterials, synthetic molecules, devices and biosystems to tackle major global challenges. As a nationally funded Laboratory, we contribute toward the growth of Singapore’s economy by nurturing research
talents, creating portfolios of intellectual properties, and commercializing new technologies.
About the Agency for Science, Technology and Research (www.a-star.edu.sg)
The Agency for Science, Technology and Research (A*STAR) is Singapore’s lead public sector agency that spearheads economic oriented research to advance scientific discovery and develop innovative technology. Through open innovation, we collaborate
with our partners in both the public and private sectors to benefit society.
As a Science and Technology Organisation, A*STAR bridges the gap between academia and industry. Our research creates economic growth and jobs for Singapore, and enhances lives by contributing to societal benefits such as improving outcomes in healthcare,
urban living, and sustainability.
We play a key role in nurturing and developing a diversity of talent and leaders in our Agency and research entities, the wider research community and industry. A*STAR’s R&D activities span biomedical sciences and physical sciences and engineering,
with research entities primarily located in Biopolis and Fusionopolis.