Prion science and its unsung heroes.

My first encounter with prion diseases dates to 1986. As a clinical resident in neuropathology, I was tasked with performing autopsies of patients who died of mysterious brain diseases. In his early 60s, my patient had developed a form of dementia that progressed at a terrifyingly rapid pace and eventually led to his death. I sampled the patient's brain and processed it for histological examination. The microscope revealed an eerie landscape of destruction. All that was left in the patient's cortex were astrocytes and microglia, and the few remaining neurons showed extensive vacuolation of their bodies and processes. Such blazing destruction of the brain was indicative of just one diagnosis: Creutzfeldt-Jakob disease, a spongiform encephalopathy caused by enigmatic infectious agents called prions.

Human transmissible spongiform encephalopathies: historic view.

The first of several pivotal moments leading to current understanding of human transmissible spongiform encephalopathies (TSEs) occurred in 1959 when veterinary pathologist W.J. Hadlow first recognized several similarities between scrapie-a slow infection of sheep caused by an unusual infectious agent-and kuru, a fatal exotic neurodegenerative disease affecting only people of a single language group in the remote mountainous interior of New Guinea, described two years earlier by D.C. Gajdusek and V. Zigas. Based on the knowledge of scrapie, Gajdusek, C.J. Gibbs, Jr., and M.P. Alpers soon initiated efforts to transmit kuru by inoculating kuru brain tissue into non-human primates, that-although requiring several years-ultimately proved successful. In the same year that Hadlow first proposed that kuru and scrapie might have similar etiology, I. Klatzo noted that kuru's histopathology resembled that of Creutzfeldt-Jakob disease (CJD), another progressive fatal neurodegenerative disease of unknown etiology that A.M. Jakob had first described in 1921. Gajdusek and colleagues went on to demonstrate that not only the more common sporadic form of CJD but also familial CJD and a generally similar familial brain disease (Gerstmann-Sträussler-Scheinker syndrome) were also transmissible, first to non-human primates and later to other animals. (Other investigators later transmitted an even rarer brain disease, fatal familial insomnia, to animals.) Iatrogenic CJD (spread by human pituitary-derived hormones and tissue grafts) was also transmitted to animals. Much later, in 1996, a new variant of CJD was attributed to human infection with the agent of bovine spongiform encephalopathy; vCJD itself caused an iatrogenic TSE spread by blood transfusion (and probably by a human-plasma-derived clotting factor). Starting in the 1930s, the scrapie agent was found to have a unique constellation of physical properties (marked resistance to inactivation by chemicals, heat and radiation), eventually interpreted as suggesting that it might be an unconventional self-replicating pathogen based on protein and containing no nucleic acid. The work of S.B. Prusiner led to the recognition in the early 1980s that a misfolded form of a ubiquitous normal host protein was usually if not always detectable in tissues containing TSE agents, greatly facilitating the diagnosis and TSEs and understanding their pathogenesis. Prusiner proposed that the TSE agent was likely to be composed partly if not entirely of the abnormal protein, for which he coined the term "prion" protein and "prion" for the agent. Expression of the prion protein by animals-while not essential for life-was later found to be obligatory to infect them with TSEs, and a variety of mutations in the protein clearly tracked with TSEs in families, explaining the autosomal dominant pattern of disease and confirming a central role for the protein in pathogenesis. Prusiner's terminology and the prion hypothesis came to be widely though not universally accepted. A popular corollary proposal, that prions arise by spontaneous misfolding of normal prion protein leading to sporadic cases of CJD, BSE, and scrapie, is more problematic and may serve to discourage continued search for environmental sources of exposure to TSE agents.

Fatal familial insomnia and sporadic fatal insomnia.

Fatal familial insomnia (FFI) and sporadic fatal insomnia (sFI), or thalamic form of sporadic Creutzfeldt-Jakob disease MM2 (sCJDMM2T), are prion diseases originally named and characterized in 1992 and 1999, respectively. FFI is genetically determined and linked to a D178N mutation coupled with the M129 genotype in the prion protein gene (PRNP) at chromosome 20. sFI is a phenocopy of FFI and likely its sporadic form. Both diseases are primarily characterized by progressive sleep impairment, disturbances of autonomic nervous system, and motor signs associated with severe loss of nerve cells in medial thalamic nuclei. Both diseases harbor an abnormal disease-associated prion protein isoform, resistant to proteases with relative mass of 19 kDa identified as resPrPTSE type 2. To date at least 70 kindreds affected by FFI with 198 members and 18 unrelated carriers along with 25 typical cases of sFI have been published. The D178N-129M mutation is thought to cause FFI by destabilizing the mutated prion protein and facilitating its conversion to PrPTSE. The thalamus is the brain region first affected. A similar mechanism triggered spontaneously may underlie sFI.

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Human prion diseases: surgical lessons learned from iatrogenic prion transmission.

The human prion diseases, or transmissible spongiform encephalopathies, have captivated our imaginations since their discovery in the Fore linguistic group in Papua New Guinea in the 1950s. The mysterious and poorly understood "infectious protein" has become somewhat of a household name in many regions across the globe. From bovine spongiform encephalopathy (BSE), commonly identified as mad cow disease, to endocannibalism, media outlets have capitalized on these devastatingly fatal neurological conditions. Interestingly, since their discovery, there have been more than 492 incidents of iatrogenic transmission of prion diseases, largely resulting from prion-contaminated growth hormone and dura mater grafts. Although fewer than 9 cases of probable iatrogenic neurosurgical cases of Creutzfeldt-Jakob disease (CJD) have been reported worldwide, the likelihood of some missed cases and the potential for prion transmission by neurosurgery create considerable concern. Laboratory studies indicate that standard decontamination and sterilization procedures may be insufficient to completely remove infectivity from prion-contaminated instruments. In this unfortunate event, the instruments may transmit the prion disease to others. Much caution therefore should be taken in the absence of strong evidence against the presence of a prion disease in a neurosurgical patient. While the Centers for Disease Control and Prevention (CDC) and World Health Organization (WHO) have devised risk assessment and decontamination protocols for the prevention of iatrogenic transmission of the prion diseases, incidents of possible exposure to prions have unfortunately occurred in the United States. In this article, the authors outline the historical discoveries that led from kuru to the identification and isolation of the pathological prion proteins in addition to providing a brief description of human prion diseases and iatrogenic forms of CJD, a brief history of prion disease nosocomial transmission, and a summary of the CDC and WHO guidelines for prevention of prion disease transmission and decontamination of prion-contaminated neurosurgical instruments.

A brief history of prions.

Proteins were described as distinct biological molecules and their significance in cellular processes was recognized as early as the 18th century. At the same time, Spanish shepherds observed a disease that compelled their Merino sheep to pathologically scrape against fences, a defining clinical sign that led to the disease being named scrapie. In the late 19th century, Robert Koch published his postulates for defining causative agents of disease. In the early 20th century, pathologists Creutzfeldt and Jakob described a neurodegenerative disease that would later be included with scrapie into a group of diseases known as transmissible spongiform encephalopathies (TSEs). Later that century, mounting evidence compelled a handful of scientists to betray the prevailing biological dogma governing pathogen replication that Watson and Crick so convincingly explained by cracking the genetic code just two decades earlier. Because TSEs seemed to defy these new rules, J.S. Griffith theorized mechanisms by which a pathogenic protein could encipher its own replication blueprint without a genetic code. Stanley Prusiner called this proteinaceous infectious pathogen a prion. Here we offer a concise account of the discovery of prions, the causative agent of TSEs, in the wider context of protein biochemistry and infectious disease. We highlight the discovery of prions in yeast and discuss the implication of prions as epigenomic carriers of biological and pathological information. We also consider expanding the prion hypothesis to include other proteins whose alternate isoforms confer new biological or pathological properties.

[Doctor Francoise Cathala and history of prions diseases]. / Le docteur Francoise Cathala Pagesy et l'histoire des maladies à prions.

Doctor Françoise Cathala Pagesy, MD, MS, born on July 7, 1921 in Paris, passed away peacefully at home on November 5, 2012. Unconventional, passionate and enthusiastic neurologist and virologist, she devoted her life to research on latent and slow viral infections, specializing mainly on unconventional transmissible agents or prions. As a research member of Inserm (French Institute for Medical Research), she soon joined the team of Carlton Gajdusek (the NINCDS - National Institute of Nervous Central System and Stroke - of NIH), who first demonstrated the transmissibility of kuru and Creutzfeldt-Jakob disease to monkeys. When she came back to Paris, where she was followed by one of NIH members, Paul Brown, she joined the Centre de Recherches du Service de Santé des Armées (Army Health Research Center), in Percy-Clamart, where she found the experimental design and the attentive help needed for her research, which appeared heretical to many French virologists, including some authorities. A large number of research programs were set up with numerous collaborations involving CEA (Center for Atomic Energy) and other institutions in Paris and Marseilles on epidemiology, results of tissue inoculation, electrophysiology and neuropathology of human and animal prions diseases, and resistance of the infectious agent. International symposia were set up, where met, in the Val-de-Grâce hospital in Paris, the research community on "slow viral diseases". Stanley Prusiner introduced the concept - then badly accepted and still in evolution - of prion, a protein only infectious agent. Before retiring from Inserm, Françoise Cathala predicted and was involved in some of the huge sanitary crises in France. These were, first, Creutzfeldt-Jakob disease from contaminated growth hormone extracted from cadavers, which led parents to instigate legal procedure - a quite unusual practice in France. The second was Mad cow disease in the United Kingdom then in France, followed by new variant of Creutzfeldt-Jakob human epidemics, paradigmatic food safety crisis bringing together the poles of production (beef and meat-and-bone meal) and consumption, and leading to an unexpected social bang. Through Françoise Cathala exemplary life, the history of French, and more generally of worldwide prions diseases is dealt with.

Historical overview of prion diseases: a view from afar.

The transmissible spongiform encephalopathies (TSEs), or prion diseases, are a group of neurodegenerative disorders which include kuru, Creutzfeldt-Jakob disease (CJD), Gerstmann-Sträussler-Scheinker (GSS) syndrome, and fatal familial insomnia in men, natural scrapie in sheep, goats and mufflons, transmissible mink encephalopathy in ranch-reared mink, chronic wasting disease of mule deer and elk, bovine spongiform encephalopathy or "mad cow disease" and its analogues in several exotic species of antelopes and wild felids in zoological gardens, and feline spongiform encephalopathy in domestic cats. This short review summarizes the history of the research to find the nature of the scrapie agent, especially as I have witnessed it unfolding before my eyes. I review the historical background of TSEs starting from the first description of scrapie in 1732. In 1957, the first prion disease in humans, kuru was described and its transmissibility was demonstrated in 1965 by seminal work of Gajdusek, Gibbs and colleagues, followed by transmission of CJD and then, GSS. In 1982, Stanley B. Prusiner formulated "prion hypothesis" which has dominated the field for the last 30 years. This theory had been recently extended to cover other neurodegenerations which are caused by misfolded proteins; these disease are called prionoids.

Koch's postulates, carnivorous cows, and tuberculosis today.

With Koch's announcement in 1882 of his work with the tubercle bacillus, his famous postulates launched the rational world of infectious disease and an abrupt social change--strict patient isolation. The postulates, so successful at their inception, soon began to show some problems, particularly with cholera, which clearly violated some of Koch's requirements. Subsequent studies of other diseases and the discovery of entirely new ones have so altered and expanded the original postulates that they now are little but a precious touch of history. The present additions and replacements of the original concepts are skillful changes that several authors have devised to introduce new order into understanding complex viral and prion diseases. In 1988, this knowledge, with the totally rational response of the British population and its cattle industry, was critical in promptly blocking the threatened epidemic of human prion disease. In contrast, the recent upsurge of tuberculosis (TB) in the worldwide AIDS epidemic in developing countries, and the sudden increase in metabolic syndrome in wealthy ones, suggests the need for focused sociobiologic research seeking ways to affect the damaging lifestyle behavior of many less educated populations in both settings. The world awaits an equivalent of Koch's Postulates in sociobiology to explain and possibly avert large self-destructive behaviors.

Iatrogenic concerns of the twentieth century: post-vaccinal encephalitis and spongiform encephalopathy.

Throughout the twentieth century, iatrogenic disease constituted an enduring problem in western medical discourse and practice. A survey of the medical literature, investigative reports, and archival material indicates that iatrogenic concerns persisted throughout the century. Two groups of case studies are presented: one associated with post-vaccinal encephalitis; the other, with the iatrogenically transmitted spongiform encephalopathies, scrapie and Creutzfeldt-Jakob disease. Kuru, a similar disease investigated in New Guinea--but which is thought to be neither iatrogenically caused nor transmitted--is also discussed to speculate on whether an iatrogenic lens might be a valuable tool with which to re-view its mode of transmission.

[History of 50 years of prion disease research].

The history of the research of the prion disease is consolidated in 50 years after the Japanese neurology association starts. It was proven that it was an infectious disease from kuru that was a local disease of New Guinea, explained how CJD, the scariest disease for a neurologist, had come to be called a prion disease, and even a newly emerging prion disease referred in the future.

[From the Scrapie syndrome of sheep and goat to the mad cow disease - the history of the discovery of prion].

Since the discovery of Scrapie Syndrome in sheep and goats in 1730, there emerged a series of diseases such as Creutzfeldt-Jakob disease, kuru disease and mad cow disease etc. In the research of kuru disease, the American scientist D. Carlteton Gajdusek found a new virus without the characteristic of DNA and RNA, which was awarded the Nobel Prize in physiology in 1976. Since then another American scientist, Stanley B. Prusiner, found a new virus-prion, taking protein as the genetic medium, which was awarded the Nobel prize in physiology and medicine in 1997. The discovery of prion is a great landmark in the research of life science, which laid a theoretical foundation for people to conquer a series of diseases such as Scrapie syndrome in sheep and goats, Creutzfeldt-Jakob disease, kuru disease and mad cow disease etc.

An historical perspective on efforts to treat transmissible spongiform encephalopathy.

Efforts to treat transmissible spongiform encephalopathy (TSE) date back to the middle of the 20(th) century. Early studies were colored by the belief that TSE was caused by a 'slow' or 'unconventional' virus, and a variety of anti-infective agents, together with scores of drugs drawn at random from other categories, predictably failed to provide any benefit, apart from polyanionic compounds and polyene antibiotics that prolonged the incubation period of disease in experimental animals. With the discovery in the 1980's that TSE apparently results from the malformation of a normal host protein, attempts at treatment could at last be rationally focused, and can be broadly categorized as genetic, immunologic, and pharmacologic. Genetic 'neutralization' of the pathogen has shown excellent results in experimental animals but is unlikely to be useful until the same kind of engineering can be effectively applied to humans. Immunologic methods to accomplish the same result have also shown some success in animals, but forays into the pharmacologic realm have been generally disappointing. Most reported 'successes' have been limited to prolonged incubation periods, and even then only when the treatment was begun at or near the time of infection, which is not known in sporadic or familial human disease. However, a few methods using the more rigorous model of treatment nearer the onset of symptomatic disease have begun to yield promising results that, if coupled with a practical screening test for pre-clinical infection, would be the optimal strategy for prevention or cure.