A R T I C L E

BSE - mad cow - scrapie, etc.: Stimulated amyloid degeneration and the toxic fats

I have written before about the protective effects of carbon dioxide and progesterone, especially for the brain, and how the structure of cell water is affected by adsorbed and dissolved materials, and by metabolic energy. In the high energy (rested) state, cell water behaves as if it were colder than its real temperature, and this affects the behavior of proteins and fats in the cell, allowing “oily” surfaces to remain in contact with the more orderly water. Carbon dioxide spontaneously combines with the amino groups in proteins, stabilizing the normal functional conformation. The loss of carbon dioxide affects the structure of all proteins in the body, and the loss of cellular energy affects the structure of the intracellular proteins and their associated molecules.

In scrapie and many other degenerative diseases (the amyloidoses), proteins condense into fibrils that tend to keep enlarging, with a variety of very harmful effects. The condensation of the “amyloid” proteins is sensitive to temperature, and a slight increase in the disorder of the water can induce functional proteins to change their conformation so that they spontaneously associate into fibrous masses. In the absence of sufficient carbon dioxide, all proteins are susceptible to structural alteration by the addition of sugars and fats and aldehydes, especially under conditions that favor lipid peroxidation.

The amyloidoses affect different tissues in different ways, but when they occur in the brain, they produce progressive loss of function, with the type of protein forming the fibrils determining the nature of the functional loss. The protein which carries thyroid hormone and vitamin A, transthyretin, can produce nerve and brain amyloid disease, but it can also protect against other amyloid brain diseases; in Alzheimer’s disease, Parkinson’s disease, Huntington’s disease, and the “prion diseases” (scrapie, kuru, CJD, BSE, etc.) amyloid particles are formed by different proteins. The transthyretin protein which is binding small molecules resists condensation into the amyloid fibrils, but without its normal vitamin A and thyroid hormone, it can create toxic fibrils. (Raghu, et al., 2002.)

Around 1970 I read E. J. Field’s suggestion that aging tissues and tissues affected by viral diseases showed some similar structures (“inclusion bodies”) under the electron microscope. In following up those observations, it turned out that old tissues appeared to develop antigens “identical with, or similar to,” scrapie-infected young tissues. The premature aging caused by removal of the thymus gland in newborn animals produced similar results.

Field’s group and others (e.g., Alpers) were clearly showing that the scrapie infection involved proteins, but not viruses with nucleic acids. In one of Field’s last publications (1978), he even suggested that the infectious process might depend on a structural rearrangement of the host’s molecules, similar to the idea which is now known as the “prion hypothesis.” Field’s suggestion was an important advance in the theory of aging, and the evidence supporting it is now voluminous, but that work has been omitted from the official histories.

Although phenomena of “imprinting” and non-genetic inheritance had been established earlier, the dogmatism of genetics led the scientific establishment to reject everything that challenged the primacy of DNA. When I mentioned to my professors (in 1971) the evidence that scrapie was transmitted without nucleic acid, I could see from their reactions that it would be a very long time before much progress would be made in understanding the degenerative brain diseases. When the exact structure of the “infectious” protein was later worked out, and the 1997 Nobel Prize awarded (to Stanley Prusiner), I was surprised that no one from Field’s group was included. (In 1976, a nobel prize had been awarded to D.C. Gajdusek, for his promotion of the idea of “slow viruses” in general, and particularly for arguing that scrapie, CJD and kuru were caused by slow viruses.)

In reading Prusiner’s autobiographical statements, I was even more surprised to see that he claimed to have been puzzled to find out, around 1983, that the infectious agent was a protein. I had thought that my professors were lethargic authoritarians when they refused to look at the evidence in 1970-72, but Prusiner’s expression of puzzlement so many years later over the absence of nucleic acid in the infectious agent is hard to account for.

In my own research in 1971, I was interested in another kind of age-related “inclusion body,” which was variously called lipofuscin, age pigment, and ceroid pigment. This brown (yellow autofluorescent) pigment contained proteins and metals, as well as polyunsaturated lipids, and overlapped in many ways with the amyloid bodies. All of these inclusion bodies were known to be associated with radiation injury, aging, and hormonal-nutritional imbalances. Excess of estrogen, polyunsaturated fatty acids, and oxidative metals were major factors in the development of lipofuscin, and estrogen was also known to cause other types of “inclusion bodies” to develop in cells.

Although very little was known about the composition of the inclusion bodies (they were usually thought to be organelles damaged by free radical activity, or antibodies resulting from autoimmunity), their involvement in aging and degenerative disease was clear, and it was widely known that ionizing radiation accelerated their formation. But it was just at this time that the national research priorities of the U.S. were redirected toward genetic explanations for all major diseases, with for example the “war on cancer” centering on the concepts of the “oncogene” and the cancer virus. Since the “slow virus” of cancer, or the viral oncogene, requires activation by something in the environment, its function is to distract the public’s attention from those environmental causes of disease, viz., radiation and chemical pollution.

The U.S. Public Health Service has historically been one of the branches of the military, and currently has 6000 commissioned officers. It has been intimately involved in all aspects of chemical, biological, and nuclear warfare, and it has participated in many covert projects, including experimentation on people without their knowledge. For decades, information on radiation injury to the public was hidden, classified, altered, or destroyed by the PHS. During the radiation disaster at Three Mile Island, they calmly defended the interests of the nuclear industry.

After the April, 1986 catastrophe at the reactor in Chernobyl, some of the food being imported into the U.S. was so highly radioactive that the FDA secretly seized it, to prevent the public from being concerned. The first cow found to have BSE in England was in November, 1986, several months after England’s pastures had been heavily contaminated by rainfall carrying radioactive material from Chernobyl, which soaked into the soil and continued to contaminate crops for years (and will continue, for centuries). The number of sick cows increased rapidly to a peak in 1992. Human deaths from the similar disease (“variant CJD”) began a few years later.

In June, 2000, a wildfire burned across southern Washington, turning the radioactive vegetation on the Hanford Nuclear Site into radioactive smoke, contaminating a wide area, including farms, dairies, and orchards. In 2003, the first cow in the U.S. with BSE was reported, from a dairy a few miles from the Hanford Site.

Beginning in 1946, Bikini Island was used to test atomic bombs. In 1954, they began to test hydrogen bombs in the Pacific; some of the bombs were deliberately designed to vaporize whole islands, so that the effects of radioactive fallout could be studied. In 1954, the first child with kuru was reported in the rainy highlands of New Guinea.

Within two years, hundreds of people in that area (of the Fore tribe) were dying from kuru, with the mortality highest among the women; in some villages, the majority of the women died from the disease, but by 1957 the mortality was falling rapidly. Between 1957 and 1964, 5% of the population of the Fore tribe died of the disease, according to D.C. Gajdusek, who had been sent by the U.S. Army to investigate the disease. Although Gajdusek graduated in 1946 from Harvard medical school as a pediatrician, in his autobiography he said that when he was drafted in 1951, the army assigned him to work in virology. In 1958, Gajdusek became director of the NIH laboratories for neurological and virological research. This was a remarkable achievement for someone who had supposedly only done some scattered field-work in infectious diseases, and whose purpose in going to New Guinea had been to study ''child growth and development in primitive cultures.'' The only published reason I have found that might be a basis for making him head of neurology, was his sending a diseased Fore brain to Fort Detrick in 1957.

Gajdusek claimed to have seen the Fore people eating dead relatives, but his figures show that the disease was already in rapid decline when he arrived. He took photographs which were widely published in the US, supposedly showing cannibalism, but 30 years later, he said the photographs showed people eating pork, and that he had seen no cannibalism. (At the time Gajdusek was observing kuru in New Guinea, the influence of “cannibalism” on brain function was already in the news, because of the discovery by J.V. McConnell that the behavior of “trained” flatworms could be transmitted to other worms by chopping them up and feeding them to the naive worms.)

Harvard medical school, in association with the military program centered at Fort Detrick, Fredericksburg, Maryland, was active in biological warfare in the 1940s, and I think it’s more plausible to see Gajdusek as a trouble-shooter for the biological warfare establishment, than as a biological researcher. One of his biographers has written that the idea of associating kuru with scrapie was suggested to him by a veterinarian, and that Gajdusek had responded by claiming to have experiments in progress to test that theory, four years before the experiments were actually made.

In other words, the slow virus theory for which Gajdusek was given the Nobel Prize is scientific junk, which Gajdusek has repeatedly reinterpreted retrospectively, making it seem to have been anticipatory of the prion theory. Whatever actually caused kuru, I think the army was afraid that it was the result of radioactive fallout from one of its bomb tests, and that Gajdusek’s job was to explain it away.

I suspect that kuru was the result of an unusual combination of malnutrition (the women were vegetarian) and radiation. In the very short time that Gajdusek spent in New Guinea, he claimed to have done studies to eliminate all of the alternative causes, nutritional, toxic, anthropological, bacterial causes, studies that would normally have required several years of well organized work. I don’t think he mentioned the possibility of radiation poisoning.

In 1998 Congress commissioned a study of the health effects of radiation from bomb testing, and although the study examined the effects of only part of the bomb tests, it concluded that they had killed 15,000 Americans. No one has tried to accurately estimate the numbers killed in other countries.

Even very low doses of ionizing radiation create an inflammatory reaction (Vickers, et al., 1991), and there is evidence that the inflammatory state can persist as long as the individual lives; in Japan, the “acute phase” proteins are still elevated in the people who were exposed to radiation from the atomic bombs. The acute phase proteins that are increased by malnutrition and radiation increase the tendency to form amyloid deposits. Strong radiation can even cause, after a delay of more than a year, the development of vacuoles, which are the most obvious feature of the “prion” brain diseases. The persistent inflammatory reaction eventually produces cellular changes, but these were originally overlooked because of the theory that radiation is harmful only when it produces immediate changes in the DNA.

Radiation damage to the brain is most visible early in life, and in old age. In 1955, Alice Stewart showed that prenatal x-rays increase the incidence of brain cancer, leukemia, and other cancers. In 1967, a study in Japanese bomb survivors found that prenatal exposure to radiation had reduced their head size and brain size. In 1979, Sternglass and Bell showed extremely close correspondence between scores on the SAT and prenatal exposure to radiation.

Serum amyloid A, which can increase 1000-fold under the influence of proinflammatory cytokines, resulting from irradiation, stress, trauma, or infection, is an activator of phospholipase A2 (PLA2), which releases fatty acids. Some of the neurodegenerative states, including amyloid-prion diseases, involve activated PLA2, as well as increases in the toxic breakdown products of the polyunsaturated fatty acids, such as 4-hydroxynonenal. The quantity of PUFA in the tissues strongly determines the susceptibility of the tissue to injury by radiation and other stresses. But a diet rich in PUFA will produce brain damage even without exceptional stressors, when there aren’t enough antioxidants, such as vitamin E and selenium, in the diet.

Amyloidosis has traditionally been thought of as a condition involving deposits mainly in blood vessels, kidneys, joints and skin and in extracellular spaces in the brain, and the fact that the “amyloid” stained in a certain way led to the idea that it was a single protein. But as more proteins--currently about 20--were identified in amyloid deposits, it was gradually realized that the deposits can be identified inside cells of many different tissues, before the larger, very visible, extracellular deposits are formed.

There is evidence of a steady increase in the death rate from amyloidosis. It kills women at a younger age than men, often at the age of 50 or 60.

Serum amyloid P is called “the female protein” in hamsters, because of its association with estrogen; castrated (or estrogen treated) males also produce large amounts of it, and its excess is associated with the deposition of amyloid (Coe and Ross, 1985). It can bind other amyloid proteins together, accelerating the formation of fibrils, but this function is probably just a variation of a normal function in immunity, tissue repair, and development.

Estrogen increases the inflammation-associated substances such as IL-6, C-reactive protein, and amyloid, and liberates fatty acids, especially the unstable polyunsaturated fatty acids. It also increases fibrinogen and decreases albumin, increasing the leakiness of capillaries. The decrease of albumin increases the concentration of free fatty acids and tryptophan, which would normally be bound to albumin.

In the U.S. and Europe, livestock are fed large amounts of high-protein feeds, and currently these typically contain fish meal and soybeans. The estrogenic materials in soybeans increase the animals’ tendency toward inflammation (with increased serum amyloid).

Officially, BSE appeared because cows were fed slaughter-house waste containing tissues of sheep that had died of scrapie. Scrapie was a nerve disease of sheep, first reported in Iceland in the 18th century. When I was studying the digestive system and nutrition of horses, I learned that it was common for horses in Norway to be fed dried fish during the winter. This abundant food was probably used for sheep, as well as for horses. The extra protein provided by fish meal is still important for sheep in areas where pastures are limited, but it has now become common to use it to increase productivity and growth throughout the lamb, beef, and dairy industries, as well as in most lab chows fed to experimental animals, such as the hamsters used for testing the infectivity of the diseased tissues.

Increased dietary polyunsaturated fatty acids (PUFA) suppress the activity of the ruminal bacteria which are responsible for the hydrogenation-detoxication of PUFA in the animal’s diet. This allows the unstable fats, 98% of which are normally destroyed, to pass into the animals’ tissues and milk.

The polyunsaturated fats in fish are very unstable, and when they get past the bacterial saturases (biohydrogenases) in the rumen that normally protect ruminants from lipid peroxidation, they are likely to cause their toxic effects more quickly than in humans, whose antioxidant systems are highly developed. The toxic effects of polyunsaturated fats involve altered (immunogenic) protein structure, decreased energy metabolism, and many inflammatory effects produced by the prostaglandin-like substances. Marine fish are now so generally polluted with dioxin, that in Japan there is a clear association between the amount of fish in a person’s diet (their body content of EPA and DHA) and the amount of dioxin in their body.

Radiation and many kinds of poisoning cause early peroxidation of those highly unsaturated fats, and the breakdown products accelerate the changes in the folding and chelating behavior of proteins. The accumulation of altered proteins is associated with the degenerative diseases. The role of toxic metals in brain inflammation is well established (e.g., aluminum, lead, mercury: Campbell, et al., 2004; Dave, et al., 1994; Ronnback and Hansson, 1992).

The “prion hypothesis” has the value of weakening the fanaticism of the DNA-genetics doctrine, but it has some problems. There are now several examples in which other degenerative diseases have been transmitted by procedures similar to those used to test the scrapie agent. (e.g., Goudsmit, et al., 1980; Xing, et al., 2001; Cui, et al., 2002.) Experimental controls haven’t been adequate to distinguish between the pure prion and its associated impurities. Gajdusek burned a sample of the infective hamster brain to ash, and found that it still retained “infectivity.” He argued that there was a mineral template that transmitted the toxic conformation to normal proteins. Others have demonstrated that the active structure of the infective agent is maintained by a carbohydrate scaffolding, or that the infectivity is destroyed by the frequency of ultraviolet light that destroys the active lipid of bacterial endotoxin, lipopolysaccharide.

But simply injuring the brain or other organ (by injecting anything) will sometimes activate a series of reactions similar to those seen in aging and the amyloidoses. When a slight trauma leads to a prolonged or expanding disturbance of structure and function, the process isn’t essentially different from transmitting a condition to another individual. The problem is being “transmitted” from the initial injury, recruiting new cells, and passing the disturbed state on to daughter cells in a disturbed form of regeneration. Keloids, hypertrophic scars, are analogous to the dementias in their overgrowth of connective tissue cells: In the aging or injured brain, the glial cells (mainly astrocytes) proliferate, in reparative processes that sometimes become exaggerated and harmful.

When tissue phospholipids contain large amounts of polyunsaturated fatty acids, large amounts of prostaglandins are immediately formed by any injury, including low doses of ionizing radiation. The liberated free fatty acids have many other effects, including the formation of highly reactive aldehydes, which modify DNA, proteins, and other cell components.

Animals which are “deficient” in the polyunsaturated fatty acids have a great resistance to a variety of inflammatory challenges. Their tissues appear to be poor allergens or antigens, since they can be easily grafted onto other animals without rejection. Something related to this can probably be seen in the data of human liver transplants. Women’s livers are subjected to more lipid peroxidation than men’s, because of the effects of estrogen (increasing growth hormone and free fatty acids, and selectively mobilizing the polyunsaturated fatty acids and increasing their oxidation). Liver transplants from middle-aged female donors fail much more often (40 to 45%) than livers from male donors (22 to 25%), and other organs show the same effect. The autoimmune diseases are several times as common in women as in men, suggesting that some tissues become relatively incompatible with their own body, after prolonged exposure to the unstable fatty acids. If we consider the healthy function of the immune system to be the removal or correction of injured tissue, it’s reasonable to view the random interactions of oxidized fats with proteins as exactly the sort of thing our immune system takes care of.

The serum amyloids A and P and the closely related lipoproteins are considered to be important parts of our “innate immunity,” operating in a more general way than the familiar system of specific acquired immunities.

The amyloids and lipoproteins are powerfully responsive to bacterial endotoxin, LPS, and their structural feature that binds it, the “pleated sheet” structure, appears to also be what allows the amyloids to form amorphous deposits and fibrils under some circumstances. Our innate immune system is perfectly competent for handling our normal stress-induced exposures to bacterial endotoxin, but as we accumulate the unstable fats, each exposure to endotoxin creates additional inflammatory stress by liberating stored fats. The brain has a very high concentration of complex fats, and is highly susceptible to the effects of lipid peroxidative stress, which become progressively worse as the unstable fats accumulate during aging.

More than 60 years ago, a vitamin E deficiency was known to cause a brain disease, sometimes associated with sterility and muscular dystrophy. The symptoms of the brain disease were similar to those of “mad cow disease,” and the condition is now usually called “crazy chick disease.” Veterinarians are usually taught that it is caused by a selenium deficiency, but it is actually the result of an excess of PUFA in the diet, and is exacerbated by increased iron or other oxidants, and prevented by increased vitamin E, selenium, or substitution of saturated fats for the unsaturated.

Terminology, established by tradition and thoughtless memorization, obscures many of the commonalities in the various brain diseases. Brain inflammation (Betmouni and Perry, 1999; Perry, et al., 1998), myelination disorders, edema, overgrowth of the astroglia, and circulatory changes are common occurrences in most of the degenerative encephalopathies, but traditional textbook descriptions have created the impression that each disease is pathologically very distinct from the others. The current classification of “the prion diseases” is reifying a group of symptoms that aren’t specific to any specific known cause. And standard laboratory procedures for preparing brain sections for microscopic examination may cause brain cells to shrink to 5% of their original volume (Hillman and Jarman, Atlas of the cellular structure of the human nervous system, 1991), so the objectivity of pathological studies shouldn’t be over-estimated.

According to a 1989 study (Laura Manuelidis, neuropathology department at Yale), 13% of the people who had died from “Alzheimer’s disease” actually had CJD. Between 1979 and 2000, the number of people dying annually from Alzheimer’s disease increased 50-fold. Very competent neuropathologists differ radically in their descriptions of the dementia epidemic.

By some tests, the “prion” resembles the LPS endotoxin. One of the interesting developments of the prion theory is that a particular structure that appears when the prion becomes toxic, the “beta pleated sheet,” is also a feature of most of the normal proteins that can form amyloid, and that this structure is directly related to binding and eliminating the bacterial LPS. If the prion theory is correct about the conversion of a normal protein into the pleated sheet, it isn’t necessarily correct about the incurability of the condition. The innate immune system should be able to inactivate the prion just as it does the bacterial endotoxin, if we remove the conditions that cause the innate immune reaction to amplify the inflammation beyond control.

In the prion diseases, the severely damaged brain appears to have a “pathological overactivity” of the serotonergic systems (Fraser, et al., 2003). This is an interesting parallel to Alzheimer’s disease, since it has been known for several years that the blood platelets have an increased tendency to release serotonin in that more common form of dementia. Serotonin itself is toxic to nerves, and is part of the adaptive system that gets out of control during prolonged inflammation. Serotonin is an important activator of the phospholipases.

The modification of proteins’ structure by glycosylation is involved in the development of the toxic form of the “prionic” protein, as well as in all the degenerative processes of aging. Until the ability to use sugar is impaired, cells produce enough carbon dioxide to protect proteins against random glycation, but with each exposure to free polyunsaturated fatty acids, the ability to use glucose is damaged. In the dementias, the brain has a greatly reduced ability to use glucose.

One of estrogen’s central effects is to shift metabolism away from the oxidation of glucose, decreasing carbon dioxide production. There is a much higher incidence of Alzheimer’s disease in women, and estrogen exposure exacerbates all of the changes that lead to it, such as shifts in nerve transmitters, increased vascular leakiness, and the increased production of the acute phase proteins.

Everything that is known about the “always fatal” prionic diseases, the diseases of disturbed protein folding, suggests that they can be avoided and even reversed by systematically reversing the processes that amplify inflammation.

People who take aspirin, drink coffee, and use tobacco, have a much lower incidence of Alzheimer’s disease than people who don’t use those things. Caffeine inhibits brain phospholipase, making it neuroprotective in a wide spectrum of conditions. In recent tests, aspirin has been found to prevent the misfolding of the prion protein, and even to reverse the misfolded beta sheet conformation, restoring it to the harmless normal conformation. Nicotine might have a similar effect, preventing deposition of amyloid fibrils and disrupting those already formed (Ono, et al., 2002). Vitamin E, aspirin, progesterone, and nicotine also inhibit phospholipase, which contributes to their antiinflammatory action. Each of the amyloid-forming proteins probably has molecules that interfere with its toxic accumulation.

Thyroid hormone, vitamins A and E, niacinamide (to inhibit systemic lipolysis), magnesium, calcium, progesterone, sugar, saturated fats, and gelatin all contribute in basic ways to prevention of the inflammatory states that eventually lead to the amyloid diseases. The scarcity of degenerative brain disease in high altitude populations is consistent with a protective role for carbon dioxide.

The relatively sudden acceptability of the idea of non-genetic transmission doesn't mean that Lamarck has been rehabilitated by the scientific establishment; it could just be that it's the most politically acceptable way to explain the outbreaks of deadly disease caused by the industrialization of foods and the exposure of the population to dangerous levels of radiation.

 

REFERENCES

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Ann Rheum Dis. 2001 Jul;60(7):694-5. Concomitant diagnosis of primary Sjogren's syndrome and systemic AL amyloidosis. Delevaux I, Andre M, Amoura Z, Kemeny JL, Piette JC, Aumaitre O.

Mol Biol Rep. 1996;23(3-4):253-60. The interaction of C-reactive protein and serum amyloid P component with nuclear antigens. Du Clos TW. “The pentraxins are a family of proteins characterized by cyclic pentameric structure, calcium-dependent ligand binding and sequence homology. The two main representatives of this family are the serum proteins, C-reactive protein (CRP) and serum amyloid P component (SAP). In man CRP is an acute phase reactant which increases up to 1,000 fold during the acute phaseresponse whereas SAP is a constitutive protein expressed at about 30 micrograms/ml. These proteins activate complement through the classical pathway and participate in opsonization of particulate antigensand bacteria. In the past several years it has been determined that both of these pentraxins interact with nuclear antigens including chromatin and small nuclear ribonucleoproteins (snRNPs). Both CRP and SAP have nuclear transport signals which facilitate their entry into the nuclei of intact cells. Furthermore, these pentraxins have been shown to affect the clearance of nuclear antigens in vivo.”

Am J Pathol. 1996 Oct;149(4):1313-20. Lipoproteins accumulate in immune deposits and are modified by lipid peroxidation in passive Heymann nephritis. Exner M, Susani M, Witztum JL, Hovorka A, Curtiss LK, Spitzauer S, Kerjaschki D.

J Med Genet. 1976 Dec;13(6):479-95. Scrapie: a review of its relation to human disease and ageing. Field EJ.

Age Ageing. 1978 Feb;7(1):28-39. Immunological assessment of ageing: emergence of scrapie-like antigens. Field EJ.

Acta Neurol Scand. 1975 Apr;51(4):299-309. Cellular sensitization in kuru, Jakob-Creutzfeldt disease and multiple sclerosis: with a note on the biohazards of slow infection work. Field EJ, Shenton BK.

Brain. 1973 Sep;96(3):629-36. Altered response to scrapie tissues in neurological disease. Possible evidence for an antigen associated with reactive astrocytes. Field EJ, Shenton BK.

Nature. 1973 Jul 20;244(5412):174-6. Scrapie-like antigen(s) in ageing tissues. Field EJ, Shenton BK.

Nature. 1973 Jul 13;244(5411):96-7. Rapid immunological method for diagnosis of natural scrapie in sheep. Field EJ, Shenton BK.

Gerontologia. 1973;19(4):203-10. Thymectomy and immunological ageing in mice: precocious emergence of scrapie-like antigen. Field EJ, Shenton BK.

Gerontologia. 1973;19(4):211-9. Emergence of new antigens in ageing tissues. Field EJ, Shenton BK.

Nature. 1972 Nov 10;240(5376):104-6. Rapid diagnosis of scrapie in the mouse. Field EJ, Shenton BK.

J Neurol Sci. 1972 Nov;17(3):347-64. An electron-microscopic study of scrapie in the rat: further observations on "inclusion bodies" and virus-like particles. Field EJ, Narang HK.

Lancet. 1970 Oct 10;2(7676):780-1. Amyloidosis, Alzheimer's disease, and ageing. Field EJ.

Nature. 1970 Jun 6;226(249):971-3. Evidence against transmission of scrapie by animal house fomites. Field EJ, Joyce G.

Arch Gesamte Virusforsch. 1970;30(2):224-37. The incorporation of (3H) thymidine and (14C) glucosamine into a DNA-polysaccharide complex in normal and scrapie-affected mouse brain. Adams DH, Caspary EA, Field EJ.

Biochem J. 1969 Sep;114(2):19P-20P. Structural changes in scrapie affected brain. Field EJ, Peat A.

J Gen Virol. 1969 Jul;5(1):149-50. Failure of interferon to modify scrapie in the mouse. Field EJ, Joyce G, Keith A.

Nature. 1969 Apr 5;221(188):90-1. Susceptibility of scrapie agent to ionizing radiation. Field EJ, Farmer F, Caspary EA, Joyce G.

Nature. 1969 Mar 29;221(187):1265-6. Neurological illness after inoculation of tissue from tumour bearing animals. Field EJ, Adams DH, Joyce G.

Lancet. 1968 May 4;1(7549):981-2. Transmission of kuru to mice. Field EJ.

Br J Exp Pathol. 1967 Dec;48(6):662-4. Invasion of the mouse nervous system by scrapie agent. Field EJ.

Acta Neuropathol (Berl). 1967 Nov 29;9(4):305-15. Scrapie in the rat: an electron-microscopic study. II. Glial inclusions. Field EJ, Raine CS, Joyce G.

J Neurosci. 2001 Jan 1;21(1):136-42. Vaccination for neuroprotection in the mouse optic nerve: implications for optic Neuropathies. Fisher J, Levkovitch-Verbin H, Schori H, Yoles E, Butovsky O, Kaye JF, Ben-Nun A, Schwartz M. “T-cell autoimmunity to myelin basic protein was recently shown to be neuroprotective in injured rat optic nerves.” “The results of this study show that survival of RGCs after axonal injury can be enhanced by vaccination with an appropriate self-antigen. Furthermore, the use of nonencephalitogenic myelin peptides for immunization apparently allows neuroprotection without incurring the risk of an autoimmune disease.”

Neuropathol Appl Neurobiol. 2003 Oct;29(5):482-95. Neuronal and astrocytic responses involving the serotonergic system in human spongiform encephalopathies. Fraser E, McDonagh AM, Head M, Bishop M, Ironside JW, Mann DM.

J Neural Transm. 2001;108(2):221-30. Difference in toxicity of beta-amyloid peptide with aging in relation to nerve growth factor content in rat brain. Fukuta T, Nitta A, Itoh A, Furukawa S, Nabeshima T. “NGF levels in the hippocampus were increased only in adult rats. These results suggest that Abeta is toxic only in the matured adult brain, and that the mechanism of toxicity is related to NGF synthesis.”

Science 197: 943-960(1977). Unconventional viruses and the origin and disappearance of kuru. Gajdusek, D.C.

Trends Mol Med. 2001 Aug;7(8):336. Beneficial autoimmunity in traumatic brain injury. Gurwitz D.

BMJ 2004; 328 :19, Effect of low doses of ionising radiation in infancy on cognitive function in adulthood: Swedish population based cohort study. Hall P, Adami HO, Trichopoulos D et al.

Arch Pathol. 1966 Oct; 82(4): 353-5. A lipofuscin-like pigment in the kidneys of estrogen-treated rats. Harris C.

Int J Radiat Biol. 2003 Feb; 79(2): 129-36. Radiation dose-dependent increases in inflammatory response markers in A-bomb Survivors. Hayashi T, Kusunoki Y, Hakoda M, Morishita Y, Kubo Y, Maki M, Kasagi F, Kodama K, Macphee DG, Kyoizumi S. “The well-documented increases in malignant tumours in the A-bomb survivors have recently been supplemented by reports that non-cancer diseases, including cardiovascular disease, may also have increased in incidence with increasing radiation dose. Given that low-level inflammatory responses are widely accepted as a significant risk factor for such diseases, we undertook a detailed investigation of the long-term effects of ionizing radiation on the levels of the inflammatory markers C-reactive protein (CRP) and interleukin 6 (IL-6) in A-bomb survivors.” “Blood samples were taken from 453 participants in a long-term epidemiological cohort of A-bomb survivors.” “CRP levels were significantly increased by about 31% Gy(-1) of estimated A-bomb radiation (p=0.0001). Higher CRP levels also correlated with age, male gender, body mass index and a history of myocardial infarction. After adjustments for these factors, CRP levels still appeared to have increased significantly with increasing radiation dose (about 28% increase at 1Gy, p=0.0002). IL-6 levels also appeared to have increased with radiation dose by 9.3% at 1Gy (p=0.0003) and after multiple adjustments by 9.8% at 1Gy (p=0.0007).” “Our results appear to indicate that exposure to A-bomb radiation has caused significant increases in inflammatory activity that are still demonstrable in the blood of A-bomb survivors and which may lead to increased risks of cardiovascular disease and other non-cancer diseases.

Immunol Rev. 2000 Oct;177:52-67. Chemokines and chemokine receptors in inflammation of the nervous system: manifold roles and exquisite regulation. Huang D, Han Y, Rani MR, Glabinski A, Trebst C, Sorensen T, Tani M, Wang J, Chien P, O'Bryan S, Bielecki B, Zhou ZL, Majumder S, Ransohoff RM.

Am J Med Genet. 1989 Dec;34(4):562-8. Mortality rate of amyloidosis in Japan: secular trends and geographical Variations. Imaizumi Y. “The death rate in Japan from amyloidosis was analyzed using Japanese Vital Statistics for 1969-1985. The amyloidosis death rate has increased gradually year by year for both sexes.” “The mean age at death from amyloidosis gradually increased year by year for both sexes, although the age was 11-23 years shorter for males and 20-25 years shorter for females than that of the general population.”

Stroke. 1991 Nov;22(11):1448-51. Platelet secretory products may contribute to neuronal injury. Joseph R, Tsering C, Grunfeld S, Welch KM.

J Neurochem. 1997 Jul; 69(1): 266-72. Aggregation of beta-amyloid peptide is promoted by membrane phospholipid metabolites elevated in Alzheimer's disease brain. Klunk WE, Xu CJ, McClure RJ, Panchalingam K, Stanley JA, Pettegrew JW. “A beta peptides have been shown to be toxic to neurons in cell culture, and this toxicity is critically dependent on the aggregation of the peptide into cross-beta-pleated sheet fibrils. Also, in vivo and postmortem NMR studies have shown changes in certain brain membrane phospholipid metabolites in normal aging and more extensive alterations in patients with Alzheimer's disease. The finding that membrane phospholipids affect the aggregation of A beta suggests that the abnormalities in membrane metabolism found in Alzheimer's disease could affect the deposition of A beta in vivo.” “Certain metabolites (glycerophosphocholine, glycerophosphoethanolamine, and alpha-glycerophosphate) augment the aggregation of A beta. Other membrane phospholipid metabolites (phosphocholine, phosphoethanolamine, and inositol-1-phosphate) have no effect.We conclude that increased membrane phospholipid metabolite concentrations may play a role in the deposition of A beta seen in normal aging and the even greater deposition of A beta observed in Alzheimer's disease.”

J Pharm Sci. 1971 Feb; 60(2): 167-80. Experimental modification of the chemistry and biology of the aging process. Kormendy CG, Bender AD.

Radiobiologiia. 1990 May-Jun;30(3):317-20. [Cholesterol and fatty acids of the nuclei and chromatin of the rat thymus at long intervals following gamma irradiation] Kulagina TP. “The FFA content in the homogenate, nuclei and chromatin of rat thymus drastically increased 60 min after the last exposure. In a month, the FFA content of nuclei and chromatin dropped to control levels, whereas that of the homogenate remained high throughout the entire period of observation and sharply increased by the third month.”

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Hepatology. 1995 Dec;22(6):1754-62. Effect of donor age and sex on the outcome of liver transplantation. Marino IR, Doyle HR, Aldrighetti L, Doria C, McMichael J, Gayowski T, Fung JJ, Tzakis AG, Starzl TE.

Brain Res. 673(1), 149-152, 1995. "Glucose deprivation increases aspartic acid release from synaptosomes of aged mice,"M. Martinez, et al., "...in the absence of glucose in the medium of incubation aspartate and glutamate release was higher in old than in young animals." "...there is an age-dependent dysfunction in this process linked to energy metabolism disturbance."

Neurobiol Aging. 1995 Nov-Dec; 16(6): 977-81. Estrogen induction of glial heat shock proteins: implications for hypothalamic Aging. Mydlarski MB, Liberman A, Schipper HM. “In the aging mammalian hypothalamus, a unique subpopulation of glial cells accumulates peroxidase-positive cytoplasmic inclusions distinct from lipofuscin. In adult rodents, this senescence-dependent glial granulation is accelerated by administration of estradiol valerate.” “Our findings indicate that estrogen elicits a heat shock response and subsequent granulation in astrocytes residing in estradiol receptor-rich brain regions including the arcuate nucleus and the wall surrounding the third ventricle but not in estradiol receptor-deficient regions such as the striatum and corpus callosum. The heat shock proteins induced by estrogen, namely, the 27, 72, and 90 kDa stress proteins, are upregulated in astrocytes in response to oxidative challenge supporting our hypothesis that estrogen mediates senescent changes in the rodent hypothalamus through oxidative mechanisms.”

Proc. Natl. Acad. Sci. USA, vol. 44, pp. 712-717 (1958): "Epigenetic Control Systems". D. L. Nanney.

Journal of the Neurological Sciences 1995;134:61-6. Mortality from motor neuron disease in Japan, 1950-1990: association with radioactive fallout from atmospheric weapons testing. Neilson S, Robinson I, Rose FC.

Biol Psychiatry. 2002 Nov 1;52(9):880-6. Nicotine breaks down preformed Alzheimer's beta-amyloid fibrils in vitro. Ono K, Hasegawa K, Yamada M, Naiki H. “The antiamyloidogenic effect of nicotine may be exerted not only by the inhibition of fAbeta formation but also by the disruption of preformed fAbeta.”

Res Immunol. 1998 Sep-Oct; 149(7-8): 721-5. The contribution of inflammation to acute and chronic neurodegeneration. Perry VH, Bolton SJ, Anthony DC, Betmouni S.

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Proc Natl Acad Sci U S A. 2003 Feb 18;100(4):1580-5. Epub 2003 Feb 03. Short-term administration of omega 3 fatty acids from fish oil results in increased transthyretin transcription in old rat hippocampus. Puskas LG, Kitajka K, Nyakas C, Barcelo-Coblijn G, Farkas T.

Arch Biochem Biophys. 2002 Apr 1;400(1):43-7. Inhibition of transthyretin amyloid fibril formation by 2,4-dinitrophenol through tetramer stabilization. Raghu P, Reddy GB, Sivakumar B.

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Radiat Res. 1967 Mar; 30(3): 640-53. Radiation studies on mice of an inbred tumor-resistant strain. The alteration of endogenous susceptibility to amyloidosis by x-irradiation. Rosenblum WI, Goldfeder A, Ghosh AK.

Neurotoxicology 15(3), 493-502, 1994."Phosphoinositide second messengers in cholinergic excitotoxicity," K. Savolainen, et al. "Acetylcholine is a powerful excitotoxic neurotransmitter in the brain. By stimulating calcium-mobilizing receptors, acetylcholine, through G-proteins, stimulates phospholipase C and cause the hydrolysis of a membrane phospholipid...."Female sex and senescence increase the sensitivity of rats to cholinergic excitotoxicity."

Int J Radiat Oncol Biol Phys. 1995 Jan 1;31(1):57-64. Radiation-induced changes in the profile of spinal cord serotonin, prostaglandin synthesis, and vascular permeability. Siegal T, Pfeffer MR. “Serotonin levels were unchanged at 2, 14,and 56 days after radiation but increased at 120 and 240 days in the irradiated cord segments when compared to both the nonirradiated thoracic and cervical segments (p < 0.01) and age-matched controls (p < 0.03).“In the first 24 h after radiation, a 104% increase in microvessel permeability was observed which returned to normal by 3 days. Normal permeability was maintained at 14 and 28 days, but at 120 and 240 days a persistent and significant increase of 98% and 73% respectively above control level was noted.”

Annual Meeting of the American Psychological Association, New York, New York, September 3, 1979, "Fallout and the Decline of Scholastic Aptitude Scores," Ernest Sternglass and Stephen Bell.

Acta Neuropathol (Berl). 1995; 90(2): 135-41. Cerebral beta amyloid deposition in patients with malignant neoplasms: its prevalence with aging and effects of radiation therapy on vascular amyloid. Sugihara S, Ogawa A, Nakazato Y, Yamaguchi H. “The prevalence of cerebral A beta deposits was about two times higher in the patients who had received brain radiation therapy (27.8%) compared to non-radiated patients (14.8%). Amyloid angiopathy was much more prominent (P < 0.05) with radiation therapy (22.2%) than without (8.0%).”

Diabetes. 2003 Dec;52(12):2882-7. Elevation of free fatty acids induces inflammation and impairs vascular reactivity in healthy subjects. Tripathy D, Mohanty P, Dhindsa S, Syed T, Ghanim H, Aljada A, Dandona P.

Arterioscler Thromb Vasc Biol. 2003 Dec 29. Effect of Lower Dosage of Oral Conjugated Equine Estrogen on Inflammatory Markers and Endothelial Function in Healthy Postmenopausal Women. Wakatsuki A, Ikenoue N, Shinohara K, Watanabe K, Fukaya T. {Oral estrogen) “... increases plasma C-reactive protein (CRP) and interleukin-6 (IL-6) concentration. The proinflammatory effect of oral ERT may explain the increased risk of coronary heart disease (CHD) associated with this treatment.”

Am J Pathol. 1997 Jun; 150(6): 2181-95. Free fatty acids stimulate the polymerization of tau and amyloid beta peptides.In vitro evidence for a common effector of pathogenesis in Alzheimer's disease. Wilson DM, Binder LI. “We have discovered that free fatty acids (FFAs) stimulate the assembly of both amyloid and tau filaments in vitro.” “Utilizing fluorescence spectroscopy, unsaturated FFAs were also demonstrated to induce beta-amyloid assembly.” [These results] “...suggest that cortical elevations of FFAs may constitute a unifying stimulatory event driving the formation of two of the obvious pathogenetic lesions in Alzheimer's disease.”

Lab Invest. 2001 Apr; 81(4): 493-9. Transmission of mouse senile amyloidosis. Xing Y, Nakamura A, Chiba T, Kogishi K, Matsushita T, Li F, Guo Z, Hosokawa M, Mori M, Higuchi K. “In mouse senile amyloidosis, apolipoprotein A-II polymerizes into amyloid fibrils (AApoAII) and deposits systemically. Peripheral injection of AApoAII fibrils into young mice induces systemic amyloidosis....” “We isolated AApoAII amyloid fibrils from the livers of old R1.P1-Apoa2(c) mice and injected them with feeding needles into the stomachs of young R1.P1-Apoa2(c) mice for 5 consecutive days. After 2 months, all mice had AApoAII deposits in the lamina propria of the small intestine. Amyloid deposition extended to the tongue, stomach, heart, and liver at 3 and 4 months after feeding. AApoAII suspended in drinking water also induced amyloidosis.” “Amyloid deposition was induced in young mice reared in the same cage for 3 months with old mice who had severe amyloidosis. Detection of AApoAII in feces of old mice and induction of amyloidosis by the injection of an amyloid fraction of feces suggested the propagation of amyloidosis by eating feces. Here, we substantiate the transmissibility of AApoAII amyloidosis and present a possible pathogenesis of amyloidosis, ie, oral transmission of amyloid fibril conformation, where we assert that exogenous amyloid fibrils act as templates and change the conformation of endogenous amyloid protein to polymerize into amyloid fibrils.”


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