Thursday, January 5, 2012

Ten years of BSE surveillance in Italy: Neuropathological findings in clinically suspected cases

doi:10.1016/j.rvsc.2011.10.008 | How to Cite or Link Using DOI


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Ten years of BSE surveillance in Italy: Neuropathological findings in clinically suspected cases


B. Iulinia, C. Maurellaa, M.D. Pintorea, E. Vallino Costassaa, D. Corbellinia, C. Porcarioa, A. Pautassoa, C. Salatab, D. Gelmettic, T. Avanzatoa, G. Palùb, A. D’Angelod, M. Caramellia, C. Casalonea, ,


Purchase


a


Reference Center for Transmissible Spongiform Encephalopathy (CEA), Istituto Zooprofilattico Sperimentale of Piemonte, Liguria and Valle D’Aosta, Italy


b


Department of Histology, Microbiology and Medical Biotechnologies, University of Padova, Italy


c


Istituto Zooprofilattico Sperimentale of Lombardia and Emilia Romagna, Italy


d


Department of Animal Pathology, University of Turin, Italy


Received 20 June 2011; Accepted 16 October 2011. Available online 13 November 2011.


Abstract


Between 2001 and 2010, 244 clinically suspected cases of bovine spongiform encephalopathy (BSE) were reported in Italy. This report summarizes the neuropathological findings in cattle displaying clinical signs consistent with a diagnosis of BSE. All animal specimens were submitted for confirmatory testing; samples testing negative underwent neuropathological examination to establish the differential diagnosis. Immunohistochemistry for scrapie prion protein (PrPSc) at the level of frontal cortex was carried out to exclude atypical BSE.


Neuropathological changes were detected in 34.9% of cases; no histological lesions were found in 52.3% of subjects; 12.8% of samples were found unsuitable for analysis. BSE was detected in one case, but no cases of atypical BSE were observed.


This study identified the diseases most commonly encountered in the differential diagnosis of BSE; furthermore, it demonstrated that the surveillance system is necessary for monitoring neuropathological disease in cattle and for the detection of BSE cases.


Keywords: Bovine; Brain; BSE; Neuropathology; Immunohistochemistry; Surveillance







"BSE was detected in one case, but no cases of atypical BSE were observed."



i don't understand this statement ???



atypical BSE has been detected and confirmed in Italy.




please see ;




We recently reported two Italian atypical cases with a PrPTSE type identical to BSE-L, pathologically characterized by PrP amyloid plaques and known as bovine amyloidotic spongiform encephalopathy (BASE).








The L-type has been found in cattle in Italy (10), Japan (11), Germany (12) and Belgium (13). So far, the H-type has been described in cattle from France (14), Germany (12) and the United States (15). The U.S. cases were animals born and raised in the U.S. (Texas, Alabama).








Identification of a second bovine amyloidotic spongiform encephalopathy: Molecular similarities with sporadic Creutzfeldt-Jakob disease


Cristina Casalone*,†, Gianluigi Zanusso†,‡, Pierluigi Acutis*, Sergio Ferrari‡, Lorenzo Capucci§, Fabrizio Tagliavini¶, Salvatore Monaco‡,?, and Maria Caramelli*


+ Author Affiliations


*Centro di Referenza Nazionale per le Encefalopatie Animali, Istituto Zooprofilattico Sperimentale del Piemonte, Liguria e Valle d'Aosta, Via Bologna, 148, 10195 Turin, Italy; ‡Department of Neurological and Visual Science, Section of Clinical Neurology, Policlinico G.B. Rossi, Piazzale L.A. Scuro, 10, 37134 Verona, Italy; §Istituto Zooprofilattico Sperimentale della Lombardia ed Emilia Romagna, Via Bianchi, 9, 25124 Brescia, Italy; and ¶Istituto Nazionale Neurologico ”Carlo Besta,” Via Celoria 11, 20133 Milan, Italy


Edited by Stanley B. Prusiner, University of California, San Francisco, CA, and approved December 23, 2003 (received for review September 9, 2003)


Next Section Abstract


Transmissible spongiform encephalopathies (TSEs), or prion diseases, are mammalian neurodegenerative disorders characterized by a posttranslational conversion and brain accumulation of an insoluble, protease-resistant isoform (PrPSc) of the host-encoded cellular prion protein (PrPC). Human and animal TSE agents exist as different phenotypes that can be biochemically differentiated on the basis of the molecular mass of the protease-resistant PrPSc fragments and the degree of glycosylation. Epidemiological, molecular, and transmission studies strongly suggest that the single strain of agent responsible for bovine spongiform encephalopathy (BSE) has infected humans, causing variant Creutzfeldt-Jakob disease. The unprecedented biological properties of the BSE agent, which circumvents the so-called ”species barrier” between cattle and humans and adapts to different mammalian species, has raised considerable concern for human health. To date, it is unknown whether more than one strain might be responsible for cattle TSE or whether the BSE agent undergoes phenotypic variation after natural transmission. Here we provide evidence of a second cattle TSE. The disorder was pathologically characterized by the presence of PrP-immunopositive amyloid plaques, as opposed to the lack of amyloid deposition in typical BSE cases, and by a different pattern of regional distribution and topology of brain PrPSc accumulation. In addition, Western blot analysis showed a PrPSc type with predominance of the low molecular mass glycoform and a protease-resistant fragment of lower molecular mass than BSE-PrPSc. Strikingly, the molecular signature of this previously undescribed bovine PrPSc was similar to that encountered in a distinct subtype of sporadic Creutzfeldt-Jakob disease.


The transmissible spongiform encephalopathies (TSEs), or prion diseases (1), encompass a group of progressive neurodegenerative disorders, including Creutzfeldt-Jakob disease (CJD) in humans, scrapie in sheep, and bovine spongiform encephalopathy (BSE) (1-4). These disorders are characterized by brain deposition of an insoluble, protease-resistant isoform of the host-encoded cellular prion protein (PrPC), named PrPSc (1, 4, 5) In different TSE phenotypes, PrPSc exhibits disease-specific properties, including distinctive cleavage sites after proteolytic treatment, ratio of glycoforms, and deposition patterns, all features useful in providing a means of strain identification (6-10).


Although not contagious, TSEs are potentially infective, and in humans may present as sporadic, inherited, and acquired diseases. Human-to-human transmission of TSE is well documented and has occurred either through oral or mucocutaneous route of infection, as in kuru (11), or after medical and surgical procedures, as in iatrogenic CJD (12). Recently, animal-to-human transmission has also occurred. Epidemiological (13), experimental transmission (14), and biochemical PrPSc typing (8) have provided strong evidence that the single prion strain responsible for BSE has infected humans, causing variant CJD (vCJD), in addition to several animal species. In BSE and BSE-related disorders, including vCJD, the molecular typing of disease-associated PrPSc shows identical PrP fragment sizes and predominance of the high molecular mass glycoform both in natural hosts and in experimentally inoculated animals. To date, at variance with CJD in humans and scrapie in sheep, only a single strain and a single PrPSc type have been detected in BSE.


The spreading of the BSE agent across mammalian species barriers has aroused considerable concern for the following reasons: (i) the possible existence of new or previously unrecognized cattle TSE strains, potentially pathogenic for humans; and (ii) the occurrence of phenotypic variation of the BSE strain, with propagation of a new agent encoding distinctive molecular and biological properties.


In Italy, an active surveillance system on BSE in cattle was started in January 2001, and by August 2003 a total of 103 BSE cases had been diagnosed of 1,638,275 statutory tested brainstem samples. Confirmatory positive results have been obtained in all cases by immunohistochemical and Western immunoblot demonstration of disease-specific protease-resistant PrPSc.


To assess molecular and neuropathological characteristics in Italian BSE cases, we have over the last few months collected whole brains of eight Italian cattle that were PrPSc-positive in Western immunoblots. In two cattle, older than other affected bovines, the PrPSc glycotype was clearly different from the BSE-associated PrPSc molecule, and widespread PrP-amyloid plaques were seen in supratentorial brain regions. Unlike typical BSE, the brainstem was less involved and no PrP deposition was detected in the dorsal nucleus of the vagus nerve. Given the biochemical and pathological similarities with sporadic CJD (sCJD) cases linked to type-2 PrPSc (9) and methionine/valine (M/V) polymorphism at codon 129 in the prion protein gene (PRNP), these findings have prompted ongoing strain typing in inbred mice. Although the present findings dictate caution, here we show that a PrPSc type associated with sCJD and the previously undescribed bovine PrPSc show convergent molecular signatures.



snip...



Phenotypic Similarities Between BASE and sCJD. The transmissibility of CJD brains was initially demonstrated in primates (27), and classification of atypical cases as CJD was based on this property (28). To date, no systematic studies of strain typing in sCJD have been provided, and classification of different subtypes is based on clinical, neuropathological, and molecular features (the polymorphic PRNP codon 129 and the PrPSc glycotype) (8, 9, 15, 19). The importance of molecular PrPSc characterization in assessing the identity of TSE strains is underscored by several studies, showing that the stability of given disease-specific PrPSc types is maintained upon experimental propagation of sCJD, familial CJD, and vCJD isolates in transgenic PrP-humanized mice (8, 29). Similarly, biochemical properties of BSE- and vCJD-associated PrPSc molecules remain stable after passage to mice expressing bovine PrP (30). Recently, however, it has been reported that PrP-humanized mice inoculated with BSE tissues may also propagate a distinctive PrPSc type, with a ”monoglycosylated-dominant” pattern and electrophoretic mobility of the unglycosylated fragment slower than that of vCJD and BSE (31). Strikingly, this PrPSc type shares its molecular properties with the a PrPSc molecule found in classical sCJD. This observation is at variance with the PrPSc type found in M/V2 sCJD cases and in cattle BASE, showing a monoglycosylated-dominant pattern but faster electrophoretic mobility of the protease-resistant fragment as compared with BSE. In addition to molecular properties of PrPSc, BASE and M/V2 sCJD share a distinctive pattern of intracerebral PrP deposition, which occurs as plaque-like and amyloid-kuru plaques. Differences were, however, observed in the regional distribution of PrPSc. While in M/V2 sCJD cases the largest amounts of PrPSc were detected in the cerebellum, brainstem, and striatum, in cattle BASE these areas were less involved and the highest levels of PrPSc were recovered from the thalamus and olfactory regions.


In conclusion, decoding the biochemical PrPSc signature of individual human and animal TSE strains may allow the identification of potential risk factors for human disorders with unknown etiology, such as sCJD. However, although BASE and sCJD share several characteristics, caution is dictated in assessing a link between conditions affecting two different mammalian species, based on convergent biochemical properties of disease-associated PrPSc types. Strains of TSE agents may be better characterized upon passage to transgenic mice. In the interim until this is accomplished, our present findings suggest a strict epidemiological surveillance of cattle TSE and sCJD based on molecular criteria.







Sunday, May 01, 2011


STUDY OF ATYPICAL BSE 2010 Annual Report May 2011







Saturday, June 25, 2011


Transmissibility of BSE-L and Cattle-Adapted TME Prion Strain to Cynomolgus Macaque



"BSE-L in North America may have existed for decades"








Over the next 8-10 weeks, approximately 40% of all the adult mink on the farm died from TME.


snip...


The rancher was a ''dead stock'' feeder using mostly (>95%) downer or dead dairy cattle...





BSE - ATYPICAL LESION DISTRIBUTION (RBSE 92-21367) statutory (obex only) diagnostic criteria CVL 1992


IN CONFIDENCE


The information contained herein should not be disseminated further except on the basis of "NEED TO KNOW".




14th ICID International Scientific Exchange Brochure -


Final Abstract Number: ISE.114


Session: International Scientific Exchange


Transmissible Spongiform encephalopathy (TSE) animal and human TSE in North America update October 2009


T. Singeltary


Bacliff, TX, USA


Background:


An update on atypical BSE and other TSE in North America. Please remember, the typical U.K. c-BSE, the atypical l-BSE (BASE), and h-BSE have all been documented in North America, along with the typical scrapie's, and atypical Nor-98 Scrapie, and to date, 2 different strains of CWD, and also TME. All these TSE in different species have been rendered and fed to food producing animals for humans and animals in North America (TSE in cats and dogs ?), and that the trading of these TSEs via animals and products via the USA and Canada has been immense over the years, decades.


Methods:


12 years independent research of available data


Results:


I propose that the current diagnostic criteria for human TSEs only enhances and helps the spreading of human TSE from the continued belief of the UKBSEnvCJD only theory in 2009. With all the science to date refuting it, to continue to validate this old myth, will only spread this TSE agent through a multitude of potential routes and sources i.e. consumption, medical i.e., surgical, blood, dental, endoscopy, optical, nutritional supplements, cosmetics etc.


Conclusion:


I would like to submit a review of past CJD surveillance in the USA, and the urgent need to make all human TSE in the USA a reportable disease, in every state, of every age group, and to make this mandatory immediately without further delay. The ramifications of not doing so will only allow this agent to spread further in the medical, dental, surgical arena's. Restricting the reporting of CJD and or any human TSE is NOT scientific. Iatrogenic CJD knows NO age group, TSE knows no boundaries. I propose as with Aguzzi, Asante, Collinge, Caughey, Deslys, Dormont, Gibbs, Gajdusek, Ironside, Manuelidis, Marsh, et al and many more, that the world of TSE Transmissible Spongiform Encephalopathy is far from an exact science, but there is enough proven science to date that this myth should be put to rest once and for all, and that we move forward with a new classification for human and animal TSE that would properly identify the infected species, the source species, and then the route.




Monday, May 23, 2011


Atypical Prion Diseases in Humans and Animals 2011


Top Curr Chem (2011)


DOI: 10.1007/128_2011_161


# Springer-Verlag Berlin Heidelberg 2011


Michael A. Tranulis, Sylvie L. Benestad, Thierry Baron, and Hans Kretzschmar


Abstract


Although prion diseases, such as Creutzfeldt-Jakob disease (CJD) in humans and scrapie in sheep, have long been recognized, our understanding of their epidemiology and pathogenesis is still in its early stages. Progress is hampered by the lengthy incubation periods and the lack of effective ways of monitoring and characterizing these agents. Protease-resistant conformers of the prion protein (PrP), known as the "scrapie form" (PrPSc), are used as disease markers, and for taxonomic purposes, in correlation with clinical, pathological, and genetic data. In humans, prion diseases can arise sporadically (sCJD) or genetically (gCJD and others), caused by mutations in the PrP-gene (PRNP), or as a foodborne infection, with the agent of bovine spongiform encephalopathy (BSE) causing variant CJD (vCJD). Person-to-person spread of human prion disease has only been known to occur following cannibalism (kuru disease in Papua New Guinea) or through medical or surgical treatment (iatrogenic CJD, iCJD). In contrast, scrapie in small ruminants and chronic wasting disease (CWD) in cervids behave as infectious diseases within these species. Recently, however, so-called atypical forms of prion diseases have been discovered in sheep (atypical/Nor98 scrapie) and in cattle, BSE-H and BSE-L. These maladies resemble sporadic or genetic human prion diseases and might be their animal equivalents. This hypothesis also raises the significant public health question of possible epidemiological links between these diseases and their counterparts in humans.


M.A. Tranulis (*)


Norwegian School of Veterinary Science, Oslo, Norway




S.L. Benestad


Norwegian Veterinary Institute, Oslo, Norway


T. Baron


Agence Nationale de Se´curite´ Sanitaire, ANSES, Lyon, France


H. Kretzschmar


Ludwig-Maximilians University of Munich, Munich, Germany


Keywords Animal Atypical Atypical/Nor98 scrapie BSE-H BSE-L Human Prion disease Prion strain Prion type




snip...SEE MORE HERE ;




Sunday, June 07, 2009


L-TYPE-BSE, H-TYPE-BSE, C-TYPE-BSE, IBNC-TYPE-BSE, TME, CWD, SCRAPIE, CJD, NORTH AMERICA





Sunday, May 10, 2009


Identification and characterization of bovine spongiform encephalopathy cases diagnosed and NOT diagnosed in the United States




Sunday, December 28, 2008


MAD COW DISEASE USA DECEMBER 28, 2008 an 8 year review of a failed and flawed policy





Wednesday, August 20, 2008


Bovine Spongiform Encephalopathy Mad Cow Disease typical and atypical strains, was there a cover-up ?




Saturday, February 28, 2009


NEW RESULTS ON IDIOPATHIC BRAINSTEM NEURONAL CHROMATOLYSIS


"All of the 15 cattle tested showed that the brains had abnormally accumulated PrP"


2009 SEAC 102/2




Wednesday, July 28, 2010


Atypical prion proteins and IBNC in cattle DEFRA project code SE1796 FOIA Final report




Sunday, September 6, 2009


MAD COW USA 1997 (SEE SECRET VIDEO)








Tuesday, November 08, 2011


Can Mortality Data Provide Reliable Indicators for Creutzfeldt-Jakob Disease Surveillance? A Study in France from 2000 to 2008 Vol. 37, No. 3-4, 2011


Original Paper


Conclusions:These findings raise doubt about the possibility of a reliable CJD surveillance only based on mortality data.






EFSA Journal 2011 The European Response to BSE: A Success Story


This is an interesting editorial about the Mad Cow Disease debacle, and it's ramifications that will continue to play out for decades to come ;


Monday, October 10, 2011


EFSA Journal 2011 The European Response to BSE: A Success Story


snip...


EFSA and the European Centre for Disease Prevention and Control (ECDC) recently delivered a scientific opinion on any possible epidemiological or molecular association between TSEs in animals and humans (EFSA Panel on Biological Hazards (BIOHAZ) and ECDC, 2011). This opinion confirmed Classical BSE prions as the only TSE agents demonstrated to be zoonotic so far but the possibility that a small proportion of human cases so far classified as "sporadic" CJD are of zoonotic origin could not be excluded. Moreover, transmission experiments to non-human primates suggest that some TSE agents in addition to Classical BSE prions in cattle (namely L-type Atypical BSE, Classical BSE in sheep, transmissible mink encephalopathy (TME) and chronic wasting disease (CWD) agents) might have zoonotic potential.


snip...






see follow-up here about North America BSE Mad Cow TSE prion risk factors, and the ever emerging strains of Transmissible Spongiform Encephalopathy in many species here in the USA, including humans ;







Wednesday, August 20, 2008



Bovine Spongiform Encephalopathy Mad Cow Disease typical and atypical strains, was there a cover-up ?




SNIP...



IN CONFIDENCE


This is a highly competitive field and it really will be a pity if we allow many of the key findings to be published by overseas groups while we are unable to pursue our research findings because of this disagreement, which I hope we can make every effort to solve.






SEE ;







COLLINGE THREATENS TO GO TO MEDIA




SEE ;







2. The discovery might indicate the existence of a different strain of BSE from that present in the general epidemic or an unusual response by an individual host.



3. If further atypical lesion distribution cases are revealed in this herd then implications of misdiagnosis of 'negative' cases in other herds may not be insignificant.



snip...



This minute is re-issued with a wider distribution. The information contained herein should NOT be disseminated further except on the basis of ''NEED TO KNOW''.



R Bradley






SEE ;







IN CONFIDENCE


BSE ATYPICAL LESION DISTRIBUTION





SEE ;






1983


BSE CONSULTANT


APPROVAL OF MATERIAL FOR PUBLICATIONS


All material for publication including written works to be published in scientific journals, books, proceedings of scientific meetings, abstracts of verbally delivered papers and the like should be scrutinized for risk to the Ministry before dispatch to the publishers.............


full text;





SEE ;






- 10 -


19. On 18th February, 1987 (YB87/2.18/1.1) I reported to Dr Watson and Dr Shreeve on a further case which we had received from Truro VIC. The brain had shown neuronal vacuolation and in brain extracts there were fibrils that were similar in size and appearance to SAFs from sheep with scrapie. The Virology Department was studying the brain further and considering a transmission study. A few weeks before this, I had discussed the possibility of a transmission study with Michael Dawson, a research officer in the Virology Department and an expert in viral diseases in sheep, and we were considering carefully the safety aspects. In my note I raised the question of whether we should disclose the information we had more widely to the VIS because this may assist in getting any other cases referred to CVL but there was the difficulty that we knew very little about the disorder and would be unable to deal with queries that might be raised.


20. On 23rd February, 1987 (YB87/2.23/1.1) I sent Mr Wells a note asking him to prepare a statement for publication in Vision, the in-house newsheet prepared by the VIS for the SVS, setting out details of what we had discovered. On 24th February, 1987 (YB87/2.25/2.1) Gerald Wells indicated in a note to me that he had discussed the proposed article with Mr Dawson and they both believed that it could be damaging to publish anything at that stage. They believed cases would be referred to CVL in any event because they were unusual and they did not feel "Vision" was an appropriate publication because its confidentiality was questionable and might lead to referrals to veterinary schools rather than CVL. Gerald Wells was also concerned about the resources available in his section to deal with referred cases. I replied (YB87/2.25/2.1) indicating a draft statement was needed by the Director before a decision on publication could be made. Gerald Wells prepared a draft statement (YB87/3.2/2.1) and sent it to me on 2nd March, 1987. In his cover note (YB87/3.2/1.1) he commented that he believed the distribution of any statement about the new disease outside of CVL to be premature because there was so little information available about the new disease. I passed on a copy of Gerald Wells' note to Dr Watson (YB87/3.2/3.1). I discussed the matter of publication with Dr Watson. No decision had been taken to publish any material at that stage and I sent a note to Gerald Wells letting him know the position and confirming that his views and those of Michael Dawson would be taken into account when a decision was taken.


- 11 -


21. In March, 1987 serious consideration was given to possible transmission (e.g. to hamsters) and other experiments (other than the collection of epidemiological data by the VIS and clinicopathology which had been in progress since the first cases were recognised in November, 1986).


22. On 23rd April, 1987 I sent a report (YB87/4.23/1.1) to Dr Watson and Dr Shreeve informing them that nine control brains were being examined for SAFs and a cow which appeared to be affected with BSE had been purchased for observation. The cow had come from the farm where the original cases had developed and had arrived at CVL on 22nd April, 1987.


23. On 15th May, 1987 Dr Watson informed me that the proposed "Vision" draft would be circulated to VICs in England and Wales if it was approved by management. On 22nd May, 1987 I was copied in on a note (YB87/5.22/2.1) from B.M Williams, (who I believe was Head of the VIS at this time but retired shortly after this), to Dr Watson. This confirmed that the draft prepared for publication in Vision was approved but that the final paragraph should be amended to make it clear that knowledge of the new disease should not be communicated to other research institutes or university departments. At a meeting with Dr Watson on 2nd June, 1987 he informed me that no communication should be made with NPU until after the meeting with the CVO on 5th June, 1987 (see my note of 3rd June, 1987 – YB87/6.3/1.1). We needed much more data and information to answer inevitable queries. ...





SEE ;











*This case study accompanies the IRGC report “Risk Governance Deficits: An analysis and illustration of the most common deficits in risk governance”.


The Bovine Spongiform Encephalopathy (BSE) Epidemic in the United Kingdom


By Belinda Cleeland1


SNIP...


A6 Misrepresenting information about risk


From the very beginning of the BSE outbreak, not only was knowledge misrepresented by the British government, but in some cases it was even withheld. For example, after the initial diagnosis of BSE by the SVS in late 1986, there was an embargo placed on the sharing, or making public, of any BSE-related information that ran until mid-1987. Also, up until at least 1990, outside scientists that requested access to BSE data to conduct further studies were denied, despite the fact the improved scientific understanding of the disease had the greatest potential to minimise the impact of the epidemic. Even government scientists within the CVL have acknowledged that there was a culture of suppressing information, to the point that studies revealing damaging evidence (e.g. that there was a causal link between BSE and the new encephalopathy found in cats) were denied publication permission [Ashraf, 2000].


The withholding of such information allowed the government to publicly assert that BSE was just like another version of scrapie – not transmissible to humans – and that there was “clear scientific evidence that British beef is perfectly safe” [UK House of Commons, 1990].2 This was certainly a misrepresentation of the knowledge held at the time, and one that was only possible due to the suppression of some scientific findings and recommendations. Of course, the main reason for this misrepresentation of knowledge was the protection of agricultural and industrial interests – the specific stakeholder favoured in this case was the British beef industry, which stood to lose billions of pounds if a large number of its animals had to be slaughtered, if export bans were put in place, or if costly regulations were implemented.


To protect the interests of the beef industry, the government would assert on many occasions that British beef was safe to eat and that regulatory controls already implemented would prevent any 2 This comment was made by the Agriculture Minister to the House of Commons.


contaminated material from entering the food chain. This was also a misrepresentation of knowledge, as the government was fully aware that their measures were not designed to eliminate exposure, but only to diminish the risk [van Zwanenberg & Millstone, 2002:161].


What’s more, many uncertainties relating to the transmissibility of the disease were either down-played or ignored, resulting in an overstatement of certainty that British beef was completely safe to eat and that BSE was not transmissible to humans. The way uncertainty was dealt with in this case was the result of a number of factors, including the desire to protect specific stakeholder interests.


One crucial factor was the underlying element of risk political culture in the UK that linked the identity of the actor to the consistency of his policy positions. This led to consistency of position being prioritised over accuracy [Dressel, 2000], and resulted in the government insisting on the absence of risk to the population, maintaining this public position despite mounting evidence to the contrary. Although aware of them, policy-makers chose not to overtly acknowledge the levels of uncertainty and the complexity of the risks involved with BSE and its spread because the ramifications of these were too great for the interests they were trying to safeguard.


B1 Responding to early warnings


The incorporation of rendered meat and bone meal into animal feed creates a number of risks related to the transmission, recycling and amplification of pathogens. Such risks were recognised well before the emergence of BSE. In the US in the mid-1970s, concerns that scrapie may be linked to CJD (although there is no evidence that scrapie is transmissible to humans) led to some regulations being placed on the incorporation of sheep or goat carcasses into human and animal foods [van Zwanenberg & Millstone, 2002:158]. In the UK, too, the Royal Commission on Environmental Pollution recommended in 1979 that minimum processing standards be implemented by the rendering industries in order to minimise the potential for disease spread [RCEP, 1979]. The incoming Thatcher government withdrew these proposed regulations, preferring to let industry decide for itself what standards to use. In retrospect, the failure to act at this point to mitigate the general risk of disease transmission may have had a crucial impact on the later outbreak of BSE, given that the disease “probably originated from a novel source in the early 1970s” [BSE Inquiry, 2000b].


Early warnings that BSE might be transmissible to humans were, in fact, observed by scientists and government officials throughout the period from 1986 (the time of first diagnosis in cattle) to 1995 (when vCJD was first observed in humans). Such observations are noted in, for example, the minutes of a meeting of the National Institute for Biological Standards and Control in May 1988, where the probability of transmission of BSE to humans is assessed as more than remote. The diagnosis in 1990 of a domestic cat with a previously unknown spongiform encephalopathy resembling BSE indicated that the disease could infect a wider range of hosts. Responses to such early warnings of potential dangers to human health were either too weak or came too late. This may have been partly a result of an ‘unwillingness to know’ due to the economic harm this knowledge would cause the UK beef industry (related to deficit A6); and partly due to institutional capacities and procedures (related to deficits B5, 9 and 10).







Tuesday, July 28, 2009



MAD COW COVER-UP USA MASKED AS SPORADIC CJD








SEE THE VIDEO NOW AT THE BOTTOM OF THE BLOG BELOW ;








Tuesday, July 14, 2009


U.S. Emergency Bovine Spongiform Encephalopathy Response Plan Summary and BSE Red Book Date: February 14, 2000 at 8:56 am PST


WHERE did we go wrong $$$








MY GOD, HOW MANY CASES GOT INTO THE FOOD CHAIN ??? IATROGENIC THERE FROM ??? ATYPICAL BSE MORE VIRULENT, HOW MANY MORE WILL DIE NEEDLESSLY IN THE YEARS AND DECADES TO COME. ...TSS




Wednesday, January 4, 2012


A Bovine Prion Acquires an Epidemic Bovine Spongiform Encephalopathy Strain-Like Phenotype on Interspecies Transmission



Monday, January 2, 2012
EFSA Minutes of the 6th Meeting of the EFSA Scientific Network on BSE-TSE Brussels, 29-30 November 2011
Saturday, June 25, 2011
Transmissibility of BSE-L and Cattle-Adapted TME Prion Strain to Cynomolgus Macaque
"BSE-L in North America may have existed for decades"
Over the next 8-10 weeks, approximately 40% of all the adult mink on the farm died from TME.
snip...
The rancher was a ''dead stock'' feeder using mostly (>95%) downer or dead dairy cattle...
2011 Monday, September 26, 2011

L-BSE BASE prion and atypical sporadic CJD
Owens, Julie
From: Terry S. Singeltary Sr. [flounder9@verizon.net]
Sent: Monday, July 24, 2006 1:09 PM
To: FSIS RegulationsComments
Subject: [Docket No. FSIS-2006-0011] FSIS Harvard Risk Assessment of Bovine Spongiform Encephalopathy (BSE)
Page 1 of 98
FSIS RFEPLY TO TSS ;
Harvard Risk Assessment of Bovine Spongiform Encephalopathy Update, October 31, 2005 INTRODUCTION The United States Department of Agriculture’s Food Safety and Inspection Service (FSIS) held a public meeting on July 25, 2006 in Washington, D.C. to present findings from the Harvard Risk Assessment of Bovine Spongiform Encephalopathy Update, October 31, 2005 (report and model located on the FSIS website:
Comments on technical aspects of the risk assessment were then submitted to FSIS. Comments were received from Food and Water Watch, Food Animal Concerns Trust (FACT), Farm Sanctuary, R-CALF USA, Linda A Detwiler, and
Terry S. Singeltary. This document provides itemized replies to the public comments received on the 2005 updated Harvard BSE risk assessment. Please bear the following points in mind:
Saturday, June 19, 2010
U.S. DENIED UPGRADED BSE STATUS FROM OIE
Friday, August 20, 2010
USDA: Animal Disease Traceability August 2010
Friday, November 18, 2011
country-of-origin labeling law (COOL) violates U.S. obligations under WTO rules WT/DS384/R WT/DS386/R

Thursday, August 4, 2011


Terry Singeltary Sr. on the Creutzfeldt-Jakob Disease Public Health Crisis, Date aired: 27 Jun 2011 (SEE VIDEO)






2011 Monday, September 26, 2011


L-BSE BASE prion and atypical sporadic CJD

 
 
 


SEE RISE OF SPORADIC CJD YEAR TO YEAR ;

http://www.cjd.ed.ac.uk/figures.htm


 
tss
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Wednesday, January 4, 2012

A Bovine Prion Acquires an Epidemic Bovine Spongiform Encephalopathy Strain-Like Phenotype on Interspecies Transmission

Neurobiology of Disease


A Bovine Prion Acquires an Epidemic Bovine Spongiform Encephalopathy Strain-Like Phenotype on Interspecies Transmission


Vincent Béringue1, Olivier Andréoletti2,*, Annick Le Dur1,*, Rachid Essalmani3, Jean-Luc Vilotte3, Caroline Lacroux2, Fabienne Reine1, Laëtitia Herzog1, Anne-Gaëlle Biacabé4, Thierry Baron4, Maria Caramelli5, Cristina Casalone5, and Hubert Laude1


+ Author Affiliations




1Institut National de la Recherche Agronomique (INRA), Unité de Recherche 892, Virologie Immunologie Moléculaires, F-78350 Jouy-en-Josas, France, 2INRA, Unité Mixte de Recherche 1225, Interactions Hôtes-Agents Pathogènes, Ecole Nationale Vétérinaire, F-31000 Toulouse, France, 3INRA, Unité de Recherche 339, Génétique Biochimique et Cytogénétique, F-78350 Jouy-en-Josas, France, 4Agence Française de Sécurité Sanitaire des Aliments, Unité Agents Transmissibles Non Conventionnels, F-69000 Lyon, France, and 5Instituto Zooprofilattico Sperimentale del Piemonte, Liguria e Valle, d'Aosta, Torino, Italy Correspondence should be addressed to either Hubert Laude or Vincent Béringue, Institut National de la Recherche Agronomique, Unité de Recherche 892, Virologie Immunologie Moléculaires, F-78350 Jouy-en-Josas, France.hubert.laude@jouy.inra.fr or vincent.beringue@jouy.inra.fr ↵*O.A. and A.L. contributed equally to this work.




Abstract


Implementation in Europe of large-scale testing to detect bovine spongiform encephalopathy (BSE)-infected cattle and prevent the transmission of this prion disease to humans has recently led to the discovery of novel types of bovine prions. We characterized atypical isolates called BSE L-type by analyzing their molecular and neuropathological properties during transmission to several mouse lines transgenic for the prion protein (PrP). Unexpectedly, such isolates acquired strain features closely similar to those of BSE-type agents when propagated in mice expressing ovine PrP, although they retained phenotypic traits distinct from BSE in other lines, including bovine PrP mice. These findings further underline the relationship between the crossing of species barrier and prion strain diversification, and, although the origin of the epidemic BSE agent has only been speculative until now, they provide new insight into the nature of the events that could have led to the appearance of this agent.




bovine prion BSE atypical BSE strain evolution degeneration transgenic




snip...




Discussion We examined the strain behavior of a class of cattle prion isolates newly identified by their atypical PrPres signature compared with the classical BSE agent (Casalone et al., 2004; Buschmann et al., 2006), designated BSE-L in the present study. During transmission to transgenic mice, the different isolates analyzed shared identical molecular and biological features, supporting the view that a unique infectious agent is actually involved in the cases named L-type BSE and BASE, depending on the authors (see Introduction). The main finding emerging from this study is that the BSE-L agent, although displaying phenotypic traits distinct from those of BSE and BSE-related agents on the other transgenic mouse lines studied, acquired a BSE-like strain phenotype during transmission to mice expressing ovine PrP.


When serially transmitted to mice expressing the same PrP sequence as the natural host (tgBov), BSE-L (four cases) and BSE (three cases) maintained separate, stable phenotypes. Thus, BSE-L isolates showed (1) faster disease transmission than cattle BSE and related agents, as was reported recently for a German case (Buschmann et al., 2006), (2) a distinctive PrPres signature, as in cattle, and (3) distinguishable PrP deposition and vacuolation patterns in the brain. Primary transmission to mouse or human PrP transgenic mice also revealed striking differences between the two agents. Thus, unlike that seen with various sources of BSE or the vCJD agent, BSE-L provoked no overt disease or detectable PrPres accumulation in tga20 mice. Inversely, it induced an early PrPres accumulation in the brain of tgHu mice relative to cattle BSE, with either agent retaining its distinctive PrPres profile. A worrying implication of this latter result is that the BSE-L agent might be transmissible to and possibly more virulent in humans than classical BSE, an issue that deserves to be investigated further.


In contrast, the BSE-L agent appeared to undergo a strain phenotype shift during transmission to tgOv mice, despite an incubation period during primary inoculation ( 400 d) much shorter than with cattle BSE ( 700 d) or BSE-H ( 600 d) (Beringue et al., 2006), suggesting a lower transmission barrier from cattle to tgOv for BSE-L. Surprisingly, this novel strain phenotype appeared very similar to that of cattle BSE and related agents propagated onto the same mice, according to various criteria. First, the survival times observed after stabilization on tgOv differed by 5% at most between BSE-L and BSE-type agents, which is unlikely to be significant. Second, the spatial distribution of PrPres in the brain showed only a few, minor differences, although being clearly distinct from the patterns observed with several classes of transmissible spongiform encephalopathy (TSE) agents characterized on these mice, including the BSE-H agent (Le Dur et al., 2005; Beringue et al., 2006) (our unpublished data). Third, the vacuolation profiles observed from the second passage on, once the spongiform changes became substantial, essentially overlapped. Fourth, the PrPres molecular profiles of BSE-L and BSE agents on tgOv mice were indistinguishable.


The available typing methods, relying on the comparison of neuropathological features or a PrPres signature (Fraser and Dickinson, 1968; Hecker et al., 1992), arguably have inherent limitations and may be considered of higher value in differentiating two strains than in looking for a potential strain identity. Another issue is the number and the diversity of isolates propagated on the recipient host. In this regard, it is worth emphasizing that 136 prion infectious sources from various species, including 100 natural sheep or goat scrapie isolates, have been transmitted successfully to tgOv mice to date (supplemental Table S1, available at www.jneurosci.org as supplemental material). Remarkably, a PrPres profile with unglycosylated species of intermediate molecular size ( 20 kDa) and prominent diglycoforms has been uniquely and consistently observed with cattle BSE or BSE-related agents, until BSE-L isolates were analyzed. All other sources generated unglycosylated species with either higher or lower (e.g., CH1641 scrapie isolate) mobility (Vilotte et al., 2001; Le Dur et al., 2005; Beringue et al., 2006). Therefore, the observed phenotypic convergence between BSE-L and BSE during transmission on tgOv mice appears as an uncommon event, so far involving only these two strains, both of bovine origin.


Our findings may represent a novel, striking example of the evolutionary potential of prion agents during transmission to a foreign host, which can promote strain shift and emergence of unprecedented properties in a yet unpredictable manner (Kimberlin et al., 1987; Scott et al., 1997; Bartz et al., 2000; Wadsworth et al., 2004). It is unclear in the present state of our investigations which type of mechanism, selection or de novo emergence, may account for the apparent conversion of BSE-L toward the classical BSE strain. Preferential selection in these mice of a classical-type BSE agent that would preexist as a minor component in the brain tissue of BSE-L-infected cattle is one possibility. Indeed, recent observations have questioned the strain homogeneity of the agent present in cattle BSE infectious sources. Thus, transmission of BSE isolates to C57BL and SJL mice expressing the same mouse PrP allele was reported to result in a divergent strain phenotype among the two lines (Asante et al., 2002; Lloyd et al., 2004). Also, biochemical analyses revealed a dual PrPres signature in BSE (and vCJD) brain homogenates (Yull et al., 2006), which may suggest, albeit not exclusively, the presence of a secondary, minor strain component. However, favored propagation of a BSE-like component preexisting in BSE-L-infected brain tissues is unlikely to explain our observation because, as mentioned above, the BSE agent produces much prolonged incubation periods compare with BSE-L in tgOv mice. A still missing piece of information is whether the observed convergence truly reflects a permanent strain shift of the BSE-L agent, because both reversible and irreversible changes have been reported to occur during heterologous transmission of a biologically cloned prion strain (Kimberlin et al., 1987; Scott et al., 1997). Experiments are underway to determine whether the “ovinized” BSE-L agent would retain BSE phenotypic traits during reinoculation to tgBov mice, as we found it to be the case for the ovinized BSE agent. It would also be of interest to learn whether BSE-L would behave similarly on mice expressing an ovine PrP allotype other than Val136Arg154Gln171 as in the present study, because even single amino acid differences in the PrP sequence might be crucial in promoting a strain phenotype shift (Bruce, 2003; Wadsworth et al., 2004).


In conclusion, the findings reported in the present study provide new insight into the nature of the events that could have contributed to the emergence of the BSE epidemic. The various theories currently proposed regarding the origin of the BSE agent invoke two kinds of mechanisms (Colchester and Colchester, 2005; Baron and Biacabe, 2006): an intrinsic cause, i.e., a spontaneously diseased cattle attributable for instance to somatic or germ-line mutation of PrP, or an extrinsic cause, i.e., the infection of cattle by a prion from another species, involving a strain change or not. Our observation is consistent with the view that the epidemic BSE agent could have originated from an endogenous, cattle prion. It also points to the theoretical possibility of a multiple causative event, in which a prion sporadically present in cattle may have “mutated” through passage on an intermediary host such as a sheep.




During the review process of this paper, a study performed on conventional mice has been published that reports converging features of BASE-subpassaged mice toward BSE-inoculated mice (Capobianco et al., 2007), thus strengthening the notion that the BSE-L agent tends to acquire epidemic BSE-like properties during transmission to a heterologous host.




full text ;






Saturday, January 29, 2011


Atypical L-Type Bovine Spongiform Encephalopathy (L-BSE) Transmission to Cynomolgus Macaques, a Non-Human Primate


Jpn. J. Infect. Dis., 64 (1), 81-84, 2011






Friday, December 23, 2011


Oral Transmission of L-type Bovine Spongiform Encephalopathy in Primate Model


Volume 18, Number 1—January 2012 Dispatch






Saturday, June 25, 2011


Transmissibility of BSE-L and Cattle-Adapted TME Prion Strain to Cynomolgus Macaque




”BSE-L IN NORTH AMERICA MAY HAVE EXISTED FOR DECADES”






Sunday, June 26, 2011


Risk Analysis of Low-Dose Prion Exposures in Cynomolgus Macaque






2. The discovery might indicate the existence of a different strain of BSE from that present in the general epidemic or an unusual response by an individual host.


3. If further atypical lesion distribution cases are revealed in this herd then implications of misdiagnosis of 'negative' cases in other herds may not be insignificant.


snip...


This minute is re-issued with a wider distribution. The information contained herein should NOT be disseminated further except on the basis of ''NEED TO KNOW''.


R Bradley




SEE ;






IN CONFIDENCE




BSE ATYPICAL LESION DISTRIBUTION






SEE ;






Over the next 8-10 weeks, approximately 40% of all the adult mink on the farm died from TME.


snip...


The rancher was a ''dead stock'' feeder using mostly (>95%) downer or dead dairy cattle...




Saturday, December 01, 2007
 
Phenotypic Similarity of Transmissible Mink Encephalopathy in Cattle and L-type Bovine Spongiform Encephalopathy in a Mouse Model
 
Volume 13, Number 12–December 2007
 
Research
 
 
 

2010-2011


When L-type BSE was inoculated into ovine transgenic mice and Syrian hamster the resulting molecular fingerprint had changed, either in the first or a subsequent passage, from L-type into C-type BSE. In addition, non-human primates are specifically susceptible for atypical BSE as demonstrated by an approximately 50% shortened incubation time for L-type BSE as compared to C-type. Considering the current scientific information available, it cannot be assumed that these different BSE types pose the same human health risks as C-type BSE or that these risks are mitigated by the same protective measures. This study will contribute to a correct definition of specified risk material (SRM) in atypical BSE. The incumbent of this position will develop new and transfer existing, ultra-sensitive methods for the detection of atypical BSE in tissue of experimentally infected cattle.




Wednesday, July 28, 2010


Atypical prion proteins and IBNC in cattle DEFRA project code SE1796 FOIA Final report




Tuesday, November 02, 2010


BSE - ATYPICAL LESION DISTRIBUTION (RBSE 92-21367) statutory (obex only) diagnostic criteria CVL 1992






Tuesday, July 14, 2009 U.S.


Emergency Bovine Spongiform Encephalopathy Response Plan Summary and BSE Red Book Date: February 14, 2000 at 8:56 am PST WHERE did we go wrong $$$




SEE FULL TEXT OF ALL THIS HERE ;


2009 UPDATE ON ALABAMA AND TEXAS MAD COWS 2005 and 2006






Thursday, December 04, 2008 2:37 PM


"we have found that H-BSE can infect humans."


personal communication with Professor Kong. ...TSS


BSE-H is also transmissible in our humanized Tg mice.


The possibility of more than two atypical BSE strains will be discussed.


Supported by NINDS NS052319, NIA AG14359, and NIH AI 77774.




PLEASE SEE FULL TEXT ;






Thursday, June 23, 2011


Experimental H-type bovine spongiform encephalopathy characterized by plaques and glial- and stellate-type prion protein deposits






LET'S take a closer look at this new prionpathy or prionopathy, and then let's look at the g-h-BSEalabama mad cow. This new prionopathy in humans? the genetic makeup is IDENTICAL to the g-h-BSEalabama mad cow, the only _documented_ mad cow in the world to date like this, ......wait, it get's better. this new prionpathy is killing young and old humans, with LONG DURATION from onset of symptoms to death, and the symptoms are very similar to nvCJD victims, OH, and the plaques are very similar in some cases too, bbbut, it's not related to the g-h-BSEalabama cow, WAIT NOW, it gets even better, the new human prionpathy that they claim is a genetic TSE, has no relation to any gene mutation in that family. daaa, ya think it could be related to that mad cow with the same genetic make-up ??? there were literally tons and tons of banned mad cow protein in Alabama in commerce, and none of it transmitted to cows, and the cows to humans there from ??? r i g h t $$$ ALABAMA MAD COW g-h-BSEalabama In this study, we identified a novel mutation in the bovine prion protein gene (Prnp), called E211K, of a confirmed BSE positive cow from Alabama, United States of America. This mutation is identical to the E200K pathogenic mutation found in humans with a genetic form of CJD. This finding represents the first report of a confirmed case of BSE with a potential pathogenic mutation within the bovine Prnp gene. We hypothesize that the bovine Prnp E211K mutation most likely has caused BSE in "the approximately 10-year-old cow" carrying the E221K mutation.








Saturday, August 14, 2010


BSE Case Associated with Prion Protein Gene Mutation (g-h-BSEalabama) and VPSPr PRIONPATHY (see mad cow feed in COMMERCE IN ALABAMA...TSS)






her healthy calf also carried the mutation (J. A. Richt and S. M. Hall PLoS Pathog. 4, e1000156; 2008).


This raises the possibility that the disease could occasionally be genetic in origin. Indeed, the report of the UK BSE Inquiry in 2000 suggested that the UK epidemic had most likely originated from such a mutation and argued against the scrapierelated assumption. Such rare potential pathogenic PRNP mutations could occur in countries at present considered to be free of BSE, such as Australia and New Zealand. So it is important to maintain strict surveillance for BSE in cattle, with rigorous enforcement of the ruminant feed ban (many countries still feed ruminant proteins to pigs). Removal of specified risk material, such as brain and spinal cord, from cattle at slaughter prevents infected material from entering the human food chain. Routine genetic screening of cattle for PRNP mutations, which is now available, could provide additional data on the risk to the public. Because the point mutation identified in the Alabama animals is identical to that responsible for the commonest type of familial (genetic) CJD in humans, it is possible that the resulting infective prion protein might cross the bovine-human species barrier more easily. Patients with vCJD continue to be identified. The fact that this is happening less often should not lead to relaxation of the controls necessary to prevent future outbreaks. Malcolm A. Ferguson-Smith Cambridge University Department of Veterinary Medicine, Madingley Road, Cambridge CB3 0ES, UK e-mail: maf12@cam.ac.uk Jürgen A. Richt College of Veterinary Medicine, Kansas State University, K224B Mosier Hall, Manhattan, Kansas 66506-5601, USA NATURE|Vol 457|26 February 2009






P.9.21 Molecular characterization of BSE in Canada


Jianmin Yang1, Sandor Dudas2, Catherine Graham2, Markus Czub3, Tim McAllister1, Stefanie Czub1 1Agriculture and Agri-Food Canada Research Centre, Canada; 2National and OIE BSE Reference Laboratory, Canada; 3University of Calgary, Canada


Background: Three BSE types (classical and two atypical) have been identified on the basis of molecular characteristics of the misfolded protein associated with the disease. To date, each of these three types have been detected in Canadian cattle.


Objectives: This study was conducted to further characterize the 16 Canadian BSE cases based on the biochemical properties of there associated PrPres.


Methods: Immuno-reactivity, molecular weight, glycoform profiles and relative proteinase K sensitivity of the PrPres from each of the 16 confirmed Canadian BSE cases was determined using modified Western blot analysis. Results: Fourteen of the 16 Canadian BSE cases were C type, 1 was H type and 1 was L type. The Canadian H and L-type BSE cases exhibited size shifts and changes in glycosylation similar to other atypical BSE cases. PK digestion under mild and stringent conditions revealed a reduced protease resistance of the atypical cases compared to the C-type cases. N terminal- specific antibodies bound to PrPres from H type but not from C or L type. The C-terminal-specific antibodies resulted in a shift in the glycoform profile and detected a fourth band in the Canadian H-type BSE.


Discussion: The C, L and H type BSE cases in Canada exhibit molecular characteristics similar to those described for classical and atypical BSE cases from Europe and Japan. This supports the theory that the importation of BSE contaminated feedstuff is the source of C-type BSE in Canada. *** It also suggests a similar cause or source for atypical BSE in these countries.








Saturday, July 23, 2011


CATTLE HEADS WITH TONSILS, BEEF TONGUES, SPINAL CORD, SPECIFIED RISK MATERIALS (SRM's) AND PRIONS, AKA MAD COW DISEASE






Saturday, November 6, 2010


TAFS1 Position Paper on Position Paper on Relaxation of the Feed Ban in the EU


Berne, 2010 TAFS INTERNATIONAL FORUM FOR TRANSMISSIBLE ANIMAL DISEASES AND FOOD SAFETY a non-profit Swiss Foundation




Archive Number 20101206.4364 Published Date 06-DEC-2010 Subject PRO/AH/EDR>


Prion disease update 2010 (11) PRION DISEASE UPDATE 2010 (11)






October 2009 O.11.3 Infectivity in skeletal muscle of BASE-infected cattle


Silvia Suardi1, Chiara Vimercati1, Fabio Moda1, Ruggerone Margherita1, Ilaria Campagnani1, Guerino Lombardi2, Daniela Gelmetti2, Martin H. Groschup3, Anne Buschmann3, Cristina Casalone4, Maria Caramelli4, Salvatore Monaco5, Gianluigi Zanusso5, Fabrizio Tagliavini1 1Carlo Besta" Neurological Institute,Italy; 2IZS Brescia, Italy; 33FLI Insel Riems, D, Germany; 4CEA-IZS Torino, Italy; 5University of Verona, Italy


Background: BASE is an atypical form of bovine spongiform encephalopathy caused by a prion strain distinct from that of BSE. Upon experimental transmission to cattle, BASE induces a previously unrecognized disease phenotype marked by mental dullness and progressive atrophy of hind limb musculature. Whether affected muscles contain infectivity is unknown. This is a critical issue since the BASE strain is readily transmissible to a variety of hosts including primates, suggesting that humans may be susceptible.


Objectives: To investigate the distribution of infectivity in peripheral tissues of cattle experimentally infected with BASE. Methods: Groups of Tg mice expressing bovine PrP (Tgbov XV, n= 7-15/group) were inoculated both i.c. and i.p. with 10% homogenates of a variety of tissues including brain, spleen, cervical lymph node, kidney and skeletal muscle (m. longissimus dorsi) from cattle intracerebrally infected with BASE. No PrPres was detectable in the peripheral tissues used for inoculation either by immunohistochemistry or Western blot.


Results: Mice inoculated with BASE-brain homogenates showed clinical signs of disease with incubation and survival times of 175±15 and 207±12 days. Five out of seven mice challenged with skeletal muscle developed a similar neurological disorder, with incubation and survival times of 380±11 and 410±12 days. At present (700 days after inoculation) mice challenged with the other peripheral tissues are still healthy. The neuropathological phenotype and PrPres type of the affected mice inoculated either with brain or muscle were indistinguishable and matched those of Tgbov XV mice infected with natural BASE.


Discussion: Our data indicate that the skeletal muscle of cattle experimentally infected with BASE contains significant amount of infectivity, at variance with BSE-affected cattle, raising the issue of intraspecies transmission and the potential risk for humans. Experiments are in progress to assess the presence of infectivity in skeletal muscles of natural BASE.






18.173 page 189


Experimental Challenge of Cattle with H-type and L-type Atypical BSE


A. Buschmann1, U. Ziegler1, M. Keller1, R. Rogers2, B. Hills3, M.H. Groschup1. 1Friedrich-Loeffler-Institut, Greifswald-Insel Riems, Germany, 2Health Canada, Bureau of Microbial Hazards, Health Products & Food Branch, Ottawa, Canada, 3Health Canada, Transmissible Spongiform Encephalopathy Secretariat, Ottawa, Canada


Background: After the detection of two novel BSE forms designated H-type and L-type atypical BSE the question of the pathogenesis and the agent distribution of these two types in cattle was fully open. From initial studies of the brain pathology, it was already known that the anatomical distribution of L-type BSE differs from that of the classical type where the obex region in the brainstem always displays the highest PrPSc concentrations. In contrast in L-type BSE cases, the thalamus and frontal cortex regions showed the highest levels of the pathological prion protein, while the obex region was only weakly involved.


Methods:We performed intracranial inoculations of cattle (five and six per group) using 10%brainstemhomogenates of the two German H- and L-type atypical BSE isolates. The animals were inoculated under narcosis and then kept in a free-ranging stable under appropriate biosafety conditions.At least one animal per group was killed and sectioned in the preclinical stage and the remaining animals were kept until they developed clinical symptoms. The animals were examined for behavioural changes every four weeks throughout the experiment following a protocol that had been established during earlier BSE pathogenesis studies with classical BSE. Results and


Discussion: All animals of both groups developed clinical symptoms and had to be euthanized within 16 months. The clinical picture differed from that of classical BSE, as the earliest signs of illness were loss of body weight and depression. However, the animals later developed hind limb ataxia and hyperesthesia predominantly and the head. Analysis of brain samples from these animals confirmed the BSE infection and the atypical Western blot profile was maintained in all animals. Samples from these animals are now being examined in order to be able to describe the pathogenesis and agent distribution for these novel BSE types.


Conclusions: A pilot study using a commercially avaialble BSE rapid test ELISA revealed an essential restriction of PrPSc to the central nervous system for both atypical BSE forms. A much more detailed analysis for PrPSc and infectivity is still ongoing.




Saturday, November 19, 2011


Novel Prion Protein in BSE-affected Cattle, Switzerland




Wednesday, February 16, 2011


IN CONFIDENCE


SCRAPIE TRANSMISSION TO CHIMPANZEES


IN CONFIDENCE




Sunday, April 18, 2010


SCRAPIE AND ATYPICAL SCRAPIE TRANSMISSION STUDIES A REVIEW 2010




Monday, April 25, 2011


Experimental Oral Transmission of Atypical Scrapie to Sheep


Volume 17, Number 5-May 2011




Thursday, June 2, 2011


USDA scrapie report for April 2011 NEW ATYPICAL NOR-98 SCRAPIE CASES Pennsylvania AND California




Monday, June 20, 2011 2011


Annual Conference of the National Institute for Animal Agriculture ATYPICAL NOR-98 LIKE SCRAPIE UPDATE USA




Thursday, July 14, 2011


Histopathological Studies of "CH1641-Like" Scrapie Sources Versus Classical Scrapie and BSE Transmitted to Ovine Transgenic Mice (TgOvPrP4)




Wednesday, October 12, 2011


White-tailed deer are susceptible to the agent of sheep scrapie by intracerebral inoculation






Price of PRION TSE aka MAD COW POKER GOES UP $$$


Saturday, December 3, 2011


Isolation of Prion with BSE Properties from Farmed Goat Volume 17, Number 12—December 2011






14th ICID International Scientific Exchange Brochure -


Final Abstract Number: ISE.114


Session: International Scientific Exchange


Transmissible Spongiform encephalopathy (TSE) animal and human TSE in North America update October 2009


T. Singeltary


Bacliff, TX, USA


Background:


An update on atypical BSE and other TSE in North America. Please remember, the typical U.K. c-BSE, the atypical l-BSE (BASE), and h-BSE have all been documented in North America, along with the typical scrapie's, and atypical Nor-98 Scrapie, and to date, 2 different strains of CWD, and also TME. All these TSE in different species have been rendered and fed to food producing animals for humans and animals in North America (TSE in cats and dogs ?), and that the trading of these TSEs via animals and products via the USA and Canada has been immense over the years, decades.


Methods:


12 years independent research of available data


Results:


I propose that the current diagnostic criteria for human TSEs only enhances and helps the spreading of human TSE from the continued belief of the UKBSEnvCJD only theory in 2009. With all the science to date refuting it, to continue to validate this old myth, will only spread this TSE agent through a multitude of potential routes and sources i.e. consumption, medical i.e., surgical, blood, dental, endoscopy, optical, nutritional supplements, cosmetics etc.


Conclusion:


I would like to submit a review of past CJD surveillance in the USA, and the urgent need to make all human TSE in the USA a reportable disease, in every state, of every age group, and to make this mandatory immediately without further delay. The ramifications of not doing so will only allow this agent to spread further in the medical, dental, surgical arena's. Restricting the reporting of CJD and or any human TSE is NOT scientific. Iatrogenic CJD knows NO age group, TSE knows no boundaries. I propose as with Aguzzi, Asante, Collinge, Caughey, Deslys, Dormont, Gibbs, Gajdusek, Ironside, Manuelidis, Marsh, et al and many more, that the world of TSE Transmissible Spongiform Encephalopathy is far from an exact science, but there is enough proven science to date that this myth should be put to rest once and for all, and that we move forward with a new classification for human and animal TSE that would properly identify the infected species, the source species, and then the route.






Wednesday, August 24, 2011


There Is No Safe Dose of Prions






Wednesday, August 24, 2011


All Clinically-Relevant Blood Components Transmit Prion Disease following a Single Blood Transfusion: A Sheep Model of vCJD






EFSA Journal 2011 The European Response to BSE: A Success Story


EFSA and the European Centre for Disease Prevention and Control (ECDC) recently delivered a scientific opinion on any possible epidemiological or molecular association between TSEs in animals and humans (EFSA Panel on Biological Hazards (BIOHAZ) and ECDC, 2011). This opinion confirmed Classical BSE prions as the only TSE agents demonstrated to be zoonotic so far but the possibility that a small proportion of human cases so far classified as "sporadic" CJD are of zoonotic origin could not be excluded. Moreover, transmission experiments to non-human primates suggest that some TSE agents in addition to Classical BSE prions in cattle (namely L-type Atypical BSE, Classical BSE in sheep, transmissible mink encephalopathy (TME) and chronic wasting disease (CWD) agents) might have zoonotic potential.


snip...






see follow-up here about North America BSE Mad Cow TSE prion risk factors, and the ever emerging strains of Transmissible Spongiform Encephalopathy in many species here in the USA, including humans ;






Thursday, November 17, 2011


International cattle ID and traceability: Competitive implications for the US


Food Policy Volume 37, Issue 1, February 2012, Pages 31-40




Friday, November 18, 2011


country-of-origin labeling law (COOL) violates U.S. obligations under WTO rules WT/DS384/R WT/DS386/R






Monday, January 2, 2012


EFSA Minutes of the 6th Meeting of the EFSA Scientific Network on BSE-TSE Brussels, 29-30 November 2011




Thursday, August 12, 2010


Seven main threats for the future linked to prions


First threat


The TSE road map defining the evolution of European policy for protection against prion diseases is based on a certain numbers of hypotheses some of which may turn out to be erroneous. In particular, a form of BSE (called atypical Bovine Spongiform Encephalopathy), recently identified by systematic testing in aged cattle without clinical signs, may be the origin of classical BSE and thus potentially constitute a reservoir, which may be impossible to eradicate if a sporadic origin is confirmed.


***Also, a link is suspected between atypical BSE and some apparently sporadic cases of Creutzfeldt-Jakob disease in humans. These atypical BSE cases constitute an unforeseen first threat that could sharply modify the European approach to prion diseases.


Second threat


snip...






2011 Monday, September 26, 2011


L-BSE BASE prion and atypical sporadic CJD






SEE RISE OF SPORADIC CJD YEAR TO YEAR ;






Saturday, March 5, 2011


MAD COW ATYPICAL CJD PRION TSE CASES WITH CLASSIFICATIONS PENDING ON THE RISE IN NORTH AMERICA






Tuesday, November 08, 2011


Can Mortality Data Provide Reliable Indicators for Creutzfeldt-Jakob Disease Surveillance? A Study in France from 2000 to 2008 Vol. 37, No. 3-4, 2011


Original Paper


Conclusions:These findings raise doubt about the possibility of a reliable CJD surveillance only based on mortality data.






Terry S. Singeltary Sr. on the Creutzfeldt-Jakob Disease Public Health Crisis








full text with source references ;
























TSS
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