Posts tagged mad cow disease
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)
The flexible tail of the prion protein poisons brain cells
For decades, there has been no answer to the question of why the altered prion protein is poisonous to brain cells. Neuropathologists from the University of Zurich and University Hospital Zurich have now shown that it is the flexible tail of the prion protein that triggers cell death. These findings have far-reaching consequences: only those antibodies that target the tail of the prion protein are suitable as potential drugs for combating prion diseases.
Prion proteins are the infectious pathogens that cause Mad Cow Disease and Creutzfeldt-Jakob disease. They occur when a normal prion protein becomes deformed and clumped. The naturally occurring prion protein is harmless and can be found in most organisms. In humans, it is found in our brain cell membrane. By contrast, the abnormally deformed prion protein is poisonous for the brain cells. Adriano Aguzzi, Professor of Neuropathology at the University of Zurich and University Hospital Zurich, has spent many years exploring why this deformation is poisonous. Aguzzi’s team has now discovered that the prion protein has a kind of «switch» that controls its toxicity. This switch covers a tiny area on the surface of the protein. If another molecule, for example an antibody, touches this switch, a lethal mechanism is triggered that can lead to very fast cell death.
Flexible tail induces cell death
In the current edition of «Nature», the scientists demonstrate that the prion protein molecule comprises two functionally distinct parts: a globular domain, which is tethered to the cell membrane, and a long and unstructured tail. Under normal conditions, this tail is very important in order to maintain the functioning of nerve cells. By contrast, in the case of a prion infection the pathogenic prion protein interacts with the globular part and the tail causes cell death – this is the hypothesis put forward by the researchers.
Aguzzi and his team tested this by generating mimetic antibodies in tissue sections from the cerebellum of mice which have a similar toxicity to that of a prion infection. The researchers found that these antibodies tripped the switch of the prion protein. «Prion proteins with a trimmed version of the flexible tail can, however, no longer damage the brain cells, even if their switch has been recognized by antibodies», explains Adriano Aguzzi. «This flexible tail is responsible for causing cell death.» If the tail is bound and made inaccessible using a further antibody, activation of the switch can likewise no longer trigger cell death.
«Our discovery has far-reaching consequences for understanding prion diseases», says Aguzzi. The findings reveal that only those antibodies that target the prion protein tail are suitable for use as potential drugs. By contrast, antibodies that trip the switch of the prion are very harmful and dangerous.
Scientists Identify First Potentially Effective Therapy for Human Prion Disease
Human diseases caused by misfolded proteins known as prions are some of most rare yet terrifying on the planet—incurable with disturbing symptoms that include dementia, personality shifts, hallucinations and coordination problems. The most well-known of these is Creutzfeldt-Jakob disease, which can be described as the naturally occurring human equivalent of mad cow disease.
Now, scientists from the Florida campus of The Scripps Research Institute (TSRI) have for the first time identified a pair of drugs already approved for human use that show anti-prion activity and, for one of them, great promise in treating these universally fatal disorders.
The study, led by TSRI Professor Corinne Lasmézas and performed in collaboration with TSRI Professor Emeritus Charles Weissmann and Director of Lead Identification Peter Hodder, was published this week online ahead of print by the journal Proceedings of the National Academy of Sciences.
The new study used an innovative high-throughput screening technique to uncover compounds that decrease the amount of the normal form of the prion protein (PrP, which becomes distorted by the disease) at the cell surface. The scientists found two compounds that reduced PrP on cell surfaces by approximately 70 percent in the screening and follow up tests.
The two compounds are already marketed as the drugs tacrolimus and astemizole.
Tacrolimus is an immune suppressant widely used in organ transplantation. Tacrolimus could prove problematic as an anti-prion drug, however, because of issues including possible neurotoxicity.
However, astemizole is an antihistamine that has potential for use as an anti-prion drug. While withdrawn voluntarily from the U.S. over-the-counter market in 1999 because of rare cardiac arrhythmias when used in high doses, it has been available in generic form in more than 30 countries and has a well-established safety profile. Astemizole not only crosses the blood-brain barrier, but works effectively at a relatively low concentration.
Lasmézas noted that astemizole appears to stimulate autophagy, the process by which cells eliminate unwanted components. “Autophagy is involved in several protein misfolding neurodegenerative diseases such as Alzheimer’s, Parkinson’s and Huntington’s diseases,” she said. “So future studies on the mode of action of astemizole may uncover potentially new therapeutic targets for prion diseases and similar disorders.”
The study noted that eliminating cell surface PrP expression could also be a potentially new approach to treat Alzheimer’s disease, which is characterized by the build-up of amyloid β plaque in the brain. PrP is a cell surface receptor for Aβ peptides and helps mediate a number of critical deleterious processes in animal models of the disease.
(Source: scripps.edu)
The good side of the prion: A molecule that is not only dangerous, but can help the brain grow
A few years ago it was found that certain proteins, the prions, when defective are dangerous, as they are involved in neurodegenerative syndromes such as the Creutzfeldt-Jakob and the Alzheimer diseases. But now research is showing their good side, too: when performing well, prions may be crucial in the development of the brain during childhood, as observed by a study carried out by a team of neuroscientists at Trieste’s SISSA which appeared yesterday in the Journal of Neuroscience.
Doctor Jekyll and Mr. Hyde: the metaphor of the good man who hides an evil side suits well the prion (PrPC in its physiological cellular form), a protein which abounds in our brain. Unlike Doctor Jekyll, the prion was at first considered for its upsetting properties: if the molecule abnormally folds over itself it unfortunately plays a crucial role in neurodegenerative processes that lead to dreadful syndromes such as the mad cow disease.
Prions, however, in their normal form abound in synapses, the contact points where the nervous signal is passed from a neuron to the next. Such protein relatively abounds in the brain of very young children, and this is the reason why scientists have assumed it may play a role in the
nervous system development, and in particular in neurogenesis, in the development of new synaptic connections and in plasticity.
More in detail
Maddalena Caiati, Victoria Safiulina, Sudhir Sivakumaran, Giuseppe Legname, Enrico Cherubini, all researchers at SISSA, and Giorgia Fattorini of the Università Politecnica delle Marche have verified at the molecular level the effects of PrPC on the cell plasticity of the hippocampus, a brain structure which has important functions related to memory. Maddalena Caiati and her colleagues have demonstrated that PrPC controls synaptic plasticity (the growth capacity of the nervous tissue) through a transduction pathway which involves also another protein, the protein kinase A enzyme (PKA). The recently published research is only the starting point. As for the future, it will be interesting to get a closer look at the role played by the prion protein in the development of neuronal circuits both under physiological and pathologic conditions in neurodegenerative diseases.
A simple blood test for Creutzfeldt-Jakob Disease and Mad Cow disease is a step closer, following a breakthrough by medical researchers at the University of Melbourne.
Using newly available genetic sequencing scientists discovered cells infected with prions (the infectious agent responsible for these diseases) release particles which contain easily recognized ‘signature genes’.
Associate Professor Andrew Hill — from the Department of Biochemistry and Molecular Biology at the Bio21 Institute — said these particles travel in the blood stream, making a diagnostic blood test a possibility.
“This might provide a way to screen people who have spent time in the UK, who currently face restrictions on their ability to donate blood,” he said.
“With a simple blood test nurses could deem a prospective donor’s blood as healthy, with the potential to significantly boost critical blood stocks.”
Mad Cow disease was linked to the deaths of nearly 200 people in Great Britain who consumed meat from infected animals in the late 1980s.
Since 2000, the Australia Red Cross Blood Service has not accepted blood from anybody who lived in the UK for more than six months between 1980 and 1996, or who received a blood transfusion in the UK after 1980.
(Photo by Peter Cade via Getty Images)