Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0042373 (vascular disease)
 17,070 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Urinary N,N,N-trimethylglycine (betaine) and N,N-dimethylglycine (DMG) have been identified and quantified for clinical purposes by proton nuclear magnetic resonance (1H NMR) measurement in previous studies. We have assessed these procedures by using both one-dimensional (1-D) and 2-D NMR spectroscopy, together with pH titration of urinary extracts to help assign 1H NMR spectral peaks. The betaine calibration curve linearity was excellent (r = 0.997, P = 0.0001) over the concentration range 0.2-1.2 mmol/L, and CVs for replicate betaine analyses ranged from 7% (n = 10) at the lowest concentration to 1% (n = 9) at the highest. The detection limit for betaine was < 15 mumol/L. Urinary DMG concentrations were substantially lower than those of betaine. Urinary betaine and DMG concentrations measured by 1H NMR spectroscopy from 13 patients with premature vascular disease and 17 normal controls provided clinically pertinent data. We conclude that 1H NMR provides unique advantages as a research tool for determination of urinary betaine and DMG concentrations.
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PMID:1H NMR determination of urinary betaine in patients with premature vascular disease and mild homocysteinemia. 753 65

In the past decade significant progress has been made in understanding of hyperhomocysteinaemia and its association with the proneness to premature development of vascular disease. Pooled data from a large number of studies demonstrate that mild hyperhomocysteinaemia after standardized methionine loading is present in 21% of patients with coronary artery disease, in 24% of patients with cerebrovascular disease, and in 32% of patients with peripheral vascular disease. A relative risk of 13.0 (95% confidence interval 5.9-28.1) of vascular disease at relatively young age can be calculated in subjects with such abnormal response to methionine loading. Pathological homocysteine levels are affected by genetic defects in homocysteine metabolism which have still not been completely clarified and which are more complex than originally supposed. Furthermore, a variety of non-genetic determinants such as deficiency of folate or vitamin B12 has to be taken into account. Mild hyperhomocysteinaemia can be reduced to normal in virtually all cases by simple and safe treatment with vitamin B6, folic acid, and betaine, each of which is involved in methionine metabolism. A clinically beneficial effect of such an intervention, which is currently under investigation, could make large-scale screening mandatory for this risk factor.
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PMID:Hyperhomocysteinaemia: a newly recognized risk factor for vascular disease. 806 83

Mild homocysteinemia occurs surprisingly often in patients with premature vascular disease. We studied the possible enzymatic sources of this mild hyperhomocysteinemia and the control of homocysteine levels in plasma by treatment of patients with the cofactors and cosubstrates of homocysteine catabolism. We assessed homocysteine metabolism in 131 patients who had premature disease in their coronary, peripheral, or cerebrovascular circulation by using a standard oral methionine-load test. Impaired homocysteine metabolism occurred in 28 patients. We assayed levels of the primary enzymes of homocysteine catabolism in cultured skin fibroblast extracts from 15 of these 28 patients. The patients' cystathionine beta-synthase levels (3.68 +/- 2.52 nmol/h per milligram of cell protein, mean +/- SD) were markedly depressed compared with those from 31 healthy adult control subjects (7.61 +/- 4.49, P < .001). The patients' levels of 5-methyltetrahydrofolate: homocysteine methyltransferase were normal. While betaine: homocysteine methyltransferase was not expressed in skin fibroblasts, 24-hour urinary betaine and N,N-dimethylglycine measurements were consistent with normal or enhanced remethylation of homocysteine by betaine: homocysteine methyltransferase in the 13 patients tested. When treated daily with choline and betaine, pyridoxine, or folic acid, there was a normalization of the postmethionine plasma homocysteine level in 16 of 19 patients. Our results indicate that mild homocysteinemia in premature vascular disease may be caused by either a folate deficiency or deficiencies in cystathionine beta-synthase activity. It does not necessarily involve deficiencies of either 5-methyltetrahydrofolate:homocysteine methyltransferase or betaine:homocysteine methyltransferase. Effective treatment regimens are also defined.
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PMID:Disordered methionine/homocysteine metabolism in premature vascular disease. Its occurrence, cofactor therapy, and enzymology. 836 9

Hyperhomocysteinaemia is associated with an increased risk of atherosclerotic vascular disease and thromboembolism, in both men and women. A variety of conditions can lead to elevated homocysteine levels, but the relation between high levels and vascular disease is present regardless of the underlying cause. Pooled data from a large number of studies demonstrate that mild hyperhomocysteinaemia after a standard methionine load is present in 21% of young patients with coronary artery disease, in 24% of patients with cerebrovascular disease, and in 32% of patients with peripheral vascular disease. From such data an odds ratio of 13.0 (95% confidence interval 5.9 to 28.1), as an estimate of the relative risk of vascular disease at a young age, can be calculated in subjects with an abnormal response to methionine loading. Furthermore, mild hyperhomo-cysteinaemia can lead to a two- or three-fold increase in the risk of recurrent venous thrombosis. Elevated homocysteine levels can be reduced to normal in virtually all cases by simple and safe treatment with vitamin B6, folic acid, and betaine, each of which is involved in methionine metabolism. A clinically beneficial effect of such an intervention, currently under investigation, would make large-scale screening for this risk factor mandatory.
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PMID:Homocystinuria: what about mild hyperhomocysteinaemia? 937 15

Mild to moderate homocysteinemia in women has been associated with an increased frequency of pregnancies with neural tube defects (NTD). Homocysteinemia is also an independent risk factor for premature vascular disease. In addition to folic acid, supplemental Vitamin B12, Vitamin B6 and betaine may normalize homocysteine metabolism, decrease the risk for NTD formation, and correct related metabolic imbalances in children with NTD. By means of automated amino acid analysis, we assessed total non-fasting homocysteine and methionine in plasma from 24 children with myelomeningocele. This study group (mean age 10.5 +/- 4.9 years) included 12 girls and 12 boys randomly selected from our Birth Defects Clinic. Homocysteine concentrations in our patients (4.7 +/- 1.8 mumol/L) did not differ from those of 20 randomly selected child controls (5.1 +/- 2.6 mumol/L). The mean homocysteine concentration for 36 adult controls (9.3 +/- 3.0 mumol/L) was significantly higher than the mean for either group of children (p < 0.0001). Linear regression analysis revealed negative correlation of total plasma homocysteine with serum folate (r = -0.53; p = 0.01), but not of homocysteine with either methionine or B12. Plasma methionine concentrations from our patients did not differ from adult reference values. Elevated homocysteine in some mothers of children with NTD has been attributed to defective methylation of homocysteine. These preliminary results do not indicate such a defect in the children themselves. A more comprehensive study of homocysteine, methionine and related metabolites in children with NTD and age-matched controls will be required to determine the clinical significance of these findings.
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PMID:Plasma homocysteine and methionine concentrations in children with neural tube defects. 900 10

Homocysteine is an intermediate compound formed during metabolism of methionine. The results of many recent studies have indicated that elevated plasma levels of homocyst(e)ine are associated with increased risk of coronary atherosclerosis, cerebrovascular disease, peripheral vascular disease, and thrombosis. The plasma level of homocyst(e)ine is dependent on genetically regulated levels of essential enzymes and the intake of folic acid, vitamin B6 (pyridoxine), and vitamin B12 (cobalamin). Impaired renal function, increased age, and pharmacologic agents (e.g. nitrous oxide, methotrexate) can contribute to increased levels of homocyst(e)ine. Plausible mechanisms by which homocyst(e)ine might contribute to atherogenesis include promotion of platelet activation and enhanced coagulability, increased smooth muscle cell proliferation, cytotoxicity, induction of endothelial dysfunction, and stimulation of LDL oxidation. Levels of homocysteine can be reduced with pharmacologic doses of folic acid, pyridoxine, vitamin B12, or betaine, but further research is required to determine the efficacy of this intervention in reducing morbidity and mortality associated with atherosclerotic vascular disease.
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PMID:Homocyst(e)ine: an important risk factor for atherosclerotic vascular disease. 912 8

The sulfur-containing amino acid, homocysteine, is formed from the essential amino acid methionine, and a number of B vitamins are involved in methionine metabolism. Pyridoxine, vitamin B6, is a cofactor for cystathionine beta synthase, which mediates the transformation of homocysteine to cystathionine, the initial step in the transsulfuration pathway and the urinary excretion of sulfur. In a normal diet there is conservation of the carbon skeleton, and about 50% of the homocysteine formed is remethylated to methionine via steps that require folic acid and vitamin B12. A deficiency of any of these three vitamins leads to modest homocyst(e)ine elevation, as does diminished renal function, both of which are common in the elderly. It is also established that homocyst(e)ine elevation of this order is associated with increased cardiovascular risk but is also associated with most established risk factors, although it is thought to be an independent contributor. In the inborn error of metabolism homocystinuria due to cystathionine beta synthase deficiency there is greatly increased circulating homocyst(e)ine and a clear association with precocious vascular disease. In about 50% of these patients there is a vascular event before the age of 30 years. The homocysteine-induced adverse vascular changes appear to result from endothelial and smooth muscle cell effects and increased thrombogenesis. We have documented a highly significant reduction in the occurrence of vascular events during 539 patient years of treatment in 32 patients with cystathionine beta synthase deficiency (mean age 30 years, range 9-66 years) by aggressive homocyst(e)ine lowering with pyridoxine, folic acid, and B12 (p = 0.0001). The 15 pyridoxine nonresponsive patients also received oral betaine. Although a cause and effect relationship is postulated for the increased cardiovascular risk associated with mild homocysteine elevation, a common cause of this elevation is the methylenetetrahydrofolate reductase C677T mutation. Homozygotes occur in about 11% of Caucasian populations. However, the mutation is not associated with increased coronary risk. Since mild homocysteine elevation is easily normalized by B vitamin supplementation, usually with folic acid, it remains for controlled clinical trials of this inexpensive therapy to determine whether normalizing mild homocyst(e)ine elevation reduces cardiovascular risk.
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PMID:B vitamins and homocysteine in cardiovascular disease and aging. 992 44

Homocysteine is a sulfur amino acid whose metabolism stands at the intersection of two pathways: remethylation to methionine, which requires folate and vitamin B12 (or betaine in an alternative reaction); and transsulfuration to cystathionine, which requires pyridoxal-5'-phosphate. The two pathways are coordinated by S-adenosylmethionine, which acts as an allosteric inhibitor of the methylenetetrahydrofolate reductase reaction and as an activator of cystathionine beta-synthase. Hyperhomocysteinemia, a condition that recent epidemiological studies have shown to be associated with increased risk of vascular disease, arises from disrupted homocysteine metabolism. Severe hyperhomocysteinemia is due to rare genetic defects resulting in deficiencies in cystathionine beta synthase, methylenetetrahydrofolate reductase, or in enzymes involved in methyl-B12 synthesis and homocysteine methylation. Mild hyperhomocysteinemia seen in fasting conditions is due to mild impairment in the methylation pathway (i.e. folate or B12 deficiencies or methylenetetrahydrofolate reductase thermolability). Post-methionine-load hyperhomocysteinemia may be due to heterozygous cystathionine beta-synthase defect or B6 deficiency. Early studies with nonphysiological high homocysteine levels showed a variety of deleterious effects on endothelial or smooth muscle cells in culture. More recent studies with human beings and animals with mild hyperhomocysteinemia provided encouraging results in the attempt to understand the mechanism that underlies this relationship between mild elevations of plasma homocysteine and vascular disease. The studies with animal models indicated the possibility that the effect of elevated homocysteine is multifactorial, affecting both the vascular wall structure and the blood coagulation system.
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PMID:Homocysteine metabolism. 1044 23

The positive correlation existing between hyperhomocyst(e)inemia [HH(e)] and vascular disease has firmly been established through data derived from numerous epidemiological and experimental observations. Clinical data corroborate that homocysteine (Hcy) is an independent risk factor for coronary, cerebral and peripheral arterial occlusive disease or peripheral venous thrombosis. Hcy is a sulfhydryl-containing amino acid that is formed by the demethylation of methionine. It is normally catalyzed to cystathionine by cystathionine beta-synthase a pyridoxal phosphate-dependent enzyme. Hcy is also remethylated to methionine by 5-methyltetrahydrofolate-Hcy methyltransferase (methionine synthase), a vitamin B12 dependent enzyme and by betaine-Hcy methyltransferase. Nutritional status such as vitamin B12, or vitamin B6, or folate deficiencies and genetic defects such as cystathionine beta-synthase or methylene-tetrahydrofolate reductase may contribute to increasing plasma homocysteine levels. The pathogenesis of Hcy-induced vascular damage may be multifactorial, including direct Hcy damage to the endothelium, stimulation of proliferation of smooth muscle cells, enhanced low-density lipoprotein peroxidation, increase of platelet aggregation, and effects on the coagulation system. Besides adverse effects on the endothelium and vessel wall, Hcy exert a toxic action on neuronal cells trough the stimulation of N-methyl-D-aspartate (NMDA) receptors. Under these conditions, neuronal damage derives from excessive calcium influx and reactive oxygen generation. This mechanism may contribute to the cognitive changes and markedly increased risk of cerebrovascular disease in children and young adults with homocystunuria. Moreover, during stroke, in hiperhomocysteinemic patients, disruption of the blood-brain barrier results in exposure of the brain to near plasma levels of Hcy. The brain is exposed to 15-50 microM H(e). Thus, the neurotoxicity of Hcy acting through the overstimulation of NMDA receptors could contribute to neuronal damage in homocystinuria and HH(e). Since HH(e) is associated with certain neurodegeneratives diseases, in the present review, the molecular mechanisms involved in neurotoxicity due to Hcy are discussed.
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PMID:[Hyperhomocysteinemia: atherothrombosis and neurotoxicity]. 1079 37

Betaine-homocysteine S-methyltransferase (BHMT) is one of the enzymes involved in the branch point metabolism of homocysteine. Elevated levels of plasma homocysteine may be a risk factor for the development of vascular disease; however, whether BHMT has a significant role in the regulation of plasma levels of homocysteine remains to be determined. As a prelude to creating a mouse strain deficient in BHMT activity, we screened a lambda library containing mouse SvJ 129 genomic DNA for the mouse BHMT gene using random probes made from the human cDNA. One genomic isolate was completely sequenced and found to encode an intronless BHMT pseudogene (mBHMT-ps). mBHMT-ps was then used as a template for the generation of random probes that were used to screen a BAC library containing mouse 129 Sv/Ev genomic DNA. In order to discriminate between pseudogenes and the authentic BHMT gene, a secondary PCR-based screen was employed which used primers designed from the pseudogene sequence that would predictably amplify across introns. Using this strategy, we isolated six mouse genomic clones that tested positive for the presence of all seven introns characteristic of the human gene, and the BHMT gene of one clone was completely sequenced. Like the human BHMT gene, the mouse gene spans 21kb and is encoded by eight exons interrupted by seven introns. The structure of the mouse BHMT gene is described herein as well as the 5'-flanking region of the gene adjacent to exon 1, which we demonstrate is capable of conferring basal promoter activity in Chinese Hamster Ovary cells.
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PMID:Isolation and characterization of a mouse betaine-homocysteine S-methyltransferase gene and pseudogene. 1085 76


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