Posts tagged living cells
Articles and news from the latest research reports.
Strange behavior: new study exposes living cells to synthetic protein
One approach to understanding components in living organisms is to attempt to create them artificially, using principles of chemistry, engineering and genetics. A suite of powerful techniques—collectively referred to as synthetic biology—have been used to produce self-replicating molecules, artificial pathways in living systems and organisms bearing synthetic genomes.
In a new twist, John Chaput, a researcher at Arizona State University’s Biodesign Institute and colleagues at the Department of Pharmacology, Midwestern University, Glendale, AZ have fabricated an artificial protein in the laboratory and examined the surprising ways living cells respond to it.
“If you take a protein that was created in a test tube and put it inside a cell, does it still function,” Chaput asks. “Does the cell recognize it? Does the cell just chew it up and spit it out?” This unexplored area represents a new domain for synthetic biology and may ultimately lead to the development of novel therapeutic agents.
The research results, reported in the advanced online edition of the journal ACS Chemical Biology, describe a peculiar set of adaptations exhibited by Escherichia coli bacterial cells exposed to a synthetic protein, dubbed DX. Inside the cell, DX proteins bind with molecules of ATP, the energy source required by all biological entities.
Made to order: printing of live cells
Surgeons may soon be able to regrow patients’ nerves, such as those in damaged spinal cords, using technology adapted from the type of inkjet printer most of us have connected to our computer at home.
Researchers at the ARC Centre of Excellence for Electromaterials Science (ACES), University of Wollongong (UOW) node in NSW, have spent the past three years developing the technology to print living human cells—nerve cells and muscle cells onto tiny biodegradable polymer scaffolds. They’ve also developed a special “ink” that carries the cells.
The ink has to keep the cells in suspension, as well as having the right chemical composition to keep them alive. It also protects them as they are shot out of the printer at amazing speeds.
The scaffolds act as the base upon which the cells thrive, and contain substances such as growth factor molecules and electrical conduits to enable stimulation to promote cell growth. The aim is to produce structures up to 4 cm long, which can be “patched” into broken or damaged nerves or muscles.
“There’s great interest from the medical world, and we are working closely with clinicians at St Vincents Hospital in Melbourne,” says Prof Gordon Wallace, director of the Materials node of ANFF and ACES. “They’re very interested in the possibilities it raises, and the collaboration is resulting in new ideas almost every week.”
“The support from ANFF and the collaborative, interdisciplinary approach that our facilities bring has attracted the best people in the world to join our teams,” he adds.
(Source: scienceinpublic.com.au)