Why homocysteine-lowering therapy does not have beneficial effects on patients with cardiovascular disease?

Homocysteine is a sulfur-containing amino acid produced during the metabolism of methionine and elevated plasma levels of homocysteine have been linked to an increased risk of atherosclerosis and cardiovascular ischemic events by numerous authors. Several mechanisms by which elevated homocysteine impairs vascular function have been proposed including impairment of endothelial function and at least some of those mechanisms are induced via homocysteine-associated DNA hypomethylation. Oral administration of folic acid and B vitamins, required for remethylation of homocysteine to methionine, decreased plasma total homocysteine levels but clinical trials using folic acid and B vitamins did not confirm that the decreased plasma levels of homocysteine through diet or drugs may be paralleled by a reduction in cardiovascular risk. In our view a plausible explanation for the discordance between the epidemiologic studies and the results of the clinical trials may be related to the homocysteine-associated global DNA hypomethylation which cannot easily be reversed by homocysteine-lowering therapy.     

Plasma homocysteine concentrations are positively associated with hostility and anger

Homocysteine is a sulphur amino acid that is positively associated with risk of vascular disease. Very few behavioral or psychological factors have been studied in relationship to homocysteine levels, despite the fact that several psychological factors have also been linked with risk for cardiovascular disease. One psychological attribute showing a strong association with risk is hostility, which is prospectively predictive of future cardiovascular disease endpoints. Another related psychological factor is anger expression; coronary heart disease risk is associated with both heightened expression and inhibition of anger. The purpose of this study was to test the relationship of hostility and anger expression with homocysteine concentrations in a sample of healthy, middle-aged men and women. Participants completed the Cook-Medley hostility questionnaire, the Speilberger Anger Expression questionnaire, and had blood taken for the assessment of plasma homocysteine concentrations. Results indicated positive and significant associations between hostility and homocysteine levels for all participants, and positive and significant correlations between anger-in and homocysteine levels for men only. These data are among the first to test the relationship between homocysteine and psychological risk factors for cardiovascular diseases, and suggest one potential mechanism for the increased cardiovascular risk associated with hostility and anger expression.     

Increase in plasma homocysteine associated with parallel increases in plasma S-adenosylhomocysteine and lymphocyte DNA hypomethylation

S-Adenosylmethionine and S-adenosylhomocysteine (SAH), as the substrate and product of essential cellular methyltransferase reactions, are important metabolic indicators of cellular methylation status. Chronic elevation of SAH, secondary to the homocysteine-mediated reversal of the SAH hydrolase reaction, reduces methylation of DNA, RNA, proteins, and phospholipids. High affinity binding of SAH to the active site of cellular methyltransferases results in product inhibition of the enzyme. Using a sensitive new high pressure liquid chromatography method with coulometric electrochemical detection, plasma SAH levels in healthy young women were found to increase linearly with mild elevation in homocysteine levels (r = 0.73; p < 0.001); however, S-adenosylmethionine levels were not affected. Plasma SAH levels were positively correlated with intracellular lymphocyte SAH levels (r = 0.81; p < 0.001) and also with lymphocyte DNA hypomethylation (r = 0.74, p < 0.001). These results suggest that chronic elevation in plasma homocysteine levels, such as those associated with nutritional deficiencies or genetic polymorphisms in the folate pathway, may have an indirect and negative effect on cellular methylation reactions through a concomitant increase in intracellular SAH levels.     

Hepatocyte-specific Dyrk1a gene transfer rescues plasma apolipoprotein A-I levels and aortic Akt/GSK3 pathways in hyperhomocysteinemic mice

Hyperhomocysteinemia, characterized by high plasma homocysteine levels, is recognized as an independent risk factor for cardiovascular diseases. The increased synthesis of homocysteine, a product of methionine metabolism involving B vitamins, and its slower intracellular utilization cause increased flux into the blood. Plasma homocysteine level is an important reflection of hepatic methionine metabolism and the rate of processes modified by B vitamins as well as different enzyme activity. Lowering homocysteine might offer therapeutic benefits. However, approximately 50% of hyperhomocysteinemic patients due to cystathionine-beta-synthase deficiency are biochemically responsive to pharmacological doses of B vitamins. Therefore, effective treatments to reduce homocysteine levels are needed, and gene therapy could provide a novel approach. We recently showed that hepatic expression of DYRK1A, a serine/threonine kinase, is negatively correlated with plasma homocysteine levels in cystathionine-beta-synthase deficient mice, a mouse model of hyperhomocysteinemia. Therefore, Dyrk1a is a good candidate for gene therapy to normalize homocysteine levels. We then used an adenoviral construct designed to restrict expression of DYRK1A to hepatocytes, and found decreased plasma homocysteine levels after hepatocyte-specific Dyrk1a gene transfer in hyperhomocysteinemic mice. The elevation of pyridoxal phosphate was consistent with the increase in cystathionine-beta-synthase activity. Commensurate with the decreased plasma homocysteine levels, targeted hepatic expression of DYRK1A resulted in elevated plasma paraoxonase-1 activity and apolipoprotein A-I levels, and rescued the Akt/GSK3 signaling pathways in aorta of mice, which can prevent homocysteine-induced endothelial dysfunction. These results demonstrate that hepatocyte-restricted Dyrk1a gene transfer can offer a useful therapeutic targets for the development of new selective homocysteine lowering therapy.     

Homocysteine and atherosclerosis.

Elevated plasma total homocysteine is an independent risk factor for atherosclerotic vascular disease. Risk rises continuously across the spectrum of homocysteine concentrations and may become appreciable at levels greater than 10 mumol/l. A compelling case can be made for screening all individuals with atherosclerotic disease or at high risk. A reasonable, but unproven, goal for treatment is a plasma total homocysteine concentration less than 10 mumol/l. Folic acid is the mainstay of treatment, but vitamins B12 and B6 may have added benefit in selected patients. The results of ongoing randomized placebo-controlled trials will not be available for several years, but will help determine whether homocysteine lowering reduces the risk of cardiovascular disease.     

Mechanisms for the formation of protein-bound homocysteine in human plasma

Hyperhomocysteinemia is an independent risk factor for cardiovascular disease. Greater than 70% of homocysteine in circulation is protein-bound. An in vitro model system using human plasma has been developed to study mechanisms of protein-bound homocysteine formation and establish the equilibrium binding capacities of plasma for homocysteine. Addition of homocysteine to plasma caused an initial rapid displacement of cysteine and a subsequent increase in protein-bound homocysteine. This rapid reaction was followed by a slower oxygen-dependent reaction forming additional protein-bound homocysteine. To determine the equilibrium binding capacity of plasma proteins for homocysteine, plasma was treated with 0.5-10 mM dl-homocysteine for 4 h at 37 degrees C under aerobic conditions. Under these conditions the equilibrium binding capacity was 4.88 +/- 0.51 and 4.74 +/- 0.68 micromol/g protein for male (n = 10) and female (n = 10) donors, respectively. The mechanism of protein-bound homocysteine formation involves both thiol-disulfide exchange and thiol oxidation reactions. We conclude that plasma proteins have a high capacity for binding homocysteine in vitro.     

Methylation demand: a key determinant of homocysteine metabolism

Elevated plasma homocysteine is a risk factor for cardiovascular disease and Alzheimer's disease. To understand the factors that determine the plasma homocysteine level it is necessary to appreciate the processes that produce homocysteine and those that remove it. Homocysteine is produced as a result of methylation reactions. Of the many methyltransferases, two are, normally, of the greatest quantitative importance. These are guanidinoacetate methyltransferase (that produces creatine) and phosphatidylethanolamine N-methyltransferase (that produces phosphatidylcholine). In addition, methylation of DOPA in patients with Parkinson's disease leads to increased homocysteine production. Homocysteine is removed either by its irreversible conversion to cysteine (transsulfuration) or by remethylation to methionine. There are two separate remethylation reactions, catalyzed by betaine:homocysteine methyltransferase and methionine synthase, respectively. The reactions that remove homocysteine are very sensitive to B vitamin status as both the transsulfuration enzymes contain pyridoxal phosphate, while methionine synthase contains cobalamin and receives its methyl group from the folic acid one-carbon pool. There are also important genetic influences on homocysteine metabolism.     

Early reduction of circulating homocysteine levels in Goto-Kakizaki rat, a spontaneous nonobese model of type 2 diabetes

Diabetes mellitus is associated with increased risk for cardiovascular disorders, which are major causes of mortality in this disease. Hyperhomocysteinemia, defined by high plasma homocysteine levels, is an independent risk factor for the development of cardiovascular diseases. Type 2 diabetic patients have higher circulating homocysteine levels than healthy subjects and these levels are even higher in plasma of obese than nonobese diabetic patients. Homocysteine metabolism that has been studied in 2 animal models of type 2 diabetes with obesity led to conflicting data. The aim of the present study was to analyze homocysteine metabolism in a spontaneous nonobese model of type 2 diabetes, the Goto-Kakizaki rats at various successive and well characterized stages of the disease: during early postnatal normoglycemia, at the onset of hyperglycemia (around weaning), and during chronic mild hyperglycemia with progressive insulin resistance. Compared to age-matched Wistar controls, Goto-Kakizaki rats showed lower plasma levels of homocysteine and a falling trend in its major byproduct antioxidant, glutathione, from the prediabetic stage onwards. Concomitantly, Goto-Kakizaki rats exhibited increased liver activity of cystathionine beta synthase, which catalyzes the condensation of homocysteine with serine in the first step of the transsulfuration pathway. These results emphasize a strong association between homocysteine metabolism and insulin via the first step of the hepatic transsulfuration pathway in Goto-Kakizaki rats.     

Plasma homocysteine is regulated by phospholipid methylation

Mild hyperhomocysteinemia is an independent risk factor for cardiovascular disease. Homocysteine, a non-protein amino acid, is formed from S-adenosylhomocysteine and partially secreted into plasma. A potential source for homocysteine is methylation of the lipid phosphatidylethanolamine to phosphatidylcholine by phosphatidylethanolamine N-methyltransferase in the liver. We show that mice that lack phosphatidylethanolamine N-methyltransferase have plasma levels of homocysteine that are approximately 50% of those in wild-type mice. Hepatocytes isolated from methyltransferase-deficient mice secrete approximately 50% less homocysteine. Rat hepatoma cells transfected with phosphatidylethanolamine N-methyltransferase secrete more homocysteine than wild-type cells. Thus, phosphatidylethanolamine N-methyltransferase is an important source of plasma homocysteine and a potential therapeutic target for hyperhomocysteinemia.     

血浆同型半胱氨酸水平升高与动脉粥样硬化

心血管疾病已成为当今全球性致残与致死的最重要原因之一。目前确定的冠心病的危险因素主要包括高龄、血脂异常、高血压、糖尿病、吸烟、肥胖症。大量的临床试验及流行病学研究已经证实血浆同型半胱氨酸水平升高是心血管疾病的一个独立的危险因素。健康人的血浆同型半胱氨酸水平为5～10μmol／L。血浆同型半胱氨酸水平严重升高的主要原因是胱硫醚-β-合成酶(cystathionine-β-synthase,CBS)基因的缺陷。CBS基因缺陷的纯合体可导致血浆同型半胱氨酸水平升高至100～500μmol／L。血浆同型半胱氨酸水平严重升高的病人通常伴随神经系统异常、早发性的动脉粥样硬化。叶酸、维生素B6和B12治疗能降低血浆同型半胱氨酸的水平并改善血管内皮功能、减少经皮冠状动脉腔内成形术(percutaneou stransluminal coronary angioplasty,PTCA)术后并发症。迄今为止,血浆同型半胱氨酸水平升高引起心血管疾病的发病机制并未完全明了,目前认为主要与以下几个方面有关：(1)内皮细胞损伤及功能障碍。我们实验室在CBS基因敲除的小鼠模型上证实血浆同型半胱氨酸水平升高能抑制eNOS的活性,导致主动脉内皮功能的障碍。我们还在细胞模型上证实了同型半胱氨酸能显著抑制内皮细胞的增殖。(2)KH固醇和甘油三脂生物合成代谢异常。我们实验室在apoE、CBS双基因敲除的小鼠模型上证实血浆同型半胱氨酸水平升高能改变肝脏的脂肪代谢,增加巨噬细胞对修饰LDL的摄取,从而导致胆固醇脂和甘油三脂在血管壁的堆积,促进主动脉粥样斑块的形成。(3)刺激血管平滑肌细胞增殖。此外还发现同型半胱氨酸能激活蛋白激酶C信号途径,促进胶原蛋白的合成,抑制弹性蛋白和胶原蛋白的交联。(4)激活血栓形成。(5)激活单核细胞。目前认为同型半胱氦酸主要通过以下几个化学机制致病;(1)自氧化产生活性氧。同型半胱氨酸在自氧化的过程中能产生大量的活性氧,从而引起血液中脂蛋白和细胞膜脂质的过氧化损伤,并进一步引起内皮功能的障碍。(2)在腺苷的参与下形成SAH,一种甲基转移抑制剂,导致细胞内的低甲基化。(3)与一氧化氮结合形成亚硝酰物。(4)参与蛋白质的合成。总之,我们和其他实验室的研究结果均表明同型半胱氨酸不仅与动脉粥样硬化相关,而且具有致病效应。尽管补充叶酸、维生素B6和B12等治疗能降低血浆同型半胱氨酸的水平,但是否能降低心血管疾病的风险仍有待于大量的动物研究及临床试验。     

Adenosine analogue inhibitors of S-adenosylhomocysteine hydrolase

Elevated plasma homocysteine (Hcy) levels are an independent risk factor for the onset and progression of Alzheimer’s disease. Reduction of Hcy to normal levels therefore presents a new approach for disease modification. Hcy is produced by the cytosolic enzyme S-adenosylhomocysteine hydrolase (AHCY), which converts S-adenosylhomocysteine (SAH) to Hcy and adenosine. Herein we describe the design and characterization of novel, substrate-based S-adenosylhomocysteine hydrolase inhibitors with low nanomolar potency in vitro and robust activity in vivo.     

Differences in the metabolic response to exogenous homocysteine in juvenile and adult rabbits

Homocysteine has recently received a lot of attention as an independent risk factor for atherosclerotic and thrombotic cardiovascular disease. Plasma homocysteine levels tend to rise with age, but are also greatly influenced by nutritional factors. Early reports suggested that there were differences in the metabolism of homocysteine in adult and immature animals. The current work tests the hypothesis that adult and juvenile animals respond differently to chronic administration of homocysteine. We have previously found that adult rabbits given homocysteine parenterally twice daily for seven weeks developed progressive folate deficiency and concurrently developed an impairment of homocysteine metabolism. We now report that juvenile rabbits do not develop folate deficiency with chronic homocysteine loading and do not have progressively higher trough levels of homocysteine, as do the adults. In addition, juvenile rabbits that have been chronically pre-treated with homocysteine exhibit a lower peak homocysteine level after a single dose than do juvenile rabbits that have never received homocysteine. This adaptation did not occur in the adult rabbits. In addition, adult homocysteine-treated rabbits had evidence of oxidative stress as evidenced by higher levels of malondialdehyde in liver tissue than adult controls. The homocysteine-treated juvenile rabbits had the same levels of malondialdehyde as the juvenile control rabbits. We conclude that the plasma elimination kinetics are altered in juvenile rabbits in response to homocysteine pre-treatment. The difference in metabolism of homocysteine may protect the juvenile rabbits from the damaging effects of homocysteine. Future studies are planned to elucidate the mechanism of this adaptive response.     

Homocysteine is a potent modulator of plasma membrane electron transport systems

The deregulation of homocysteine metabolism leads to hyperhomocysteinemia, a condition described as an independent cardiovascular disease risk factor. Ubiquitous plasma membrane redox systems can play a dual pro-oxidant and anti-oxidant role in defense. In this study, we test the hypothesis that homocysteine, as a redox active compound, could modulate the endothelial plasma membrane redox system. We show that homocysteine behaves as a very potent stimulator of this activity. Furthermore, we show that this inducing effect is also produced on tumor cells and that it can be observed at both the activity and protein levels. On the other hand, homocysteine treatment decreases the activity of the specific ectocellular tumor NADH oxidase. Taken together, these results underscore a potential antitumoral action of homocysteine.     

Plasma homocysteine is decreased in the hypothyroid rat

Recent clinical studies have indicated that plasma homocysteine was significantly increased in hypothyroid patients. Since hyperhomocysteinemia is an independent risk factor for cardiovascular disease we investigated homocysteine metabolism in hypothyroid rats. Hypothyroidism was induced in one study by addition of propylthiouracil (PTU) to the drinking water for 2 weeks. In a second study, thyroidectomized and sham-operated rats were used with thyroid hormone replacement via mini-osmotic pumps. Unlike the human hypothyroid patients, both groups of hypothyroid rats exhibited decreased total plasma homocysteine (30% in PTU rats, 50% in thyroidectomized rats) versus their respective controls. Thyroid replacement normalised homocysteine levels in the thyroidectomized rat. Increased activities of the hepatic trans-sulfuration enzymes were found in both models of hypothyroidism. These results provide a possible explanation for the decreased plasma homocysteine concentrations. The hypothyroid rat cannot be used as a model to study homocysteine metabolism in hypothyroid patients.     

Plasma total homocysteine level and methylenetetrahydrofolate reductase 677C>T genetic polymorphism in Japanese patients with rheumatoid arthritis

Hyperhomocysteinemia is a known risk factor of cardiovascular disease. Homocysteine has been also linked to inflammation in rheumatoid arthritis (RA). In this study, we investigated the relationship between plasma homocysteine levels and single nucleotide polymorphism (SNP) of the gene coding for methylenetetrahydrofolate reductase (MTHFR), an enzyme involved in the biosynthesis of homocysteine, and the correlation between the plasma homocysteine levels and generally used inflammatory markers (C-reactive protein, erythrocyte sedimentation rate and matrix metalloproteinase-3) in 96 Japanese patients with RA. Plasma homocysteine levels in patients with the MTHFR 677TT genotype were significantly higher than in those with the 677CC genotype (p < 0.05). In addition, plasma homocysteine levels were increased along with the elevation of general inflammatory markers. Therefore, we conclude that homocysteine might affect the inflammatory status of patients, and the MTHFR 677C>T SNP could be a predictive factor of hyperhomocysteinemia in patients with RA.     

In vitro and in vivo interactions of homocysteine with human plasma transthyretin

Hyperhomocysteinemia is an independent risk factor for cardiovascular disease and an emerging risk factor for cognitive dysfunction and Alzheimer's disease. Greater than 70% of the homocysteine in plasma is disulfide-bonded to protein cysteine residues. The identity and functional consequences of protein homocysteinylation are just now emerging. The amyloidogenic protein transthyretin (prealbumin), as we now report, undergoes homocysteinylation at its single cysteine residue (Cys10) both in vitro and in vivo. Thus, when human plasma or highly purified transthyretin was incubated with 35S-L-homocysteine followed by SDS-PAGE and PhosphorImaging, two bands corresponding to transthyretin dimer and tetramer were observed. Treatment of the labeled samples with beta-mercaptoethanol prior to SDS-PAGE removed the disulfide-bound homocysteine. Transthyretin-Cys10-S-S-homocysteine was then identified in vivo in plasma from normal donors, patients with end-stage renal disease, and homocystinurics by immunoprecipitation and high performance liquid chromatography/electrospray mass spectrometry. The ratios of transthyretin-Cys10-S-S-homocysteine and transthyretin-Cys10-S-S-sulfonate to that of unmodified transthyretin increased with increasing homocysteine plasma concentrations, whereas the ratio of transthyretin-Cys10-S-S-cysteine to that of unmodified transthyretin decreased. The hyperhomocysteinemic burden is thus reflected in the plasma levels of transthyretin-Cys10-S-S-homocysteine, which in turn may contribute to the pathological consequences of amyloid disease.     

Plasma total homocysteine and subarachnoid haemorrhage in a co-factor replete population

Summary. Mild hyperhomocysteinaemia is a postulated risk factor for occlusive vascular disease, including stroke. Subarachnoid haemorrhage (SAH) has an annual incidence of 10–20 per 100,000 and accounts for 5–10% of all strokes. Measurement of plasma total homocysteine (tHcy) in a cohort of vitamin B12 and folate replete patients did not reveal any association between tHcy and the aetiology of SAH. Received November 6, 2000 Accepted February 12, 2001     

Detection of altered global DNA methylation in coronary artery disease patients

Epigenetic modifications, especially alteration in DNA methylation, are increasingly being recognized as a key factor in the pathogenesis of complex disorders, including atherosclerosis. However, there are limited data on the epigenetic changes in the coronary artery disease (CAD) patients. In the present study we evaluated the methylation status of genomic DNA from peripheral lymphocytes in a cohort of 287 individuals: 137 angiographically confirmed CAD patients and 150 controls. The differential susceptibility of genomic DNA to methylation-sensitive restriction enzymes was utilized to assess the methylation status of the genome. We observed that the genomic DNA methylation in CAD patients is significantly higher than in controls (p < 0.05). Since elevated homocysteine levels are known to be an independent risk factor for CAD and a key modulator of macromolecular methylation, we investigated the probable correlation between plasma homocysteine levels and global DNA methylation. We observed a significant positive correlation of global DNA methylation with plasma homocysteine levels in CAD patients (p = 0.001). Further, within a higher range of serum homocysteine levels (>/=12-50 muM), global DNA methylation was significantly higher in CAD patients than in controls. The alteration in genomic DNA methylation associated with cardiovascular disease per se appears to be further accentuated by higher homocysteine levels.     

Nutritional modulation of leptin expression and leptin action in obesity and obesity-associated complications

In obesity, an elevated accumulation and dysregulation of adipose tissue, due to an imbalance between energy intake and energy expenditure, usually coexists with the loss of responsiveness to leptin in central nervous system, and subsequently with hyperleptinemia. Leptin, a peptide hormone mainly produced by white adipose tissue, regulates energy homeostasis by stimulating energy expenditure and inhibiting food intake. Human obesity is characterized by increased plasma leptin levels, which have been related with different obesity-associated complications, such as chronic inflammatory state (risk factor for diabetes, cardiovascular and autoimmune diseases), as well as infertility and different types of cancer. Besides, leptin is also produced by placenta, and high leptin levels during pregnancy may be related with some pathological conditions such as gestational diabetes. This review focuses on the current insights and emerging concepts on potentially valuable nutrients and food components that may modulate leptin metabolism. Notably, several dietary food components, such as phenols, peptides, and vitamins, are able to decrease inflammation and improve leptin sensitivity by up- or down-regulation of leptin signaling molecules. On the other hand, some food components, such as saturated fatty acids may worsen chronic inflammation increasing the risk for pathological complications. Future research into nutritional mechanisms that restore leptin metabolism and signals of energy homeostasis may inspire new treatment options for obesity-related disorders.