Healthy or sick? Tiny cell bubbles may hold the answer
Rutgers researchers provide insight into genes that can spread cancer or heal wounds
- Date:
- December 11, 2015
- Source:
- Rutgers University
- Summary:
- Scientists have uncovered biological pathways in the roundworm that provide insight into how tiny bubbles released by cells can have beneficial health effects, like promoting tissue repair, or may play a diabolical role and carry disease signals for cancer or neurodegenerative diseases like Alzheimer's.
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Rutgers scientists have uncovered biological pathways in the roundworm that provide insight into how tiny bubbles released by cells can have beneficial health effects, like promoting tissue repair, or may play a diabolical role and carry disease signals for cancer or neurodegenerative diseases like Alzheimer's.
In a new study, published in Current Biology, Rutgers scientists isolated and profiled these sub-micron sized cells, known as extracellular vesicles (EVs) in adult C. elegans and identified 335 genes that provide significant information about the biology of EVs and their relationship to human diseases.
They and colleagues from Princeton University, the University of Oxford and Albert Einstein College of Medicine, determined that 10 percent of the 335 identified genes in the roundworm regulate the formation, release, and possible function of the EVs. Understanding how EVs are made, dispersed and communicate with other cells can shed light on the difference between EVs carrying sickness or health.
"These EV's are exciting but scary because we don't know what the mechanisms are that decide what is packaged inside them." said Maureen Barr, lead author and a professor in the Department of Genetics in Rutgers' School of Arts and Sciences. "It's like getting a letter in the mail and you don't know whether it's a letter saying that you won the lottery or a letter containing anthrax."
For decades scientists believed that the EV material released by some human cells -- which can only be seen through high-tech electron microscopes -- was nothing more than biological debris.
While this theory has changed -- with researchers now having a better understanding of the role these EVs play in cancer, infectious diseases and neurodegenerative disorders -- scientists still aren't certain how they are made or why the same parcels can result in different outcomes.
But Barr said using C. elegans, which have many genes similar to humans, Rutgers scientists have identified new pathways that could control the production of EVs and the cargo they carry, including the proteins responsible for polycystic kidney disease, the most commonly inherited disease in humans. The polycystic kidney disease gene products are secreted in tiny EVs from both humans and worms and no one knows why these proteins are in the EVs, she said.
"The knowledge gained from this tiny worm is essential for determining the biological significance of EVs, for understanding their relationship to human diseases like polycystic kidney disease, and for harnessing their potential therapeutic uses, "Barr said.
Because EVs are found in bodily fluids like urine, blood and cerebral spinal fluid, Barr said it is nearly impossible to determine the cellular source from which they are derived. This is why very little is known about how EVs are made and how the molecular cargo is released.
By understanding how a cell makes and packages proteins, lipids and nucleic acids into EVs, Barr said, pharmaceutical treatments and therapies could be developed, for instance, that would prevent cancer cells from producing EVs carrying cargo necessary for tumor growth.
"When we know exactly how they work, scientists will be able to use EVs for our advantage," said Barr. "This means that pathological EVs that cause disease could be blocked and therapeutic EVs that can help heal can be designed to carry beneficial cargo."
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Materials provided by Rutgers University. Note: Content may be edited for style and length.
Journal Reference:
- Juan Wang , Rachel Kaletsky , Malan Silva , April Williams , Leonard A. Haas , Rebecca J. Androwski , Jessica N. Landis , Cory Patrick , Alina Rashid , Dianaliz Santiago-Martinez , Maria Gravato-Nobre , Jonathan Hodgkin , David H. Hall , Coleen T. Murphy , Maureen M. Barr. Cell-Specific Transcriptional Profiling of Ciliated Sensory Neurons Reveals Regulators of Behavior and Extracellular Vesicle Biogenesis. Current Biology, 2015 DOI: 10.1016/j.cub.2015.10.057
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