Study Confirms No Transmission of Alzheimer's Proteins between Humans
News Feb 06, 2013
Mounting evidence demonstrates that the pathological proteins linked to the onset and progression of neurodegenerative disorders are capable of spreading from cell-to-cell within the brains of affected individuals and thereby “spread” disease from one interconnected brain region to another.
A new study found no evidence to support concerns that these abnormal disease proteins are “infectious” or transmitted from animals to humans or from one person to another. The study by researchers from the Perelman School of Medicine at the University of Pennsylvania, in conjunction with experts from the U.S. Centers for Disease Control and the Department of Health and Human Services, appears online in JAMA Neurology.
Cell-to-cell transmission is a potentially common pathway for disease spreading and progression in diseases like Alzheimer's (AD) and Parkinson's (PD) disease as well as frontotemporal lobar degeneration (FTLD), amyotrophic lateral sclerosis (ALS) and other related disorders. It appears that misfolded proteins spread from one cell to another and that the affected neurons become dysfunctional, while these toxic proteins go on to damage other regions of the brain over time.
"By interrogating an existing database with information on a cohort of well-characterized patients, we were able to determine that there is no evidence suggesting the pathology of Alzheimer’s or Parkinson’s can transmit between humans," said senior author John Q. Trojanowski, MD, PhD, professor of Pathology and Laboratory Medicine and co-director of the Penn Center for Neurodegenerative Disease Research. "We can now redouble efforts to find treatments, via immunotherapies or other approaches to stop the spreading of these toxic proteins between cells."
In order to verify whether such proteins could potentially be carried from person to person, the team of researchers analyzed data from an existing cohort of patients who had received human growth hormone (hGH) from cadaveric pituitary glands via a national program, as a beneficial treatment for stunted growth, before synthetic hGH was available. Nearly 7,700 patients were treated with cadaver-derived hGH (c-hGH) in the US between 1963 and 1985. In the mid-1980s, more than 200 patients worldwide who had received c-hGH inadvertently contaminated with prion proteins from affected donor pituitary tissue went on to develop an acquired form of Creutzfeldt-Jakob disease (CJD), a rare, degenerative, invariably fatal brain disorder caused by pathological prion proteins that also are the cause of Mad Cow disease. Since then, the cohort has been followed to track any additional cases of CJD, with extensive medical histories for patients over the 30+ years since the c-hGH therapy was stopped after the link to CJD was discovered in 1985.
In this current study, researchers looked for signs of an elevated risk of AD, PD, FTLD or ALS among this group and found that none of the c-hGH recipients developed AD, PD or FTLD. The team did identify three ALS cases of unclear significance, given that no traces of ALS disease proteins (TDP-43, FUS and Ubiquilin) were found in human pituitary glands, despite the presence of pathological AD (tau, Aβ) and PD (alpha-synuclein) proteins. This clarified that c-hGH recipients were most likely exposed to these neurodegenerative disease proteins linked to AD, PD and FTLD but this did not result in transmission of disease from person to person.
"This cohort is an invaluable resource and should continue to be followed, especially as we rapidly increase our understanding of disease progression in neurodegenerative conditions," said David Irwin, MD, lead author, and fellow in the Center for Neurodegenerative Disease Research and the department of Neurology in the Perelman School of Medicine.
About 422 million people around the world, including more than 30 million Americans, have diabetes. Obesity is the most significant risk factor for type 2 diabetes. yet about 30 percent of obese people do not develop type 2 diabetes or other metabolic conditions. New research aims to understand on a cellular level, how this separation occurs.READ MORE