Living Test for Mad Cow Disease

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22 Aug 2005 14:45:44 -0000

Living Test for Mad Cow Disease

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ISIS Press Release 22/08/05

ISIS Exclusive

Living Test for Mad Cow Disease

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A new diagnostic test that claims to detect Mad Cow Disease

in living animals before symptoms appear also raises

questions on the cause of the disease Dr. Mae-Wan Ho

 

The fully referenced article is posted on ISIS members'

website http://www.i-sis.org.uk/full/LTFMCDFull.php. Details

here http://www.i-sis.org.uk/membership.php

 

Mad Cow Disease and variant CJD

 

It has been 20 years since Mad Cow Disease (bovine

spongiform encephalopathy, BSE) appeared in Britain, killing

more than180 000 cattle, and causing the mass slaughter of a

further 5 million. The disease has jumped species to human

beings, resulting in some 160 known cases worldwide of the

fatal variant Creutzfeldt-Jakob Disease (vCJD); although the

precise extent of the CJD epidemic is suspected to be 20

times worse than appears (see Box). The disease agent,

according to the current establishment view, is a highly

unusual misfolded protein, prion, which both causes and

transmits the disease. Prion proteins are present in the

brain tissues of all healthy animals in the correctly folded

form. However, on being exposed to the misfolded form, the

correctly folded normal protein becomes misfolded, causing

it to aggregate into dense fibres, clogging up the cells and

triggering a degenerative disease that turns the brain into

a sponge. There has been little progress in diagnosis or

treatment for either BSE or vCJD. The only available tests

are those done post mortem on brain tissue from slaughtered

animals, based on detecting the misfolded prion protein

that's found after the disease has progressed to a late

stage. This not only underestimates the cases of BSE, but

can also allow infected cattle to pass into the human food

chain. A tiny amount of misfolded prion protein may be

sufficient to make a healthy animal's own correctly folded

prion protein to misfold. A number of laboratories have been

trying to develop a test that can detect BSE in live animals

before the disease symptoms appear; nearly all based on

improving the sensitivity of detecting prion proteins.

 

 

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Box A brief history of Mad Cow Disease Mad Cow Disease first

appeared in Britain in the mid1980s, where it was officially

diagnosed in 1986 as bovine spongiform encephalopathy (BSE),

as it turns the brain into a sponge-like mass [1]. It killed

over 180 000 cattle and devastated the British beef industry

and farmers. Humans have contracted variant Creutzfeldt-

Jakob Disease (vCJD), a disease most closely similar to BSE,

by eating meat from infected animals. From Britain the

epidemic spread to the rest of Europe infecting over 4 200

cattle in 19 countries by mid-2003. As the disease has

jumped species barriers, infecting and killing humans, the

European authorities have destroyed more than 5 million

potentially infected cattle as a precautionary measure.

Since 1996, cattle over 30 months old have been banned from

entering the food chain, a measure that is thought to remove

over 99 percent of infected cattle [2]. Nevertheless,

infected cattle have appeared in Canada, Japan, Israel, Oman

and the Falkland Islands; and in the United States at the

end of 2003 [3]. By 2003, more than 150 people have

contracted vCJD: 143 in the UK, 6 in France, 2 in Canada and

one each in Ireland, Italy and the US [1]. (The figure for

UK has increased to 157 at the end of July 2005, and cases

of human contracting vCJD from blood transfusions have been

discovered [4].) Variant CJD tends to strike young people,

is invariably fatal and takes about 14 months to kill its

victim. Classic CJD strikes mainly the elderly. Recent

evidence suggests that BSE can cause both classic as well as

variant CJD, which may explain the rising numbers of CJD

cases in Europe, and the disturbing trend to younger CJD

cases in the US. Several autopsy studies in the US suggest

that 3 to 13% of patients diagnosed with Alzheimer's or

dementia are actually CJD cases; thus, at least 120 000 CJD

cases may go undetected and excluded from official

statistics [5]. Similarly, a team of UK scientists found

that 3 out of 12 674 stored appendix and tonsil samples

showed evidence of infection, which gives an estimate of

about 3 800 individuals in the UK who would test positive

[6, 7]. Mad Cow Disease, CJD and related diseases –

including chronic wasting disease spreading among the US

deer and elk population – are associated with misfolded

proteins called prions that aggregate to form dense tangled

fibres in the brain cells, thereby killing them. Prions are

highly resistant to heat, chemicals and radiation

treatments, and cannot be inactivated with disinfection

measures used to kill ordinary disease agents such as

viruses and bacteria. The misfolded prion proteins are

believed to be both the cause of BSE and the infectious

agents transmitting the disease, and that feeding cattle

with rendered remains of sheep affected with a related

disease, scrapie, led to the outbreak of the BSE epidemic

(but see main text).

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Living test depends on specific genetic markers

 

In July 2005, a company in Gottingen, Germany, published a

peer-review paper in the journal, Clinical and Diagnostic

Laboratory Immunology, reporting a diagnostic test for BSE

in live animals, which does not depend on detecting the

prion protein. Instead, the " Gottingen Living Test (GLT) " ,

as it is called, depends on detecting " unique, specific gene

markers " that are in 100 percent of cows with confirmed BSE,

and in 100 percent of groups of associated high-risk

animals, i.e., cows in the same feeding cohorts as those

with BSE [8]. In contrast, only 0.6 percent of the control

group of healthy animals tested positive on the GLT. This

suggests that the test could be used to identify animals

that are at risk of developing BSE in BSE eradication and

surveillance programmes. The GLT will enable animals at-risk

to be removed from the food chain while still alive, thereby

reducing both the threat to human health and the economic

impact on the cattle industry.

 

Circulating nucleic acids and chronic diseases

 

The development of GLT involved the collaboration between

the Institute of Veterinary Medicine in Georg-August

University, Gottingen, a leading research institute in BSE,

and Chronix Biomedical, a genomics company whose core

technology – protected by patent - is based on developing

tests for detecting and monitoring a new class of markers

for chronic illnesses: circulating nucleic acids (CNAs).

CNAs are RNA and DNA detected in biological fluids free of

cells or cellular material and found to be useful for the

staging of some chronic illnesses. Most CNA lab diagnostics

are based on amplifying either RNA or DNA with primers

(probes) for single-copy functional coding regions of genes

associated with infectious agents such as West Nile virus,

HIV, hepatitis B virus. In contrast, some CNA studies have

focussed on endogenous repeat sequences found in the genome.

Dr. Howard Urnovitz, the CEO of Chronix Biomedical, found

three out of three sick veterans of the 1991 Gulf War had

the same repetitive sequences, including short Alu

repetitive sequences in their CNAs ( " Dynamic genomics &

environmental health " , SiS 19). Similarly, repetitive

sequences in CNAs were associated with the clinical status

of individual multiple myeloma patients.

 

BSE diagnosis in both sick cows and healthy BSE-exposed cows

 

For BSE diagnosis, a specific polymerase chain reaction

(PCR) probe was used that amplified the tail-end of a bovine

genome short interspersed nuclear element (SINE), Bov-tA,

about 285 000 copies of which are present in the genome,

often at the 3'(tail-end) unstranslated region of genes. The

probe detected multiple CNAs, ranging from less than 150 to

350bp, found only in the sera of BSE-confirmed cows and

among high-risk cows exposed to BSE in the same feeding

cohorts. None of the bands was amplified from the sera of

healthy control animals. The PCR products from two BSE cases

and six BSE cohort animals were cloned and sequenced. The

range of fragment sizes was from 105 to 304bp, with an

average size of 210bp. A stretch of about 80bp - found in

nearly all the clones (150 out of 163) – was part of Bov-tA,

as expected. However, this 80bp piece has other bits of

sequences attached downstream, which, though they also

appear to belong to the bovine genome, are not found in the

bovine genome as contiguous sequences. The researcher team

analysed a further four confirmed BSE cases, eight unrelated

cohorts consisting of a total of 135 animals that were

diagnosed BSE-negative by the standard prion tests, and 176

healthy control cows, which included 148 samples from a

slaughterhouse processing cattle from the same area where

the BSE cases developed (to avoid a regional bias), and 28

samples from a BSE non-exposed healthy control herd. The BSE

cases tested 100 percent positive by the same PCR diagnosis,

i.e., 4 out of 4, while only 1 out of 176 healthy controls

tested positive, or 0.6 percent. The 8 BSE-cohorts tested 33

percent to 91 percent positive, with an average of 63

percent positive. This was a very significant result, as

these BSE-cohort cows were diagnosed BSE-negative by the

standard tests for prion proteins in brain tissue after they

were slaughtered. According to data provided by the German

Ministry of Consumer Safety, Nutrition and Agriculture, the

likelihood of detecting a prion positive animal among

cohorts of BSE cattle is more than 100-fold greater than in

healthy, non-cohort cattle. This figure matches the finding

in the present report: 63 percent of cohorts reacting

positive compared to 0.6 percent positive in noncohort

healthy cattle. In a further field study, an additional 669

samples from a slaughterhouse were tested. These samples

originated from 257 different farms. Only four samples were

found to be repeatedly positive (0.59%), which confirms the

results with the previous 176 normal control cattle.

 

What is the basis of the diagnosis?

 

The diagnosis depends on amplifying circulating nucleic

acids all of which contain a fragment of a particular

repetitive element (Bov-tA, a member of SINE) present in the

bovine genome. The expression of SINE elements is associated

with cell stress, as previous work by other researchers has

indicated. For example, cells stressed by exposure to the

toxic drugs cycloheximide or puromycin rapidly and for a

short while increased the abundance of Alu-containing RNA

(Alu is a SINE specific to primates including humans). Thus,

finding SINE-containing CNAs in both BSE and BSE-exposed

cohorts suggest that cell stress may be involved in BSE; and

further, that detection of specific cell-stress CNAs could

offer an early diagnosis of impending disease. The sequences

attached to the SINE sequence in the BSE-associated CNAs

appear to be rearranged or scrambled bovine genome

sequences. This is consistent with the strong involvement of

SINE sequences in recombination events. The results suggest,

therefore, that exposure to toxic agents causing cell-stress

has led to activation of repetitive elements in the genome

involved in recombination, and extensive scrambling of

genome sequences in animals that had developed BSE and

others " exposed to BSE " .

 

This research does appear to be the first living test for

BSE or very nearly so. To really clinch the test, it would

be necessary to see if the healthy BSE-exposed animals which

tested positive will actually go on to develop BSE. But in

the absence of any other contender test for the disease,

most farmers and regulators might be willing to accept the

present test at least as an indicator for BSE-exposure, so

that animals at-risk can be removed from the food chain,

thereby reducing both the threat to human health and the

economic impact on the cattle industry. Another argument in

its favour is that in the absence of such a test, the whole

herd would have had to be slaughtered as a precautionary

measure in any case.

 

What really caused BSE?

 

This research also raises important questions over the cause

of BSE. There are many scientists who remain doubtful of the

official account that prion proteins are the infectious

agent [10]; as this runs counter to the conventional wisdom

that all known infectious agents such bacteria and viruses

contain genetic material - RNA or DNA – which is crucial for

infectivity. There is also doubt as to whether the BSE

epidemic was caused by feeding cattle with improperly

treated meat and bone meal feed containing the related

scrapie agent from sheep remains. Organic farmer Mark Purdey

in Britain reviewed extensive epidemiological and

biochemical evidence contradicting the official view on the

origin and cause of BSE [11]. This evidence suggests instead

that BSE was triggered by the widespread use of the

organophosphate insecticide Phosmet following the Warble Fly

Order issued by UK's then Ministry of Agriculture, Fisheries

and Food in 1984, coupled with the industrial pollution of

agricultural land by manganese, which appears to be involved

in the misfolding of prion proteins. Purdey's hypothesis is

consistent with the cell-stress circulating nucleic acids

found in BSE-diagnosed and BSE-exposed animals reported by

Chronix Biomedical. Further research should be done to see

if BSE-specific cell-stress CNAs correlates with exposure of

cattle herds to toxic agents such as organophosphate

insecticides and manganese.

 

 

 

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