Monday, May 6, 2013

Warning of mad cow disease threat to blood transfusions

Warning of mad cow disease threat to blood transfusions


Ben Riley-Smith Reporter Monday 6 May 2013


patients could contract the human form of Creutzfeldt-Jakob Disease (CJD) from blood transfusions because current tests cannot detect a dormant strain of the virus, a leading scientist has warned.

Professor Marc Turner, medical director for the Scottish National Blood Transfusion Service, said shortfalls in technology mean blood donors are not screened for the passive form of variant (vCJD), otherwise known as mad cow disease.


Some 2500 Scots are estimated to be "silent" carriers of defective proteins that have caused people to develop the deadly brain-wasting illness, which can kill sufferers in 12 to 18 months.

The lack of understanding about the variant form means it is impossible to know which carriers of the proteins – known as prions – will go on to develop the disease, or if new cases will emerge.

Humans cannot now contract vCJD from eating British beef, following the culling of millions of cows in the late 1980s.


However, UK Government experts fear one in 20,000 Britons carry a dormant form that could be passed on in blood donations.

Mr Turner said: "We know vCJD can pass through blood transfusion... what's unknown is whether what we've done collectively so far in terms of precautionary measures has been enough to mitigate the risk of transmission. The key issue is whether [donors] have any evidence of infection in their blood.


Unfortunately it has proved very technically demanding to develop a vCJD blood test due to the very low levels of abnormal prions you might find in the blood of such individuals."


Mr Turner said most people over the age of 16 or 17 would have been exposed to BSE in the food chain, especially during the 1980s, and warned that in principle those exposed could have been infected with a form of vCJD.


He said these kind of diseases could have an incubation period of up to 50 years but there was no certainty the dormant form would ever become active.


The comments follow reports that up to 1000 people could die from the disease through infected blood given to them in hospitals, according to a risk assessment by the UK Government's Health Protection Analytical team. The total death toll from vCJD currently stands at 176.


Last month Nick Baxter, 65, the founder and former chief executive of leading Scottish social care charity Cornerstone, died after contracting sporadic CJD, one of four forms of the disease. Mr Baxter did not have the human form of mad cow disease.


Politicians and experts said the findings in the Government's report were worrying and called for nationwide screening of blood donors to be established.


Asked if he wanted to see such a system, Mr Turner said: "If we can get a test which we know is sensitive enough to pick up people who are incubating the illness and specific enough not to falsely identify positive people then yes, that would be clearly a good thing."


A Department of Health spokesman said it continues to encourage everyone to give blood, adding the UK has one of the safest blood supplies in the world.


He added: "There is no evidence of any UK clinical cases of vCJD being linked to a blood transfusion given after 1999. There have been no new cases in the UK for more than two years."
 
 
 


Monday, May 6, 2013

BSE-associated Prion-Amyloid Cardiomyopathy in Primates

Volume 19, Number 6—June 2013

 
 
 

Tuesday, April 30, 2013

Mad cow infected blood 'to kill 1,000’

http://vcjdtransfusion.blogspot.com/2013/04/mad-cow-infected-blood-to-kill-1000.html




Monday, April 15, 2013

Dr. Stephen B. Thacker Director Centers for Disease Control and Prevention′s Office of Science, Epidemiology and Laboratory Services (OSELS) dies from Creutzfeldt Jakob Disease CJD

http://creutzfeldt-jakob-disease.blogspot.com/2013/04/dr-stephen-b-thacker-director-centers.html




Tuesday, March 5, 2013

Use of Materials Derived From Cattle in Human Food and Cosmetics; Reopening of the Comment Period FDA-2004-N-0188-0051 (TSS SUBMISSION)

FDA believes current regulation protects the public from BSE but reopens comment period due to new studies

http://transmissiblespongiformencephalopathy.blogspot.com/2013/03/use-of-materials-derived-from-cattle-in_6452.html




Sunday, February 10, 2013

Creutzfeldt-Jakob disease (CJD) biannual update (February 2013) Infection report/CJD

http://creutzfeldt-jakob-disease.blogspot.com/2013/02/creutzfeldt-jakob-disease-cjd-biannual.html




Sunday, June 3, 2012

A new neurological disease in primates inoculated with prion-infected blood or blood components

http://transmissiblespongiformencephalopathy.blogspot.com/2012/06/new-neurological-disease-in-primates.html




Thursday, August 16, 2012

Blood products, collected from a donor who was at risk for variant Creutzfeldt-Jakob disease ( vCJD) USA JUNE, JULY, AUGUST 2012

http://vcjdtransfusion.blogspot.com/2012/08/blood-products-collected-from-donor-who.html

http://transmissiblespongiformencephalopathy.blogspot.com/




Wednesday, August 24, 2011

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

http://transmissiblespongiformencephalopathy.blogspot.com/2011/08/all-clinically-relevant-blood.html




Sunday, May 1, 2011

W.H.O. T.S.E. PRION Blood products and related biologicals May 2011

http://transmissiblespongiformencephalopathy.blogspot.com/2011/05/who-tse-prion-blood-products-and.html




Monday, February 7, 2011

FDA’s Currently-Recommended Policies to Reduce the Possible Risk of Transmission of CJD and vCJD by Blood and Blood Products 2011 ???

http://tseac.blogspot.com/2011/02/fdas-currently-recommended-policies-to.html




Sunday, August 01, 2010

Blood product, collected from a donors possibly at increased risk for vCJD only, was distributed USA JULY 2010

http://vcjdtransfusion.blogspot.com/2010/08/blood-product-collected-from-donors.html




Tuesday, September 14, 2010

Transmissible Spongiform Encephalopathies Advisory Committee; Notice of Meeting October 28 and 29, 2010 (COMMENT SUBMISSION)

http://tseac.blogspot.com/2010/09/transmissible-spongiform_14.html




nothing like missing the bigger picture, but they been missing (ignroing) it since 1985 $$$


*** 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.

http://www.landesbioscience.com/journals/prion/01-Prion6-2-OralPresentations.pdf?nocache=1216084967




Wednesday, March 28, 2012

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

http://prionopathy.blogspot.com/2012/03/variably-protease-sensitve-prionopathy.html



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...

http://www.neuroprion.org/en/np-neuroprion.html


Thursday, August 12, 2010

Seven main threats for the future linked to prions

http://prionpathy.blogspot.com/2010/08/seven-main-threats-for-future-linked-to.html




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...

http://www.efsa.europa.eu/en/efsajournal/pub/e991.htm?emt=1

http://www.efsa.europa.eu/en/efsajournal/doc/e991.pdf




Rural and Regional Affairs and Transport References Committee

The possible impacts and consequences for public health, trade and agriculture of the Government's decision to relax import restrictions on beef Final report June 2010

2.65 At its hearing on 14 May 2010, the committee heard evidence from Dr Alan Fahey who has recently submitted a thesis on the clinical neuropsychiatric, epidemiological and diagnostic features of Creutzfeldt-Jakob disease.48 Dr Fahey told the committee of his concerns regarding the lengthy incubation period for transmissible spongiform encephalopathies, the inadequacy of current tests and the limited nature of our current understanding of this group of diseases.49

2.66 Dr Fahey also told the committee that in the last two years a link has been established between forms of atypical CJD and atypical BSE. Dr Fahey said that: They now believe that those atypical BSEs overseas are in fact causing sporadic Creutzfeldt-Jakob disease. They were not sure if it was due to mad sheep disease or a different form. If you look in the textbooks it looks like this is just arising by itself. But in my research I have a summary of a document which states that there has never been any proof that sporadic Creutzfeldt-Jakob disease has arisen de novo-has arisen of itself. There is no proof of that. The recent research is that in fact it is due to atypical forms of mad cow disease which have been found across Europe, have been found in America and have been found in Asia. These atypical forms of mad cow disease typically have even longer incubation periods than the classical mad cow disease.50

http://www.aph.gov.au/senate/committee/rrat_ctte/mad_cows/report/report.pdf




Atypical BSE in Cattle

To date the OIE/WAHO assumes that the human and animal health standards set out in the BSE chapter for classical BSE (C-Type) applies to all forms of BSE which include the H-type and L-type atypical forms. This assumption is scientifically not completely justified and accumulating evidence suggests that this may in fact not be the case. Molecular characterization and the spatial distribution pattern of histopathologic lesions and immunohistochemistry (IHC) signals are used to identify and characterize atypical BSE. Both the L-type and H-type atypical cases display significant differences in the conformation and spatial accumulation of the disease associated prion protein (PrPSc) in brains of afflicted cattle. Transmission studies in bovine transgenic and wild type mouse models support that the atypical BSE types might be unique strains because they have different incubation times and lesion profiles when compared to C-type BSE. 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.

http://www.prionetcanada.ca/detail.aspx?menu=5&dt=293380&app=93&cat1=387&tp=20&lk=no&cat2




P.4.23

Transmission of atypical BSE in humanized mouse models

Liuting Qing1, Wenquan Zou1, Cristina Casalone2, Martin Groschup3, Miroslaw Polak4, Maria Caramelli2, Pierluigi Gambetti1, Juergen Richt5, Qingzhong Kong1 1Case Western Reserve University, USA; 2Instituto Zooprofilattico Sperimentale, Italy; 3Friedrich-Loeffler-Institut, Germany; 4National Veterinary Research Institute, Poland; 5Kansas State University (Previously at USDA National Animal Disease Center), USA

Background: Classical BSE is a world-wide prion disease in cattle, and the classical BSE strain (BSE-C) has led to over 200 cases of clinical human infection (variant CJD). Atypical BSE cases have been discovered in three continents since 2004; they include the L-type (also named BASE), the H-type, and the first reported case of naturally occurring BSE with mutated bovine PRNP (termed BSE-M). The public health risks posed by atypical BSE were largely undefined.

Objectives: To investigate these atypical BSE types in terms of their transmissibility and phenotypes in humanized mice. Methods: Transgenic mice expressing human PrP were inoculated with several classical (C-type) and atypical (L-, H-, or Mtype) BSE isolates, and the transmission rate, incubation time, characteristics and distribution of PrPSc, symptoms, and histopathology were or will be examined and compared.

Results: Sixty percent of BASE-inoculated humanized mice became infected with minimal spongiosis and an average incubation time of 20-22 months, whereas only one of the C-type BSE-inoculated mice developed prion disease after more than 2 years. Protease-resistant PrPSc in BASE-infected humanized Tg mouse brains was biochemically different from bovine BASE or sCJD. PrPSc was also detected in the spleen of 22% of BASE-infected humanized mice, but not in those infected with sCJD. Secondary transmission of BASE in the humanized mice led to a small reduction in incubation time.*** The atypical BSE-H strain is also transmissible with distinct phenotypes in the humanized mice, but no BSE-M transmission has been observed so far.

Discussion: Our results demonstrate that BASE is more virulent than classical BSE, has a lymphotropic phenotype, and displays a modest transmission barrier in our humanized mice. 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.

http://www.prion2009.com/sites/default/files/Prion2009_Book_of_Abstracts.pdf




P26 TRANSMISSION OF ATYPICAL BOVINE SPONGIFORM ENCEPHALOPATHY (BSE) IN HUMANIZED MOUSE MODELS

Liuting Qing1, Fusong Chen1, Michael Payne1, Wenquan Zou1, Cristina Casalone2, Martin Groschup3, Miroslaw Polak4, Maria Caramelli2, Pierluigi Gambetti1, Juergen Richt5*, and Qingzhong Kong1 1Department of Pathology, Case Western Reserve University, Cleveland, OH 44106, USA; 2CEA, Istituto Zooprofilattico Sperimentale, Italy; 3Friedrich-Loeffler-Institut, Germany; 4National Veterinary Research Institute, Poland; 5Kansas State University, Diagnostic Medicine/Pathobiology Department, Manhattan, KS 66506, USA. *Previous address: USDA National Animal Disease Center, Ames, IA 50010, USA

Classical BSE is a world-wide prion disease in cattle, and the classical BSE strain (BSE-C) has led to over 200 cases of clinical human infection (variant CJD). Two atypical BSE strains, BSE-L (also named BASE) and BSE-H, have been discovered in three continents since 2004. The first case of naturally occurring BSE with mutated bovine PrP gene (termed BSE-M) was also found in 2006 in the USA. The transmissibility and phenotypes of these atypical BSE strains/isolates in humans were unknown. We have inoculated humanized transgenic mice with classical and atypical BSE strains (BSE-C, BSE-L, BSE-H) and the BSE-M isolate. We have found that the atypical BSE-L strain is much more virulent than the classical BSE-C. *** The atypical BSE-H strain is also transmissible in the humanized transgenic mice with distinct phenotype, but no transmission has been observed for the BSE-M isolate so far.

III International Symposium on THE NEW PRION BIOLOGY: BASIC SCIENCE, DIAGNOSIS AND THERAPY 2 - 4 APRIL 2009, VENEZIA (ITALY)

http://www.istitutoveneto.it/prion_09/Abstracts_09.pdf




I ask Professor Kong ;

Thursday, December 04, 2008 3:37 PM Subject: RE: re--Chronic Wating Disease (CWD) and Bovine Spongiform Encephalopathies (BSE): Public Health Risk Assessment

''IS the h-BSE more virulent than typical BSE as well, or the same as cBSE, or less virulent than cBSE? just curious.....''

Professor Kong reply ;

.....snip

''As to the H-BSE, we do not have sufficient data to say one way or another, but we have found that H-BSE can infect humans. I hope we could publish these data once the study is complete. Thanks for your interest.''

Best regards, Qingzhong Kong, PhD Associate Professor Department of Pathology Case Western Reserve University Cleveland, OH 44106 USA

END...TSS

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.

http://www.prion2009.com/sites/default/files/Prion2009_Book_of_Abstracts.pdf

http://transmissiblespongiformencephalopathy.blogspot.com/2011/06/experimental-h-type-bovine-spongiform.html

http://bse-atypical.blogspot.com/2012/03/experimental-h-type-and-l-type-bovine.html




Atypical BSE (BASE) Transmitted from Asymptomatic Aging Cattle to a Primate

Emmanuel E. Comoy1*, Cristina Casalone2, Nathalie Lescoutra-Etchegaray1, Gianluigi Zanusso3, Sophie Freire1, Dominique Marcé1, Frédéric Auvré1, Marie-Magdeleine Ruchoux1, Sergio Ferrari3, Salvatore Monaco3, Nicole Salès4, Maria Caramelli2, Philippe Leboulch1,5, Paul Brown1, Corinne I. Lasmézas4, Jean-Philippe Deslys1

1 Institute of Emerging Diseases and Innovative Therapies, CEA, Fontenay-aux-Roses, France, 2 Istituto Zooprofilattico Sperimentale del Piemonte, Turin, Italy, 3 Policlinico G.B. Rossi, Verona, Italy, 4 Scripps Florida, Jupiter, Florida, United States of America, 5 Genetics Division, Brigham & Women's Hospital, Harvard Medical School, Boston, Massachusetts, United States of America

Abstract Top Background Human variant Creutzfeldt-Jakob Disease (vCJD) results from foodborne transmission of prions from slaughtered cattle with classical Bovine Spongiform Encephalopathy (cBSE). Atypical forms of BSE, which remain mostly asymptomatic in aging cattle, were recently identified at slaughterhouses throughout Europe and North America, raising a question about human susceptibility to these new prion strains.

Methodology/Principal Findings Brain homogenates from cattle with classical BSE and atypical (BASE) infections were inoculated intracerebrally into cynomolgus monkeys (Macacca fascicularis), a non-human primate model previously demonstrated to be susceptible to the original strain of cBSE. The resulting diseases were compared in terms of clinical signs, histology and biochemistry of the abnormal prion protein (PrPres). The single monkey infected with BASE had a shorter survival, and a different clinical evolution, histopathology, and prion protein (PrPres) pattern than was observed for either classical BSE or vCJD-inoculated animals. Also, the biochemical signature of PrPres in the BASE-inoculated animal was found to have a higher proteinase K sensitivity of the octa-repeat region. We found the same biochemical signature in three of four human patients with sporadic CJD and an MM type 2 PrP genotype who lived in the same country as the infected bovine.

Conclusion/Significance Our results point to a possibly higher degree of pathogenicity of BASE than classical BSE in primates and also raise a question about a possible link to one uncommon subset of cases of apparently sporadic CJD. Thus, despite the waning epidemic of classical BSE, the occurrence of atypical strains should temper the urge to relax measures currently in place to protect public health from accidental contamination by BSE-contaminated products.

Citation: Comoy EE, Casalone C, Lescoutra-Etchegaray N, Zanusso G, Freire S, et al. (2008) Atypical BSE (BASE) Transmitted from Asymptomatic Aging Cattle to a Primate. PLoS ONE 3(8): e3017. doi:10.1371/journal.pone.0003017

Editor: Neil Mabbott, University of Edinburgh, United Kingdom

Received: April 24, 2008; Accepted: August 1, 2008; Published: August 20, 2008

Copyright: © 2008 Comoy et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Funding: This work has been supported by the Network of Excellence NeuroPrion.

Competing interests: CEA owns a patent covering the BSE diagnostic tests commercialized by the company Bio-Rad.

* E-mail: mailto:emmanuel.comoy%40cea.fr

snip...

In summary, we have transmitted one atypical form of BSE (BASE) to a cynomolgus macaque monkey that had a shorter incubation period than monkeys infected with classical BSE, with distinctive clinical, neuropathological, and biochemical features; and have shown that the molecular biological signature resembled that seen in a comparatively uncommon subtype of sporadic CJD. We cannot yet say whether BASE is more pathogenic for primates (including humans) than cBSE, nor can we predict whether its molecular biological features represent a clue to one cause of apparently sporadic human CJD. However, the evidence presented here and by others justifies concern about a potential human health hazard from undetected atypical forms of BSE, and despite the waning epizoonosis of classical BSE, it would be premature to abandon the precautionary measures that have been so successful in reversing the impact of cBSE. We would instead urge a gradual, staged reduction that takes into account the evolving knowledge about atypical ruminant diseases, and both a permanent ban on the use of bovine central nervous system tissue for either animal or human use, and its destruction so as to eliminate any risk of environmental contamination.

http://www.plosone.org/article/info%3Adoi%2F10.1371%2Fjournal.pone.0003017


Proc Natl Acad Sci U S A. 2004 March 2; 101(9): 3065–3070. Published online 2004 February 17. doi: 10.1073/pnas.0305777101 PMCID: PMC365745 Medical Sciences

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*

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.

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.

http://www.ncbi.nlm.nih.gov/pmc/articles/PMC365745/



FC5.1.1

Transmission Results in Squirrel Monkeys Inoculated with Human sCJD, vCJD, and GSS Blood Specimens: the Baxter Study

Brown, P1; Gibson, S2; Williams, L3; Ironside, J4; Will, R4; Kreil, T5; Abee, C3 1Fondation Alliance BioSecure, France; 2University of South Alabama, USA; 3University of Texas MD Anderson Cancer Center, USA; 4Western General Hospital, UK; 5Baxter BioSience, Austria

Background: Rodent and sheep models of Transmissible Spongiform Encephalopathy (TSE) have documented blood infectivity in both the pre-clinical and clinical phases of disease. Results in a (presumably more appropriate) non-human primate model have not been reported.

Objective: To determine if blood components (red cells, white cells, platelets, and plasma) from various forms of human TSE are infectious.

Methods: Blood components were inoculated intra-cerebrally (0.1 ml) and intravenously (0.5 ml) into squirrel monkeys from 2 patients with sporadic Creutzfeldt- Jakob disease (sCJD) and 3 patients with variant Creutzfeldt-Jakob disease (vCJD). Additional monkeys were inoculated with buffy coat or plasma samples from chimpanzees infected with either sCJD or Gerstmann-Sträussler-Scheinker disease (GSS). Animals were monitored for a period of 5 years, and all dying or sacrificed animals had post-mortem neuropathological examinations and Western blots to determine the presence or absence of the misfolded prion protein (PrPTSE).

Results: No transmissions occurred in any of the animals inoculated with blood components from patients with sporadic or variant CJD. All donor chimpanzees (sCJD and GSS) became symptomatic within 6 weeks of their pre-clinical phase plasmapheresis, several months earlier than the expected onset of illness. One monkey inoculated with purified leukocytes from a pre-clinical GSS chimpanzee developed disease after 36 months.

Conclusion: No infectivity was found in small volumes of blood components from 4 patients with sporadic CJD and 3 patients with variant CJD. ***However, a single transmission from a chimpanzee-passaged strain of GSS shows that infectivity may be present in leukocytes, and the shock of general anaesthesia and plasmspheresis appears to have triggered the onset of illness in pre-clinical donor chimpanzees.

Saturday, September 5, 2009

TSEAC MEETING FEBRUARY 12, 2004 THE BAXTER STUDY GSS

snip...

http://tseac.blogspot.com/2011/06/tseac-meeting-august-1-2011-donor.html



Saturday, September 5, 2009

TSEAC MEETING FEBRUARY 12, 2004 THE BAXTER STUDY GSS

snip...

But the first thing is our own study, and as I mentioned, it's a Baxter primate study, and those are the major participants. And the goal was twofold, and here is the first one: to see whether CJD, either sporadic or familial -- actually it turns out to be the familial CJD is incorrect. It really should be the Fukuoka strain of Gerstmann-Straussler-Scheinker disease. So it's really GSS instead of familial CJD -- when passaged through chimps into squirrel monkeys using purified blood components, very pure blood components.

So this addresses the question that was raised just recently about whether or not red cell infectivity that's been found in rodents is really in the red cells or is it contaminated.

We prepared these samples with exquisite care, and they are ultra-ultra-ultra purified. There's virtually no contamination of any of the components that we looked at ? platelets, red cells, plasma, white cells -- with any other component.

These are a sort of new set of slides, and what I've tried to do is make them less complicated and more clear, but I'm afraid I haven't included the build. So you'll just have to try and follow what I explain with this little red pointer.

There were three initial patients. Two of them had sporadic CJD. One of them had Gerstmann-Straussler-Scheinker syndrome. Brain tissue from each individual patient was inoculated intracerebrally into a pair of chimpanzees. All right?

From those chimps, either plasma or ultra purified -- in fact, everything is ultra-purified. I'll just talk about purified plasma, purified white cells -- were inoculated intracerebrally and intravenously to get the maximum amount of infective load into a pair of squirrel monkeys.

The same thing was done for each of these three sets. This monkey died from non-CJD causes at 34 months post inoculation.

Let me go back for a second. I didn't point out the fact that these were not sacrificed at this point. These chimpanzees were apheresed at 27 weeks when they were still asymptomatic. In this instance, we apheresed them terminally when they were symptomatic.

And before I forget, I want to mention just a little sidelight of this. Chimpanzees in our experience -- and I think we may be the only people that have ever inoculated chimpanzees, and that's no longer a possibility, so this was 20, 30 years ago -- the shortest incubation period of any chimpanzee that we have ever seen with direct intracerebral inoculation is 13 months.

So we chose 27 weeks, which is about seven months, and incidentally typically the incubation period is more like 16 or 18 months. The shortest was 13 months. We chose the 27th week, which is about six and a half months, thinking that this would be about halfway through the incubation period, which we wanted to check for the presence or absence of infectivity.

But within four weeks after the apheresis, which was conducted under general anesthesia for three or four hours apiece, every single one of the six chimpanzees became symptomatic. That is another experiment that I would love to conclude, perhaps because this is simply not heard of, and it very much smells like we triggered clinical illness. We didn't trigger the disease, but it certainly looks like we triggered symptomatic disease at a point that was much earlier than one would have possibly expected.

Maybe it will never be done because it would probably open the floodgates of litigation. There's no end of little things that you can find out from CJD patients after the fact. For example, the neighbor's dog comes over, barks at a patient, makes him fall down, and three weeks later he gets CJD. So you have a lawsuit against the neighbor.

I mean, this is not an unheard of matter, but I do think that physical stress in the form of anesthesia and four hours of whatever goes on with anesthesia, low blood pressure, sometimes a little hypoxemia looks like it's a bad thing.

So here we have the 31st week. All of the chimps are symptomatic, and here what we did was in order to make the most use of the fewest monkeys, which is always a problem in primate research, we took these same three patients and these six chimps. Only now we pooled these components; that is to say, we pooled the plasma from all six chimps. We pooled ultra-purified white cells from all six chimps because here we wanted to see whether or not we could distinguish a difference between intracerebral route of infection and intravenous route of infection.

With respect to platelets and red blood cells, we did not follow that. We inoculated both intracerebral and intravenously, as we had done earlier because nobody has any information on whether or not platelets and red cells are infectious, and so we wanted again to get the maximum.

This is an IV versus IC goal. This one, again, is just getting the maximum load in to see whether there is, in fact, any infectivity in pure platelets, in pure red cells.

And of all of the above, the only transmission of disease related to the inoculation was in a squirrel monkey that received pure leukocytes from the presymptomatic apheresis. So that goes some way to address the question as to whether or not it's a matter of contamination. To date the red cells have not been -- the monkeys that receive red cells have not been observed for more than a year because that was a later experiment.

So we still can't say about red cells, but we're about four and a half years down the road now, and we have a single transmission from purified leukocytes, nothing from plasma and nothing from platelets.

That was the first part of the experiment. The second part was undertaken with the cooperation of Bob Will and others supplying material to us. These were a couple of human, sporadic cases of CJD and three variant cases of CJD from which we obtained buffy coat and plasma separated in a normal way. That is, these are not purified components.

The two cases of sporadic CJD, the plasma was pooled from both patients. The buffy coat was pooled from both patients, and then inoculated intracerebrally and intravenously into three squirrel monkeys each. This is a non-CJD death five years after inoculation. The other animals are still alive.

For variant CJD we decided not to pool. It was more important to eliminate the possibility that there was just a little bit of infectivity in one patient that would have been diluted to extinction, if you like, by mixing them if it were to so occur with two patients, for example, who did not have infectivity. So each one of these was done individually, but the principle was the same: plasma and buffy coat for each patient was inoculated into either two or three squirrel monkeys. This is, again, a non-CJD related death.

In addition to that, we inoculated rain as a positive control from the two sporadic disease cases of human -- from the two human sporadic cases at ten to the minus one and ten to the minus three dilutions. We have done this many, many times in the past with other sporadic patients. So we knew what to expect, and we got exactly what we did expect, namely, after an incubation period not quite two years, all four monkeys developed disease at this dilution and at the minus three dilution, not a whole lot of difference between the two.

Now, these are the crucial monkeys because each one of these monkeys every three to four months was bled and the blood transfused into a new healthy monkey, but the same monkey all the time. So this monkey, for example, would have received in the course of 21 months about six different transfusions of blood from this monkey into this monkey, similarly with this pair, this pair, and this pair. So you can call these buddies. This is sort of the term that was used. These monkeys are still alive.

In the same way, the three human variant CJD specimens, brain, were inoculated into four monkeys, and again, each one of these monkeys has been repeatedly bled at three to four month intervals and that blood transfused into a squirrel monkey, the same one each time. Ideally we would love to have taken bleeding at three months and inoculated a monkey and then let him go, watch him, and then done the same thing at six months. It would have increased the number of monkeys eightfold and just unacceptably expensive. So we did the best we could.

That, again, is a non-CJD death, as is this.

This was of interest mainly to show that the titer of infectivity in brain from variant CJD is just about the same as it from sporadic. We didn't do a minus five and a minus seven in sporadic because we have an enormous experience already with sporadic disease in squirrel monkeys, and we know that this is exactly what happens. It disappears at about ten to the minus five. So the brain titer in monkeys receiving human vCJD is identical to the brain titer in monkeys that have been inoculated with sporadic CJD.

That's the experiment. All of the monkeys in aqua are still alive. They are approaching a five-year observation period, and I think the termination of this experiment will now need to be discussed very seriously in view of a probable six-year incubation period in the U.K. case. The original plan was to terminate the experiment after five years of observation with the understanding that ideally you would keep these animals for their entire life span, which is what we used to do when had unlimited space, money, and facilities. We can't do that anymore.

It's not cheap, but I think in view of the U.K. case, it will be very important to think very seriously about allowing at least these buddies and the buddies from the sporadic CJD to go on for several more years because although you might think that the U.K. case has made experimental work redundant, in point of fact, anything that bears on the risk of this disease in humans is worthwhile knowing, and one of the things we don't know is frequency of infection. We don't know whether this case in the U.K. is going to be unique and never happen again or whether all 13 or 14 patients have received blood components are ultimately going to die. Let's hope not.

The French primate study is primarily directed now by Corinne Lasmezas. As you know, the late Dominique Dromont was the original, originally initiated this work, and they have very active primate laboratory in France, and I'm only going to show two very simple slides to summarize what they did.

The first one is simply to show you the basis of their statement that the IV route of infection looks to be pretty efficient because we all know that the intracerebral route of infection is the most efficient, and if you look at this where they inoculated the same infective load either intracerebrally or intravenously, the incubation periods were not substantially different, which suggests but doesn't prove, but doesn't prove that the route of infection is pretty efficient.

Lower doses of brain material given IV did extend the incubation period and presumably it's because of the usual dose response phenomenon that you see in any infectious disease.

With a whopping dose of brain orally, the incubation period was even lower. Again, just one more example of inefficiency of the route of infection and the necessity to use more infective material to get transmissions.

And they also have blood inoculated IV which is on test, and the final slide or at least the penultimate slide shows you what they have on test and the time of observation, that taken human vCJD and like us inoculated buffy coat, they've also inoculated whole blood which we did not do.

So to a great extent their studies are complementary to ours and makes it all worthwhile.

We have about -- oh, I don't know -- a one to two-year lead time on the French, but they're still getting into pretty good observation periods. Here's three-plus years.

They have variant CJD adapted to the macaque. That is to say this one was passaged in macaque monkeys, the cynomolgus, and they did the same thing. Again, we're talking about a study here in which like ours there are no transmissions. I mean, we have that one transmission from leukocytes, and that's it.

Here is a BSE adapted to the macaque. Whole blood, and then they chose to inoculate leukodepleted whole blood, in both instances IV. Here they are out to five years without a transmission.

And then finally oral dosing of the macaque, which had been infected with -- which was infected with BSE, but a macaque passaged BSE, whole blood buffy coat and plasma, all by the IC route, and they're out to three years.

So with the single exception of the leukocyte transmission from our chimp that was inoculated with a sporadic case of CJD or -- excuse me -- with a GSS, Gerstmann-Straussler, in neither our study nor the French study, which are not yet completed have we yet seen a transmission.

And I will just close with a little cartoon that appeared in the Washington Post that I modified slightly lest you get too wound up with these questions of the risk from blood. This should be a "corrective."

(Laughter.)

DR. BROWN: Thanks.

Questions?

CHAIRPERSON PRIOLA: Yes. Any questions for Dr. Brown? Dr. Linden.

DR. LINDEN: I just want to make sure I understand your study design correctly. When you mention the monkeys that have the IV and IC inoculations, the individual monkeys had both or --

DR. BROWN: Yes, yes, yes. That's exactly right.

DR. LINDEN: So an individual monkey had both of those as opposed to some monkeys had one and some had the other?

DR. BROWN: Correct, correct. Where IC and IV are put down together was IC plus IV into a given monkey.

DR. LINDEN: Into a given monkey. Okay.

And the IC inoculations, where were those given?

DR. BROWN: Right parietal cortex, Southern Alabama.

(Laughter.)

DR. BROWN: Oh, it can't be that clear. Yeah, here, Pierluigi.

CHAIRPERSON PRIOLA: Dr. Epstein.

DR. BROWN: Pierluigi always damns me with feint praise. He always says that's a very interesting study, but. I'm waiting for that, Pierluigi.

I think Jay Epstein --

DR. GAMBETTI: I will say that there's an interesting study and will say, but I just --

(Laughter.)

DR. GAMBETTI: -- I just point of review. You talk about a point of information. You say that -- you mention GSS, I guess, and the what, Fukuowa (phonetic) --

DR. BROWN: Yes, Fukuoka 1.

DR. GAMBETTI: Fukuowa, and is that from the 102, if I remember correctly, of the --

DR. BROWN: Yes, that is correct.

DR. GAMBETTI: Because that is the only one that also --

DR. BROWN: No, it's not 102. It's 101. It's the standard. It's a classical GSS. Oh, excuse me. You're right. One, oh, two is classical GSS. It's been so long since I've done genetics. You're right.

DR. GAMBETTI: Because that is the only one I know, I think, that I can remember that has both the seven kv fragment that is characteristic of GSS, but also the PrPsc 2730. So in a sense, it can be stretching a little bit compared to the sporadic CJD.

DR. BROWN: Yeah, I think that's right. That's why I want to be sure that I made you aware on the very first slide that that was not accurate, that it truly was GSS.

There's a GSS strain that has been adapted to mice, and it's a hot strain, and therefore, it may not be translatable to sporadic disease, correct. All we can say for sure is that it is a human TSE, and it is not variant. I think that's about it.

DR. GAMBETTI: I agree, but this is also not perhaps the best --

DR. BROWN: No, it is not the best. We understand --

DR. GAMBETTI: -- of GSS either.

DR. BROWN: Yeah. If we had to do it over again, we'd look around for a -- well, I don't know. We'd probably do it the same way because we have two sporadics already on test they haven't transmitted, and so you can take your pick of what you want to pay attention to.

Jay?

DR. EPSTEIN: Yes, Paul. Could you just comment? If I understood you correctly, when you did the pooled apheresis plasma from the six chimps when they were symptomatic at 31 weeks, you also put leukocytes into squirrel monkeys in that case separately IV and IC, but in that instance you have not seen an infection come down in squirrel monkey, and the question is whether it's puzzling that you got transmission from the 27-week asymptomatic sampling, whereas you did not see transmission from the 31-week sampling in symptomatic animals.

DR. BROWN: Yes, I think there are two or three possible explanations, and I don't know if any of them are important. The pre-symptomatic animal was almost symptomatic as it turned out so that we were pretty close to the period at which symptoms would being, and whether you can, you know, make much money on saying one was incubation period and the other was symptomatic in this particular case because both bleedings were so close together. That's one possibility.

The other possibility is we're dealing with a very irregular phenomenon and you're not surprised at all by surprises, so to speak so that a single animal, you could see it almost anywhere.

The third is that we, in fact, did just what I suggested we didn't want to do for the preclinical, namely, by pooling we got under the threshold. See?

You can again take that for what it's worth. It is a possible explanation, and again, until we know what the levels of infectivity are and whether by pooling we get under the threshold of transmission, we simply cannot make pronouncements.

CHAIRPERSON PRIOLA: Dr. DeArmond.

DR. DeARMOND: Yeah, it was very interesting data, but the --

(Laughter.)

DR. BROWN: I just love it. Go ahead.

DR. DeARMOND: Two comments. The first one was that the GSS cases, as I remember from reading your publications -- I think Gibbs was involved with them -- when you transmitted the GSS into animals, into monkeys, perhaps I think it was chimps, the transmission was more typical of CJD rather than GSS. There were no amyloid plaques. It was vacuolar degeneration so that you may be transmitting a peculiar form, as I criticized once in Bali and then you jumped all over me about.

DR. BROWN: I may do it again.

DR. DeARMOND: Calling me a bigot and some other few things like that.

(Laughter.)

DR. BROWN: Surely not. I wouldn't have said that.

DR. DeARMOND: So there could be something strange about that particular --

DR. BROWN: Yeah. I think you and Pierluigi are on the same page here. This may be an unusual strain from a number of points of view.

DR. DeARMOND: The other question though has to do with species barrier because the data you're showing is kind of very reassuring to us that it's hard to transmit from blood, but the data from the sheep and from the hamsters and some of the work, I think, that has been done by others, that it's easy in some other animals to transmit, hamster to hamster, mouse to mouse.

Could you comment on the --

DR. BROWN: That's exactly why we went to primates. That's exactly it, because a primate is closer to a human than a mouse is, and that's just common sense.

And so to try and get a little closer to the human situation and not totally depend on rodents for transferrable data, that is why you would use a primate. Otherwise you wouldn't use them. They're too expensive and they cause grief to animal care study people and protocol makers and the whole thing.

Primate studies are a real pain.

DR. DeARMOND: But right now it's inconclusive and you need more time on it.

DR. BROWN: I believe that's true. I think if we cut it off at six years you could still say it was inconclusive, and cutting it off at all will be to some degree inconclusive, and that's just the way it is.

DR. DeARMOND: So what has to be done? Who do you have to convince, or who do we all have to convince to keep that going?

DR. BROWN: Thomas?

Without trying to be flip at all, the people that would be the first people to try to convince would be the funders of the original study. If that fails, and it might for purely practical reasons of finance, then we will have to look elsewhere because I really don't want to see those animals sacrificed, not those eight buddies. Those are crucial animals, and they don't cost a whole lot to maintain. You can maintain eight -- well, they cost a lot from my point of view, but 15 to $20,000 a year would keep them going year after year.

CHAIRPERSON PRIOLA: Dr. Johnson.

DR. JOHNSON: Yeah, Paul, I'm intrigued as you are by the shortening of the incubation period. Have you in all of the other years of handling these animals when they were transfused, when they were flown out to Louisiana at night -- a lot of the stressful things have happened to some of these chimps. Have you ever noticed that before or is this a new observation?

DR. BROWN: Brand new.

MR. JOHNSON: Brand new. Okay.

CHAIRPERSON PRIOLA: Bob, did you want to say something? Dr. Rohwer.

DR. ROHWER: The Frederick fire, wasn't that correlated with a lot of --

DR. BROWN: Not that I k now of, but you may --

DR. ROHWER: Well, that occurred shortly after I came to NIH, and what I remember is that there were a whole bunch of conversions that occurred within the few months following the fire. That was fire that occurred adjacent to the NINDS facility, but in order to protect it, they moved the monkeys out onto the tarmac because they weren't sure it wouldn't burn as well.

DR. BROWN: Well, if you're right, then it's not brand new, but I mean, I'm not sure how we'll ever know because if I call Carlton and ask him, I'm not sure but what I would trust the answer that he gives me, short of records.

You know, Carlot is a very enthusiastic person, and he might say, "Oh, yeah, my God, the whole floor died within three days," but I would want to verify that.

On the other hand, it may be verifiable. There possibly are records that are still extant.

DR. ROHWER: Actually I thought I heard the story from you.

(Laughter.)

DR. BROWN: You didn't because it's brand new for me. I mean, either that or I'm on the way

(Laughter.)

CHAIRPERSON PRIOLA: Dr. Bracey.

DR. BRACEY: I was wondering if some of the variability in terms of the intravenous infection route may be related to intraspecies barriers, that is, the genetic differences, the way the cells, the white leukocytes are processed, whether or not microchimerism is established, et cetera.

DR. BROWN: I don't think that processing is at fault, but the question, the point that you raise is a very good one, and needless to say, we have material with which we can analyze genetically all of the animals, and should it turn out that we get, for example, -- I don't know -- a transmission in one variant monkey and no transmissions in another and a transmission in three sporadic monkeys, we will at that point genetically analyze every single animal that has been used in this study, but we wanted to wait until we could see what would be most useful to analyze.

but the material is there, and if need be, we'll do it.

CHAIRPERSON PRIOLA: Okay. Thank you very much, Dr. Brown.

I think we'll move on to the open public hearing section of the morning.

snip...

http://www.fda.gov/ohrms/dockets/ac/04/transcripts/4019t1.DOC



snip...

see full text ;

http://tseac.blogspot.com/2009/09/tseac-meeting-february-12-2004-baxter.html




(Laughter.)

Saturday, January 20, 2007

Fourth case of transfusion-associated vCJD infection in the United Kingdom

http://vcjdtransfusion.blogspot.com/2007/01/fourth-case-of-transfusion-associated.html





(Laughter.)


Friday, June 29, 2012

Highly Efficient Prion Transmission by Blood Transfusion

http://transmissiblespongiformencephalopathy.blogspot.com/2012/06/highly-efficient-prion-transmission-by.html




(Laughter.)


Wednesday, August 24, 2011

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

http://transmissiblespongiformencephalopathy.blogspot.com/2011/08/all-clinically-relevant-blood.html





(Laughter.)

Sunday, July 20, 2008

Red Cross told to fix blood collection or face charges 15 years after warnings issued, few changes made to ensure safety

http://vcjdblood.blogspot.com/2008/07/red-cross-told-to-fix-blood-collection.html




Saturday, December 08, 2007

Transfusion Transmission of Human Prion Diseases

http://vcjdblood.blogspot.com/2006/12/vcjd-case-study-highlights-blood.html





Tuesday, October 09, 2007

nvCJD TSE BLOOD UPDATE

http://vcjdblood.blogspot.com/2007/10/nvcjd-tse-blood-update.html





Saturday, December 08, 2007

Transfusion Transmission of Human Prion Diseases

http://vcjdblood.blogspot.com/2007/12/transfusion-transmission-of-human-prion.html





Saturday, January 20, 2007

Fourth case of transfusion-associated vCJD infection in the United Kingdom

http://vcjdtransfusion.blogspot.com/2007/01/fourth-case-of-transfusion-associated.html





vCJD case study highlights blood transfusion risk 9 Dec 2006 by Terry S. Singeltary Sr.

THIS was like closing the barn door after the mad cows got loose. not only the red cross, but the FDA has failed the public in protecting them from the TSE aka mad cow agent. TSE agent ie bse, base, cwd, scrapie, tme, ...

vCJD case study highlights blood transfusion risk -

http://www.mrc.ac.uk/Newspublications/News/MRC003431

http://vcjdblood.blogspot.com/2006/12/vcjd-case-study-highlights-blood.html

http://vcjdblood.blogspot.com/




Friday, April 19, 2013

APHIS 2013 Stakeholder Meeting (March 2013) BSE TSE PRION

http://madcowusda.blogspot.com/2013/04/aphis-2013-stakeholder-meeting-march.html




TSS

BSE-associated Prion-Amyloid Cardiomyopathy in Primates

Volume 19, Number 6—June 2013


Dispatch



BSE-associated Prion-Amyloid Cardiomyopathy in Primates



Susanne Krasemann, Giulia Mearini, Elisabeth Krämer, Katja Wagenführ, Walter Schulz-Schaeffer, Melanie Neumann, Walter Bodemer, Franz-Josef Kaup, Michael Beekes, Lucie Carrier, Adriano Aguzzi1, and Markus Glatzel1Comments to Author
Author affiliations: University Medical Center Hamburg-Eppendorf, Hamburg, Germany (S. Krasemann, G. Mearini, E. Krämer, M. Neumann, L. Carrier, M. Glatzel); Robert Koch Institute, Berlin, Germany (K. Wagenführ, M. Beekes); University Hospital Göttingen, Göttingen, Germany (W. Schulz-Schaeffer); German Primate Center, Göttingen (W. Bodemer, F.-J. Kaup); University of Zurich, Zurich, Switzerland (A. Aguzzi)
 
 

Abstract





Prion amyloidosis occurred in the heart of 1 of 3 macaques intraperitoneally inoculated with bovine spongiform encephalopathy prions. This macaque had a remarkably long duration of disease and signs of cardiac distress. Variant Creutzfeldt-Jakob disease, caused by transmission of bovine spongiform encephalopathy to humans, may manifest with cardiac symptoms from prion-amyloid cardiomyopathy.



 
Human prion diseases are progressive neurologic disorders that include sporadic, genetic, and acquired forms of Creutzfeldt-Jakob disease (CJD) (1). A key step in disease initiation is conversion of PrPC into PrPSc, which is partially resistant to proteolytic digestion and an essential part of prion infectivity. Transmission of bovine spongiform encephalopathy (BSE) to humans has led to a novel form of acquired CJD, termed variant CJD (vCJD) (2). The pathogenesis of vCJD differs substantially from sporadic CJD with remarkable colonization of non–central nervous system regions with infectious prions and PrPSc (3).
 
 
 
 
Although risk reduction measures have been introduced to limit transmission from BSE-diseased cattle to humans, vCJD has occurred in several hundred instances (www.eurocjd.ed.ac.uk). Most clinically affected vCJD patients are homozygous for methionine on polymorphic codon 129 on the gene coding PrP (PRNP), and the clinical presentation of vCJD in these patients is uniform (4). The occurrence of atypical clinical features in persons with vCJD that encodes methionine and valine on PRNP codon 129 and human-to-human transmission of vCJD through blood transfusion have raised concern about atypical clinical features and alternative distribution of PrPSc in vCJD (5). We report on the novel clinicopathologic characteristics of vCJD as prion-amyloid cardiomyopathy in 1 of 3 macaques inoculated with BSE.
 
 
 
 

The Study

Figure 1
Thumbnail of PrPSc distribution and content in brain of bovine spongiform encephalopathy (BSE)–infected rhesus macaques. A) Paraffin-embedded tissue blot of striatum and cerebellum show a typical BSE-like deposition pattern of PrPSc with no differences between individual BSE-diseased monkeys at 49, 59, and 61 months postinoculation (mpi). Scale bar = 1 mm. B) Western blot analysis for PrPSc in brain of BSE-infected monkeys with incubation times of 49, 59, and 61 mpi. PrPSc-type is as expected fo



Figure 1. . PrPSc distribution and content in brain of bovine spongiform encephalopathy (BSE)–infected rhesus macaques. A) Paraffin-embedded tissue blot of striatum and cerebellum show a typical BSE-like deposition pattern of PrPSc with...



 
In 2002, three rhesus macaques were inoculated with BSE intraperitoneally (10 mL of a 10% homogenate of brain from BSE-diseased cattle). As controls, 2 rhesus macaques received saline (10 mL) and 1 was untreated. All procedures involving rhesus macaques were performed at the Institute of Neuropathology, University Medical Center Hamburg-Eppendorf (Hamburg, Germany), in accordance with the German Animal Welfare Act and the Council Directive 86/609/EEC (Permit 33.42502/08–08.02 LAVES, Lower Saxony, Germany). Animals were observed for clinical signs of prion disease and, when signs of terminal prion disease became evident, were euthanized and underwent autopsy. In all 3 BSE-challenged macaques and none of the controls a progressive neurologic disease developed 49, 59, and 61 months postinoculation. Examination of brain by using hematoxylin and eosin staining showed typical neuropathologic features of vCJD (data not shown) and abundant deposits of PrPSc in the cortex, basal ganglia, and cerebellum in paraffin-embedded tissue blots performed as described by using 12F10 monclonal antiprion antibody (6) (Figure 1, panel A). The mobility of the unglycosylated PrPSc band and the glycoform ratio of proteinase K–digested PrPSc were similar to those in BSE when assessed by Western blot analysis by using monoclonal POM-1 antiprion antibody as described (7) (Figure 1, panel B).

 
 
 
 
Figure 2
 
 
Thumbnail of Abundant PrPSc in heart of 1 bovine spongiform encephalopathy (BSE)–infected rhesus macaque. A) In sodium phosphotungstic acid precipitation of PrPSc, followed by Western blotting, highly abundant PrPSc was demonstrated in the heart of 1 BSE-infected primate. In this monkey, only the heart contained PrPSc. Controls include cardiac muscle spiked with minimal amounts brain of a healthy (–) and prion-diseased (+) primate. All analyses were prepared from 50 mg of tissue except the heart



Figure 2. . Abundant PrPSc in heart of 1 bovine spongiform encephalopathy (BSE)–infected rhesus macaque. A) In sodium phosphotungstic acid precipitation of PrPSc, followed by Western blotting, highly abundant PrPSc was demonstrated in...



 
Besides lymphoreticular tissues, the muscular compartment is targeted by prions (7,8). Thus, we assessed presence of PrPSc in skeletal and heart muscle by Western blot analysis with sodium phosphotungstic acid precipitation for enrichment of PrPSc and protein misfolding cyclic amplification by using published protocols (3). We could not detect substantial amounts of PrPSc in skeletal muscle (Figure 2, panel A). One macaque showed abundant PrPSc (≈1/100 of PrPSc found in brain) in heart in Western blot and protein misfolding cyclic amplification (Figure 2, panels A, B). Paraffin-embedded tissue blot analysis of this heart showed PrPSc as amyloid, occupying considerable stretches of heart tissue, mainly in the septum (Figure 2, panel C), whereas no PrPSc could be seen in hearts of other macaques (data not shown). These findings were confirmed by strong Congo red–positive patch-like depositions in cardiomyocytes in the heart of this monkey (Figure 2, panel D). The primate with cardiac PrPSc showed the longest disease duration (4 months, compared with 4 weeks for other BSE-infected monkeys), signs of cardiac affection when assessed by relevant makers of cardiac hypertrophy and of cardiac distress–associated inflammation, and only this macaque showed clinical signs of fatigue and signs of cardiac distress (i.e., venous congestion) on autopsy (Technical Appendix Adobe PDF file [PDF - 132 KB - 2 pages], Table). Histologic examination of heart tissue with hematoxylin and eosin staining and immunohistochemical stainings against B and T cells (CD20 [not shown] and CD3) did not provide evidence for toxic cardiomyopathy (i.e., fibrosis or vacuolization), nor did we find signs of inflammatory reaction (Figure 2, panel D).

 

 

Conclusions




 
Although the vCJD epidemic is declining, considerable concern exists that clinical characterastics of vCJD will shift. The most important genetic risk factor for development of vCJD is homozygosity for methionine on PRNP codon 129, and all but 1 patient with clinical vCJD carry this polymorphism (5). Thus, future cases of vCJD with longer incubation times are likely to comprise more patients with alternative codon 129 polymorphisms than methionine homozygosity. Data from rodent experiments indicate that clinical features of vCJD may differ in these patients (9). Thus, the next decades may see a shift in vCJD phenotypes. Further uncertainty for atypical cases in humans results from the possibility of secondary transmission of vCJD through blood products from subclinical carriers, which may lead to development of nonclassical vCJD phenotypes (5).





We showed that BSE infection of primates may occur as prion-amyloid cardiomyopathy. Because prion-amyloid cardiomyopathy developed in only 1 of 3 macaques, host-encoded factors, such as genetic makeup, probably influence development of this cardiac phenotype. All macaques are homozygous for methionine on PRNP codon 129; thus, prion-amyloid cardiomyopathy cannot be related to polymorphic codon 129 in our study (10). Cardiac involvement has been observed in a patient with sporadic CJD and is prominent in prion-diseased mice expressing PrPC lacking its membrane anchor (11,12). We considered the possibility that preexisting pathology, such as spontaneous cardiomyopathy or inflammation of the heart, might have contributed to cardiac PrPSc, and the fact that we did not find any evidence for toxic cardiomyopathy or inflammation in the primate does not exclude this possibility. Because the macaque with abundant PrPSc deposition in heart had longer disease duration, it is also possible that longer disease duration, which favors centrifugal spread of prions to peripheral tissues, contributed to cardiac affection in this primate (7). Peripheral deposition of PrPSc in vCJD is well studied (3). We were surprised by the amount and deposition type of PrPSc in heart, reaching 1/100 of the amount seen in brain and deposited as amyloid across large stretches of heart tissue. Skeletal muscle of prion-diseased patients and nonhuman primates routinely harbor minimal amounts of PrPSc (<1 and="" brain="" found="" in="" prp="" sup="" that="">Sc
in muscle is virtually impossible to detect by in situ methods (6,8,13). To our knowledge, PrPSc has not been detected in heart of vCJD-diseased persons or in patients with systemic amyloidosis, although primates orally exposed to BSE show very low amounts of cardiac PrPSc (8,14,15). The lack of cardiac PrPSc in vCJD may result from small cohorts investigated. Because the spectrum of vCJD is likely to change, broad application of current clinical criteria for vCJD in clinical practice may lead to underreporting of vCJD, missing atypical cases of vCJD.




In conclusion, we showed that BSE-infection of primates may lead to prion-amyloid cardiomyopathy. These data should be considered when vCJD surveillance is conducted.





Dr Krasemann is a research scientist at the Institute of Neuropathology of the University of Hamburg working on prion spread. Her primary research interests are factors involved in spread and clearance of prions.




 

Acknowledgments

This work was financed by the European Union grant EU BMH4 CT 98 7026, DFG grants KA 864/2-1, GL 589/2-1, and the BMBF-DLR grant 01GZ0712 to S.K.
The overall study was conceived and designed by M.G., A.A., F.J.K., and S.K. Animal care, housing, and observation were conducted by F.J.K., W.B., and W.S.S. Experiments were performed by S.K., G.M., E.K., K.W., W.S.S., and M.N. Data were analyzed by S.K., G.M., M.B., A.A., and M.G. S.K. and M.G. wrote the paper with substantial contributions from G.M. and A.A.




 

References





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Figures

Table

Technical Appendix



 
 
 
Suggested citation for this article: Krasemann S, Mearini G, Krämer E, Wagenführ K, Schulz-Schaeffer W, Neumann M, et al. BSE-associated prion-amyloid cardiomyopathy in primates. Emerg Infect Dis [Internet]. 2013 Jun [date cited]. http://dx.doi.org/10.3201/eid1906.120906External Web Site Icon
DOI: 10.3201/eid1906.120906




1These authors contributed equally to this article.





http://wwwnc.cdc.gov/eid/article/19/6/12-0906_article.htm








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