Chemical Pathology of Homocysteine VIII. Effects of Tocotrienol, Geranylgeraniol, and Squalene on Thioretinaco Ozonide, Mitochondrial Permeability, and Oxidative Phosphorylation in Arteriosclerosis, Cancer, Neurodegeneration and Aging.

A century ago a fat-soluble vitamin from leafy vegetables, later named vitamin E, was discovered to enhance fertility in animals. Vitamin E consists of 8 isomers of tocopherols and tocotrienols, each containing chromanol groups that confer antioxidant properties and differ only in the 15-carbon saturated phytyl poly-isoprenoid side chain of tocopherols and the 15-carbon unsaturated farnesyl poly-isoprenoid side chain of tocotrienols. Although tocotrienol was first isolated from rubber plants in 1964, its importance in multiple disease processes was not recognized until two decades later, when the cholesterol-lowering and anti-cancer effects were first reported. Tocotrienol (T3) protects against radiation injury and mitochondrial dysfunction by preventing opening of the mitochondrial permeability transition pore, thereby inhibiting loss of the active site for oxidative phosphorylation, thioretinaco ozonide oxygen ATP, from mitochondria by complex formation with the active site, TR2CoO3O2NAD+H2PO4 -T3. The preventive effects of tocotrienol on vascular disease, cancer, neurodegeneration and aging are attributed to its effects on cellular apoptosis and senescence. Geranylgeraniol is an important intermediate in the biosynthesis of cholesterol, and cholesterol auxotrophy of lymphoma cell lines and primary tumors is attributed to loss of squalene monooxygenase and accumulation of intracellular squalene. Geranylgeraniol and tocotrienol have synergistic inhibitory effects on growth and HMG CoA reductase activity, accompanied by reduction of membrane KRAS protein of cultured human prostate carcinoma cells. Since cholesterol inhibits opening of the mPTP pore of mitochondria, inhibition of cholesterol biosynthesis by these effects of tocotrienol and geranylgeraniol produces increased mitochondrial dysfunction and apoptosis from loss of the active site of oxidative phosphorylation from mitochondria.

Environmental Pollution, Oxidative Stress and Thioretinaco Ozonide: Effects of Glyphosate, Fluoride and Electromagnetic Fields on Mitochondrial Dysfunction in Carcinogenesis, Atherogenesis and Aging.

Environmental pollutants, such as pesticides, herbicides, additives to food and water, and electromagnetic fields threaten public health by promotion of cancer, heart disease and chronic diseases of aging. Many of these pollutants cause adverse health outcomes by effects on mitochondrial function to produce oxidative stress through loss of the active site complex for oxidative phosphorylation, thioretinaco ozonide oxygen nicotinamide adenine dinucleotide phosphate, from opening of the mitochondrial permeability transition pore. Glyphosate, fluoride, and electromagnetic fields are examples of carcinogenic pollutants that promote loss and decomposition of the active site for oxidative phosphorylation, producing mitochondrial dysfunction and oxidative stress. Ionizing radiation has long been known to be carcinogenic, and non-ionizing electromagnetic fields from microwaves, radar, cell phones and cathode ray screens are carcinogenic and produce deleterious effects on capillaries, nerve cells, blood brain barrier, embryonic and germ cells, lenses and cardiac function. Adverse health effects of electromagnetic fields include cataracts, infertility, congenital malformations, cancer, lymphocytosis, leukemia, hearing loss, blindness, retinal hemorrhages, cardiac arrhythmias, dermatitis, hair loss, depression, memory loss, premature aging, heart attacks, and weaponized mind control. The hyperhomocysteinemia, suppressed immunity, and altered oxidative metabolism observed in atherosclerosis and dementia are attributed to deficiency of adenosyl methionine which results from increased polyamine biosynthesis by pathogenic microbes that are demonstrated in atherosclerotic plaques and cerebral plaques. Thus, environmental pollutants potentially promote diseases of aging, atherosclerosis, cancer, and premature aging by production of mitochondrial dysfunction.

The new European guidelines for prevention of cardiovascular disease are misleading.

Introduction: The European Society of Cardiology and European Atherosclerosis Society (ESC/EAS) have recently published three major revisions of their guidelines for the management of chronic heart disease, blood lipids, and diabetes. Areas covered: We have scrutinized these guidelines in detail and found that the authors have ignored many studies that are in conflict with their conclusions and recommendations. Expert commentary: The authors of the guidelines have ignored that LDL-cholesterol (LDL-C) of patients with acute myocardial infarction is lower than normal; that high cholesterol is not a risk factor for diabetics; that the degree of coronary artery calcification is not associated with LDL-C; and that 27 follow-up studies have shown that people with high total cholesterol or LDL-C live just as long or longer than people with low cholesterol. They have also ignored the lack of exposure-response in the statin trials; that several of these trials have been unable to lower CVD or total mortality; that no statin trial has succeeded with lowering mortality in women, elderly people, or diabetics; and that cholesterol-lowering with statins has been associated with many serious side effects.

Chemical Pathology of Homocysteine VII. Cholesterol, Thioretinaco Ozonide, Mitochondrial Dysfunction, and Prevention of Mortality.

The purpose of this review is to elucidate how low blood cholesterol promotes mitochondrial dysfunction and mortality by the loss of thioretinaco ozonide from opening of the mitochondrial permeability transition pore (mPTP). Mortality from infections and cancer are both inversely associated with blood cholesterol, as determined by multiple cohort studies from 10 to 30 years earlier. Moreover, low-density lipoprotein (LDL) is inversely related to all-cause and/or cardiovascular mortality, as determined by followup study of elderly cohorts. LDL adheres to and inactivates most microorganisms and their toxins, causing aggregation of LDL and homocysteinylated autoantibodies which obstruct vasa vasorum and produce intimal microabscesses, the vulnerable atherosclerotic plaques. The active site of mitochondrial oxidative phosphorylation and adenosine triphosphate (ATP) biosynthesis is proposed to consist of thioretinaco, a complex of two molecules of thioretinamide with cobalamin, oxidized to the disulfonium thioretinaco ozonide and complexed with oxygen, nicotinamide adenine dinucleotide (NAD+), phosphate, and ATP. Loss of the active site complex from mitochondria results from the opening of the mPTP and from decomposition of the disulfonium active site by electrophilic carcinogens, oncogenic viruses, microbes, and by reactive oxygen radicals from ionizing and non-ionizing radiation. Suppression of innate immunity is caused by the depletion of adenosyl methionine because of increased polyamine biosynthesis, resulting in inhibition of nitric oxide and peroxynitrite biosynthesis. Opening of the mPTP produces a loss of thioretinaco ozonide from mitochondria. This loss impairs ATP biosynthesis and causes the mitochondrial dysfunction observed in carcinogenesis, atherosclerosis, aging and dementia. Cholesterol inhibits the opening of the mPTP by preventing integration of the pro-apoptotic Bcl-2-associated X protein (BAX) in the outer mitochondrial membrane. This inhibition explains how elevated LDL reduces mitochondrial dysfunction by preventing loss of the active site of oxidative phosphorylation from mitochondria.

Homocysteine, Thioretinaco Ozonide, and Oxidative Phosphorylation in Cancer and Aging: A Proposed Clinical Trial Protocol.

The objective of the proposed clinical interventional trial is to demonstrate the efficacy of a novel therapeutic strategy in subjects with cancer and hyperhomocysteinemia. Following discovery of abnormal homocysteine thiolactone metabolism in cultured malignant cells, thioretinamide, the amide synthesized from retinoic acid and homocysteine thiolactone, and thioretinaco, the complex formed from cobalamin and thioretinamide, were demonstrated to have antineoplastic, anticarcinogenic, and anti-atherogenic properties in animal models. Retinol, ascorbate, and homocysteine thiolactone are necessary for biosynthesis of thioretinamide and thioretinaco by cystathionine synthase and for formation of thioretinaco ozonide from thioretinamide, cobalamin, and ozone. Thioretinaco ozonide is required for prevention of abnormal oxidative metabolism, aerobic glycolysis, suppressed immunity, and hyperhomocysteinemia in cancer.The pancreatic enzyme therapy of cancer promotes catabolism of proteins, nucleic acids, and glycosaminoglycans with excess homocysteinylated amino groups resulting from abnormal accumulation of homocysteine thiolactone in malignant cells. Dietary deficiencies of pyridoxal, folate, cobalamin, and nitriloside contribute to hyperhomocysteinemia in cancer, and in protein energy malnutrition. A deficiency of dietary sulfur amino acids downregulates cystathionine synthase, causing hyperhomocysteinemia.The organic sulfur compound diallyl trisulfide increases hydrogen sulfide production from homocysteine in animal models, inhibits Stat3 signaling in cancer stem cells, and produces apoptosis of malignant cells. The furanonaphthoquinone compound napabucasin inhibits Stat3 signaling and causes mitochondrial dysfunction, decreased oxidative phosphorylation, and apoptosis of malignant cells. The protocol of the proposed clinical trial in subjects with myelodysplasia consists of thioretinamide and cobalamin as precursors of thioretinaco ozonide, combined with pancreatic enzyme extracts, diallyl trisulfide, napabucasin, nutritional modification to minimize processed foods, vitamin supplements, essential amino acids, and beneficial dietary fats and proteins.

Review: Chemical Pathology of Homocysteine VI. Aging, Cellular Senescence, and Mitochondrial Dysfunction.

Following the discovery that caloric restriction extends the lifespan of many species of animals, the free radical theory of aging attributes the occurrence of oxidized nucleic acids, proteins, and lipids to reactive oxygen radical species originating from the metabolism of foods and the diminished efficacy of oxidative metabolism. Because of the decline of many critical neuro-hormones in aging, the neuroendocrine theory of aging attributes these changes to reduced feedback control of hormone production by the hypothalamus. Several rare genetic diseases attribute accelerated aging to changes in deoxyribonucleic acid (DNA) repair, depletion of the coenzyme nicotinamide adenine dinucleotide (NAD+), and altered methionine and homocysteine metabolism. The theory of oxidative phosphorylation attributes mitochondrial adenosine triphosphate (ATP) synthesis to the active site, thioretinaco ozonide oxygen NAD+ phosphate, which couples polymerization of NAD+ and phosphate to ATP produced by reduction of oxygen by electrons derived from foods. Loss of the thioretinaco ozonide oxygen ATP complex from the opening of the mitochondrial permeability transition pore (mPTP) is proposed to explain the abnormalities of oxidative metabolism occurring in cellular aging and carcinogenesis, thereby uniting the free radical and neuroendocrine theories of aging. Cellular senescence is associated with shortening of telomeres and decreased activity of telomerase, and exposure of cultured endothelial cells to homocysteine causes cellular senescence, shortened telomeres, and increased acidic ß-galactosidase, a marker of cellular senescence. The decrease in telomerase with aging is related to decreased nitric oxide production by nitric oxide synthase. The pathogenic microbes occurring in atherosclerotic plaques and in cerebral plaques in dementia inhibit nitric oxide synthesis by up-regulation of polyamine biosynthesis from adenosyl methionine and putrescene, causing the hyperhomocysteinemia and suppressed immunity that is observed in atherosclerosis and dementia. Progressive mitochondrial dysfunction occurs in aging because of loss of the thioretinaco ozonide oxygen ATP complex from mitochondrial membranes by opening of the mitochondrial permeability transition pore. Melatonin, a neuro-hormone, and cycloastragenol, a telomerase activator, both prevent mitochondrial dysfunction by inhibition of mPTP pore opening. The carcinogenic effects of radiofrequency radiation and mycotoxins are attributed to loss of thioretinaco ozonide from opening of the mPTP and decomposition of the active site of oxidative phosphorylation. The anti-aging effects of retinoids, the decreased concentration of cerebral cobalamin coenzymes in aging, and the diminished concentration of NAD+ from sirtuin activation, as observed in aging, all support the concept of loss of the thioretinaco ozonide oxygen ATP active site from mitochondria as the cause of decreased oxidative phosphorylation and mitochondrial dysfunction in aging.

Loss of the Thioretinaco Ozonide Oxygen Adenosine Triphosphate Complex from Mitochondria Produces Mitochondrial Dysfunction and Carcinogenesis.

The active site of oxidative phosphorylation and adenosine triphosphate (ATP) biosynthesis is proposed to consist of thioretinaco, a complex of two molecules of thioretinamide with cobalamin, oxidized to the disulfonium derivative, thioretinaco ozonide, and complexed with oxygen, nicotinamide adenine dinucleotide, inorganic phosphate and ATP. Reduction of the active site complex by electrons from mitochondrial electron transport complexes releases ATP from binding to the active site, producing nicotinamide riboside and hydroperoxide and generating a membrane potential from proton transport to the active site. Opening of the mitochondrial permeability transition pore from decreased mitochondrial melatonin leads to loss of the active site complex from mitochondrial membranes, as observed in aging and dementia. Loss of the active site complex from mitochondria also results from opening of the permeability transition pore and from decomposition of the disulfonium active site by electrophilic carcinogens, oncogenic viruses and microbes which cause depletion of adenosyl methionine because of increased biosynthesis of polyamines, and by free radical oxygen species generated by ionizing radiation, and by catecholamines. Thus the loss of thioretinaco ozonide from mitochondria produces the impaired oxidative phosphorylation, oxidative stress, calcium influx, apoptosis, aerobic glycolysis, and mitochondrial dysfunction that are observed in chemical carcinogenesis, microbial carcinogenesis, traumatic brain injury, aging and dementia.

Communication: Melatonin, Hyperhomocysteinemia, Thioretinaco Ozonide, Adenosylmethionine and Mitochondrial Dysfunction in Aging and Dementia.

The indoleamine hormone melatonin is synthesized by the pineal gland, controls circadian rhythm, and is dependent upon adenosyl methionine for enzymatic synthesis of melatonin from N-acetyl serotonin. Pineal melatonin secretion declines dramatically with aging and dementia. Elevated plasma homocysteine is a risk factor for atherosclerosis and Alzheimer's disease, and the marked decline in adenosyl methionine with aging leads to dysregulation of methionine metabolism and hyperhomocysteinemia. Thioretinaco ozonide is a disulfonium complex formed from thioretinamide, cobalamin, and ozone, which binds the alpha and gamma-phosphate groups of adenosine triphosphate (ATP) and oxygen in the process of oxidative phosphorylation within mitochondria. Decreased adenosyl methionine concentrations with aging are attributed to the loss of thioretinaco ozonide from mitochondria, impairing adenosyl methionine synthesis from thioretinaco ozonide and ATP. Melatonin is present in mitochondria, where it inhibits the opening of the mitochondrial permeability transition pore, explaining its anti-oxidant and anti-apoptotic effects by reducing oxygen consumption, restoration of membrane potential and reduction of superoxide production. In aging, the enzyme cyclic nucleotide phosphodiesterase is lost from mitochondria by the opening of the permeability transition pore and disruption of the outer mitochondrial membrane, a process that is inhibited by melatonin. Thioretinaco ozonide is progressively lost from dysfunctional mitochondria by disruption of the outer mitochondrial membrane, explaining its depletion during the aging process. Accordingly, the anti-aging effects of diallyl trisulfide and metformin are attributable to inhibition of the opening of the mitochondrial permeability transition pore, preventing loss of thioretinaco ozonide from mitochondria. The hyperhomocysteinemia and suppressed immunity that are observed in atherosclerosis and dementia are attributed to the deficiency of adenosylmethionine caused by increased polyamine synthesis and decreased nitric oxide synthesis by host cells infected with pathogenic microbes. According to this analysis, the critical loss of thioretinaco ozonide from mitochondria through the opening of the permeability transition pore and disruption of the outer mitochondrial membrane by decreased melatonin secretion leads to the impaired oxidative phosphorylation, oxidative stress, calcium influx, apoptosis and mitochondrial dysfunction observed in aging and dementia.

LDL-C does not cause cardiovascular disease: a comprehensive review of the current literature.

INTRODUCTION: For half a century, a high level of total cholesterol (TC) or low-density lipoprotein cholesterol (LDL-C) has been considered to be the major cause of atherosclerosis and cardiovascular disease (CVD), and statin treatment has been widely promoted for cardiovascular prevention. However, there is an increasing understanding that the mechanisms are more complicated and that statin treatment, in particular when used as primary prevention, is of doubtful benefit. Areas covered: The authors of three large reviews recently published by statin advocates have attempted to validate the current dogma. This article delineates the serious errors in these three reviews as well as other obvious falsifications of the cholesterol hypothesis. Expert commentary: Our search for falsifications of the cholesterol hypothesis confirms that it is unable to satisfy any of the Bradford Hill criteria for causality and that the conclusions of the authors of the three reviews are based on misleading statistics, exclusion of unsuccessful trials and by ignoring numerous contradictory observations.

Homocysteine, vitamins, and vascular disease prevention.

In mid-20th century United States, deaths from vascular disease reached a peak incidence in 1955, but little was known about the underlying causes of this epidemic of disease. The significance of homocysteine in human disease was unknown until 1962, when cases of homocystinuria were first associated with vascular disease. Analysis of an archival case of homocystinuria from 1933 and a case of cobalamin C disease from 1968 led to the conclusion that homocysteine causes vascular disease by a direct effect of the amino acid on arterial cells and tissues. The homocysteine theory of arteriosclerosis attributes one of the underlying causes of vascular disease to elevation of blood homocysteine concentrations as the result of dietary, genetic, metabolic, hormonal, or toxic factors. Dietary deficiency of vitamin B-6 and folic acid and absorptive deficiency of vitamin B-12, which result from traditional food processing or abnormal absorption of B vitamins, are important factors in causing elevations in blood homocysteine. Numerous clinical and epidemiologic studies have established elevated blood homocysteine as a potent independent risk factor for vascular disease in the general population. Dietary improvement, providing abundant vitamin B-6, folic acid, and cobalamin, may prevent vascular disease by lowering blood homocysteine. The dramatic decline in cardiovascular mortality in the United States since 1950 may possibly be attributable in part to voluntary fortification of the food supply with vitamin B-6 and folic acid. Fortification of the US food supply with folic acid in 1998, as mandated by the US Food and Drug Administration, was associated with a further decline in mortality from vascular disease, presumably because of increased blood folate and decreased blood homocysteine in the population.

Hyperhomocysteinemia, Suppressed Immunity, and Altered Oxidative Metabolism Caused by Pathogenic Microbes in Atherosclerosis and Dementia.

Many pathogenic microorganisms have been demonstrated in atherosclerotic plaques and in cerebral plaques in dementia. Hyperhomocysteinemia, which is a risk factor for atherosclerosis and dementia, is caused by dysregulation of methionine metabolism secondary to deficiency of the allosteric regulator, adenosyl methionine. Deficiency of adenosyl methionine results from increased polyamine biosynthesis by infected host cells, causing increased activity of ornithine decarboxylase, decreased nitric oxide and peroxynitrate formation and impaired immune reactions. The down-regulation of oxidative phosphorylation that is observed in aging and dementia is attributed to deficiency of thioretinaco ozonide oxygen complexed with nicotinamide adenine dinucleotide and phosphate, which catalyzes oxidative phosphorylation. Adenosyl methionine biosynthesis is dependent upon thioretinaco ozonide and adenosine triphosphate (ATP), and the deficiency of adenosyl methionine and impaired immune function in aging are attributed to depletion of thioretinaco ozonide from mitochondrial membranes. Allyl sulfides and furanonaphthoquinones protect against oxidative stress and apoptosis by increasing the endogenous production of hydrogen sulfide and by inhibiting electron transfer to the active site of oxidative phosphorylation. Diallyl trisulfide and napabucasin inhibit the signaling by the signal transducer and activator of transcription 3 (Stat3), potentially enhancing immune function by effects on T helper lymphocytes and promotion of apoptosis. Homocysteine promotes endothelial dysfunction and apoptosis by the unfolded protein response and endoplasmic reticulum stress through activation of the N-methyl D-aspartate (NMDA) receptor, causing oxidative stress, calcium influx, apoptosis and endothelial dysfunction. The prevention of atherosclerosis and dementia may be accomplished by a proposed nutritional metabolic homocysteine-lowering protocol which enhances immunity and corrects the altered oxidative metabolism in atherosclerosis and dementia.

Communication: Homocysteine, Thioretinaco Ozonide, Oxidative Phosphorylation, Biosynthesis of Phosphoadenosine Phosphosulfate and the Pathogenesis of Atherosclerosis.

The formation of phosphoadenosine phosphosulfate (PAPS) is accomplished by the action of the enzyme 3'-phosphoadenosine 5'-phosphosulfate synthase (PAPSS) in two sequential reactions, consisting of (1) reaction of inorganic sulfate with adenosine triphosphate (ATP) to form adenosine phosphosulfate (APS) and pyrophosphate and (2) reaction of APS with inorganic phosphate to form PAPS and adenosine diphosphate (ADP). The hydrolysis of guanosine triphosphate (GTP) is coordinated with synthesis of APS in a reaction sequence which provides the chemical energy for synthesis of APS. The present proposal is that the active site of oxidative phosphorylation, thioretinaco ozonide oxygen (TR2CoO3O2), functions as the source of APS synthesis from nicotinamide adenine dinucleotide (NAD+) and hydrosulfate (HSO4-) by reduction of the complex with electrons from electron transport complexes, releasing APS and thioretinaco hydroperoxide (TR2CoO3O2H) upon protonation. Subsequently, APS reacts with GTP, which is produced from the active site of oxidative phosphorylation, TR2CoO3O2ATP, to phosphorylate APS to PAPS. These proposed reactions for PAPS synthesis in atherosclerosis explain the metabolic pathway for formation of PAPS from homocysteine through the intermediate formation of thioretinamide (TR) and explain how hyperhomocysteinemia stimulates production of sulfated glycosaminoglycans (GAG), which are essential components of atherosclerotic plaques.

Homocysteine, Infections, Polyamines, Oxidative Metabolism, and the Pathogenesis of Dementia and Atherosclerosis.

Hyperhomocysteinemia is a risk factor for development of dementia and Alzheimer's disease (AD), and low blood levels of folate and cobalamin are associated with hyperhomocysteinemia and AD. In elderly subjects with cognitive decline, supplementation with folate, cobalamin, and pyridoxal demonstrated reduction of cerebral atrophy in gray matter regions vulnerable to the AD process. Multiple pathogenic microbes are implicated as pathogenic factors in AD and atherosclerosis, and the deposition of amyloid-ß (Aß), phosphorylation of tau protein, neuronal injury, and apoptosis in AD are secondary to microbial infection. Glucose utilization and blood flow are reduced in AD, and these changes are accompanied by downregulation of glucose transport, Na, K-ATPase, oxidative phosphorylation, and energy consumption. Thioretinaco ozonide, the complex formed from thioretinamide, cobalamin, ozone, and oxygen is proposed to constitute the active site of oxidative phosphorylation, catalyzing synthesis of adenosine triphosphate (ATP) from nicotinamide adenine dinucleotide (NAD+) and phosphate. Pathogenic microbes cause synthesis of polyamines in host cells by increasing the transfer of aminopropyl groups from adenosyl methionine to putrescine, resulting in depletion of intracellular adenosyl methionine concentrations in host cells. Depletion of adenosyl methionine causes dysregulation of methionine metabolism, hyperhomocysteinemia, reduced biosynthesis of thioretinamide and thioretinaco ozonide, decreased oxidative phosphorylation, decreased production of nitric oxide and peroxynitrite, and impaired host response to infectious microbes, contributing to the pathogenesis of dementia and atherosclerosis.

Lack of an association or an inverse association between low-density-lipoprotein cholesterol and mortality in the elderly: a systematic review.

OBJECTIVE: It is well known that total cholesterol becomes less of a risk factor or not at all for all-cause and cardiovascular (CV) mortality with increasing age, but as little is known as to whether low-density lipoprotein cholesterol (LDL-C), one component of total cholesterol, is associated with mortality in the elderly, we decided to investigate this issue. SETTING, PARTICIPANTS AND OUTCOME MEASURES: We sought PubMed for cohort studies, where LDL-C had been investigated as a risk factor for all-cause and/or CV mortality in individuals ≥60 years from the general population. RESULTS: We identified 19 cohort studies including 30 cohorts with a total of 68 094 elderly people, where all-cause mortality was recorded in 28 cohorts and CV mortality in 9 cohorts. Inverse association between all-cause mortality and LDL-C was seen in 16 cohorts (in 14 with statistical significance) representing 92% of the number of participants, where this association was recorded. In the rest, no association was found. In two cohorts, CV mortality was highest in the lowest LDL-C quartile and with statistical significance; in seven cohorts, no association was found. CONCLUSIONS: High LDL-C is inversely associated with mortality in most people over 60 years. This finding is inconsistent with the cholesterol hypothesis (ie, that cholesterol, particularly LDL-C, is inherently atherogenic). Since elderly people with high LDL-C live as long or longer than those with low LDL-C, our analysis provides reason to question the validity of the cholesterol hypothesis. Moreover, our study provides the rationale for a re-evaluation of guidelines recommending pharmacological reduction of LDL-C in the elderly as a component of cardiovascular disease prevention strategies.

Homocysteine and the pathogenesis of atherosclerosis.

The homocysteine theory of arteriosclerosis was discovered by study of arteriosclerotic plaques occurring in homocystinuria, a disease caused by deficiencies of cystathionine synthase, methionine synthase or methylenetetrahydrofolate reductase. According to the homocysteine theory, metabolic and nutritional abnormalities leading to elevation of plasma homocysteine cause atherosclerosis in the general population without these rare enzymatic abnormalities. Through studies of metabolism of homocysteine thiolactone, the anhydride of homocysteine, in cell cultures from homocystinuric children, the pathway for synthesis of sulfate was found to be dependent upon thioretinamide, the amide formed from retinoic acid and homocysteine thiolactone. Two molecules of thioretinamide form the complex thioretinaco with cobalamin, and oxidative phosphorylation is catalyzed by reduction of oxygen, which is bound to thioretinaco ozonide, by electrons from electron transport particles. Atherogenesis is attributed to formation of aggregates of homocysteinylated lipoproteins with microorganisms, which obstruct the vasa vasorum during formation of arterial vulnerable plaques.

The active site of oxidative phosphorylation and the origin of hyperhomocysteinemia in aging and dementia.

The active site of oxidative phosphorylation and adenosine triphosphate (ATP) synthesis in mitochondria is proposed to consist of two molecules of thioretinamide bound to cobalamin, forming thioretinaco, complexed with ozone, oxygen, nicotinamide adenine dinucleotide. and inorganic phosphate, TR2CoO3O2NAD(+)H2PO4(-). Reduction of the pyridinium nitrogen of the nicotinamide group by an electron from electron transport complexes initiates polymerization of phosphate with adenosine diphosphate, yielding nicotinamide riboside and ATP bound to thioretinaco ozonide oxygen. A second electron reduces oxygen to hydroperoxyl radical, releasing ATP from the active site. A proton gradient is created within F1F0 ATPase complexes of mitochondria by reaction of protons with reduced nicotinamide riboside and with hydroperoxyl radical, yielding reduced nicotinamide riboside and hydroperoxide. The hyperhomocysteinemia of aging and dementia is attributed to decreased synthesis of adenosyl methionine by thioretinaco ozonide and ATP, causing decreased allosteric activation of cystathionine synthase and decreased allosteric inhibition of methylenetetrahydrofolate reductase and resulting in dysregulation of methionine metabolism.

Homocysteine Metabolism, Atherosclerosis, and Diseases of Aging.

The importance of homocysteine in vascular function and arteriosclerosis was discovered by demonstration of arteriosclerotic plaques in children with homocystinuria caused by inherited enzymatic deficiencies of cystathionine synthase, methionine synthase, or methylene-tetrahydrofolate reductase. According to the homocysteine theory of arteriosclerosis, an elevated blood homocysteine level is an important risk factor for atherosclerosis in subjects without these rare enzymatic abnormalities. The homocysteine theory is supported by demonstration of arterial plaques in experimental animals with hyperhomocysteinemia, by discovery of a pathway for conversion of homocysteine thiolactone to sulfate in cell cultures from children with homocystinuria, and by demonstration of growth promotion by homocysteic acid in normal and hypophysectomized animals. Studies with cultured malignant cells revealed abnormal homocysteine thiolactone metabolism, resulting in homocysteinylation of proteins, nucleic acids, and glycosaminoglycans, explaining the abnormal oxidative metabolism, abnormalities of cellular membranes, and altered genetic expression observed in malignancy. Abnormal homocysteine metabolism in malignant cells is attributed to deficiency of thioretinamide, the amide synthesized from retinoic acid and homocysteine thiolactone. Two molecules of thioretinamide combine with cobalamin to form thioretinaco. Based on the molecular structure of thioretinaco, a theory of oxidative phosphorylation was proposed, involving oxidation to a disulfonium derivative by ozone, and binding of oxygen, nicotinamide adenine dinucleotide and phosphate as the active site of adenosine triphosphate synthesis in mitochondria. Obstruction of vasa vasorum by aggregates of microorganisms with homocysteinylated low-density lipoproteins is proposed to cause ischemia of arterial wall and a microabscess of the intima, the vulnerable atherosclerotic plaque.

Homocysteine, vitamins, and prevention of vascular disease.

Within the past four decades, the efforts of investigators worldwide have established the amino acid homocysteine as an important factor in arteriosclerosis and diseases of aging. After its discovery in 1932, homocysteine was demonstrated to be an important intermediate in the metabolism of amino acids. However, little was known about the broader biomedical significance of homocysteine until 1962, when children with mental retardation, accelerated growth, dislocated ocular lenses, and frequent vascular thrombosis were found to excrete homocysteine in the urine. My study of two patients with homocystinuria caused by different inherited enzymatic disorders in 1968 disclosed advanced widespread arteriosclerotic plaques in both cases. This discovery led to the conclusion that homocysteine causes vascular disease by a direct effect on the cells and tissues of the arteries. This interpretation suggests that homocysteine is important in the pathogenesis of arteriosclerosis in persons with hereditary, dietary, environmental, hormonal, metabolic, and other factors predisposing them to hyperhomocysteinemia. Within the past decade, many major clinical and epidemiological studies have proven that hyperhomocysteinemia is a potent independent risk factor for vascular disease. According to the homocysteine theory of arteriosclerosis, insufficient dietary intake of the B vitamins, folic acid and pyridoxine, caused by losses of these nutrients during processing of foods, leads to elevation of blood homocysteine and vascular disease in the general population. The dramatic decline in cardiovascular mortality since the 1960s in the United States is attributed to fortification of the food supply by synthetic pyridoxine and folic acid. The recent Swiss Heart Study showed that B vitamins slowed restenosis in patients with coronary arteriosclerosis treated with angioplasty. Currently, more than 20 prospective, worldwide, interventional trials involving at least 100,000 participants are examining whether lowering plasma homocysteine levels with supplemental B vitamins will prevent mortality and morbidity from arteriosclerotic vascular disease.