Monday, December 10, 2012

Report on the monitoring of ruminants for the presence of Transmissible Spongiform Encephalopathies (TSEs) in the EU in 2011 Final version 18 October 2012

Report on the monitoring of ruminants for the presence of Transmissible Spongiform Encephalopathies (TSEs) in the EU in 2011 Final version 18 October 2012






TABLE OF CONTENTS


1. SUMMARY.................................................................................................................4


1.1. Bovine animals.............................................................................................


1.2. Ovine and caprine animals......................................................................


2. MONITORING PROGRAMMES, SAMPLING AND DIAGNOSTIC


METHODS APPLICABLE IN 2011 .....................................................................


2.1. Legal basis.....................................................................................................


2.2. BSE monitoring of bovine animals .......................................................


2.3. TSE monitoring of ovine and caprine animals.................................


2.4. Sampling and testing for the prion protein genotype determination in ovine animals.............................................................


3. ANNUAL AND MONTHLY REPORTS.................................................................


4. SUMMARY OF THE BSE TESTING IN BOVINE ANIMALS DURING 2011.......................................................................................................


4.1. Sampling ......................................................................................................


4.2. BSE positive cases....................................................................................


4.3. Testing by target group..........................................................................


4.4. Age distribution of BSE positive cases .............................................


4.5. Year of birth distribution of BSE positive cases detected since 2001 ...................................................................................................


4.6. Prevalence of BSE in different age categories in 2011..............


4.7. BSE in young animals .............................................................................


4.8. Atypical BSE cases ...................................................................................


5. SUMMARY OF TSE TESTING IN OVINE AND CAPRINE


ANIMALS DURING 2011...................................................................................


5.1. Sampling ......................................................................................................


5.2. Positive cases .............................................................................................


5.3. Atypical cases.............................................................................................


5.4. TSE discriminatory tests ........................................................................


5.5. Age distribution of TSE positive cases..............................................


5.6. Genotyping..................................................................................................




1. SUMMARY


1.1. Bovine animals


In 2011, a total of 6 361 591 bovine animals were tested in the EU 27 in the framework of the BSE monitoring programmes. 28 bovine animals turned out positive.


Out of the 28 BSE cases identified in 2011, 23 were submitted to discriminatory testing by the Member States, on a voluntary basis. These tests confirmed 17 cases of classical BSE, 3 cases of atypical H-type BSE and 3 cases of atypical L-type BSE.


1 090 192 risk bovine animals and 5 270 593 healthy animals slaughtered for human consumption were tested by rapid tests. 93 animals were tested in the framework of culling of animals with an epidemiological connection to a BSE case. In addition, 713 bovine animals were tested in the framework of passive surveillance (animals reported as official BSE suspects. 100 % of positive cases were detected by the active monitoring (testing of risk animals, healthy slaughtered and culled cattle) and 0 % were detected by passive surveillance.


No BSE cases were found in Belgium, Bulgaria, Czech Republic, Denmark, Germany, Estonia, Greece, Cyprus, Latvia, Lithuania, Luxembourg, Hungary, Malta, Netherlands, Austria, Romania, Slovenia, Slovakia, Finland and Sweden. The number of BSE cases and the overall prevalence in tested animals decreased by respectively 38 % and 27 % in 2011 compared to 2010.


1.2. Ovine and caprine animals


In 2011, a total of 369 417 ovine and 140 843 caprine animals were tested in the EU 27 in the framework of the TSE monitoring programmes. 1589 ovine and 366 caprine animals turned out positive to classical scrapie.


369 055 ovine animals were tested by active monitoring, while 362 were animals reported as official TSE suspects and therefore subjected to laboratory examination. In caprine animals, the numbers of tests in the respective groups were 139 612 (active monitoring) and 1 231 (TSE suspects). Some 698 and 134 TSE cases in respectively sheep and goats confirmed in 2011 were subjected to discriminatory testing. None of them have been confirmed to be BSE.


All Member States submitted information on the the TSE testing of bovine, ovine and caprine animals. In addition to the Member States, Norway also submitted information on their TSE testing programmes.




snip...




4. SUMMARY OF THE BSE TESTING IN BOVINE ANIMALS DURING 2011


The information was extracted directly from the electronic submission of monthly and case reports by Member States. The monthly information is often updated and/or corrected by the Member States in following reports. The information shown in the following summaries is updated according to the information received electronically until 18 October 2012. Information on adult cattle population in 2011 was obtained from Eurostat.


4.1. Sampling


Comments on the sampling


Sampling decreased in 2011 from about 7.5 million cattle in 2010 to a little less than 6.4 million in 2011. This drop can be explained by the fact that 25 Member States were allowed, as of 1 July 2011, to test only healthy cattle over 72 months of age at the slaughterhouse. A similar drop should be expected in 2012 when this new age limit will have been applied to the whole year. Over 102 million cattle have been tested in the EU since 2001.


Chart B1: Total tests performed in the period 2001–2011 in the EU27




snip...




4.2. BSE positive cases


Comments on BSE positive cases


When analysing the evolution of BSE positive cases, it should be kept in mind that active monitoring was limited before 2001 and has decreased since 2009 for some Member States due to the modification of the age limit for testing. The expanded active monitoring became fully applicable in July 2001. The annual number of tests was about 25 % higher in the period 2002-2008 than in 2001 (see Chart B1). Despite the fact that the number of tests remained stable between 2002 and 2008, and decreased since 2009, the prevalence of BSE in tested animals (ratio of positives per 10 000 tests) has been steadily dropping since 2002, due to the decline in positive cases.


Overall the number of cases and the prevalence in tested animals of BSE dropped by 36% and 27% respectively in the EU in 2011 compared to 2010.


Chart B2: Evolution of the number of BSE positive cases in the 27 EU Member States since 2001





snip...




Comments on the age distribution of BSE positive animals


The previous tables and charts confirm in 2011 the general trend of the past years of a regular increase of the average age of the BSE cases detected. The slight drop of the average age of BSE cases in risk animals observed in 2010 was not confirmed in 2011. The average age of BSE cases in risk animals is now close to 172 months, and a little over 178 months in healthy slaughtered animals has actually almost converged in 2011 and is now close to 178 months, almost 15 years.


The overall evolution of the average age of positive cases appears favourable since 2001. Taking into consideration an average incubation period of 5-6 years, these figures are an indication that measures taken (mainly feed ban) have been effective.




snip...





(***PLEASE NOTE INCREASE IN ATYPICAL BSE CASES COMPARED TO TYPICAL BSE CASES...TSS)





Table B35: Proportion in each target group of all BSE cases submitted to further discriminatory testing and reported atypical BSE cases, by Member State, from 2001 to 2011






(***ALSO PLEASE NOTE THE AGE COMPARISON WITH TYPICAL C-BSE WITH THE SUPPOSEDLY OLD AGE CATTLE SYNDROME OF THE ATYPICAL H AND L TYPE BSE, SEEMS STRANGE THAT THE C-BSE AGE IS GOING UP, HIGHER THAN THE ATYPICAL CASES NOW???...TSS)






Chart B12: Average age (in months) of the Classical, L and H-type BSE cases detected in the EU from 2001 to 2011 after discriminatory testing






SNIP...





Comments on atypical BSE




The 2011 annual report provides data on atypical BSE cases for the time. The TSE regulation does not require the Member States to conduct discriminatory testing of all BSE cases. The present data reflect the tests conducted by some Member States on a voluntary basis. In most contributing Member States, only part of the past BSE cases have been submitted to discriminatory testing. The present results should therefore not be considered representative of the national or EU real situation.




These provisional results suggest that approximately a quarter of the BSE cases in the EU may be atypical cases, splitting relatively evenly in atypical H and atypical L- type cases. They also suggest that a higher proportion of atypical BSE may be found in the fallen stock cases than in the healthy slaughtered cattle cases.




Chart 12 also suggests that the average ages of atypical H and L-type cases are similar and have been stable since 2001. During the same period of time, the average age of classical BSE cases has been steadily increasing and appears to be higher in 2011 than the average age of atypical H and L-type cases.






snip...





Comments on genotyping


Only one case of classical scrapie was submitted in 2011 (Greece) in a sheep of the ARR/ARR genotype.


No trend in the genetic profile can be identified from 2004 to 2011 in most of the EU based on the results of the regulatory random genotyping of the ovine population. However, the results of the exhaustive genotyping of the sheep population in Cyprus show a very significant increase of the NSP1 and NSP2 groups since 2005.




(see charts at link...tss)











Wednesday, November 28, 2012


Scientific and technical assistance on the provisional results of the study on genetic resistance to Classical scrapie in goats in Cyprus 1


SCIENTIFIC REPORT OF EFSA









Sunday, September 23, 2012


EU-Approved Rapid Tests for Bovine Spongiform Encephalopathy Detect Atypical Forms: A Study for Their Sensitivities









Wednesday, December 21, 2011


Potential mad cows that entered food supply without being tested for BSE 2011: UK END OF YEAR REVIEW








Thursday, September 6, 2012


UK Breaches of BSE controls in consignments of beef 2011 communications missing four reports









Friday, November 30, 2012


PROPOSED DECISION TO STOP BSE TESTING OF HEALTHY CATTLE SLAUGHTERED FOR HUMAN CONSUMPTION FSA 12/12/04 Open Board – 11 December 2012









Sunday, December 2, 2012


CANADA 19 cases of mad cow disease SCENARIO 4: ‘WE HAD OUR CHANCE AND WE BLEW IT’










**** Tuesday, November 6, 2012


Transmission of New Bovine Prion to Mice, Atypical Scrapie, BSE, and Sporadic CJD, November-December 2012 update










Owner and Corporation Plead Guilty to Defrauding Bovine Spongiform Encephalopathy (BSE) Surveillance Program


An Arizona meat processing company and its owner pled guilty in February 2007 to charges of theft of Government funds, mail fraud, and wire fraud. The owner and his company defrauded the BSE Surveillance Program when they falsified BSE Surveillance Data Collection Forms and then submitted payment requests to USDA for the services. In addition to the targeted sample population (those cattle that were more than 30 months old or had other risk factors for BSE), the owner submitted to USDA, or caused to be submitted, BSE obex (brain stem) samples from healthy USDA-inspected cattle. As a result, the owner fraudulently received approximately $390,000. Sentencing is scheduled for May 2007.


snip...


Topics that will be covered in ongoing or planned reviews under Goal 1 include:


soundness of BSE maintenance sampling (APHIS),


implementation of Performance-Based Inspection System enhancements for specified risk material (SRM) violations and improved inspection controls over SRMs (FSIS and APHIS),


snip...


The findings and recommendations from these efforts will be covered in future semiannual reports as the relevant audits and investigations are completed.


4 USDA OIG SEMIANNUAL REPORT TO CONGRESS FY 2007 1st Half









-MORE Office of the United States Attorney District of Arizona FOR IMMEDIATE RELEASE For Information Contact Public Affairs February 16, 2007 WYN HORNBUCKLE Telephone: (602) 514-7625 Cell: (602) 525-2681


CORPORATION AND ITS PRESIDENT PLEAD GUILTY TO DEFRAUDING GOVERNMENTS MAD COW DISEASE SURVEILLANCE PROGRAM


PHOENIX -- Farm Fresh Meats, Inc. and Roland Emerson Farabee, 55, of Maricopa, Arizona, pleaded guilty to stealing $390,000 in government funds, mail fraud and wire fraud, in federal district court in Phoenix. U.S. Attorney Daniel Knauss stated, The integrity of the system that tests for mad cow disease relies upon the honest cooperation of enterprises like Farm Fresh Meats. Without that honest cooperation, consumers both in the U.S. and internationally are at risk. We want to thank the USDAs Office of Inspector General for their continuing efforts to safeguard the public health and enforce the law. Farm Fresh Meats and Farabee were charged by Information with theft of government funds, mail fraud and wire fraud. According to the Information, on June 7, 2004, Farabee, on behalf of Farm Fresh Meats, signed a contract with the U.S. Department of Agriculture (the USDA Agreement) to collect obex samples from cattle at high risk of mad cow disease (the Targeted Cattle Population). The Targeted Cattle Population consisted of the following cattle: cattle over thirty months of age; nonambulatory cattle; cattle exhibiting signs of central nervous system disorders; cattle exhibiting signs of mad cow disease; and dead cattle. Pursuant to the USDA Agreement, the USDA agreed to pay Farm Fresh Meats $150 per obex sample for collecting obex samples from cattle within the Targeted Cattle Population, and submitting the obex samples to a USDA laboratory for mad cow disease testing. Farm Fresh Meats further agreed to maintain in cold storage the sampled cattle carcasses and heads until the test results were received by Farm Fresh Meats.


Evidence uncovered during the governments investigation established that Farm Fresh Meats and Farabee submitted samples from cattle outside the Targeted Cattle Population. Specifically, Farm Fresh Meats and Farabee submitted, or caused to be submitted, obex samples from healthy, USDA inspected cattle, in order to steal government moneys.


Evidence collected also demonstrated that Farm Fresh Meats and Farabee failed to maintain cattle carcasses and heads pending test results and falsified corporate books and records to conceal their malfeasance. Such actions, to the extent an obex sample tested positive (fortunately, none did), could have jeopardized the USDAs ability to identify the diseased animal and pinpoint its place of origin. On Wednesday, February 14, 2007, Farm Fresh Meats and Farabee pleaded guilty to stealing government funds and using the mails and wires to effect the scheme. According to their guilty pleas:


(a) Farm Fresh Meats collected, and Farabee directed others to collect, obex samples from cattle outside the Targeted Cattle Population, which were not subject to payment by the USDA;


(b) Farm Fresh Meats 2 and Farabee caused to be submitted payment requests to the USDA knowing that the requests were based on obex samples that were not subject to payment under the USDA Agreement;


(c) Farm Fresh Meats completed and submitted, and Farabee directed others to complete and submit, BSE Surveillance Data Collection Forms to the USDAs testing laboratory that were false and misleading;


(d) Farm Fresh Meats completed and submitted, and Farabee directed others to complete and submit, BSE Surveillance Submission Forms filed with the USDA that were false and misleading;


(e) Farm Fresh Meats falsified, and Farabee directed others to falsify, internal Farm Fresh Meats documents to conceal the fact that Farm Fresh Meats was seeking and obtaining payment from the USDA for obex samples obtained from cattle outside the Targeted Cattle Population; and


(f) Farm Fresh Meats failed to comply with, and Farabee directed others to fail to comply with, the USDA Agreement by discarding cattle carcasses and heads prior to receiving BSE test results. A conviction for theft of government funds carries a maximum penalty of 10 years imprisonment. Mail fraud and wire fraud convictions carry a maximum penalty of 20 years imprisonment. Convictions for the above referenced violations also carry a maximum fine of $250,000 for individuals and $500,000 for organizations. In determining an actual sentence, Judge Earl H. Carroll will consult the U.S. Sentencing Guidelines, which provide appropriate sentencing ranges. The judge, however, is not bound by those guidelines in determining a sentence.


Sentencing is set before Judge Earl H. Carroll on May 14, 2007. The investigation in this case was conducted by Assistant Special Agent in Charge Alejandro Quintero, United States Department of Agriculture, Office of Inspector General. The prosecution is being handled by Robert Long, Assistant U.S. Attorney, District of Arizona, Phoenix. CASE NUMBER: CR-07-00160-PHX-EHC RELEASE NUMBER: 2007-051(Farabee) # # #











Friday, May 4, 2012


May 2, 2012: Update from APHIS Regarding a Detection of Bovine Spongiform Encephalopathy (BSE) in the United States








PAUL BROWN COMMENT TO ME ON THIS ISSUE


Tuesday, September 12, 2006 11:10 AM


"Actually, Terry, I have been critical of the USDA handling of the mad cow issue for some years, and with Linda Detwiler and others sent lengthy detailed critiques and recommendations to both the USDA and the Canadian Food Agency." ........TSS








OR, what the Honorable Phyllis Fong of the OIG found ;


Audit Report Animal and Plant Health Inspection Service Bovine Spongiform Encephalopathy (BSE) Surveillance Program ­ Phase II and Food Safety and Inspection Service


Controls Over BSE Sampling, Specified Risk Materials, and Advanced Meat Recovery Products - Phase III


Report No. 50601-10-KC January 2006


Finding 2 Inherent Challenges in Identifying and Testing High-Risk Cattle Still Remain







Tuesday, January 1, 2008


BSE OIE USDA


Subject: OIE BSE RECOMMENDATION FOR USA, bought and paid for by your local cattle dealers i.e. USDA


Date: May 14, 2007 at 9:00 am PST


OIE BSE RECOMMENDATION FOR USA, bought and paid for by your local cattle dealers i.e. USDA


STATEMENT BY DR. RON DEHAVEN REGARDING OIE RISK RECOMMENDATION


March 9, 2007










Tuesday, November 02, 2010


IN CONFIDENCE


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


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










2009 UPDATE ON ALABAMA AND TEXAS MAD COWS 2005 and 2006









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:










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, USDA, REPLY TO SINGELTARY










U.S.A. 50 STATE BSE MAD COW CONFERENCE CALL Jan. 9, 2001












2012 atypical L-type BSE BASE California reports


Saturday, August 4, 2012


Final Feed Investigation Summary - California BSE Case - July 2012








SUMMARY REPORT CALIFORNIA BOVINE SPONGIFORM ENCEPHALOPATHY CASE INVESTIGATION JULY 2012


Summary Report BSE 2012


Executive Summary








Saturday, August 4, 2012


Update from APHIS Regarding Release of the Final Report on the BSE Epidemiological Investigation








CENSORSHIP IS A TERRIBLE THING $$$





Canada has had a COVER-UP policy of mad cow disease since about the 17th case OR 18th case of mad cow disease. AFTER THAT, all FOIA request were ignored $$$


THIS proves there is indeed an epidemic of mad cow disease in North America, and it has been covered up for years and years, if not for decades, and it’s getting worse $$$





Thursday, February 10, 2011


TRANSMISSIBLE SPONGIFORM ENCEPHALOPATHY REPORT UPDATE CANADA FEBRUARY 2011 and how to hide mad cow disease in Canada Current as of: 2011-01-31









Wednesday, August 11, 2010


REPORT ON THE INVESTIGATION OF THE SIXTEENTH CASE OF BOVINE SPONGIFORM ENCEPHALOPATHY (BSE) IN CANADA








Thursday, August 19, 2010


REPORT ON THE INVESTIGATION OF THE SEVENTEENTH CASE OF BOVINE SPONGIFORM ENCEPHALOPATHY (BSE) IN CANADA








Friday, March 4, 2011


Alberta dairy cow found with mad cow disease








Reasons for the New Regulation Order No. 23 (as well as amending Order No. 149) of the State Committee for Veterinary Medicine name BSE as the reason for new import requirement. The legal title for Order No. 23 is "On Urgent Measures Aimed at Prevention and Elimination of BSE and Other Prion Infections in Cattle”. Neither Order explains how the threat of introduction of BSE can be addressed through the inspection of producers of all products of animal origin including fish, dairy products, poultry and pork. It is not clear what other concerns are addressed through the proposed inspections. Formal Notification of Trading Partners On August 3rd, Ukraine's Notification and Enquiry Point issued a legal Notification G/SPS/N/UKR/3/Rev.1 found on the Official WTO Website (Committee on Sanitary and Phytosanitary Measures)








Thursday, March 29, 2012


atypical Nor-98 Scrapie has spread from coast to coast in the USA 2012


NIAA Annual Conference April 11-14, 2011San Antonio, Texas








Monday, November 30, 2009


USDA AND OIE COLLABORATE TO EXCLUDE ATYPICAL SCRAPIE NOR-98 ANIMAL HEALTH CODE








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...









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 ;









2011 Monday, September 26, 2011


L-BSE BASE prion and atypical sporadic CJD









Saturday, March 5, 2011


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








Wednesday, August 01, 2012


Behavioural and Psychiatric Features of the Human Prion Diseases: Experience in 368 Prospectively Studied Patients









Monday, August 06, 2012


Atypical neuropathological sCJD-MM phenotype with abundant white matter Kuru-type plaques sparing the cerebellar cortex









Tuesday, June 26, 2012


Creutzfeldt Jakob Disease Human TSE report update North America, Canada, Mexico, and USDA PRION UNIT as of May 18, 2012


type determination pending Creutzfeldt Jakob Disease (tdpCJD), is on the rise in Canada and the USA









Friday, August 24, 2012


Iatrogenic prion diseases in humans: an update









Monday, July 23, 2012


The National Prion Disease Pathology Surveillance Center July 2012









OR-10: Variably protease-sensitive prionopathy is transmissible in bank voles


Romolo Nonno,1 Michele Di Bari,1 Laura Pirisinu,1 Claudia D’Agostino,1 Stefano Marcon,1 Geraldina Riccardi,1 Gabriele Vaccari,1 Piero Parchi,2 Wenquan Zou,3 Pierluigi Gambetti,3 Umberto Agrimi1 1Istituto Superiore di Sanità; Rome, Italy; 2Dipartimento di Scienze Neurologiche, Università di Bologna; Bologna, Italy; 3Case Western Reserve University; Cleveland, OH USA


Background. Variably protease-sensitive prionopathy (VPSPr) is a recently described “sporadic”neurodegenerative disease involving prion protein aggregation, which has clinical similarities with non-Alzheimer dementias, such as fronto-temporal dementia. Currently, 30 cases of VPSPr have been reported in Europe and USA, of which 19 cases were homozygous for valine at codon 129 of the prion protein (VV), 8 were MV and 3 were MM. A distinctive feature of VPSPr is the electrophoretic pattern of PrPSc after digestion with proteinase K (PK). After PK-treatment, PrP from VPSPr forms a ladder-like electrophoretic pattern similar to that described in GSS cases. The clinical and pathological features of VPSPr raised the question of the correct classification of VPSPr among prion diseases or other forms of neurodegenerative disorders. Here we report preliminary data on the transmissibility and pathological features of VPSPr cases in bank voles.


Materials and Methods. Seven VPSPr cases were inoculated in two genetic lines of bank voles, carrying either methionine or isoleucine at codon 109 of the prion protein (named BvM109 and BvI109, respectively). Among the VPSPr cases selected, 2 were VV at PrP codon 129, 3 were MV and 2 were MM. Clinical diagnosis in voles was confirmed by brain pathological assessment and western blot for PK-resistant PrPSc (PrPres) with mAbs SAF32, SAF84, 12B2 and 9A2.


Results. To date, 2 VPSPr cases (1 MV and 1 MM) gave positive transmission in BvM109. Overall, 3 voles were positive with survival time between 290 and 588 d post inoculation (d.p.i.). All positive voles accumulated PrPres in the form of the typical PrP27–30, which was indistinguishable to that previously observed in BvM109 inoculated with sCJDMM1 cases.


In BvI109, 3 VPSPr cases (2 VV and 1 MM) showed positive transmission until now. Overall, 5 voles were positive with survival time between 281 and 596 d.p.i.. In contrast to what observed in BvM109, all BvI109 showed a GSS-like PrPSc electrophoretic pattern, characterized by low molecular weight PrPres. These PrPres fragments were positive with mAb 9A2 and 12B2, while being negative with SAF32 and SAF84, suggesting that they are cleaved at both the C-terminus and the N-terminus. Second passages are in progress from these first successful transmissions.


Conclusions. Preliminary results from transmission studies in bank voles strongly support the notion that VPSPr is a transmissible prion disease. Interestingly, VPSPr undergoes divergent evolution in the two genetic lines of voles, with sCJD-like features in BvM109 and GSS-like properties in BvI109.


The discovery of previously unrecognized prion diseases in both humans and animals (i.e., Nor98 in small ruminants) demonstrates that the range of prion diseases might be wider than expected and raises crucial questions about the epidemiology and strain properties of these new forms. We are investigating this latter issue by molecular and biological comparison of VPSPr, GSS and Nor98.










Wednesday, March 28, 2012


VARIABLY PROTEASE-SENSITVE PRIONOPATHY IS TRANSMISSIBLE, price of prion poker goes up again $









*** The discovery of previously unrecognized prion diseases in both humans and animals (i.e., Nor98 in small ruminants) demonstrates that the range of prion diseases might be wider than expected and raises crucial questions about the epidemiology and strain properties of these new forms. We are investigating this latter issue by molecular and biological comparison of VPSPr, GSS and Nor98.


AS OF AUGUST 2012 ;


CJD UPDATE USA


1 Listed based on the year of death or, if not available, on year of referral; 2 Cases with suspected prion disease for which brain tissue and/or blood (in familial cases) were submitted; 3 Disease acquired in the United Kingdom; 4 Disease was acquired in the United Kingdom in one case and in Saudi Arabia in the other case; *** 5 Includes 8 cases in which the diagnosis is pending, and 18 inconclusive cases; *** 6 Includes 10 (9 from 2012) cases with type determination pending in which the diagnosis of vCJD has been excluded. *** The Sporadic cases include 16 cases of sporadic Fatal Insomnia (sFI) and 42 cases of Variably Protease-Sensitive Prionopathy (VPSPr) and 2224 cases of sporadic Creutzfeldt-Jakob disease (sCJD).










Friday, November 23, 2012


sporadic Creutzfeldt-Jakob Disease update As at 5th November 2012 UK, USA, AND CANADA










Sunday, December 9, 2012


Prions, prionoids and pathogenic proteins in Alzheimer disease








R.I.P. MOM DOD 12/14/97 hvCJD confirmed...






TSS


Wednesday, November 28, 2012

Scientific and technical assistance on the provisional results of the study on genetic resistance to Classical scrapie in goats in Cyprus 1

SCIENTIFIC REPORT OF EFSA


Scientific and technical assistance on the provisional results of the study on genetic resistance to Classical scrapie in goats in Cyprus1


European Food Safety Authority2, 3


European Food Safety Authority (EFSA), Parma, Italy


ABSTRACT


This EFSA Scientific Report reviews and discusses the provisional results of a study (EURL/Cypriot study) on genetic resistance to Classical scrapie in goats in Cyprus. It is concluded that the provisional results obtained in the study further support the lower susceptibility to Classical scrapie in goats carrying the D146 and S146 alleles compared to wild type (N146N) goats. The results from intracerebral challenge are not compatible with a level of resistance as high as the one observed in sheep carrying the ARR allele or in goats carrying the K222 allele. Final results from the oral challenge will be crucial in determining the level of resistance associated with the D146 and S146 alleles. Furthermore, it is concluded that the provisional results obtained in the study are compatible with the possibility to use the D146 and S146 alleles to build a genetic strategy to control and eradicate Classical scrapie in goats in Cyprus. However, the success of such a strategy will be determined by the level of resistance associated with the D146 and S146 alleles against infection with all the different TSE agents proved to be circulating in Cyprus, which at this stage of the EURL/Cypriot study remains to be definitively assessed. In addition, as compared to the results of the model developed in the study, it is concluded that the efficiency of the implementation in the field of a breeding strategy selecting for the D146 and S146 alleles may be lower due to potential practical constraints related to the management of genetic diversity, to the selection for production and health traits and to the need of moving animals for breeding purposes in Cyprus. Recommendations on aspects that may be considered when completing the study are formulated.


© European Food Safety Authority, 2012


KEY WORDS


TSE, Classical scrapie, goat, genetic resistance, breeding programme, Cyprus.


snip...


Interim Conclusions


The oral challenge studies, the management cull and the whole herd cull data all support the previously published field observations that on one side the genotype N146N is particularly associated with scrapie susceptibility and on the other side the genotypes N146D, N146S, D146D, D146S and S146S are associated with a degree of resistance.


All genotypes can succumb to challenge by the intracerebral route, but the resulting phenotype is different when comparing the animals carrying genotype N146N with all the others (most notably, no detection of PrPSc in the periphery of infected animals with all the non-N146N-genotypes).


It is important that the oral challenges are continued to endpoint to establish the relative resistance of other genotypes to challenge by this more natural route Appendix A to Scientific Report of EFSA, EFSA Journal 2012;10(11):2972


Cyprus/EURL resistance in goats protocol Report May 2012


Page 13 of 13


All components of the study reinforce previously published UK caprine data3 which indicates that the current ELISA rapid test screen has considerably lower sensitivity (approx 50%) than immunohistochemistry.


The wider issue of discriminatory testing for BSE vs scrapie may need to be reviewed (regardless of genotype), since data from these studies suggest that direct extrapolation from ovine data may not be appropriate for all caprine isolates.


The TSE European Union Reference Laboratory at the Animal Health and Veterinary Laboratory Agency New Haw, UK


The Government Veterinary Services, Cyprus


May 2012







Wednesday, January 18, 2012


BSE IN GOATS CAN BE MISTAKEN FOR SCRAPIE


February 1, 2012



posted January 18, 2012



BSE in goats can be mistaken for scrapie



Bovine spongiform encephalopathy in goats could be misdiagnosed as scrapie in the absence of appropriate discriminatory tests, and such misidentification occurred at least once before such tests were developed, according to a report released in December.



The article, "Isolation of prion with BSE properties from farmed goat" (Emerging Infectious Diseases 2011;17:2253-2261), indicates BSE can affect small ruminants under natural conditions and that the condition can be misdiagnosed. The agent that causes scrapie is not known to infect humans, but consumption of beef contaminated with the prions that cause BSE is connected with variant Creutzfeldt-Jakob disease, a neurodegenerative disorder in humans.



The report calls for continued extensive surveillance and breeding plans to prevent BSE outbreaks among small ruminants. Such outbreaks could harm public health.



The authors stated in the text that the misdiagnosis occurred in 1990 in the United Kingdom. The case had been identified as suspected BSE in 2006 because differential immunohistochemical analysis of fixed brain tissue produced a signature indistinguishable from BSE. The authors of the recent report used a bioassay to confirm the BSE diagnosis.



The sample collected in 1990 was among 26 historic samples collected from 1984-2002, the report states.



The report indicates the U.K. goat and a goat in France found to have BSE in 2005 both likely became infected through contaminated food supplements.



While BSE lesions are contained mainly within nervous tissue in cattle, the report states "in small ruminants the BSE agent is widely distributed in peripheral tissues and can be transmitted horizontally." Feed ban measures alone would be insufficient for controlling a BSE outbreak in small ruminants, according to the report.



"Also, it would be impossible to prevent BSE from entering the human food chain through consumption of food products derived from small ruminants," the report states.













Discussion




We confirmed that the agent responsible for TSE in a UK goat, which was initially reported as scrapie in 1990 and subsequently as suspected BSE in 2006 (16), was a BSE agent. This conclusion was based on bioassay of nervous tissue in mice demonstrating similarities of histopathologic lesions, PrPSc mapping in the brain, and WB of PrPSc with those of mice inoculated with BSE from various ovine, caprine, and bovine sources.











Saturday, December 3, 2011




Isolation of Prion with BSE Properties from Farmed Goat Volume 17, Number




12—December 2011









snip...see full text ;








Scientific Opinion on genetic TSE resistance in goats in all European Union Member States Question number: EFSA-Q-2009-00448


Adopted: 21 October 2009 Summary (0.1Mb)


Opinion (0.3Mb)


Summary


Following a request from the European Commission, the Panel on Biological Hazards (BIOHAZ) was asked to deliver a scientific opinion on genetic resistance to Transmissible Spongiform Encephalopathies (TSE) in goats.


For a first part of that request, the BIOHAZ Panel adopted on 5th March 2009 a scientific opinion on the scientific validity of a study carried out by the Cypriot authorities under the auspices of the Community Reference Laboratory (CRL) for TSEs. That scientific opinion also indicated to what extent the information contained in the study could be used as relevant tools to control Classical scrapie in Cyprus.


In the current scientific opinion the BIOHAZ Panel addresses genetic resistance as a relevant tool for breeding for resistance to all TSEs of goats (including Atypical scrapie and BSE) in all the Member States (MSs) (except for Classical scrapie in Cyprus).


To carry out this task, available scientific knowledge on genetic TSE resistance in goats in the EU is reviewed, addressing those PRNP polymorphisms for which a capacity to provide resistance to TSEs in goats has been (or is being) investigated. Details tailored to the different TSEs found in this small ruminants (i.e. Classical scrapie, Atypical scrapie and BSE) are also considered and presented.


Further on, the feasibility of a large-scale breeding program in animal populations would need to be supported by a sound logistical and technical infrastructure in any given territory. In order to collect preliminary data that could help to evaluate the specific situation in the different EU MSs, a questionnaire was developed and circulated among the EFSA BSE-TSE Network. The results of the analysis of the replies received are also presented herewith.


The BIOHAZ Panel concluded that there are encouraging but as yet incomplete data to consider supporting a breeding programme for resistance in goats against Classical scrapie in all EU MSs, and ongoing studies are expected to provide a more robust scientific background in the coming years. On the other hand, at this moment there are not enough data available to consider supporting a breeding programme for resistance against Atypical scrapie and BSE in goats in all EU MSs. Experiments are ongoing on BSE in goats and results will be available in the next years. Furthermore, there are limited data suggesting that an allele (H154) might confer resistance to Classical scrapie but increase susceptibility to Atypical scrapie.


The frequency of the wild type allele, which is known to confer susceptibility to Classical scrapie, is high in all goat breeds considered. Thus, selection for putative resistance alleles will be slow, complicated and highly dependent on breeding structure.


It is acknowledged that any large scale breeding programme for TSE resistance in goats must take into consideration key elements related to the current dissemination of potentially TSE protective polymorphisms in the goat population of each EU MS and the characterisation of the real protection provided by those polymorphisms. At present, only a few EU MSs seem to have in place the necessary elements to introduce a breeding for resistance programme for Classical scrapie in goats.


The BIOHAZ Panel makes a series of recommendations on new investigations in order to assess the efficacy of breeding for the candidate PRNP alleles as a mean to control TSEs in goats. Furthermore, research on the possible adverse effects of the candidate PRNP polymorphisms on other production traits should be encouraged. In addition, it is recommended that a breeding for resistance programme for TSE in goats is first implemented in the seven EU MSs with the largest goat population as this would have the most impact.


Published: 9 November 2009







OPINION








Tuesday, November 10, 2009


A retrospective immunohistochemical study reveals atypical scrapie has existed in the United Kingdom since at least 1987


Brief Research Reports








-------- Original Message --------


Subject: Twelve Greek goats were found to be suffering from the brain-wasting disease scrapie in the first half of 2004


Date: Wed, 19 Jan 2005 13:30:26 –0600


From: "Terry S. Singeltary Sr."


To: Bovine Spongiform Encephalopathy


CC: cjdvoice@yahoogroups.com


Wednesday January 19, 2005


Brain disease in Greek goats


Twelve Greek goats were found to be suffering from the brain-wasting disease scrapie in the first half of 2004, EU figures made public yesterday reveal.


The data, issued by the European Food Safety Authority (EFSA), show that 12 cases of transmissible spongiform encephalopathies (TSE) were discovered in Greece, eight in Cyprus and 26 in France out of some 17,294 goats tested throughout the EU in 2004. The figures were made public by Left Coalition Synaspismos MEP Dimitris Papadopoulos.


Some 100 Europeans have died from the human form of bovine spongiform encephalopathy (BSE), or mad cow disease, a strain of the TSE group. Meanwhile, tests are continuing in the case of a French goat slaughtered in 2002, which experts think may have developed BSE. The EU bans the use of milk and meat from herds affected by a TSE case.









TSS





-------- Original Message --------


Subject: Twelve Greek goats were found to be suffering from the brain-wasting disease scrapie in the first half of 2004


Date: Wed, 19 Jan 2005 13:30:26 –0600


From: "Terry S. Singeltary Sr."


To: Bovine Spongiform Encephalopathy


CC: cjdvoice@yahoogroups.com


Wednesday January 19, 2005


Brain disease in Greek goats


Twelve Greek goats were found to be suffering from the brain-wasting disease scrapie in the first half of 2004, EU figures made public yesterday reveal.


The data, issued by the European Food Safety Authority (EFSA), show that 12 cases of transmissible spongiform encephalopathies (TSE) were discovered in Greece, eight in Cyprus and 26 in France out of some 17,294 goats tested throughout the EU in 2004. The figures were made public by Left Coalition Synaspismos MEP Dimitris Papadopoulos.


Some 100 Europeans have died from the human form of bovine spongiform encephalopathy (BSE), or mad cow disease, a strain of the TSE group. Meanwhile, tests are continuing in the case of a French goat slaughtered in 2002, which experts think may have developed BSE. The EU bans the use of milk and meat from herds affected by a TSE case.










TSS





Comment from Terry S Singeltary, CJD WATCH/VOICE




Document ID: APHIS-2007-0033-0002 Document Type: Public Submission
This is comment on Proposed Rule: Agricultural Bioterrorism Protection Act of 2002; Biennial Review and Republication of the Select Agent and Toxin List
Docket ID:
RIN:0579-AC53

Topics: No Topics associated with this document

View Document:





snip...



Under APHIS-PPQ’s agriculture quarantine inspection monitoring, 584 air passengers from Greece were sampled for items of agricultural interest in fiscal year 2000. Of these passengers, 14 carried meat (non-pork) items that could potentially transmit pathogens that cause BSE; most passengers carried from one to two kilograms (kg) of meat, although one passenger in November 1999 carried 23 kg of meat in a suitcase. Florida, Massachusetts, and New York were the reported destinations of these passengers. None of the passengers with meat items reported plans to visit or work on a ranch or farm while in the US.





Source: US Department of Transportation, and APHIS-PPQ Agricultural Quarantine Inspection data base

















Monday, November 19, 2012

Prion in Saliva of Bovine Spongiform Encephalopathy–Infected Cattle

Letter



Prion in Saliva of Bovine Spongiform Encephalopathy–Infected Cattle



To the Editor: A definitive diagnosis of bovine spongiform encephalopathy (BSE) in cattle usually relies on Western blot and immunohistochemical testing of samples from the obex region of the brainstem. These conventional diagnostic tests can detect the presence of the abnormal (disease-associated) form of the prion protein (PrPSc) in brain samples several months before the onset of clinical signs; however, there is no appropriate, universal tool for early preclinical and antemortem diagnosis of BSE. Furthermore, confirmation of the disease is currently only possible by postmortem examination of brain tissues. In this study, we used the serial protein misfolding cyclic amplification (sPMCA) technique to determine the presence of PrPSc in saliva samples collected from BSE-infected cows before and after the onset of disease (1). In a previous study (2), we analyzed the tissue distribution of PrPSc in cattle up to 66 months after they were orally inoculated with a relatively low dose (5 g) of homogenized brainstem from animals with naturally occurring BSE in England. In 2011, after publication of that study and 83.3 months after the cows were inoculated, clinical signs of BSE developed in 1 cow (no. 5444); necropsy was performed 84.7 months after inoculation. In addition, we used saliva samples from 2 BSE-affected cows (nos. 5413 and 5437) (2) to determine the presence of PrPSc. We collected saliva samples from animals at 4 monthly intervals, beginning in 2009, 56 months after inoculation. Samples were stored at −80°C until analysis. Using the sodium phosphotungstic acid precipitation method, we concentrated (100-fold) individual 1-mL saliva samples from each time point. We then diluted the concentrated samples 1:10 with the normal isoform of prion protein substrate containing 0.5% potassium dextran sulfate. Using the sPMCA technique as described (1), we amplified the samples in 3–8 tubes, and we used Western blot to analyze the proteinase K–treated sPMCA products (2). Using Western blot and immunohistochemical tests, we detected the accumulation of PrPSc in brains collected at necropsy from the 3 cows examined. In addition, using the sPMCA technique, we detected PrPSc signal in 1) saliva samples that were concentrated from samples collected from the same 3 cows at necropsy and in 2) concentrated saliva samples that were collected from 2 of the cows (nos. 5413 and 5444) at the early clinical stages of disease.




Figure



Figure. . Western blot detection, using the serial protein misfolding cyclic amplification technique, of the abnormal (disease-associated) form of the prion protein (PrPSc) in concentrated saliva samples from 3 cows experimentally infected...



After saliva samples underwent 3 rounds of amplification, we detected PrPSc in a saliva sample that was collected from cow number 5437 two months before the clinical onset of clinical symptoms (Figure). For 2 of the cows (nos. 5413 and 5437), the positive ratio of salivary PrPSc at round 4 of amplification increased as the disease progressed (Figure). Because PrPSc signal could be detected in BSE-infected brain homogenates diluted up to 10−10 after 2 rounds of amplification (1), we estimated PrPSc levels in the nonconcentrated original saliva samples to be lower than those in BSE-infected brain homogenate diluted to 10−12. No PrPSc signal was detected in samples collected from the 3 cows 3–5 months before the onset of clinical symptoms or from age-matched noninfected controls, even after 4 rounds of amplification. We demonstrated the presence of PrPSc in saliva of BSE-affected cows during the clinical stage of the disease, and in 1 case, at the preclinical or asymptomatic stage. Our findings suggest that PrPSc is likely to be detected in the saliva of BSE-affected cattle during the clinical stage of disease, after accumulation of PrPSc in the brain. PrPSc was found in the salivary glands of BSE-affected cattle at the terminal stage of infection (1). Therefore, once the infectious agent reaches the central nervous system, it may spread centrifugally from the brain to the salivary glands through the autonomic nervous system. Infectivity of saliva and the presence of PrPSc in saliva have been reported in other ruminants affected with transmissible spongiform encephalopathy. Infectivity of saliva was demonstrated in deer with chronic wasting disease (3) and in scrapie-affected sheep (4); the immunolabeled PrPSc accumulated in the salivary glands of scrapie-affected sheep (5). A low level of PrPSc was detected in concentrated buccal swab samples of preclinical scrapie-infected sheep by using sPMCA (6,7). These results suggest that small amounts of PrPSc may accumulate in the salivary glands and are then secreted into saliva. The presence of infectious prions in saliva may explain the facile horizontal transmission of scrapie in sheep (4–6) and chronic wasting disease in deer (4,8). There has been no epidemiologic evidence, however, that saliva, milk, blood, and cerebrospinal fluid from BSE-infected cattle are infectious (9). Nonetheless, the potential risk for BSE transmission by body fluids or excretions from BSE-infected cattle is cannot be ruled out by the current data.



Hiroyuki Okada, Yuichi Murayama , Noriko Shimozaki, Miyako Yoshioka, Kentaro Masujin, Morikazu Imamura, Yoshifumi Iwamaru, Yuichi Matsuura, Kohtaro Miyazawa, Shigeo Fukuda, Takashi Yokoyama, and Shirou Mohri



Author affiliations: Author affiliations: National Agriculture and Food Research Organization, Tsukuba, Japan (H. Okada, Y. Murayama, N. Shimozaki, M. Yoshioka, K. Masujin, M. Imamura, Y. Iwamaru, Y. Matsuura, K. Miyazawa, T. Yokoyama, S. Mohri); Hokkaido Research Organization, Shintoku, Japan (S. Fukuda)



Acknowledgment



This work was supported by a grant-in-aid from the BSE and Other Prion Disease Project of the Ministry of Agriculture, Forestry and Fisheries, Japan.



References



1.Murayama Y, Yoshioka M, Masujin K, Okada H, Iwamaru Y, Imamura M, Sulfated dextrans enhance in vitro amplification of bovine spongiform encephalopathy PrPSc and enable ultrasensitive detection of bovine PrPSc. PLoS ONE. 2010;5:e13152. DOIPubMed 2.Okada H, Iwamaru Y, Imamura M, Masujin K, Matsuura Y, Murayama Y, Detection of disease-associated prion protein in the posterior portion of the small intestine involving the continuous Peyer’s patch in cattle orally infected with bovine spongiform encephalopathy agent. Transbound Emerg Dis. 2011;58:333–43. DOIPubMed 3.Haley NJ, Seelig DM, Zabel MD, Telling GC, Hoover EA. Detection of CWD prions in urine and saliva of deer by transgenic mouse bioassay. PLoS ONE. 2009;4:e4848. DOIPubMed 4.Tamgüney G, Richt JA, Hamir AN, Greenlee JJ, Miller MW, Wolfe LL, Salivary prions in sheep and deer. Prion. 2012;6:52–61. DOIPubMed 5.Vascellari M, Nonno R, Mutinelli F, Bigolaro M, Di Bari MA, Melchiotti E, PrPSc in salivary glands of scrapie-affected sheep. J Virol. 2007;81:4872–6. DOIPubMed 6.Maddison BC, Rees HC, Baker CA, Taema M, Bellworthy SJ, Thorne L, Prions are secreted into the oral cavity in sheep with preclinical scrapie. J Infect Dis. 2010;201:1672–6. DOIPubMed 7.Gough KC, Baker CA, Rees HC, Terry LA, Spiropoulos J, Thorne L, The oral secretion of infectious scrapie prions occurs in preclinical sheep with a range of PRNP genotypes. J Virol. 2012;86:566–71. DOIPubMed 8.Mathiason CK, Powers JG, Dahmes SJ, Osborn DA, Miller KV, Warren RJ, Infectious prions in the saliva and blood of deer with chronic wasting disease. Science. 2006;314:133–6. DOIPubMed 9.Brown P, Andréoletti O, Bradley R, Budka H, Deslys JP, Groschup M, WHO tables on tissue infectivity distribution in transmissible spongiform encephalopathies. Geneva: World Health Organization; 2010 [cited 2011 Nov 2]. http://www.who.int/bloodproducts/tablestissueinfectivity.pdf



Figure Figure. . Western blot detection, using the serial protein misfolding cyclic amplification technique, of the abnormal (disease-associated) form of the prion protein (PrPSc) in concentrated saliva samples from 3 cows experimentally...



Suggested citation for this article: Okada H, Murayama Y, Shimozaki N, Yoshioka M, Masujin K, Imamura M, et al. Prion in saliva of bovine spongiform encephalopathy–infected cattle [letter]. Emerg Infect Dis [Internet]. 2012 Dec [date cited]. DOI: http://dx.doi.org/10.3201/eid1812.120528



DOI: 10.3201/eid1812.120528









DISSERTATION



CHRONIC WASTING DISEASE: A MODEL FOR PRION TRANSMISSION VIA SALIVA AND URINE


Submitted by Nicholas James Haley


Department of Microbiology, Immunology and Pathology In partial fulfillment of the requirements For the Degree of Doctor of Philosophy Colorado State University Fort Collins, Colorado Summer 2010



ABSTRACT OF DISSERTATION CHRONIC WASTING DISEASE: A MODEL FOR PRION TRANSMISSION VIA SALIVA AND URINE



Chronic wasting disease (CWD) of cervids is a prion disease distinguished by its high level of transmissibility, wherein bodily fluids and excretions are thought to play an important role. Typical of all prion diseases, CWD is characterized by the forced conversion of the normal prion protein (PrPC) into a misfolded isoform (PrPCWD), which has been shown to accumulate primarily in tissues of the lymphoid and nervous systems, though has also been found in other peripheral tissues including elements of the cardiovascular, musculoskeletal, and urogenital systems. Despite strong evidence that natural infection is acquired from the environment, as well as saliva and blood, a more thorough evaluation of excreta, including saliva, urine, and feces, is essential for a comprehensive foundation for (1) understanding how environmental CWDcontamination occurs, (2) developing in vitro assays for the antemortem identification of CWD-infected cervids, and (3) demonstrating the pathogenesis of the disease in the natural host.


In this dissertation, two approaches are used to identify infectious CWD prions and PrPCWD in the bodily fluids and tissues of CWD-exposed white-tailed deer: a novel bioassay system using a transgenic mouse line expressing the cervid PrP protein (Tg[CerPrP] mice), and a recently developed prion amplification assay known as serial iv protein misfolding cyclic amplification (sPMCA). In conjunction with immunohistochemistry and western blotting, these two assays were used to definitively identify CWD prions in saliva and urine, in addition to elements of the lymphoreticular system, central and peripheral nervous systems, and urogenital and oropharyngeal tissues. In initial experiments, concentrated urine and saliva samples from terminal CWD+ white-tailed deer, suspected of harboring infectious CWD prions, was assessed by Tg[CerPrP] bioassay and sPMCA. Authentic prion infectivity was detected in urine and saliva using both detection systems in the case of urine, though only mouse bioassay successfully demonstrated CWD prions in saliva. The concentration of abnormal prion protein in bodily fluids was very low, as indicated by: undetectable PrPCWD levels by traditional assays (western blot, ELISA) and prolonged incubation periods and incomplete TSE attack rates in inoculated Tg[CerPrP] mice. These findings helped to extend the understanding of CWD prion shedding and transmission and portend the detection of infectious prions in body fluids in other prion infections.


Based on the identification of CWD prions in saliva (“prionsialia”) and urine (“prionuria”), I next sought to determine whether deer previously exposed orally to urine and feces from CWD+ sources, while conventional test-negative, may actually be harboring very low level CWD infection not evident in the 19 month observation period in initial cervid bioassay studies. A selection of tissues, including those of the lymphoreticular and both central and peripheral nervous systems were fully examined, initially using Tg[CerPrP] bioassay to demonstrate true infectivity, and secondarily with sPMCA. Positive controls consisted of issues from CWD+ deer exposed orally to saliva; negative control tissue sets were collected from deer exposed orally and intracranially to


v


CWD-negative brain. PrPCWD was detected in the tissues of orally exposed deer by both sPMCA and Tg[CerPrP] mouse bioassay; each assay revealed very low levels of CWD prions previously undetectable by western blot, ELISA, or IHC. Serial PMCA analysis of individual tissues identified that obex alone was positive in urine/feces exposed deer. PrPCWD was amplified from both LRS and neural tissues of positive control deer but not from the same tissues of negative control deer. Detection of subclinical infection in deer orally exposed to urine and feces (1) suggests that a prolonged subclinical state can exist such that observation periods in excess of two years may be needed to detect CWD infection, and (2) illustrates the sensitive and specific application of sPMCA in the diagnosis of low-level prion infection.


Despite the confirmation of infectious prions in urine and saliva, along with conventional test-negative deer exposed to urine and feces, the manner in which infectivity is transferred to these excreta is unknown. To address this, I went on to apply sPMCA to tissues associated with production and excretion of urine and saliva in an effort to seek proximal sources of prion shedding. I blindly analyzed oropharyngeal and urogenital tissues, reproducibly demonstrating PrPCWD in each tissue examined in 3 rounds of sPMCA; whereas blood samples from the same animals and concurrent negative controls remained negative. Tissue distribution was affected by route of inoculation and CNS burden. The identification of PrPCWD in bodily fluids and conventional-test negative tissues – in the absence of detection by conventional methods – may indicate the presence of protease-sensitive infectious prions in excretory tissues not revealed by assays employing PK digestion or other means to remove PrPC reactivity.


vi


The continued evaluation of bodily fluids and peripheral tissues via sPMCA may therefore allow additional insights into prion transmission, trafficking, and pathogenesis.


Nicholas James Haley Department of Microbiology, Immunology and Pathology Colorado State University Fort Collins, CO 80523 Summer 2010


snip...


In summary, this study demonstrates for the first time amplifiable PrPCWD in various organs and tissues associated with prionsialia and prionuria. The ultimate source and mechanism of release into bodily fluids remain unknown, though elevated levels in both salivary gland and urinary bladder provides strong evidence that these tissues play a crucial role in prion excretion. In addition, the source and route of inoculation weighed heavily on the terminal peripheral distribution of PrPCWD, as did an individual’s apparent central nervous system burden. Finally, while this discovery provides evidence for prion invasion of peripheral excretory tissues, the timing of infiltration during CWD infection and the protease resistance profile of these prions warrant future studies in serial pathogenesis and detection of alternate infectious prion species.












Sunday, July 03, 2011


Prion Disease Detection, PMCA Kinetics, and IgG in Urine from Naturally/Experimentally Infected Scrapie Sheep and Preclinical/Clinical CWD Deer






Thursday, June 09, 2011


Detection of CWD prions in salivary, urinary, and intestinal tissues of deer: potential mechanisms of prion shedding and transmission





CHRONIC WASTING DISEASE: A MODEL FOR PRION TRANSMISSION VIA SALIVA AND URINE






Sunday, December 06, 2009


Detection of Sub-Clinical CWD Infection in Conventional Test-Negative Deer Long after Oral Exposure to Urine and Feces from CWD+ Deer






Wednesday, March 18, 2009


Detection of CWD Prions in Urine and Saliva of Deer by Transgenic Mouse Bioassay






*** Tuesday, September 02, 2008


Detection of infectious prions in urine (Soto et al Available online 13 August 2008.)






Friday, October 26, 2012


CHRONIC WASTING DISEASE CWD PENNSYLVANIA GAME FARMS, URINE ATTRACTANT PRODUCTS, BAITING, AND MINERAL LICKS






TSS