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Monday, November 16, 2015

Wyoming Latest round of testing CWD surveillance program has found the disease in three new hunt areas

Game and Fish Weekly News - CWD found in new areas and more hunter feedback welcomed Wyoming Game & Fish Department sent this bulletin at 11/16/2015 01:45 PM MST

Fall3

Latest round of testing finds CWD in new hunt areas

CHEYENNE - The latest round of tests from the Wyoming Game and Fish Department’s chronic wasting disease (CWD) surveillance program has found the disease in three new hunt areas. CWD is a fatal neurological disease of deer, elk and moose. The National Park Service also recently found CWD at Devils Tower National Monument. Staff at the Wyoming Game and Fish Department’s wildlife disease laboratory in Laramie confirmed the presence of CWD in a bull elk from elk hunt area 12 northeast of Saratoga, in a white-tailed buck from deer hunt area 112 southwest of Cody and a white-tailed doe in deer hunt area 171 north of Lander. Consistent with previous CWD findings for the season, these hunt areas are all near or overlap areas where CWD has been detected before. As is the case with Park Service’s finding, which corresponds with deer hunt area 1.

“We continue to work hard to monitor CWD, research its impacts and potential vaccines,” said Scott Edberg Deputy Chief of Game and Fish’s Wildlife Division. “By the end of the year, we will be releasing a draft updated CWD management plan for public review and comment. We look forward to hearing from the public about this proposed plan.”

After public review and input, the revised CWD plan will be brought to the Wyoming Game and Fish Commission for approval sometime in early 2016. Personnel continue to collect samples of deer, elk and moose through hunter field checks and at CWD sampling stations. Game and Fish personnel collect and analyze more than 1,600 CWD samples annually throughout the state. Hunters who wish to have their deer, elk or moose tested for CWD outside of the department’s CWD surveillance program can to do so by contacting the Wyoming State Veterinary Lab at (307) 766-9925. Hunters should be aware that it may take a few weeks after their animal is sampled to get their test results.

For more information on chronic wasting disease transmission and regulations on transportation and disposal of carcasses please visit the Game and Fish website at:




Wyoming WGF Commission Meeting 11/6/2015 Afternoon Edition Video

CWD starts at minute 58:51 of first hour of meeting discussion of previous models predicting extinction of deer population and elk population.

please mark hour 1:02 where remarks were made about potential resistant genes and prolonged survival, however a recent study (I posted directly next after youtube link) where it states ;

‘’Our study also demonstrates that mice expressing the deer S96-PRNP allele, previously shown to be resistant to various cervid prions, are susceptible to H95+ CWD prions. The potential for the generation of novel strains raises the possibility of an expanded host range for CWD. ‘’

hour minute mark 1:03

captive Elk study

39 femail elk calves captured on National Elk Refuge In Jackson, WY

Transported to WGFD Thorne-Williams Wildlife Research Unit (Sybille, TWWRU)

Worst-case scenario for prion exposure

Genotypes

-27 M/M132 (69.2%)

-11 M/L132 (28.2%)

-1 L/L132 (2.6%)

38 of 39 elk died over 10-year study

1 remaining elk was L/L132

still alive and remained negative for PrPCWD by rectal biopsy

Appears healthy, weighs 242kg, and bore healthy calf in May, 2012

CWD infection rate in this study ???

https://www.youtube.com/watch?v=bnlk4kW3fFw

> During the analysis, 37 of 39 elk died, all of which were positive for CWD.

http://www.esajournals.org/doi/pdf/10.1890/ES14-00013.1

*** Our study also demonstrates that mice expressing the deer S96-PRNP allele, previously shown to be resistant to various cervid prions, are susceptible to H95+ CWD prions. ***

*** The potential for the generation of novel strains raises the possibility of an expanded host range for CWD. ***

Deer Prion Proteins Modulate the Emergence and Adaptation of Chronic Wasting Disease Strains

Camilo Duque Velásqueza,b, Chiye Kima,c, Allen Herbsta,b, Nathalie Daudea,d, Maria Carmen Garzaa,e, Holger Willea,e, Judd Aikena,b and Debbie McKenziea,c aCentre for Prions and Protein Folding Diseases, University of Alberta, Edmonton, Alberta, Canada bDepartment of Agricultural, Food and Nutritional Science, University of Alberta, Edmonton, Alberta, Canada cDepartment of Biological Sciences, University of Alberta, Edmonton, Alberta, Canada dDepartment of Medicine, University of Alberta, Edmonton, Alberta, Canada eDepartment of Biochemistry, University of Alberta, Edmonton, Alberta, Canada

B. Caughey, Editor

+ Author Affiliations

ABSTRACT

Transmission of chronic wasting disease (CWD) between cervids is influenced by the primary structure of the host cellular prion protein (PrPC). In white-tailed deer, PRNP alleles encode the polymorphisms Q95 G96 (wild type [wt]), Q95 S96 (referred to as the S96 allele), and H95 G96 (referred to as the H95 allele), which differentially impact CWD progression. We hypothesize that the transmission of CWD prions between deer expressing different allotypes of PrPC modifies the contagious agent affecting disease spread. To evaluate the transmission properties of CWD prions derived experimentally from deer of four PRNP genotypes (wt/wt, S96/wt, H95/wt, or H95/S96), transgenic (tg) mice expressing the wt allele (tg33) or S96 allele (tg60) were challenged with these prion agents. Passage of deer CWD prions into tg33 mice resulted in 100% attack rates, with the CWD H95/S96 prions having significantly longer incubation periods. The disease signs and neuropathological and protease-resistant prion protein (PrP-res) profiles in infected tg33 mice were similar between groups, indicating that a prion strain (Wisc-1) common to all CWD inocula was amplified. In contrast, tg60 mice developed prion disease only when inoculated with the H95/wt and H95/S96 CWD allotypes. Serial passage in tg60 mice resulted in adaptation of a novel CWD strain (H95+) with distinct biological properties. Transmission of first-passage tg60CWD-H95+ isolates into tg33 mice, however, elicited two prion disease presentations consistent with a mixture of strains associated with different PrP-res glycotypes. Our data indicate that H95-PRNP heterozygous deer accumulated two CWD strains whose emergence was dictated by the PrPC primary structure of the recipient host. These findings suggest that CWD transmission between cervids expressing distinct PrPC molecules results in the generation of novel CWD strains.

IMPORTANCE CWD prions are contagious among wild and captive cervids in North America and in South Korea. We present data linking the amino acid variant Q95H in white-tailed deer cellular prion protein (PrPC) to the emergence of a novel CWD strain (H95+). We show that, upon infection, deer expressing H95-PrPC molecules accumulated a mixture of CWD strains that selectively propagated depending on the PRNP genotype of the host in which they were passaged. Our study also demonstrates that mice expressing the deer S96-PRNP allele, previously shown to be resistant to various cervid prions, are susceptible to H95+ CWD prions. The potential for the generation of novel strains raises the possibility of an expanded host range for CWD.

http://jvi.asm.org/content/89/24/12362.abstract?etoc

*** Our study also demonstrates that mice expressing the deer S96-PRNP allele, previously shown to be resistant to various cervid prions, are susceptible to H95+ CWD prions. ***

*** The potential for the generation of novel strains raises the possibility of an expanded host range for CWD. ***

UPDATE CWD VACCINE ELK minute mark 1:22:00

VACCINE

RECOMBINANT PROTEIN FUSION VACCINE

Hedlin, PD et al ‘’Design and delivery of a cryptic PrP c epitope for induction of Prp Sc-specific antibody responses.’’ Vaccine 28.4 (2010) 981-988.

PAN-PROVINCIAL VACCINE ENTERPRISES (PREVENT)

Dose: 2ml IM CWD VACCINE UPDATE IS A FAILURE, I REPEAT, A NEGATIVE RESULTS FOR CWD VACCINE. .tss

https://www.youtube.com/watch?v=bnlk4kW3fFw


Sent: Saturday, November 14, 2015 4:15 PM
Subject: [BSE-L] Wyoming Chronic Wasting Disease CWD Surveillance Results 2014 reported in 2015
 

Subject: Wyoming Chronic Wasting Disease CWD Surveillance Results 2014 reported in 2015
 
Wyoming Game and Fish Department
 
2014 Chronic Wasting Disease Surveillance
 
February 2015
 
2014 Surveillance:
 
A total of 1,632 deer, elk, and moose samples were analyzed. Of these samples, 110 tested positive for CWD representing 83 mule deer, 12 white-tailed deer, and 15 elk. This year’s surveillance efforts identified seven new deer hunt areas: 36 near Shoshoni, 84 and 98 east of Rawlins, 97 near Muddy Gap, 116 by Meeteetse, 123 in the Lovell area, and 160 near Lander. Hunt area 108 was the lone elk area identified (see map below). Of the 1,632 total samples received, 86% were derived from hunter-killed animals, 8% from targeted and 6% from road-killed deer, elk and moose. The proportion of positive samples in each of these categories was 5.6% (79/1,403) for hunter-killed, 23% (30/129) for targeted and 1% (1/100) in road-killed animals. It should be noted that the majority of road-killed surveillance occurs outside of the known endemic area for chronic wasting disease.
 
As of 2005, the Department incorporated moose into the CWD surveillance program, and in 2008 a positive moose was identified in moose hunt area 23 near Bedford. Since the initial case, over 750 moose samples have been tested, and to date, this disease has not been identified again in free-ranging moose. In 2014, 14 hunter-killed, 26 targeted and 13 road-killed moose were tested. For complete information on CWD in Wyoming please go to: http://wgfd.wyo.gov/web2011/wildlife-1000282.aspx
 
 

 
 
 
 
 
 
 
Subject: Wyoming Chronic Wasting Disease CWD Surveillance Results 2014 102 postive cases as at January 2015
 
Wyoming Chronic Wasting Disease CWD Surveillance Results 2014 102 postive cases as at January 2015
 
2014 CWD Surveillance – Results
 
1,647 Samples tested (102 positives)
 
822 Mule deer (72)
 
186 White-tailed deer (14)
 
608 Elk (16)
 
31 Moose (0)
 
88% Hunter-killed, 6% targeted, 6% road-killed
 
SOURCE
 
January 2015 Commission Notebook Master 11 CWD Update
 
2 items
 

01 CWD Memo.pdf
 
Jan 9
 
Sheridan Todd
 
Jan 6
 
 
Sheridan Todd
 
 
 
 
 
 
 
Section 15. Transportation and Disposal of Deer, Elk and Moose Taken from Chronic Wasting Disease (CWD) Hunt Areas within Wyoming. It shall be the purpose of this section to regulate the transportation and disposal of potentially CWD infected deer, elk and moose carcasses to areas outside of the hunt areas with CWD and potentially reduce the spread of the disease to other areas in and outside of Wyoming. Hunters may obtain current CWD information on the Department’s website at http://wgfd.wyo.gov.
 
(a) No deer, elk or moose taken or possessed from any hunt area shall be transported to any other hunt area within Wyoming or to any other state, province or country except as provided in this section.
 
(b) Deer, elk and moose carcasses harvested from any hunt area in Wyoming may be transported within Wyoming to a camp, a private residence for processing, a taxidermist, a processor, or a CWD sample collection site in Wyoming, provided the head and all portions of the spinal column remain at the site of the kill or such parts are disposed of in any approved landfill in Wyoming.
 
(c) Except as provided in subsection (b) of this section, only the following parts of any deer, elk or moose harvested from any hunt area in Wyoming may be transported to any other hunt area in Wyoming: edible portions with no part of the spinal column or head attached; cleaned hide without the head; skull plate or antlers that have been cleaned of all meat and brain tissue; teeth; or finished taxidermy mounts.
 
(d) Only the following parts of any deer, elk or moose harvested from any hunt areas in Wyoming may be transported to other states, provinces or countries: edible portions with no part of the spinal column or head attached; cleaned hide without the head; skull plate or antlers that have been cleaned of all meat and brain tissue; teeth; or finished taxidermy mounts. Whole deer, elk and moose carcasses harvested from any area shall not be transported out of Wyoming.
 
(e) Nothing in this section shall allow for the removal of evidence of sex or species required by Section 6 of this regulation.
 
(f) Nothing in this section shall apply to the transportation or disposal of deer, elk and moose carcasses by any governmental agency or educational institution.
 
2-7
 
Section 16. Importation or Transportation of Deer, Elk, or Moose Taken From Identified CWD Areas Outside of Wyoming.
 
snip...see full text ;
 
 
Wyoming Game and Fish Commission
 
2015 Elk Hunting Regulations
 
CHRONIC WASTING DISEASE (CWD) is a fatal disease of deer, elk and moose. Special regulations below were formulated to decrease the spread of the disease. Details about CWD, where it exists in Wyoming and testing for CWD, can be found on the Department website.
 
The Department will be collecting tissue samples at various check stations and meat processing facilities for CWD prevalence. Hunters wishing to have their animal tested outside the Department’s surveillance program may have an animal tested at the Wyoming State Veterinary Lab (WSVL) in Laramie for a fee. Hunters need to contact the WSVL at (307) 766‐9925 for testing details and cost.
 
The Department and public health officials recommend not eating any animal that is obviously ill. Wear rubber/latex gloves when field dressing an animal as a general precaution against all diseases.
 
IMPORTATION OR TRANSPORTATION OF DEER, ELK OR MOOSE TAKEN FROM IDENTIFIED CWD AREAS OUTSIDE OF WYOMING.
 
(a) No deer, elk or moose taken from within any other state, province or country within areas designated by the appropriate jurisdictional agency as positive for CWD in either deer, elk or moose shall be imported into Wyoming except harvested deer, elk or moose carcasses may be imported or transported into Wyoming to a private residence for processing, to a taxidermist, to a processor or to a CWD sample collection site in Wyoming provided the head and all portions of the spinal column are disposed of in an approved landfill.
 
(b) Except as provided in subsection (a) of this Section, only the following parts of any deer, elk or moose harvested may be imported: edible portions with no part of the spinal column or head attached; cleaned hide without the head; skull plate or antlers cleaned of all meat and brain tissue; teeth; or finished taxidermy mounts that have been cleaned of all meat and brain tissue.
 
snip...
 
TRANSPORTATION AND DISPOSAL OF DEER, ELK AND MOOSE TAKEN FROM CHRONIC WASTING DISEASE (CWD) HUNT AREAS WITHIN WYOMING. It shall be the purpose of this section to regulate the transportation and disposal of potentially CWD infected deer, elk and moose carcasses to areas outside of the hunt areas with CWD and potentially reduce the spread of the disease to other areas in and outside of Wyoming. Hunters may obtain current CWD information on the Department website.
 
(a) No deer, elk or moose taken or possessed from any hunt area shall be transported to any other hunt area within Wyoming or to any other state, province or country except as provided in this section.
 
(b) Deer, elk and moose carcasses harvested from any hunt area in Wyoming may be transported within Wyoming to a camp, a private residence for processing, a taxidermist, a processor, or a CWD sample collection site in Wyoming, provided the head and all portions of the spinal column remain at the site of the kill or such parts are disposed of in any approved landfill in Wyoming.
 
(c) Except as provided in this subsection (b) of this section, only the following parts of any deer, elk or moose harvested from any hunt area in Wyoming may be transported to any other hunt area in Wyoming: edible portions with no part of the spinal column or head attached; cleaned hide without the head; skull plate or antlers that have been cleaned of all meat and brain tissue; teeth; or finished taxidermy mounts.
 
(d) Only the following parts of any deer, elk or moose harvested from any hunt areas in Wyoming may be transported to other states, provinces or countries: edible portions with no part of the spinal column or head attached; cleaned hide without the head; skull plate or antlers that have been cleaned of all meat and brain tissue; teeth; or finished taxidermy mounts. Whole deer, elk and moose carcasses harvested from any area shall not be transported out of Wyoming.
 
(e) Nothing in this section shall allow for the removal of evidence of sex or species required by regulation.
 
(f) Nothing in this section shall apply to the transportation or disposal of deer, elk and moose carcasses by any governmental agency or educational institution.
 
snip...
 
 
Wednesday, October 28, 2015
 
Wyoming Game and Fish Department’s chronic wasting disease (CWD) surveillance program has found the disease in a new elk hunt area 21
 
The Wyoming Game and Fish Department’s chronic wasting disease (CWD) surveillance program has found the disease in a new elk hunt area.
 
10/26/2015 3:04:42 PM
 
Green River - CWD is a fatal neurological disease of deer, elk and moose.
 
Staff at the Game and Fish Department’s wildlife disease laboratory in Laramie confirmed the presence of CWD in a bull elk harvested on Oct. 7 near Deep Creek, in elk hunt area 21, which lies about 15 miles northeast of Baggs. Elk hunt area 21 overlaps with deer hunt area 82 where Game and Fish documented CWD in 2002. ...
 
 
Subject: Wyoming Deer tests positive for CWD in hunt area 100
 
Page 5
 
Deer tests positive for CWD in hunt area 100
 
Game and Fish personnel take lymph nodes from mule deer at a check station in Kemmerer to test them for the presence of Chronic Wasting Disease.
 
The Wyoming Game and Fish Department’s chronic wasting disease (CWD) surveillance program has found the disease in a new deer hunt area. CWD is a fatal neurological disease of deer, elk and moose.
 
Staff at the Game and Fish Department’s wildlife disease laboratory in Laramie confirmed the presence of CWD in a buck mule deer harvested on Oct. 2 near Flat Top Mountain, in deer hunt area 100, which lies about 15 miles northwest of Baggs. Deer hunt area 100 is bordered by CWD positive deer hunt areas 82 and 84 to the east and 98 to the northeast. “This is our first new positive hunt area this year. We again appreciate the help of hunters who help with the surveillance program. We do recommend people not eat deer, elk or moose that test positive for CWD,” Deputy Chief of the Wyoming Game and Fish Department Wildlife Division, Scott Edberg said.
 
Green River region personnel continue to collect samples of deer, elk and moose through hunter field checks and at CWD sampling stations. WGFD personnel collect and analyze more than 1,600 CWD samples annually throughout the state. Hunters who wish to have their deer, elk or moose tested for CWD outside of the department’s CWD surveillance program can to do so by contacting the Wyoming State Veterinary Lab at (307) 766-9925. Hunters should be aware that it may take a few weeks after their animal is sampled to get their test results.
 
For more information on chronic wasting disease transmission and regulations on transportation and disposal of carcasses please visit the Game and Fish website at:
 
 
Wednesday, October 14, 2015
 
Wyoming Game and Fish Finds CWD In New Deer Hunt Area buck mule deer harvested on Oct. 2 near Flat Top Mountain hunt area 100
 
 
WYOMING CWD 1998...
 
Harry Harju, assistant wildlife chief with Wyoming Fish and Game, reported that elk or game farming is now prohibited in Wyoming. Only one game ranch exists in Wyoming, which was operating before the passage of the law. The state of Wyoming was sued by several game breeders associations for not allowing elk farming. The game breeders lost their suit in the United States Court of Appeals, Tenth Circuit. The court maintained that the state had authority to regulate commerce and protect wildlife. Wyoming has had problems with big game farming originating in surrounding states. Wyoming has documented the harvest of red deer and their hybrids during elk hunts on the Snowy Mountain range that borders Colorado. Wyoming speculates that the red deer were escapees from Colorado game farms. Hybridization is viewed as threat to the genetic integrity of Wyoming's wild elk population. In a public hearing, the public voted against game farms in the state of Wyoming. Wyoming's Cattlemen's Association and Department of Agriculture opposed elk and big game farms, as well, particularly due to disease risks. Brucellosis is a major problem for wildlife and livestock in the Yellowstone Basin.
 
 
 
 
Research Project: TRANSMISSION, DIFFERENTIATION, AND PATHOBIOLOGY OF TRANSMISSIBLE SPONGIFORM ENCEPHALOPATHIES
 
*** Title: Transmission of scrapie prions to primate after an extended silent incubation period Authors
 
item Comoy, Emmanuel - item Mikol, Jacqueline - item Luccantoni-Freire, Sophie - item Correia, Evelyne - item Lescoutra-Etchegaray, Nathalie - item Durand, Valérie - item Dehen, Capucine - item Andreoletti, Olivier - item Casalone, Cristina - item Richt, Juergen item Greenlee, Justin item Baron, Thierry - item Benestad, Sylvie - item Hills, Bob - item Brown, Paul - item Deslys, Jean-Philippe -
 
Submitted to: Scientific Reports Publication Type: Peer Reviewed Journal Publication Acceptance Date: May 28, 2015 Publication Date: June 30, 2015 Citation: Comoy, E.E., Mikol, J., Luccantoni-Freire, S., Correia, E., Lescoutra-Etchegaray, N., Durand, V., Dehen, C., Andreoletti, O., Casalone, C., Richt, J.A., Greenlee, J.J., Baron, T., Benestad, S., Brown, P., Deslys, J. 2015. Transmission of scrapie prions to primate after an extended silent incubation period. Scientific Reports. 5:11573. Interpretive Summary: The transmissible spongiform encephalopathies (also called prion diseases) are fatal neurodegenerative diseases that affect animals and humans. The agent of prion diseases is a misfolded form of the prion protein that is resistant to breakdown by the host cells. Since all mammals express prion protein on the surface of various cells such as neurons, all mammals are, in theory, capable of replicating prion diseases. One example of a prion disease, bovine spongiform encephalopathy (BSE; also called mad cow disease), has been shown to infect cattle, sheep, exotic undulates, cats, non-human primates, and humans when the new host is exposed to feeds or foods contaminated with the disease agent. The purpose of this study was to test whether non-human primates (cynomologous macaque) are susceptible to the agent of sheep scrapie. After an incubation period of approximately 10 years a macaque developed progressive clinical signs suggestive of neurologic disease. Upon postmortem examination and microscopic examination of tissues, there was a widespread distribution of lesions consistent with a transmissible spongiform encephalopathy. This information will have a scientific impact since it is the first study that demonstrates the transmission of scrapie to a non-human primate with a close genetic relationship to humans. This information is especially useful to regulatory officials and those involved with risk assessment of the potential transmission of animal prion diseases to humans.
 
Technical Abstract: Classical bovine spongiform encephalopathy (c-BSE) is an animal prion disease that also causes variant Creutzfeldt-Jakob disease in humans. Over the past decades, c-BSE's zoonotic potential has been the driving force in establishing extensive protective measures for animal and human health. In complement to the recent demonstration that humanized mice are susceptible to scrapie, we report here the first observation of direct transmission of a natural classical scrapie isolate to a macaque after a 10-year incubation period. Neuropathologic examination revealed all of the features of a prion disease: spongiform change, neuronal loss, and accumulation of PrPres throughout the CNS.
 
***This observation strengthens the questioning of the harmlessness of scrapie to humans, at a time when protective measures for human and animal health are being dismantled and reduced as c-BSE is considered controlled and being eradicated. Our results underscore the importance of precautionary and protective measures and the necessity for long-term experimental transmission studies to assess the zoonotic potential of other animal prion strains.
 
 
Research Project: TRANSMISSION, DIFFERENTIATION, AND PATHOBIOLOGY OF TRANSMISSIBLE SPONGIFORM ENCEPHALOPATHIES
 
Title: Transmission of the agent of sheep scrapie to deer results in PrPSc with two distinct molecular profiles Authors
 
item Greenlee, Justin item Moore, Sarah - item Smith, Jodi item West Greenlee, Mary - item Kunkle, Robert
 
Submitted to: Prion Publication Type: Abstract Only Publication Acceptance Date: March 31, 2015 Publication Date: May 25, 2015 Citation: Greenlee, J., Moore, S.J., Smith, J.., West Greenlee, M.H., Kunkle, R. 2015.
 
Scrapie transmits to white-tailed deer by the oral route and has a molecular profile similar to chronic wasting disease and distinct from the scrapie inoculum. Prion 2015. p. S62. Technical Abstract: The purpose of this work was to determine susceptibility of white-tailed deer (WTD) to the agent of sheep scrapie and to compare the resultant PrPSc to that of the original inoculum and chronic wasting disease (CWD). We inoculated WTD by a natural route of exposure (concurrent oral and intranasal (IN); n=5) with a US scrapie isolate. All scrapie-inoculated deer had evidence of PrPSc accumulation. PrPSc was detected in lymphoid tissues at preclinical time points, and deer necropsied after 28 months post-inoculation had clinical signs, spongiform encephalopathy, and widespread distribution of PrPSc in neural and lymphoid tissues. Western blotting (WB) revealed PrPSc with 2 distinct molecular profiles. WB on cerebral cortex had a profile similar to the original scrapie inoculum, whereas WB of brainstem, cerebellum, or lymph nodes reveal PrPSc with a higher profile resembling CWD. Homogenates with the 2 distinct profiles from WTD with clinical scrapie were further passaged to mice expressing cervid prion protein and intranasally to sheep and WTD. In cervidized mice, the two inocula have distinct incubation times. Sheep inoculated intranasally with WTD derived scrapie developed disease, but only after inoculation with the inoculum that had a scrapie-like profile. The WTD study is ongoing, but deer in both inoculation groups are positive for PrPSc by rectal mucosal biopsy. In summary, this work demonstrates that WTD are susceptible to the agent of scrapie, two distinct molecular profiles of PrPSc are present in the tissues of affected deer, and inoculum of either profile type readily passes to deer.
 
 
Research Project: TRANSMISSION, DIFFERENTIATION, AND PATHOBIOLOGY OF TRANSMISSIBLE SPONGIFORM ENCEPHALOPATHIES
 
Title: Scrapie transmits to white-tailed deer by the oral route and has a molecular profile similar to chronic wasting disease Authors
 
item Greenlee, Justin item Moore, S - item Smith, Jodi - item Kunkle, Robert item West Greenlee, M -
 
Submitted to: American College of Veterinary Pathologists Meeting Publication Type: Abstract Only Publication Acceptance Date: August 12, 2015 Publication Date: N/A
 
Technical Abstract: The purpose of this work was to determine susceptibility of white-tailed deer (WTD) to the agent of sheep scrapie and to compare the resultant PrPSc to that of the original inoculum and chronic wasting disease (CWD). We inoculated WTD by a natural route of exposure (concurrent oral and intranasal (IN); n=5) with a US scrapie isolate. All scrapie-inoculated deer had evidence of PrPSc accumulation. PrPSc was detected in lymphoid tissues at preclinical time points, and deer necropsied after 28 months post-inoculation had clinical signs, spongiform encephalopathy, and widespread distribution of PrPSc in neural and lymphoid tissues. Western blotting (WB) revealed PrPSc with 2 distinct molecular profiles. WB on cerebral cortex had a profile similar to the original scrapie inoculum, whereas WB of brainstem, cerebellum, or lymph nodes revealed PrPSc with a higher profile resembling CWD. Homogenates with the 2 distinct profiles from WTD with clinical scrapie were further passaged to mice expressing cervid prion protein and intranasally to sheep and WTD. In cervidized mice, the two inocula have distinct incubation times. Sheep inoculated intranasally with WTD derived scrapie developed disease, but only after inoculation with the inoculum that had a scrapie-like profile. The WTD study is ongoing, but deer in both inoculation groups are positive for PrPSc by rectal mucosal biopsy. In summary, this work demonstrates that WTD are susceptible to the agent of scrapie, two distinct molecular profiles of PrPSc are present in the tissues of affected deer, and inoculum of either profile readily passes to deer.
 
 
Sunday, October 25, 2015
 
USAHA Detailed Events Schedule – 119th USAHA Annual Meeting CAPTIVE LIVESTOCK CWD SCRAPIE TSE PRION
 
 
Thursday, November 05, 2015
 
TPW Commission Adopts Interim Deer Breeder Movement Rules
 
 
*** Spraker suggested an interesting explanation for the occurrence of CWD. The deer pens at the Foot Hills Campus were built some 30-40 years ago by a Dr. Bob Davis. At or abut that time, allegedly, some scrapie work was conducted at this site. When deer were introduced to the pens they occupied ground that had previously been occupied by sheep.
 
 
White-tailed Deer are Susceptible to Scrapie by Natural Route of Infection
 
Jodi D. Smith, Justin J. Greenlee, and Robert A. Kunkle; Virus and Prion Research Unit, National Animal Disease Center, USDA-ARS
 
Interspecies transmission studies afford the opportunity to better understand the potential host range and origins of prion diseases. Previous experiments demonstrated that white-tailed deer are susceptible to sheep-derived scrapie by intracranial inoculation. The purpose of this study was to determine susceptibility of white-tailed deer to scrapie after a natural route of exposure. Deer (n=5) were inoculated by concurrent oral (30 ml) and intranasal (1 ml) instillation of a 10% (wt/vol) brain homogenate derived from a sheep clinically affected with scrapie. Non-inoculated deer were maintained as negative controls. All deer were observed daily for clinical signs. Deer were euthanized and necropsied when neurologic disease was evident, and tissues were examined for abnormal prion protein (PrPSc) by immunohistochemistry (IHC) and western blot (WB). One animal was euthanized 15 months post-inoculation (MPI) due to an injury. At that time, examination of obex and lymphoid tissues by IHC was positive, but WB of obex and colliculus were negative. Remaining deer developed clinical signs of wasting and mental depression and were necropsied from 28 to 33 MPI. Tissues from these deer were positive for scrapie by IHC and WB. Tissues with PrPSc immunoreactivity included brain, tonsil, retropharyngeal and mesenteric lymph nodes, hemal node, Peyer’s patches, and spleen. This work demonstrates for the first time that white-tailed deer are susceptible to sheep scrapie by potential natural routes of inoculation. In-depth analysis of tissues will be done to determine similarities between scrapie in deer after intracranial and oral/intranasal inoculation and chronic wasting disease resulting from similar routes of inoculation.
 
see full text ;
 
 
PO-039: A comparison of scrapie and chronic wasting disease in white-tailed deer
 
Justin Greenlee, Jodi Smith, Eric Nicholson US Dept. Agriculture; Agricultural Research Service, National Animal Disease Center; Ames, IA USA
 
 
White-tailed deer are susceptible to the agent of sheep scrapie by intracerebral inoculation
 
snip...
 
It is unlikely that CWD will be eradicated from free-ranging cervids, and the disease is likely to continue to spread geographically [10]. However, the potential that white-tailed deer may be susceptible to sheep scrapie by a natural route presents an additional confounding factor to halting the spread of CWD. This leads to the additional speculations that
 
1) infected deer could serve as a reservoir to infect sheep with scrapie offering challenges to scrapie eradication efforts and
 
2) CWD spread need not remain geographically confined to current endemic areas, but could occur anywhere that sheep with scrapie and susceptible cervids cohabitate.
 
This work demonstrates for the first time that white-tailed deer are susceptible to sheep scrapie by intracerebral inoculation with a high attack rate and that the disease that results has similarities to CWD. These experiments will be repeated with a more natural route of inoculation to determine the likelihood of the potential transmission of sheep scrapie to white-tailed deer. If scrapie were to occur in white-tailed deer, results of this study indicate that it would be detected as a TSE, but may be difficult to differentiate from CWD without in-depth biochemical analysis.
 
 
 
2012
 
PO-039: A comparison of scrapie and chronic wasting disease in white-tailed deer
 
Justin Greenlee, Jodi Smith, Eric Nicholson US Dept. Agriculture; Agricultural Research Service, National Animal Disease Center; Ames, IA USA
 
snip...
 
The results of this study suggest that there are many similarities in the manifestation of CWD and scrapie in WTD after IC inoculation including early and widespread presence of PrPSc in lymphoid tissues, clinical signs of depression and weight loss progressing to wasting, and an incubation time of 21-23 months. Moreover, western blots (WB) done on brain material from the obex region have a molecular profile similar to CWD and distinct from tissues of the cerebrum or the scrapie inoculum. However, results of microscopic and IHC examination indicate that there are differences between the lesions expected in CWD and those that occur in deer with scrapie: amyloid plaques were not noted in any sections of brain examined from these deer and the pattern of immunoreactivity by IHC was diffuse rather than plaque-like.
 
*** After a natural route of exposure, 100% of WTD were susceptible to scrapie.
 
Deer developed clinical signs of wasting and mental depression and were necropsied from 28 to 33 months PI. Tissues from these deer were positive for PrPSc by IHC and WB. Similar to IC inoculated deer, samples from these deer exhibited two different molecular profiles: samples from obex resembled CWD whereas those from cerebrum were similar to the original scrapie inoculum. On further examination by WB using a panel of antibodies, the tissues from deer with scrapie exhibit properties differing from tissues either from sheep with scrapie or WTD with CWD. Samples from WTD with CWD or sheep with scrapie are strongly immunoreactive when probed with mAb P4, however, samples from WTD with scrapie are only weakly immunoreactive. In contrast, when probed with mAb’s 6H4 or SAF 84, samples from sheep with scrapie and WTD with CWD are weakly immunoreactive and samples from WTD with scrapie are strongly positive. This work demonstrates that WTD are highly susceptible to sheep scrapie, but on first passage, scrapie in WTD is differentiable from CWD.
 
 
2011
 
*** After a natural route of exposure, 100% of white-tailed deer were susceptible to scrapie.
 
 
Sunday, October 25, 2015
 
USAHA Detailed Events Schedule – 119th USAHA Annual Meeting CAPTIVE LIVESTOCK CWD SCRAPIE TSE PRION
 
 
*** PRION 2015 CONFERENCE FT. COLLINS CWD RISK FACTORS TO HUMANS ***
 
*** LATE-BREAKING ABSTRACTS PRION 2015 CONFERENCE ***
 
O18
 
Zoonotic Potential of CWD Prions
 
Liuting Qing1, Ignazio Cali1,2, Jue Yuan1, Shenghai Huang3, Diane Kofskey1, Pierluigi Gambetti1, Wenquan Zou1, Qingzhong Kong1 1Case Western Reserve University, Cleveland, Ohio, USA, 2Second University of Naples, Naples, Italy, 3Encore Health Resources, Houston, Texas, USA
 
***These results indicate that the CWD prion has the potential to infect human CNS and peripheral lymphoid tissues and that there might be asymptomatic human carriers of CWD infection.***
 
P.105: RT-QuIC models trans-species prion transmission
 
Kristen Davenport, Davin Henderson, Candace Mathiason, and Edward Hoover Prion Research Center; Colorado State University; Fort Collins, CO USA
 
Additionally, human rPrP was competent for conversion by CWD and fCWD.
 
***This insinuates that, at the level of protein:protein interactions, the barrier preventing transmission of CWD to humans is less robust than previously estimated.***
 
 
From: Terry S. Singeltary Sr.
 
Sent: Saturday, November 15, 2014 9:29 PM
 
To: Terry S. Singeltary Sr.
 
Subject: THE EPIDEMIOLOGY OF CREUTZFELDT-JAKOB DISEASE R. G. WILL 1984
 
THE EPIDEMIOLOGY OF CREUTZFELDT-JAKOB DISEASE
 
R. G. WILL
 
1984
 
*** The association between venison eating and risk of CJD shows similar pattern, with regular venison eating associated with a 9 FOLD INCREASE IN RISK OF CJD (p = 0.04). (SEE LINK IN REPORT HERE...TSS) PLUS, THE CDC DID NOT PUT THIS WARNING OUT FOR THE WELL BEING OF THE DEER AND ELK ;
 
snip...
 
 
85%+ of all human tse prion disease is sporadic CJD.
 
see what the NIH prion Gods say themselves ;
 
‘’In the Archives of Neurology you quoted (the abstract of which was attached to your email), we did not say CWD in humans will present like variant CJD. That assumption would be wrong.’’
 
‘’Also, we do not claim that "no-one has ever been infected with prion disease from eating venison." Our conclusion stating that we found no strong evidence of CWD transmission to humans in the article you quoted or in any other forum is limited to the patients we investigated.’’
 
*** These results would seem to suggest that CWD does indeed have zoonotic potential, at least as judged by the compatibility of CWD prions and their human PrPC target. Furthermore, extrapolation from this simple in vitro assay suggests that if zoonotic CWD occurred, it would most likely effect those of the PRNP codon 129-MM genotype and that the PrPres type would be similar to that found in the most common subtype of sCJD (MM1).***
 
 
*** The potential impact of prion diseases on human health was greatly magnified by the recognition that interspecies transfer of BSE to humans by beef ingestion resulted in vCJD. While changes in animal feed constituents and slaughter practices appear to have curtailed vCJD, there is concern that CWD of free-ranging deer and elk in the U.S. might also cross the species barrier. Thus, consuming venison could be a source of human prion disease. Whether BSE and CWD represent interspecies scrapie transfer or are newly arisen prion diseases is unknown. Therefore, the possibility of transmission of prion disease through other food animals cannot be ruled out. There is evidence that vCJD can be transmitted through blood transfusion. There is likely a pool of unknown size of asymptomatic individuals infected with vCJD, and there may be asymptomatic individuals infected with the CWD equivalent. These circumstances represent a potential threat to blood, blood products, and plasma supplies.
 
 
now, let’s see what the authors said about this casual link, personal communications years ago. see where it is stated NO STRONG evidence. so, does this mean there IS casual evidence ???? “Our conclusion stating that we found no strong evidence of CWD transmission to humans”
 
From: TSS (216-119-163-189.ipset45.wt.net)
 
Subject: CWD aka MAD DEER/ELK TO HUMANS ???
 
Date: September 30, 2002 at 7:06 am PST
 
From: "Belay, Ermias"
 
To: Cc: "Race, Richard (NIH)" ; ; "Belay, Ermias"
 
Sent: Monday, September 30, 2002 9:22 AM
 
Subject: RE: TO CDC AND NIH - PUB MED- 3 MORE DEATHS - CWD - YOUNG HUNTERS
 
Dear Sir/Madam,
 
In the Archives of Neurology you quoted (the abstract of which was attached to your email), we did not say CWD in humans will present like variant CJD. That assumption would be wrong. I encourage you to read the whole article and call me if you have questions or need more clarification (phone: 404-639-3091). Also, we do not claim that "no-one has ever been infected with prion disease from eating venison." Our conclusion stating that we found no strong evidence of CWD transmission to humans in the article you quoted or in any other forum is limited to the patients we investigated.
 
Ermias Belay, M.D. Centers for Disease Control and Prevention
 
-----Original Message-----
 
From: Sent: Sunday, September 29, 2002 10:15 AM
 
To: rr26k@nih.gov; rrace@niaid.nih.gov; ebb8@CDC.GOV
 
Subject: TO CDC AND NIH - PUB MED- 3 MORE DEATHS - CWD - YOUNG HUNTERS
 
Sunday, November 10, 2002 6:26 PM ......snip........end..............TSS
 
Thursday, April 03, 2008
 
A prion disease of cervids: Chronic wasting disease 2008 1: Vet Res. 2008 Apr 3;39(4):41 A prion disease of cervids: Chronic wasting disease Sigurdson CJ.
 
snip...
 
*** twenty-seven CJD patients who regularly consumed venison were reported to the Surveillance Center***,
 
snip... full text ;
 
 
July's Milwaukee Journal Sentinel article did prod state officials to ask CDC to investigate the cases of the three men who shared wild game feasts. The two men the CDC is still investigating were 55 and 66 years old. But there's also Kevin Boss, a Minnesota hunter who ate Barron County venison and died of CJD at 41. And there's Jeff Schwan, whose Michigan Tech fraternity brothers used to bring venison sausage back to the frat house. His mother, Terry, says that in May 2001, Jeff, 26, began complaining about his vision. A friend noticed misspellings in his e-mail, which was totally unlike him. Jeff began losing weight. He became irritable and withdrawn. By the end of June, he couldn't remember the four-digit code to open the garage door or when and how to feed his parents' cats. At a family gathering in July, he stuck to his parents and girlfriend, barely talking. "On the night we took him to the hospital, he was speaking like he was drunk or high and I noticed his pupils were so dilated I couldn't see the irises," his mother says. By then, Jeff was no longer able to do even simple things on his computer at work, and "in the hospital, he couldn't drink enough water." When he died on September 27, 2001, an autopsy confirmed he had sporadic CJD.
 
In 2000, Belay looked into three CJD cases reported by The Denver Post, two hunters who ate meat from animals killed in Wyoming and the daughter of a hunter who ate venison from a plant that processed Colorado elk. All three died of CJD before they were 30 years old. The CDC asked the USDA to kill 1,000 deer and elk in the area where the men hunted. Belay and others reported their findings in the Archives of Neurology, writing that although "circumstances suggested a link between the three cases and chronic wasting disease, they could find no 'causal' link." Which means, says Belay, "not a single one of those 1,000 deer tested positive for CWD. For all we know, these cases may be CWD. What we have now doesn't indicate a connection. That's reassuring, but it would be wrong to say it will never happen."
 
So far, says NIH researcher Race, the two Wisconsin cases pinpointed by the newspaper look like spontaneous CJD. "But we don't know how CWD would look in human brains. It probably would look like some garden-variety sporadic CJD." What the CDC will do with these cases and four others (three from Colorado and Schwan from Upper Michigan), Race says, is "sequence the prion protein from these people, inject it into mice and wait to see what the disease looks like in their brains. That will take two years."
 
CJD is so rare in people under age 30, one case in a billion (leaving out medical mishaps), that four cases under 30 is "very high," says Colorado neurologist Bosque. "Then, if you add these other two from Wisconsin [cases in the newspaper], six cases of CJD in people associated with venison is very, very high." Only now, with Mary Riley, there are at least seven, and possibly eight, with Steve, her dining companion. "It's not critical mass that matters," however, Belay says. "One case would do it for me." The chance that two people who know each other would both contact CJD, like the two Wisconsin sportsmen, is so unlikely, experts say, it would happen only once in 140 years.
 
Given the incubation period for TSEs in humans, it may require another generation to write the final chapter on CWD in Wisconsin. "Does chronic wasting disease pass into humans? We'll be able to answer that in 2022," says Race. Meanwhile, the state has become part of an immense experiment.
 
 
I urge everyone to watch this video closely...terry
 
*** you can see video here and interview with Jeff's Mom, and scientist telling you to test everything and potential risk factors for humans ***
 
 
*** These results would seem to suggest that CWD does indeed have zoonotic potential, at least as judged by the compatibility of CWD prions and their human PrPC target. Furthermore, extrapolation from this simple in vitro assay suggests that if zoonotic CWD occurred, it would most likely effect those of the PRNP codon 129-MM genotype and that the PrPres type would be similar to that found in the most common subtype of sCJD (MM1).***
 
 
O.05: Transmission of prions to primates after extended silent incubation periods: Implications for BSE and scrapie risk assessment in human populations
 
Emmanuel Comoy, Jacqueline Mikol, Val erie Durand, Sophie Luccantoni, Evelyne Correia, Nathalie Lescoutra, Capucine Dehen, and Jean-Philippe Deslys Atomic Energy Commission; Fontenay-aux-Roses, France
 
Prion diseases (PD) are the unique neurodegenerative proteinopathies reputed to be transmissible under field conditions since decades. The transmission of Bovine Spongiform Encephalopathy (BSE) to humans evidenced that an animal PD might be zoonotic under appropriate conditions. Contrarily, in the absence of obvious (epidemiological or experimental) elements supporting a transmission or genetic predispositions, PD, like the other proteinopathies, are reputed to occur spontaneously (atpical animal prion strains, sporadic CJD summing 80% of human prion cases). Non-human primate models provided the first evidences supporting the transmissibiity of human prion strains and the zoonotic potential of BSE. Among them, cynomolgus macaques brought major information for BSE risk assessment for human health (Chen, 2014), according to their phylogenetic proximity to humans and extended lifetime. We used this model to assess the zoonotic potential of other animal PD from bovine, ovine and cervid origins even after very long silent incubation periods.
 
*** We recently observed the direct transmission of a natural classical scrapie isolate to macaque after a 10-year silent incubation period,
 
***with features similar to some reported for human cases of sporadic CJD, albeit requiring fourfold longe incubation than BSE. Scrapie, as recently evoked in humanized mice (Cassard, 2014),
 
***is the third potentially zoonotic PD (with BSE and L-type BSE),
 
***thus questioning the origin of human sporadic cases. We will present an updated panorama of our different transmission studies and discuss the implications of such extended incubation periods on risk assessment of animal PD for human health.
 
===============
 
***thus questioning the origin of human sporadic cases...TSS
 
===============
 
 
PL1
 
Using in vitro prion replication for high sensitive detection of prions and prionlike proteins and for understanding mechanisms of transmission.
 
Claudio Soto
 
Mitchell Center for Alzheimer's diseases and related Brain disorders, Department of Neurology, University of Texas Medical School at Houston.
 
Prion and prion-like proteins are misfolded protein aggregates with the ability to selfpropagate to spread disease between cells, organs and in some cases across individuals. I n T r a n s m i s s i b l e s p o n g i f o r m encephalopathies (TSEs), prions are mostly composed by a misfolded form of the prion protein (PrPSc), which propagates by transmitting its misfolding to the normal prion protein (PrPC). The availability of a procedure to replicate prions in the laboratory may be important to study the mechanism of prion and prion-like spreading and to develop high sensitive detection of small quantities of misfolded proteins in biological fluids, tissues and environmental samples. Protein Misfolding Cyclic Amplification (PMCA) is a simple, fast and efficient methodology to mimic prion replication in the test tube. PMCA is a platform technology that may enable amplification of any prion-like misfolded protein aggregating through a seeding/nucleation process. In TSEs, PMCA is able to detect the equivalent of one single molecule of infectious PrPSc and propagate prions that maintain high infectivity, strain properties and species specificity. Using PMCA we have been able to detect PrPSc in blood and urine of experimentally infected animals and humans affected by vCJD with high sensitivity and specificity. Recently, we have expanded the principles of PMCA to amplify amyloid-beta (Aβ) and alphasynuclein (α-syn) aggregates implicated in Alzheimer's and Parkinson's diseases, respectively. Experiments are ongoing to study the utility of this technology to detect Aβ and α-syn aggregates in samples of CSF and blood from patients affected by these diseases.
 
=========================
 
***Recently, we have been using PMCA to study the role of environmental prion contamination on the horizontal spreading of TSEs. These experiments have focused on the study of the interaction of prions with plants and environmentally relevant surfaces. Our results show that plants (both leaves and roots) bind tightly to prions present in brain extracts and excreta (urine and feces) and retain even small quantities of PrPSc for long periods of time. Strikingly, ingestion of prioncontaminated leaves and roots produced disease with a 100% attack rate and an incubation period not substantially longer than feeding animals directly with scrapie brain homogenate. Furthermore, plants can uptake prions from contaminated soil and transport them to different parts of the plant tissue (stem and leaves). Similarly, prions bind tightly to a variety of environmentally relevant surfaces, including stones, wood, metals, plastic, glass, cement, etc. Prion contaminated surfaces efficiently transmit prion disease when these materials were directly injected into the brain of animals and strikingly when the contaminated surfaces were just placed in the animal cage. These findings demonstrate that environmental materials can efficiently bind infectious prions and act as carriers of infectivity, suggesting that they may play an important role in the horizontal transmission of the disease.
 
========================
 
Since its invention 13 years ago, PMCA has helped to answer fundamental questions of prion propagation and has broad applications in research areas including the food industry, blood bank safety and human and veterinary disease diagnosis.
 
 
see ;
 
 
 
 
 
 
98 | Veterinary Record | January 24, 2015
 
EDITORIAL
 
Scrapie: a particularly persistent pathogen
 
Cristina Acín
 
Resistant prions in the environment have been the sword of Damocles for scrapie control and eradication. Attempts to establish which physical and chemical agents could be applied to inactivate or moderate scrapie infectivity were initiated in the 1960s and 1970s,with the first study of this type focusing on the effect of heat treatment in reducing prion infectivity (Hunter and Millson 1964). Nowadays, most of the chemical procedures that aim to inactivate the prion protein are based on the method developed by Kimberlin and collaborators (1983). This procedure consists of treatment with 20,000 parts per million free chlorine solution, for a minimum of one hour, of all surfaces that need to be sterilised (in laboratories, lambing pens, slaughterhouses, and so on). Despite this, veterinarians and farmers may still ask a range of questions, such as ‘Is there an official procedure published somewhere?’ and ‘Is there an international organisation which recommends and defines the exact method of scrapie decontamination that must be applied?’
 
From a European perspective, it is difficult to find a treatment that could be applied, especially in relation to the disinfection of surfaces in lambing pens of affected flocks. A 999/2001 EU regulation on controlling spongiform encephalopathies (European Parliament and Council 2001) did not specify a particular decontamination measure to be used when an outbreak of scrapie is diagnosed. There is only a brief recommendation in Annex VII concerning the control and eradication of transmissible spongiform encephalopathies (TSE s).
 
Chapter B of the regulation explains the measures that must be applied if new caprine animals are to be introduced to a holding where a scrapie outbreak has previously been diagnosed. In that case, the statement indicates that caprine animals can be introduced ‘provided that a cleaning and disinfection of all animal housing on the premises has been carried out following destocking’.
 
Issues around cleaning and disinfection are common in prion prevention recommendations, but relevant authorities, veterinarians and farmers may have difficulties in finding the specific protocol which applies. The European Food and Safety Authority (EFSA ) published a detailed report about the efficacy of certain biocides, such as sodium hydroxide, sodium hypochlorite, guanidine and even a formulation of copper or iron metal ions in combination with hydrogen peroxide, against prions (EFSA 2009). The report was based on scientific evidence (Fichet and others 2004, Lemmer and others 2004, Gao and others 2006, Solassol and others 2006) but unfortunately the decontamination measures were not assessed under outbreak conditions.
 
The EFSA Panel on Biological Hazards recently published its conclusions on the scrapie situation in the EU after 10 years of monitoring and control of the disease in sheep and goats (EFSA 2014), and one of the most interesting findings was the Icelandic experience regarding the effect of disinfection in scrapie control. The Icelandic plan consisted of: culling scrapie-affected sheep or the whole flock in newly diagnosed outbreaks; deep cleaning and disinfection of stables, sheds, barns and equipment with high pressure washing followed by cleaning with 500 parts per million of hypochlorite; drying and treatment with 300 ppm of iodophor; and restocking was not permitted for at least two years. Even when all of these measures were implemented, scrapie recurred on several farms, indicating that the infectious agent survived for years in the environment, even as many as 16 years after restocking (Georgsson and others 2006).
 
In the rest of the countries considered in the EFSA (2014) report, recommendations for disinfection measures were not specifically defined at the government level. In the report, the only recommendation that is made for sheep is repopulation with sheep with scrapie-resistant genotypes. This reduces the risk of scrapie recurrence but it is difficult to know its effect on the infection.
 
Until the EFSA was established (in May 2003), scientific opinions about TSE s were provided by the Scientific Steering Committee (SSC) of the EC, whose advice regarding inactivation procedures focused on treating animal waste at high temperatures (150°C for three hours) and high pressure alkaline hydrolysis (SSC 2003). At the same time, the TSE Risk Management Subgroup of the Advisory Committee on Dangerous Pathogens (ACDP) in the UK published guidance on safe working and the prevention of TSE infection. Annex C of the ACDP report established that sodium hypochlorite was considered to be effective, but only if 20,000 ppm of available chlorine was present for at least one hour, which has practical limitations such as the release of chlorine gas, corrosion, incompatibility with formaldehyde, alcohols and acids, rapid inactivation of its active chemicals and the stability of dilutions (ACDP 2009).
 
In an international context, the World Organisation for Animal Health (OIE) does not recommend a specific disinfection protocol for prion agents in its Terrestrial Code or Manual. Chapter 4.13 of the Terrestrial Code, General recommendations on disinfection and disinsection (OIE 2014), focuses on foot-and-mouth disease virus, mycobacteria and Bacillus anthracis, but not on prion disinfection. Nevertheless, the last update published by the OIE on bovine spongiform encephalopathy (OIE 2012) indicates that few effective decontamination techniques are available to inactivate the agent on surfaces, and recommends the removal of all organic material and the use of sodium hydroxide, or a sodium hypochlorite solution containing 2 per cent available chlorine, for more than one hour at 20ºC.
 
The World Health Organization outlines guidelines for the control of TSE s, and also emphasises the importance of mechanically cleaning surfaces before disinfection with sodium hydroxide or sodium hypochlorite for one hour (WHO 1999).
 
Finally, the relevant agencies in both Canada and the USA suggest that the best treatments for surfaces potentially contaminated with prions are sodium hydroxide or sodium hypochlorite at 20,000 ppm. This is a 2 per cent solution, while most commercial household bleaches contain 5.25 per cent sodium hypochlorite. It is therefore recommended to dilute one part 5.25 per cent bleach with 1.5 parts water (CDC 2009, Canadian Food Inspection Agency 2013).
 
So what should we do about disinfection against prions? First, it is suggested that a single protocol be created by international authorities to homogenise inactivation procedures and enable their application in all scrapie-affected countries. Sodium hypochlorite with 20,000 ppm of available chlorine seems to be the procedure used in most countries, as noted in a paper summarised on p 99 of this issue of Veterinary Record (Hawkins and others 2015). But are we totally sure of its effectiveness as a preventive measure in a scrapie outbreak? Would an in-depth study of the recurrence of scrapie disease be needed?
 
What we can conclude is that, if we want to fight prion diseases, and specifically classical scrapie, we must focus on the accuracy of diagnosis, monitoring and surveillance; appropriate animal identification and control of movements; and, in the end, have homogeneous and suitable protocols to decontaminate and disinfect lambing barns, sheds and equipment available to veterinarians and farmers. Finally, further investigations into the resistance of prion proteins in the diversity of environmental surfaces are required.
 
References
 
snip...
 
98 | Veterinary Record | January 24, 2015
 
 
Persistence of ovine scrapie infectivity in a farm environment following cleaning and decontamination
 
Steve A. C. Hawkins, MIBiol, Pathology Department1, Hugh A. Simmons, BVSc MRCVS, MBA, MA Animal Services Unit1, Kevin C. Gough, BSc, PhD2 and Ben C. Maddison, BSc, PhD3 + Author Affiliations
 
1Animal and Plant Health Agency, Woodham Lane, New Haw, Addlestone, Surrey KT15 3NB, UK 2School of Veterinary Medicine and Science, The University of Nottingham, Sutton Bonington, Loughborough, Leicestershire LE12 5RD, UK 3ADAS UK, School of Veterinary Medicine and Science, The University of Nottingham, Sutton Bonington, Loughborough, Leicestershire LE12 5RD, UK E-mail for correspondence: ben.maddison@adas.co.uk Abstract Scrapie of sheep/goats and chronic wasting disease of deer/elk are contagious prion diseases where environmental reservoirs are directly implicated in the transmission of disease. In this study, the effectiveness of recommended scrapie farm decontamination regimens was evaluated by a sheep bioassay using buildings naturally contaminated with scrapie. Pens within a farm building were treated with either 20,000 parts per million free chorine solution for one hour or were treated with the same but were followed by painting and full re-galvanisation or replacement of metalwork within the pen. Scrapie susceptible lambs of the PRNP genotype VRQ/VRQ were reared within these pens and their scrapie status was monitored by recto-anal mucosa-associated lymphoid tissue. All animals became infected over an 18-month period, even in the pen that had been subject to the most stringent decontamination process. These data suggest that recommended current guidelines for the decontamination of farm buildings following outbreaks of scrapie do little to reduce the titre of infectious scrapie material and that environmental recontamination could also be an issue associated with these premises.
 
SNIP...
 
Discussion
 
Thorough pressure washing of a pen had no effect on the amount of bioavailable scrapie infectivity (pen B). The routine removal of prions from surfaces within a laboratory setting is treatment for a minimum of one hour with 20,000 ppm free chlorine, a method originally based on the use of brain macerates from infected rodents to evaluate the effectiveness of decontamination (Kimberlin and others 1983). Further studies have also investigated the effectiveness of hypochlorite disinfection of metal surfaces to simulate the decontamination of surgical devices within a hospital setting. Such treatments with hypochlorite solution were able to reduce infectivity by 5.5 logs to lower than the sensitivity of the bioassay used (Lemmer and others 2004). Analogous treatment of the pen surfaces did not effectively remove the levels of scrapie infectivity over that of the control pens, indicating that this method of decontamination is not effective within a farm setting. This may be due to the high level of biological matrix that is present upon surfaces within the farm environment, which may reduce the amount of free chlorine available to inactivate any infectious prion. Remarkably 1/5 sheep introduced into pen D had also became scrapie positive within nine months, with all animals in this pen being RAMALT positive by 18 months of age. Pen D was no further away from the control pen (pen A) than any of the other pens within this barn. Localised hot spots of infectivity may be present within scrapie-contaminated environments, but it is unlikely that pen D area had an amount of scrapie contamination that was significantly different than the other areas within this building. Similarly, there were no differences in how the biosecurity of pen D was maintained, or how this pen was ventilated compared with the other pens. This observation, perhaps, indicates the slower kinetics of disease uptake within this pen and is consistent with a more thorough prion removal and recontamination. These observations may also account for the presence of inadvertent scrapie cases within other studies, where despite stringent biosecurity, control animals have become scrapie positive during challenge studies using barns that also housed scrapie-affected animals (Ryder and others 2009).
 
***The bioassay data indicate that the exposure of the sheep to a farm environment after decontamination efforts thought to be effective in removing scrapie is sufficient for the animals to become infected with scrapie. The main exposure routes within this scenario are likely to be via the oral route, during feeding and drinking, and respiratory and conjunctival routes. It has been demonstrated that scrapie infectivity can be efficiently transmitted via the nasal route in sheep (Hamir and others 2008), as is the case for CWD in both murine models and in white-tailed deer (Denkers and others 2010, 2013).
 
Recently, it has also been demonstrated that CWD prions presented as dust when bound to the soil mineral montmorillonite can be infectious via the nasal route (Nichols and others 2013). When considering pens C and D, the actual source of the infectious agent in the pens is not known, it is possible that biologically relevant levels of prion survive on surfaces during the decontamination regimen (pen C). With the use of galvanising and painting (pen D) covering and sealing the surface of the pen, it is possible that scrapie material recontaminated the pens by the movement of infectious prions contained within dusts originating from other parts of the barn that were not decontaminated or from other areas of the farm.
 
Given that scrapie prions are widespread on the surfaces of affected farms (Maddison and others 2010a), irrespective of the source of the infectious prions in the pens, this study clearly highlights the difficulties that are faced with the effective removal of environmentally associated scrapie infectivity. This is likely to be paralleled in CWD which shows strong similarities to scrapie in terms of both the dissemination of prions into the environment and the facile mode of disease transmission. These data further contribute to the understanding that prion diseases can be highly transmissible between susceptible individuals not just by direct contact but through highly stable environmental reservoirs that are refractory to decontamination.
 
The presence of these environmentally associated prions in farm buildings make the control of these diseases a considerable challenge, especially in animal species such as goats where there is lack of genetic resistance to scrapie and, therefore, no scope to re-stock farms with animals that are resistant to scrapie.
 
Scrapie Sheep Goats Transmissible spongiform encephalopathies (TSE) Accepted October 12, 2014. Published Online First 31 October 2014
 
 
Monday, November 3, 2014
 
Persistence of ovine scrapie infectivity in a farm environment following cleaning and decontamination
 
 
PPo3-22:
 
Detection of Environmentally Associated PrPSc on a Farm with Endemic Scrapie
 
Ben C. Maddison,1 Claire A. Baker,1 Helen C. Rees,1 Linda A. Terry,2 Leigh Thorne,2 Susan J. Belworthy2 and Kevin C. Gough3 1ADAS-UK LTD; Department of Biology; University of Leicester; Leicester, UK; 2Veterinary Laboratories Agency; Surry, KT UK; 3Department of Veterinary Medicine and Science; University of Nottingham; Sutton Bonington, Loughborough UK
 
Key words: scrapie, evironmental persistence, sPMCA
 
Ovine scrapie shows considerable horizontal transmission, yet the routes of transmission and specifically the role of fomites in transmission remain poorly defined. Here we present biochemical data demonstrating that on a scrapie-affected sheep farm, scrapie prion contamination is widespread. It was anticipated at the outset that if prions contaminate the environment that they would be there at extremely low levels, as such the most sensitive method available for the detection of PrPSc, serial Protein Misfolding Cyclic Amplification (sPMCA), was used in this study. We investigated the distribution of environmental scrapie prions by applying ovine sPMCA to samples taken from a range of surfaces that were accessible to animals and could be collected by use of a wetted foam swab. Prion was amplified by sPMCA from a number of these environmental swab samples including those taken from metal, plastic and wooden surfaces, both in the indoor and outdoor environment. At the time of sampling there had been no sheep contact with these areas for at least 20 days prior to sampling indicating that prions persist for at least this duration in the environment. These data implicate inanimate objects as environmental reservoirs of prion infectivity which are likely to contribute to disease transmission.
 
 
the tse prion aka mad cow type disease is not your normal pathogen.
 
The TSE prion disease survives ashing to 600 degrees celsius, that’s around 1112 degrees farenheit.
 
you cannot cook the TSE prion disease out of meat. you can take the ash and mix it with saline and inject that ash into a mouse, and the mouse will go down with TSE.
 
Prion Infected Meat-and-Bone Meal Is Still Infectious after Biodiesel Production as well.
 
the TSE prion agent also survives Simulated Wastewater Treatment Processes.
 
IN fact, you should also know that the TSE Prion agent will survive in the environment for years, if not decades.
 
you can bury it and it will not go away.
 
The TSE agent is capable of infected your water table i.e. Detection of protease-resistant cervid prion protein in water from a CWD-endemic area.
 
it’s not your ordinary pathogen you can just cook it out and be done with.
 
that’s what’s so worrisome about Iatrogenic mode of transmission, a simple autoclave will not kill this TSE prion agent.
 
cwd to humans, consumption, exposure, sub-clinical, iatrogenic, what if ?
 
Assessing Transmissible Spongiform Encephalopathy Species Barriers with an In Vitro Prion Protein Conversion Assay
 
Christopher J. Johnson1, Christina M. Carlson2, Aaron R. Morawski3, Alyson Manthei4, Neil R. Cashman5
 
1USGS National Wildlife Health Center, 2Department of Soil Science, University of Wisconsin–Madison, 3Laboratory of Immunology, National Institute of Allergy and Infectious Diseases, National Institutes of Health, 4Merial Veterinary Scholars Program, School of Veterinary Medicine, University of Wisconsin–Madison, 5Department of Neurology, University of British Columbia
 
Summary
 
Measuring the barrier to the interspecies transmission of prion diseases is challenging and typically involves animal challenges or biochemical assays. Here, we present an in vitro prion protein conversion assay with the ability to predict species barriers.
 
Date Published: 3/10/2015, Issue 97; doi: 10.3791/52522
 
Keywords: Medicine, Issue 97, Prion, species barrier, conversion, immunoblotting, transmissible spongiform encephalopathy, interspecies transmission Cite this Article
 
Johnson, C. J., Carlson, C. M., Morawski, A. R., Manthei, A., Cashman, N. R. Assessing Transmissible Spongiform Encephalopathy Species Barriers with an In Vitro Prion Protein Conversion Assay. J. Vis. Exp. (97), e52522, doi:10.3791/52522 (2015). Abstract
 
Studies to understanding interspecies transmission of transmissible spongiform encephalopathies (TSEs, prion diseases) are challenging in that they typically rely upon lengthy and costly in vivo animal challenge studies. A number of in vitro assays have been developed to aid in measuring prion species barriers, thereby reducing animal use and providing quicker results than animal bioassays. Here, we present the protocol for a rapid in vitro prion conversion assay called the conversion efficiency ratio (CER) assay. In this assay cellular prion protein (PrPC) from an uninfected host brain is denatured at both pH 7.4 and 3.5 to produce two substrates. When the pH 7.4 substrate is incubated with TSE agent, the amount of PrPC that converts to a proteinase K (PK)-resistant state is modulated by the original host’s species barrier to the TSE agent. In contrast, PrPC in the pH 3.5 substrate is misfolded by any TSE agent. By comparing the amount of PK-resistant prion protein in the two substrates, an assessment of the host’s species barrier can be made. We show that the CER assay correctly predicts known prion species barriers of laboratory mice and, as an example, show some preliminary results suggesting that bobcats (Lynx rufus) may be susceptible to white-tailed deer (Odocoileus virginianus) chronic wasting disease agent.
 
 
>>> show some preliminary results suggesting that bobcats (Lynx rufus) may be susceptible to white-tailed deer (Odocoileus virginianus) chronic wasting disease agent.
 
AD.63: Susceptibility of domestic cats to chronic wasting disease
 
Amy V.Nalls,1 Candace Mathiason,1 Davis Seelig,2 Susan Kraft,1 Kevin Carnes,1 Kelly Anderson,1 Jeanette Hayes-Klug1 and Edward A. Hoover1
 
1Colorado State University; Fort Collins, CO USA; 2University of Minnesota; Saint Paul, MN USA
 
Domestic and nondomestic cats have been shown to be susceptible to feline spongiform encephalopathy (FSE), almost certainly caused by consumption of bovine spongiform encephalopathy (BSE)-contaminated meat. Because domestic and free-ranging nondomestic felids scavenge cervid carcasses, including those in areas affected by chronic wasting disease (CWD), we evaluated the susceptibility of the domestic cat (Felis catus) to CWD infection experimentally. Cohorts of 5 cats each were inoculated either intracerebrally (IC) or orally (PO) with CWD-infected deer brain. At 40 and 42 mo post-inoculation, two IC-inoculated cats developed signs consistent with prion disease, including a stilted gait, weight loss, anorexia, polydipsia, patterned motor behaviors, head and tail tremors, and ataxia, and progressed to terminal disease within 5 mo. Brains from these two cats were pooled and inoculated into cohorts of cats by IC, PO, and intraperitoneal and subcutaneous (IP/SC) routes. Upon subpassage, feline-adapted CWD (FelCWD) was transmitted to all IC-inoculated cats with a decreased incubation period of 23 to 27 mo. FelCWD was detected in the brains of all the symptomatic cats by western blotting and immunohistochemistry and abnormalities were seen in magnetic resonance imaging, including multifocal T2 fluid attenuated inversion recovery (FLAIR) signal hyper-intensities, ventricular size increases, prominent sulci, and white matter tract cavitation. Currently, 3 of 4 IP/SQ and 2 of 4 PO inoculared cats have developed abnormal behavior patterns consistent with the early stage of feline CWD. These results demonstrate that CWD can be transmitted and adapted to the domestic cat, thus raising the issue of potential cervid-to- feline transmission in nature.
 
 
www.landesbioscience.com
 
PO-081: Chronic wasting disease in the cat— Similarities to feline spongiform encephalopathy (FSE)
 
 
 
 
 
PO-081: Chronic wasting disease in the cat— Similarities to feline spongiform encephalopathy (FSE)
 
 
 
Thursday, May 31, 2012
 
CHRONIC WASTING DISEASE CWD PRION2012 Aerosol, Inhalation transmission, Scrapie, cats, species barrier, burial, and more
 
 
Monday, August 8, 2011
 
Susceptibility of Domestic Cats to CWD Infection
 
 
Sunday, August 25, 2013
 
Prion2013 Chronic Wasting Disease CWD risk factors, humans, domestic cats, blood, and mother to offspring transmission
 
 
Feline Spongiform Encephalopathy (FSE) FSE was first identified in the UK in 1990. Most cases have been reported in the UK, where the epidemic has been consistent with that of the BSE epidemic. Some other countries (e.g. Norway, Liechtenstein and France) have also reported cases.
 
Most cases have been reported in domestic cats but there have also been cases in captive exotic cats (e.g. Cheetah, Lion, Asian leopard cat, Ocelot, Puma and Tiger). The disease is characterised by progressive nervous signs, including ataxia, hyper-reactivity and behavioural changes and is fatal.
 
The chemical and biological properties of the infectious agent are identical to those of the BSE and vCJD agents. These findings support the hypothesis that the FSE epidemic resulted from the consumption of food contaminated with the BSE agent.
 
The FSE epidemic has declined as a result of tight controls on the disposal of specified risk material and other animal by-products.
 
References: Leggett, M.M. et al.(1990) A spongiform encephalopathy in a cat. Veterinary Record. 127. 586-588
 
Synge, B.A. et al. (1991) Spongiform encephalopathy in a Scottish cat. Veterinary Record. 129. 320
 
Wyatt, J. M. et al. (1991) Naturally occurring scrapie-like spongiform encephalopathy in five domestic cats. Veterinary Record. 129. 233.
 
Gruffydd-Jones, T. J.et al.. (1991) Feline spongiform encephalopathy. J. Small Animal Practice. 33. 471-476.
 
Pearson, G. R. et al. (1992) Feline spongiform encephalopathy: fibril and PrP studies. Veterinary Record. 131. 307-310.
 
Willoughby, K. et al. (1992) Spongiform encephalopathy in a captive puma (Felis concolor). Veterinary Record. 131. 431-434.
 
Fraser, H. et al. (1994) Transmission of feline spongiform encephalopathy to mice. Veterinary Record 134. 449.
 
Bratberg, B. et al. (1995) Feline spongiform encephalopathy in a cat in Norway. Veterinary Record 136. 444
 
Baron, T. et al. (1997) Spongiform encephalopathy in an imported cheetah in France. Veterinary Record 141. 270-271
 
Zanusso, G et al. (1998) Simultaneous occurrence of spongiform encephalopathy in a man and his cat in Italy. Lancet, V352, N9134, OCT 3, Pp 1116-1117.
 
Ryder, S.J. et al. (2001) Inconsistent detection of PrP in extraneural tissues of cats with feline spongiform encephalopathy. Veterinary Record 146. 437-441
 
Kelly, D.F. et al. (2005) Neuropathological findings in cats with clinically suspect but histologically unconfirmed feline spongiform encephalopathy. Veterinary Record 156. 472-477.
 
 
3 further cheetah cases have occured, plus 1 lion, plus all the primates, and 20 additional house cats. Nothing has been published on any of these UK cases either. One supposes the problem here with publishing is that many unpublished cases were _born_ long after the feed "ban". Caught between a rock and a hard place: leaky ban or horizontal transmission (or both).
 
 
 
YOU explained that imported crushed heads were extensively used in the petfood industry...
 
 
In particular I do not believe one can say that the levels of the scrapie agent in pet food are so low that domestic animals are not exposed...
 
 
 
on occassions, materials obtained from slaughterhouses will be derived from sheep affected with scrapie or cattle that may be incubating BSE for use in petfood manufacture...
 
 
*** Meldrum's notes on pet foods and materials used
 
 
*** BSE & Pedigree Petfoods ***
 
 
In 2003, Denver Post reporter Theo Stein interviewed scientists about CWD spreading though deer and elk in Colorado. Dr. Valerius Geist, who paradoxically has become a darling of anti-wolfers, made this assertion about the significance of wolves in containing CWD spread via proteins called prions.
 
“Wolves will certainly bring the disease to a halt,” he said. “They will remove infected individuals and clean up carcasses that could transmit the disease.”
 
Stein added that “Geist and Princeton University biologist Andrew Dobson theorize that killing off the wolf allowed CWD to take hold in the first place.”
 
Wolves aren’t alone. In a 2009 study titled “Mountain lions prey selectively on prion-infected mule deer,” researchers in Colorado discovered that “adult mule deer killed by mountain lions were more likely to be prion-infected than were deer killed more randomly … suggesting that mountain lions were selecting for infected individuals when they targeted adult deer.”
 
 
NO, NO, NOT NO, BUT HELL KNOW !!!
 
PLEASE be careful what you ask for.
 
recently, canine spongiform encephalopathy has been confirmed.
 
I proved this in 2005, with a letter from MAFF/DEFRA et al confirming my suspicions of the ‘hound study’ way back. this was covered up. see documents below.
 
also, recently, cwd to the domestic cat is a great concern.
 
even though to date, as far as I am aware of, the cwd study on the mountain lion has not produced any confirmation yet, we already know that the feline species is highly succeptible to the TSE prion. domestic cats and the exotic zoo big cats.
 
so in my honest opinion, any program that would use wild animals to prey on other wild animals, as a tool to help curb CWD TSE prion disease, would only help enhance the spread of disease, and it would only help spread the disease to other species. ...TSS
 
Monday, February 14, 2011
 
THE ROLE OF PREDATION IN DISEASE CONTROL: A COMPARISON OF SELECTIVE AND NONSELECTIVE REMOVAL ON PRION DISEASE DYNAMICS IN DEER
 
NO, NO, NOT NO, BUT HELL NO !
 
Journal of Wildlife Diseases, 47(1), 2011, pp. 78-93 © Wildlife Disease Association 2011
 
 
OR-09: Canine spongiform encephalopathy—A new form of animal prion disease
 
Monique David, Mourad Tayebi UT Health; Houston, TX USA
 
It was also hypothesized that BSE might have originated from an unrecognized sporadic or genetic case of bovine prion disease incorporated into cattle feed or even cattle feed contaminated with prion-infected human remains.1 However, strong support for a genetic origin of BSE has recently been demonstrated in an H-type BSE case exhibiting the novel mutation E211K.2 Furthermore, a specific prion protein strain causing BSE in cattle is believed to be the etiological agent responsible for the novel human prion disease, variant Creutzfeldt-Jakob disease (vCJD).3 Cases of vCJD have been identified in a number countries, including France, Italy, Ireland, the Netherlands, Canada, Japan, US and the UK with the largest number of cases. Naturally occurring feline spongiform encephalopathy of domestic cats4 and spongiform encephalopathies of a number of zoo animals so-called exotic ungulate encephalopathies5,6 are also recognized as animal prion diseases, and are thought to have resulted from the same BSE-contaminated food given to cattle and humans, although and at least in some of these cases, a sporadic and/or genetic etiology cannot be ruled out. The canine species seems to display resistance to prion disease and no single case has so far been reported.7,8 Here, we describe a case of a 9 week old male Rottweiler puppy presenting neurological deficits; and histological examination revealed spongiform vacuolation characteristic of those associated with prion diseases.9 Initial biochemical studies using anti-PrP antibodies revealed the presence of partially proteinase K-resistant fragment by western blotting. Furthermore, immunohistochemistry revealed spongiform degeneration consistent with those found in prion disease and displayed staining for PrPSc in the cortex.
 
Of major importance, PrPSc isolated from the Rottweiler was able to cross the species barrier transmitted to hamster in vitro with PMCA and in vivo (one hamster out of 5). Futhermore, second in vivo passage to hamsters, led to 100% attack rate (n = 4) and animals displayed untypical lesional profile and shorter incubation period.
 
In this study, we show that the canine species might be sensitive to prion disease and that PrPSc isolated from a dog can be transmitted to dogs and hamsters in vitro using PMCA and in vivo to hamsters.
 
If our preliminary results are confirmed, the proposal will have a major impact on animal and public health and would certainly lead to implementing new control measures for ‘canine spongiform encephalopathy’ (CSE).
 
References 1. Colchester AC, Colchester NT. The origin of bovine spongiform encephalopathy: the human prion disease hypothesis. Lancet 2005; 366:856-61; PMID:16139661; http:// dx.doi.org/10.1016/S0140-6736(05)67218-2.
 
2. Richt JA, Hall SM. BSE case associated with prion protein gene mutation. PLoS Pathog 2008; 4:e1000156; PMID:18787697; http://dx.doi.org/10.1371/journal. ppat.1000156.
 
3. Collinge J. Human prion diseases and bovine spongiform encephalopathy (BSE). Hum Mol Genet 1997; 6:1699-705; PMID:9300662; http://dx.doi.org/10.1093/ hmg/6.10.1699.
 
4. Wyatt JM, Pearson GR, Smerdon TN, Gruffydd-Jones TJ, Wells GA, Wilesmith JW. Naturally occurring scrapie-like spongiform encephalopathy in five domestic cats. Vet Rec 1991; 129:233-6; PMID:1957458; http://dx.doi.org/10.1136/vr.129.11.233.
 
5. Jeffrey M, Wells GA. Spongiform encephalopathy in a nyala (Tragelaphus angasi). Vet Pathol 1988; 25:398-9; PMID:3232315; http://dx.doi.org/10.1177/030098588802500514.
 
6. Kirkwood JK, Wells GA, Wilesmith JW, Cunningham AA, Jackson SI. Spongiform encephalopathy in an arabian oryx (Oryx leucoryx) and a greater kudu (Tragelaphus strepsiceros). Vet Rec 1990; 127:418-20; PMID:2264242.
 
7. Bartz JC, McKenzie DI, Bessen RA, Marsh RF, Aiken JM. Transmissible mink encephalopathy species barrier effect between ferret and mink: PrP gene and protein analysis. J Gen Virol 1994; 75:2947-53; PMID:7964604; http://dx.doi.org/10.1099/0022-1317- 75-11-2947.
 
8. Lysek DA, Schorn C, Nivon LG, Esteve-Moya V, Christen B, Calzolai L, et al. Prion protein NMR structures of cats, dogs, pigs, and sheep. Proc Natl Acad Sci U S A 2005; 102:640-5; PMID:15647367; http://dx.doi.org/10.1073/pnas.0408937102.
 
9. Budka H. Neuropathology of prion diseases. Br Med Bull 2003; 66:121-30; PMID:14522854; http://dx.doi.org/10.1093/bmb/66.1.121.
 
 
Monday, March 26, 2012
 
CANINE SPONGIFORM ENCEPHALOPATHY: A NEW FORM OF ANIMAL PRION DISEASE
 
 
Monday, March 8, 2010
 
Canine Spongiform Encephalopathy aka MAD DOG DISEASE
 
 
=======================================
 
2013
 
Strain characteristics of the in vitro-adapted rabbit and dog BSE agent remained invariable with respect to the original cattle BSE prion, suggesting that the naturally low susceptibility of rabbits and dogs to prion infections should not alter their zoonotic potential if these animals became infected with BSE.
 
=======================================
 
Neurobiology of Disease
 
Bovine Spongiform Encephalopathy Induces Misfolding of Alleged Prion-Resistant Species Cellular Prion Protein without Altering Its Pathobiological Features
 
Enric Vidal3, Natalia Fernández-Borges1, Belén Pintado4, Montserrat Ordóñez3, Mercedes Márquez6, Dolors Fondevila5,6, Juan María Torres7, Martí Pumarola5,6, and Joaquín Castilla1,2 + Author Affiliations
 
1CIC bioGUNE, 48160 Derio, Bizkaia, Spain,
 
2IKERBASQUE, Basque Foundation for Science, 48011 Bilbao, Bizkaia, Spain,
 
3Centre de Recerca en Sanitat Animal, Campus de la Universitat Autònoma de Barcelona (UAB)-IRTA, 08193 Bellaterra, Barcelona, Spain,
 
4Centro Nacional de Biotecnología, Campus de Cantoblanco, 28049 Cantoblanco, Madrid, Spain,
 
5Department of Animal Medicine and Surgery, Veterinary Faculty, UAB, 08193 Bellaterra (Cerdanyola del Vallès), Barcelona, Spain,
 
6Murine Pathology Unit, Centre de Biotecnologia Animal i Teràpia Gènica, UAB, 08193 Bellaterra (Cerdanyola del Vallès), Barcelona, Spain, and
 
7Centro de Investigación en Sanidad Animal-Instituto Nacional de Investigación y Tecnología Agraria y Alimentaria, 28130 Valdeolmos, Madrid, Spain
 
Author contributions: E.V., N.F.-B., and J.C. designed research; E.V., N.F.-B., B.P., M.O., M.M., D.F., and J.C. performed research; E.V., N.F.-B., B.P., and J.C. contributed unpublished reagents/analytic tools; E.V., N.F.-B., B.P., M.O., M.M., D.F., J.M.T., M.P., and J.C. analyzed data; E.V. and J.C. wrote the paper.
 
Abstract
 
Bovine spongiform encephalopathy (BSE) prions were responsible for an unforeseen epizootic in cattle which had a vast social, economic, and public health impact. This was primarily because BSE prions were found to be transmissible to humans. Other species were also susceptible to BSE either by natural infection (e.g., felids, caprids) or in experimental settings (e.g., sheep, mice). However, certain species closely related to humans, such as canids and leporids, were apparently resistant to BSE. In vitro prion amplification techniques (saPMCA) were used to successfully misfold the cellular prion protein (PrPc) of these allegedly resistant species into a BSE-type prion protein. The biochemical and biological properties of the new prions generated in vitro after seeding rabbit and dog brain homogenates with classical BSE were studied. Pathobiological features of the resultant prion strains were determined after their inoculation into transgenic mice expressing bovine and human PrPC. Strain characteristics of the in vitro-adapted rabbit and dog BSE agent remained invariable with respect to the original cattle BSE prion, suggesting that the naturally low susceptibility of rabbits and dogs to prion infections should not alter their zoonotic potential if these animals became infected with BSE. This study provides a sound basis for risk assessment regarding prion diseases in purportedly resistant species.
 
Received January 18, 2013. Revision received March 7, 2013. Accepted March 23, 2013. Copyright © 2013 the authors 0270-6474/13/337778-09$15.00/0
 
 
2005
 
DEFRA Department for Environment, Food & Rural Affairs
 
Area 307, London, SW1P 4PQ Telephone: 0207 904 6000 Direct line: 0207 904 6287 E-mail: h.mcdonagh.defra.gsi.gov.uk
 
GTN: FAX:
 
Mr T S Singeltary P.O. Box 42 Bacliff Texas USA 77518
 
21 November 2001
 
Dear Mr Singeltary
 
TSE IN HOUNDS
 
Thank you for e-mail regarding the hounds survey. I am sorry for the long delay in responding.
 
As you note, the hound survey remains unpublished. However the Spongiform Encephalopathy Advisory Committee (SEAC), the UK Government's independent Advisory Committee on all aspects related to BSE-like disease, gave the hound study detailed consideration at their meeting in January 1994. As a summary of this meeting published in the BSE inquiry noted, the Committee were clearly concerned about the work that had been carried out, concluding that there had clearly been problems with it, particularly the control on the histology, and that it was more or less inconclusive. However was agreed that there should be a re-evaluation of the pathological material in the study.
 
Later, at their meeting in June 95, The Committee re-evaluated the hound study to see if any useful results could be gained from it. The Chairman concluded that there were varying opinions within the Committee on further work. It did not suggest any further transmission studies and thought that the lack of clinical data was a major weakness.
 
Overall, it is clear that SEAC had major concerns about the survey as conducted. As a result it is likely that the authors felt that it would not stand up to r~eer review and hence it was never published. As noted above, and in the detailed minutes of the SEAC meeting in June 95, SEAC considered whether additional work should be performed to examine dogs for evidence of TSE infection. Although the Committee had mixed views about the merits of conducting further work, the Chairman noted that when the Southwood Committee made their recommendation to complete an assessment of possible spongiform disease in dogs, no TSEs had been identified in other species and hence dogs were perceived as a high risk population and worthy of study. However subsequent to the original recommendation, made in 1990, a number of other species had been identified with TSE ( e.g. cats) so a study in hounds was less
 
 
As this study remains unpublished, my understanding is that the ownership of the data essentially remains with the original researchers. Thus unfortunately, I am unable to help with your request to supply information on the hound survey directly. My only suggestion is that you contact one of the researchers originally involved in the project, such as Gerald Wells. He can be contacted at the following address.
 
Dr Gerald Wells, Veterinary Laboratories Agency, New Haw, Addlestone, Surrey, KT 15 3NB, UK
 
You may also wish to be aware that since November 1994 all suspected cases of spongiform encephalopathy in animals and poultry were made notifiable. Hence since that date there has been a requirement for vets to report any suspect SE in dogs for further investigation. To date there has never been positive identification of a TSE in a dog.
 
I hope this is helpful
 
Yours sincerely 4
 
HUGH MCDONAGH BSE CORRESPONDENCE SECTION
 
======================================
 
HOUND SURVEY
 
I am sorry, but I really could have been a co-signatory of Gerald's minute.
 
I do NOT think that we can justify devoting any resources to this study, especially as larger and more important projects such as the pathogenesis study will be quite demanding.
 
If there is a POLITICAL need to continue with the examination of hound brains then it should be passed entirely to the VI Service.
 
J W WILESMITH Epidemiology Unit 18 October 1991
 
Mr. R Bradley
 
cc: Mr. G A H Wells
 
 
3.3. Mr R J Higgins in conjunction with Mr G A Wells and Mr A C Scott would by the end of the year, indentify the three brains that were from the ''POSITIVE'' end of the lesion spectrum.
 
 
TSE in dogs have not been documented simply because OF THE ONLY STUDY, those brain tissue samples were screwed up too. see my investigation of this here, and to follow, later follow up, a letter from defra, AND SEE SUSPICIOUS BRAIN TISSUE SAF's. ...TSS
 
 
TSE & HOUNDS
 
GAH WELLS (very important statement here...TSS)
 
HOUND STUDY
 
AS implied in the Inset 25 we must not _ASSUME_ that transmission of BSE to other species will invariably present pathology typical of a scrapie-like disease.
 
snip...
 
 
76 pages on hound study;
 
snip...
 
 
The spongiform changes were not pathognomonic (ie. conclusive proof) for prion disease, as they were atypical, being largely present in white matter rather than grey matter in the brain and spinal cord. However, Tony Scott, then head of electron microscopy work on TSEs, had no doubt that these SAFs were genuine and that these hounds therefore must have had a scrapie-like disease. I reviewed all the sections myself (original notes appended) and although the pathology was not typical, I could not exclude the possibility that this was a scrapie-like disorder, as white matter vacuolation is seen in TSEs and Wallerian degeneration was also present in the white matter of the hounds, another feature of scrapie.
 
38.I reviewed the literature on hound neuropathology, and discovered that micrographs and descriptive neuropathology from papers on 'hound ataxia' mirrored those in material from Robert Higgins' hound survey. Dr Tony Palmer (Cambridge) had done much of this work, and I obtained original sections from hound ataxia cases from him. This enabled me provisionally to conclude that Robert Higgins had in all probability detected hound ataxia, but also that hound ataxia itself was possibly a TSE. Gerald Wells confirmed in 'blind' examination of single restricted microscopic fields that there was no distinction between the white matter vacuolation present in BSE and scrapie cases, and that occurring in hound ataxia and the hound survey cases.
 
39.Hound ataxia had reportedly been occurring since the 1930's, and a known risk factor for its development was the feeding to hounds of downer cows, and particularly bovine offal. Circumstantial evidence suggests that bovine offal may also be causal in FSE, and TME in mink. Despite the inconclusive nature of the neuropathology, it was clearly evident that this putative canine spongiform encephalopathy merited further investigation.
 
40.The inconclusive results in hounds were never confirmed, nor was the link with hound ataxia pursued. I telephoned Robert Higgins six years after he first sent the slides to CVL. I was informed that despite his submitting a yearly report to the CVO including the suggestion that the hound work be continued, no further work had been done since 1991. This was surprising, to say the very least.
 
41.The hound work could have provided valuable evidence that a scrapie-like agent may have been present in cattle offal long before the BSE epidemic was recognised. The MAFF hound survey remains unpublished.
 
Histopathological support to various other published MAFF experiments
 
42.These included neuropathological examination of material from experiments studying the attempted transmission of BSE to chickens and pigs (CVL 1991) and to mice (RVC 1994).
 
 
It was thought likely that at least some, and probably all, of the cases in zoo animals were caused by the BSE agent. Strong support for this hypothesis came from the findings of Bruce and others (1994) ( Bruce, M.E., Chree, A., McConnell, I., Foster, J., Pearson, G. & Fraser, H. (1994) Transmission of bovine spongiform encephalopathy and scrapie to mice: strain variation and species barrier. Philosophical Transactions of the Royal Society B 343, 405-411: J/PTRSL/343/405 ), who demonstrated that the pattern of variation in incubation period and lesion profile in six strains of mice inoculated with brain homogenates from an affected kudu and the nyala, was similar to that seen when this panel of mouse strains was inoculated with brain from cattle with BSE. The affected zoo bovids were all from herds that were exposed to feeds that were likely to have contained contaminated ruminant-derived protein and the zoo felids had been exposed, if only occasionally in some cases, to tissues from cattle unfit for human consumption.
 
snip...
 
 
NEW URL ;
 
 
Friday, March 8, 2013
 
Dogs may have been used to make Petfood and animal feed
 
 
 
 
Tuesday, June 11, 2013
 
Weld County Bi-Products dba Fort Morgan Pet Foods 6/1/12 significant deviations from requirements in FDA regulations that are intended to reduce the risk of bovine spongiform encephalopathy (BSE) within the United States
 
 
Comment from Terry Singeltary This is a Comment on the Food and Drug Administration (FDA) Notice: Draft Guidance for Industry on Ensuring Safety of Animal Feed Maintained and Fed On-Farm; Availability
 
For related information, Open Docket Folder Docket folder icon
 
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Comment View document:
 
 
 
Guidance for Industry Ensuring Safety of Animal Feed Maintained and Fed On-Farm Draft Guidance FDA-2014-D-1180 Singeltary Comment
 
Greetings FDA et al,
 
I wish to comment on Guidance for Industry Ensuring Safety of Animal Feed Maintained and Fed On-Farm Draft Guidance FDA-2014-D-1180.
 
Once again, I wish to kindly bring up the failed attempt of the FDA and the ruminant to ruminant mad cow feed ban of August 4, 1997. This feed ban is still failing today, as we speak. Even more worrisome, is the fact it is still legal to feed cervids to cervids in the USA, in fact, the FDA only _recommends_ that deer and elk considered to be of _high_ risk for CWD do not enter the animal food chain, but there is NO law, its only voluntary, a recipe for a TSE prion disaster, as we have seen with the ruminant to ruminant feed ban for cattle, where in 2007, one decade post August 1997 mad cow feed ban, where in 2007 10,000,000 POUNDS OF BANNED BLOOD LACED MEAT AND BONE MEAL WHEN OUT INTO COMMERCE, TO BE FED OUT. Since 2007, these BSE feed ban rules have been breached time and time again. tons and tons of mad cow feed went out in Alabama as well, where one of the mad cows were documented, just the year before in 2006, and in 2013 and 2014, breaches so bad (OAI) Official Action Indicated were issued. those are like the one issued where 10 million pounds of banned blood laced meat and bone meal were fed out.
 
Saturday, January 31, 2015
 
European red deer (Cervus elaphus elaphus) are susceptible to Bovine Spongiform Encephalopathy BSE by Oral Alimentary route
 
 
I strenuously once again urge the FDA and its industry constituents, to make it MANDATORY that all ruminant feed be banned to all ruminants, and this should include all cervids as soon as possible for the following reasons...
 
======
 
In the USA, under the Food and Drug Administrations BSE Feed Regulation (21 CFR 589.2000) most material (exceptions include milk, tallow, and gelatin) from deer and elk is prohibited for use in feed for ruminant animals. With regards to feed for non-ruminant animals, under FDA law, CWD positive deer may not be used for any animal feed or feed ingredients. For elk and deer considered at high risk for CWD, the FDA recommends that these animals do not enter the animal feed system.
 
***However, this recommendation is guidance and not a requirement by law.
 
======
 
31 Jan 2015 at 20:14 GMT
 
*** Ruminant feed ban for cervids in the United States? ***
 
31 Jan 2015 at 20:14 GMT
 
 
Monday, October 26, 2015
 
*** FDA PART 589 -- SUBSTANCES PROHIBITED FROM USE IN ANIMAL FOOD OR FEED VIOLATIONS OFFICIAL ACTION INDICATED OIA UPDATE October 2015
 
 
Friday, August 14, 2015
 
*** Susceptibility of cattle to the agent of chronic wasting disease from elk after intracranial inoculation
 
 
Friday, August 14, 2015
 
*** Carcass Management During a Mass Animal Health Emergency Draft Programmatic Environmental Impact Statement—August 2015
 
 
Tuesday, September 22, 2015
 
*** Host Determinants of Prion Strain Diversity Independent of Prion Protein Genotype
 
 
Friday, August 28, 2015
 
*** Chronic Wasting Disease CWD TSE Prion Diagnostics and subclinical infection ***
 
 
Thursday, November 05, 2015
 
TPW Commission Adopts Interim Deer Breeder Movement Rules
 
 
 
Terry S. Singeltary Sr.
 
 
Saturday, November 14, 2015
 
Wyoming Chronic Wasting Disease CWD Surveillance Results 2014 reported in 2015
 
 
 

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