Posts tagged e. coli
Articles and news from the latest research reports.
Recombinant Human Prion Protein Inhibits Prion Propagation
Case Western Reserve University researchers today published findings that point to a promising discovery for the treatment and prevention of prion diseases, rare neurodegenerative disorders that are always fatal. The researchers discovered that recombinant human prion protein stops the propagation of prions, the infectious pathogens that cause the diseases.
“This is the very first time recombinant protein has been shown to inhibit diseased human prions,” said Wen-Quan Zou, MD, PhD, senior author of the study and associate professor of pathology and neurology at Case Western Reserve School of Medicine.
Recombinant human prion protein is generated in E. coli bacteria and it has the same protein sequence as normal human brain protein. But different in that, the recombinant protein lacks attached sugars and lipids. In the study, published online in Scientific Reports, researchers used a method called protein misfolding cyclic amplification which, in a test-tube, mimics the prions’ replication within the human brain. The propagation of human prions was completely inhibited when the recombinant protein was added into the test-tube. The researchers found that the inhibition is dose-dependent and highly specific in responding to the human-form of the recombinant protein, as compared to recombinant mouse and bovine prion proteins. They demonstrated that the recombinant protein works not only in the cell-free model but also in cultured cells, which are the first steps of translational research. Further, since the recombinant protein has an identical sequence to the brain protein, the application of the recombinant protein is less likely to cause side effects.
Prion diseases are a group of fatal transmissible brain diseases affecting both humans and animals. Prions are formed through a structural change of a normal prion protein that resides in all humans. Once formed, they continue to recruit other normal prion protein and finally cause spongiform-like damage in the brain. Currently, the diseases have no cure.
Previous outbreaks of mad cow disease and subsequent occurrences of the human form, variant Creutzfeldt–Jakob disease, have garnered a great deal of public attention. The fear of future outbreaks makes the search for successful interventions all the more urgent.
(Source: casemed.case.edu)
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.