Bioelectricity new weapon to fight dangerous infectionStaff Writer | May 27, 2017
Changing the natural electrical signaling that exists in cells outside the nervous system can improve resistance to life-threatening bacterial infections, according to new research from Tufts University biologists.
New method E. coli infection and injury
This reveals a novel aspect of the immune system - regulation by non-neural bioelectricity - and suggests a new approach for clinical applications in human medicine. The study is published online May 26, 2017, in npj Regenerative Medicine, a Nature Research journal.
"All cells, not just nerve cells, naturally generate and receive electrical signals.
Being able to regulate such non-neural bioelectricity with the many ion channel and neurotransmitter drugs that are already human-approved gives us an amazing new toolkit to augment the immune system's ability to resist infections," said the paper's corresponding author Michael Levin, Ph.D., Vannevar Bush professor of biology and director of the Allen Discovery Center at Tufts and the Tufts Center for Regenerative and Developmental Biology in the School of Arts and Sciences.
Levin is also an associate faculty member of the Wyss Institute of Biologically Inspired Engineering at Harvard University.
All vertebrates, from fish to people, have two kinds of immunity with common features. The adaptive immune system relies on the memory of previous exposure to a specific pathogen and is the basis for current vaccination strategies.
The innate immune system is present from the time an egg is fertilized and provides a first line of defense against pathogens through surface barriers, antimicrobial amino acids called peptides, and certain blood cells.
The innate immune system also plays a role in tissue repair and regeneration, and the interplay between regeneration and innate immunity is an emerging field of study.
Better understanding of innate immunity can advance efforts to combat new pathogens to which no adaptive memory has developed, address geographic migration of diseases, support immune-deficient patients, and develop more effective treatment of traumatic injuries. ■