Plasma homocysteine, vitamin B12 and folate in Alzheimer's patients and healthy Arabs in Israel.

High plasma homocysteine (tHcy) is a risk factor for cardiovascular disease and stroke and Alzheimer's disease (AD). An inverse relationship has been reported between tHcy and plasma B12 and folate levels. Seventy-nine AD patients and 156 controls from three Arab villages in northern Israel participated. Plasma tHcy, B12 and folate levels were determined. Data were analyzed using univariate statistical tests and logistical regression with confounders. tHcy was significantly higher in AD patients (20.6+/-8.7 micromol/l) than in controls (16.4+/-6.5 micromol/l) (p=0.03) after correction for year of birth, gender and smoking status. Plasma B12 (322.9+/-136.0/350.5+/-175.3 pmol/l) and plasma folate (4.5+/-3.8/4.9+/-2.6 nmol/l) levels did not differ significantly between AD patients and controls. Subjects in the highest tHcy tertile or in the lowest B12 and folate tertiles did not have greater risk to develop AD. In this population residing in Arab villages in northern Israel, tHcy levels were significantly higher among AD patients than in controls. Plasma B12 and folate levels were lower among cases but were not significant. There was not a significant association between plasma tHcy, B12 and folate levels in controls or AD patients. High levels of tHcy may suggest the need for folate and vitamin B12 supplementation in this population.

Plasma total homocysteine levels, dietary vitamin B6 and folate intake in AD and healthy aging.

PURPOSE: To study the association between Alzheimer s disease (AD) and plasma total homocysteine (tHcy), dietary folate and vitamin B6. METHODS: 64 AD patients were matched by gender, age, and smoking status to 64 healthy controls. tHcy was determined using an automated immunoassay. Dietary patterns for three age periods (20-39, 40-59, and 60 + yrs) were assessed using a questionnaire adapted from the Block Health Habits and History Questionnaire. Respondents (cases by proxy) reported food frequencies, which were translated into estimated daily nutrient intakes. APOE genotype, cognitive performance (CDR, MMSE), blood lipids, and albumin were obtained for patients and controls. RESULTS: tHcy did not differ significantly between controls (11.5 +/- 3.7 mmol/L) and AD patients (12.3 +/- 4.3 mmol/L)(p=0.25). tHcy levels were not related in AD patients or controls to education, CDR, MMSE, blood lipids, albumin or ApoE genotype (p>0.15). There was a negative correlation between plasma tHcy and triglyceride levels in AD patients (p=0.023), but not in controls. AD patients consumed significantly less dietary vitamin B6 (p=0.05) and folate (p=0.001) after age 60 than controls. CONCLUSIONS: Although plasma tHcy levels were higher in cases than controls, this difference was not significant. tHcy levels were not related to cognitive status. Plasma tHcy was inversely correlated with triglyceride levels in AD patients but not in controls.

Relative roles of albumin and ceruloplasmin in the formation of homocystine, homocysteine-cysteine-mixed disulfide, and cystine in circulation.

Disulfide forms of homocysteine account for >98% of total homocysteine in plasma from healthy individuals. We recently reported that homocysteine reacts with albumin-Cys(34)-S-S-cysteine to form homocysteine-cysteine mixed disulfide and albumin-Cys(34) thiolate anion. The latter then reacts with homocystine or homocysteine-cysteine mixed disulfide to form albumin-bound homocysteine (Sengupta, S., Chen, H., Togawa, T., DiBello, P. M., Majors, A. K., Büdy, B., Ketterer, M. E., and Jacobsen, D. W. (2001) J. Biol. Chem. 276, 30111-30117). We now extend these studies to show that human albumin, but not ceruloplasmin, mediates the conversion of homocysteine to its low molecular weight disulfide forms (homocystine and homocysteine-cysteine mixed disulfide) by thiol/disulfide exchange reactions. Only a small fraction of homocystine is formed by an oxidative process in which copper bound to albumin, but not ceruloplasmin, mediates the reaction. When copper is removed from albumin by chelation, the overall conversion of homocysteine to its disulfide forms is reduced by only 20%. Ceruloplasmin was an ineffective catalyst of homocysteine oxidation, and immunoprecipitation of ceruloplasmin from human plasma did not inhibit the capacity of plasma to mediate the conversion of homocysteine to its disulfide forms. In contrast, ceruloplasmin was a highly efficient catalyst for the oxidation of cysteine and cysteinylglycine to cystine and bis(-S-cysteinylglycine), respectively. However, when thiols (cysteine and homocysteine) that are disulfide-bonded to albumin-Cys(34) are removed by treatment with dithiothreitol to form albumin-Cys(34)-SH (mercaptalbumin), the conversion of homocysteine to its disulfide forms is completely blocked. In conclusion, albumin mediates the formation of disulfide forms of homocysteine by thiol/disulfide exchange, whereas ceruloplasmin converts cysteine to cystine by copper-dependent autooxidation.

Homocysteine induces expression and secretion of monocyte chemoattractant protein-1 and interleukin-8 in human aortic endothelial cells: implications for vascular disease.

BACKGROUND: Proinflammatory cytokines play key roles in atherogenesis and disease progression. Because hyperhomocysteinemia is an independent risk factor for cardiovascular disease, we hypothesized that homocysteine could be atherogenic by altering the expression of specific cytokines in vascular endothelial cells. METHODS AND RESULTS: Northern blot and RNase protection assays showed that DL-homocysteine induced mRNA expression of the proinflammatory cytokines monocyte chemoattractant protein-1 (MCP-1) and interleukin-8 (IL-8) in cultured human aortic endothelial cells (HAECs). Homocysteine had no effect on expression of other cytokines, namely tumor necrosis factor-alpha, granulocyte-macrophage colony-stimulating factor, interleukin-1beta, and transforming growth factor-beta. MCP-1 mRNA expression increased 1 hour after homocysteine treatment, reached a maximum within 2 to 4 hours, and declined to basal levels over the next 24 hours. Induction of mRNA expression for both chemokines was observed with as little as 10 micromol/L DL-homocysteine, and maximal expression was achieved with 50 micromol/L DL-homocysteine. Homocysteine also triggered the release of MCP-1 and IL-8 protein from HAECs into the culture medium. The induction was specific for homocysteine, because equimolar concentrations of L-homocystine, L-cysteine, and L-methionine had no effect on mRNA levels and protein release. Furthermore, L-homocysteine induced chemokine expression, but D-homocysteine did not, thus demonstrating enantiomeric specificity. The culture medium from homocysteine-treated HAECs promoted chemotaxis in human peripheral blood monocytes and U937 cells. Anti-human recombinant MCP-1 antibody blocked the migration. CONCLUSIONS: Pathophysiological levels of L-homocysteine alter endothelial cell function by upregulating MCP-1 and IL-8 expression and secretion. This suggests that L-homocysteine may contribute to the initiation and progression of vascular disease by promoting leukocyte recruitment.

Albumin thiolate anion is an intermediate in the formation of albumin-S-S-homocysteine.

An elevated concentration of plasma total homocysteine is an independent risk factor for cardiovascular disease. Greater than 80% of circulating homocysteine is covalently bound to plasma protein by disulfide bonds. It is known that albumin combines with cysteine in circulation to form albumin-Cys(34)-S-S-Cys. Studies are now presented to show that the formation of albumin-bound homocysteine proceeds through the generation of an albumin thiolate anion. Incubation of human plasma with l-(35)S-homocysteine results in the association of >90% of the protein-bound (35)S-homocysteine with albumin as shown by nonreduced SDS-polyacrylamide gel electrophoresis. Treatment of the complex with beta-mercaptoethanol results in near quantitative release of the bound l-(35)S-homocysteine, demonstrating that the binding of homocysteine to albumin is through a disulfide bond. Furthermore, using an in vitro model system to study the mechanisms of this disulfide bond formation, we show that homocysteine binds to albumin in two steps. In the first step homocysteine rapidly displaces cysteine from albumin-Cys(34)-S-S-Cys, forming albumin-Cys(34) thiolate anion and homocysteine-cysteine mixed disulfide. In the second step, albumin thiolate anion attacks homocysteine-cysteine mixed disulfide to yield primarily albumin-Cys(34)-S-S-Hcy and to a much lesser extent albumin-Cys(34)-S-S-Cys. The results clearly suggest that when reduced homocysteine enters circulation, it attacks albumin-Cys(34)-S-S-Cys to form albumin-Cys(34) thiolate anion, which in turn, reacts with homocysteine-cysteine mixed disulfide or homocystine to form albumin-bound homocysteine.

Glutathione protects chemokine-scavenging and antioxidative defense functions in human RBCs.

Oxidant stress, in vivo or in vitro, is known to induce oxidative changes in human red blood cells (RBCs). Our objective was to examine the effect of augmenting RBC glutathione (GSH) synthesis on 1) degenerative protein loss and 2) RBC chemokine- and free radical-scavenging functions in the oxidatively stressed human RBCs by using banked RBCs as a model. Packed RBCs were stored up to 84 days at 1-6 degrees C in Adsol or in the experimental additive solution (Adsol fortified with glutamine, glycine, and N-acetyl-L-cysteine). Supplementing the conventional additive with GSH precursor amino acids improved RBC GSH synthesis and maintenance. The rise in RBC gamma-glutamylcysteine ligase activity was directly proportional to the GSH content and inversely proportional to extracellular homocysteine concentration, methemoglobin formation, and losses of the RBC proteins band 3, band 4.1, band 4.2, glyceraldehyde-3-phosphate dehydrogenase, and Duffy antigen (P < 0.01). Reduced loss of Duffy antigen correlated well with a decrease in chemokine RANTES (regulated upon activation, normal T-cell expressed, and secreted) concentration. We conclude that the concomitant loss of GSH and proteins in oxidatively stressed RBCs can compromise RBC scavenging function. Upregulating GSH synthesis can protect RBC scavenging (free radical and chemokine) function. These results have implications not only in a transfusion setting but also in conditions like diabetes and sickle cell anemia, in which RBCs are subjected to chronic/acute oxidant stresses.

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.

Serum glutathione in adolescent males predicts parental coronary heart disease.

BACKGROUND: Traditional risk factors account for only half of the morbidity and mortality from coronary heart disease (CHD). There is substantial evidence that oxidative injury plays a major role in the atherosclerotic process. Thus, antioxidants may protect against development of atherosclerosis. Glutathione, an intracellular tripeptide with antioxidant properties, may be protective. METHODS AND RESULTS: This case-control study compared total serum glutathione (tGSH) in 81 adolescent male offspring of parents with premature CHD (ie, before 56 years of age) and 78 control male offspring of parents without known or suspected CHD. Case offspring had significantly lower tGSH than control offspring. In multiple logistic regression with parental CHD status as the dependent variable, age entered as a covariate, and other CHD risk factors competing to enter the model as significant independent predictor variables, LDL cholesterol (odds ratio [OR], 2.15 [units=1.5 SD]; 95% CI, 1.21 to 3.82), tGSH (OR, 0.40; 95% CI, 0.22 to 0.71), HDL cholesterol (OR, 0.42; 95% CI, 0.22 to 0.78), and total serum homocysteine (OR, 2.6; 95% CI, 1.35 to 5.02) entered the model as significant predictors of parental CHD status. CONCLUSIONS: Low tGSH in adolescent boys is a significant independent predictor of parental CHD, in addition to elevated LDL cholesterol, low HDL cholesterol, and elevated total serum homocysteine concentrations.

Protein and lipid oxidation of banked human erythrocytes: role of glutathione.

In banked human erythrocytes (RBCs), biochemical and functional changes are accompanied with vesiculation and reduced in vivo survival. We hypothesized that some of these changes might have resulted from oxidative modification of membrane lipids, proteins, or both as a result of atrophy of the antioxidant defense system(s). In banked RBCs, we observed a time-dependent increase in protein clustering, especially band 3; carbonyl modification of band 4.1; and malondialdehyde, a lipid peroxidation product. Examination of the antioxidative defense system showed a time-dependent decline in glutathione (GSH) concentration and glutathione-peroxidase (GSH-PX) activity, with a concomitant increase in extracellular GSH, cysteine, and homocysteine, and unchanged catalase activity. When subjected to acute oxidant stress by exposure to ferric/ascorbic acid or tert-butylhydroperoxide (tert-BHT), catalase activity showed a steeper decline compared with GSH-PX. The results demonstrate that GSH and GSH-PX appear to provide the primary antioxidant defense in stored RBCs, and their decline, concurrent with an increase in oxidative modifications of membrane lipids and proteins, may destabilize the membrane skeleton, thereby compromising RBC survival.

Normalization of hyperhomocysteinemia with L-thyroxine in hypothyroidism.

BACKGROUND: Hyperhomocysteinemia is an independent risk factor for coronary, peripheral, and cerebrovascular disease. Elevated plasma homocysteine levels were described in a preliminary report on primary hypothyroidism. OBJECTIVE: To determine whether restoration of euthyroidism by L-thyroxine replacement therapy would reduce or normalize plasma homocysteine levels. DESIGN: Prospective cohort study. SETTING: Outpatient endocrinology department of a tertiary center. PATIENTS: 14 patients (10 women and 4 men; 25 to 77 years of age): 4 with newly diagnosed chronic (Hashimoto) hypothyroidism and 10 who had been rendered acutely hypothyroid (thyroid-stimulating hormone level > 25 mU/L) by total thyroidectomy for thyroid carcinoma. MEASUREMENTS: Total plasma homocysteine levels were measured at baseline and 3 to 9 months later, after euthyroidism had been attained by L-thyroxine replacement therapy. RESULTS: Median baseline plasma homocysteine levels in both sexes (women, 11.65 micromol/L [range, 7.2 to 26.5 micromol/L]; men, 15.1 micromol/L [range, 14.1 to 16.3 micromol/L]) were higher (P = 0.002) than those in healthy female (n = 35) and male (n = 36) volunteers (women, 7.52 micromol/L [range, 4.3 to 14.0 micromol/L]; men, 8.72 micromol/L [range, 5.94 to 14.98 micromol/L]). Eight patients (57%) had baseline plasma homocysteine levels that exceeded the upper limit of sex-specific reference ranges. Upon attainment of euthyroidism, all patients had a diminution in plasma homocysteine levels. The median overall change of -5.5 micromol/L (range, -15.4 to -1.8 micromol/L) corresponds to a difference of -44% (range, -58% to -13%) (P < 0.001). Homocysteine levels returned to normal in 7 of the 8 patients with elevated pretreatment values. CONCLUSIONS: Hypothyroidism may be a treatable cause of hyperhomocysteinemia, and elevated plasma homocysteine levels may be an independent risk factor for the accelerated atherosclerosis seen in primary hypothyroidism.

Homocysteine metabolism in cardiovascular cells and tissues: implications for hyperhomocysteinemia and cardiovascular disease.

We have determined the activity and protein levels of CBS in a number of cardiovascular cells and tissues by direct enzyme assay and Western blot analysis, respectively. We have also determined the activity of BHMT in these same tissues and cells and have come to the conclusion that neither enzyme is expressed. This results suggests that in the human cardiovascular system homocysteine metabolism is limited to the remethylation pathway catalyzed by MS. Thus, hyperhomocysteinemia in conjunction with a limited metabolic capacity for homocysteine in the cardiovascular system could result in cellular dysfunction.

Prevalence and determinants of hyperhomocysteinemia in hemodialysis and peritoneal dialysis.

BACKGROUND: Hyperhomocysteinemia is an independent risk factor for atherosclerotic complications in patients with end-stage renal disease, although the mechanisms remain unclear. The major determinants of plasma homocysteine concentration are usually folate, vitamin B12, pyridoxal 5'-phosphate (vitamin B6), and glomerular filtration rate. METHODS: We measured factors, including plasma folate, vitamin B12, vitamin B6, creatinine, as well as the dose and duration of dialysis, that might affect plasma homocysteine concentrations in 130 patients on hemodialysis (HD) and compared these observations with those in 46 patients on peritoneal dialysis (PD). Independent determinants of total homocysteine were identified using a multiple logistical regression analysis. RESULTS: Total homocysteine values averaged 29.8 mumol/liter in HD patients, significantly higher than the mean value of 19.9 mumol/liter observed in patients on PD (P < 0.001). The prevalence of hyperhomocysteinemia was 90.8% among HD patients, significantly higher than the prevalence of 67.4% among PD patients. Folate values in HD patients averaged 45.5 nmol/liter and were significantly lower than in PD patients (104.2 nmol/liter, P < 0.001). For patients on HD, the only determinant of total homocysteine concentration was plasma folate (r = -0.31, P < 0.001). In contrast, for PD patients, total homocysteine did not correlate with plasma folate, vitamin B12, or vitamin B6. CONCLUSIONS: Hyperhomocysteinemia is more prevalent and intense in HD patients compared with those on PD. The homocysteine response may become refractory to excess folate supplementation in PD patients.

Neutrophil nuclear segmentation in mild cobalamin deficiency: relation to metabolic tests of cobalamin status and observations on ethnic differences in neutrophil segmentation.

Neutrophil hypersegmentation is considered the most sensitive peripheral blood cell marker of cobalamin deficiency. However, its diagnostic value in the mild deficiency states that accompany most low cobalamin levels and its relation to metabolic test of cobalamin status are unknown. The authors compared neutrophil lobe averages and percent neutrophils with 5 or more lobes (%5+ lobes) in 169 subjects with their mean corpuscular volume (MCV) and serum cobalamin, methylmalonic acid (MMA), homocysteine, and folate levels and, in 65 cases, with the deoxyuridine suppression test (dUST). Only 9 subjects had hypersegmentation by lobe average and 20 subjects by %5+ lobes. They were not more often cobalamin-deficient than subjects without hypersegmentation. Moreover, only one of 34 subjects with dUST results diagnostic for cobalamin deficiency had neutrophil hypersegmentation. Both indices of neutrophil segmentation in the 169 subjects correlated significantly with homocysteine levels. They also showed weak inverse correlation with cobalamin levels, but did not correlate with MMA, folate, or MCV values. Cobalamin therapy for 6 months did not significantly change neutrophil lobe averages in 35 subjects with mild deficiency, compared with 8 nondeficient controls, and only marginally improved the %5+ lobes. A surprising, incidental observation was that blacks had significantly greater neutrophil segmentation by both criteria than did whites and others. This difference was unrelated to cobalamin or folate status. Our results indicate that dUST abnormalities precede all morphologic changes of deficiency, including hypersegmentation. Although a tendency exists for neutrophil segmentation to increase very slightly as some serum values, especially homocysteine, start to worsen in mild cobalamin deficiency, the metabolic changes precede overt hypersegmentation. Neutrophil nuclear segmentation is insufficiently sensitive in relation to metabolic evidence of deficiency to be used as a clinical tool in the diagnosis of mild cobalamin deficiency.

Comparison of the deoxyuridine suppression test with serum levels of methylmalonic acid and homocysteine in mild cobalamin deficiency.

Both the deoxyuridine suppression test (dUST) and the cobalamin-dependent metabolites, methylmalonic acid (MMA) and homocysteine, are valuable tools for identifying clinical cobalamin deficiency. Examination of these metabolic changes in mild or marginal deficiency can provide useful comparisons of diagnostic frequencies and sensitivities and help define the sequence of metabolic changes in early deficiency. These tests were therefore compared directly with each other in 50 patients with low cobalamin levels and few or no obvious signs of deficiency. Serum homocysteine (P=0.0003) and MMA levels (P=0.0004) correlated with dUST results. However, the dUST results were abnormal significantly more often (38/50 patients) when matched against levels of homocysteine (25 abnormal results of 50; P=0.007) or MMA (20/50; P=0.008). Abnormalities of one or both serum metabolite levels (30/50 patients) occurred almost as often as dUST abnormalities (P=0.059). Metabolite levels, even when originally 'normal', fell with cobalamin therapy in many cases. The results indicate that both the dUST and serum metabolite levels become abnormal before macrocytic anaemia develops in mild cobalamin deficiency. The dUST appears to be most frequently abnormal of the tests; metabolite levels appear to rise almost concurrently but they do not become diagnostically abnormal as soon.

Homocysteine and coronary atherosclerosis.

Homocysteine is increasingly recognized as a risk factor for coronary artery disease. An understanding of its metabolism and of the importance of vitamins B6 and B12 and folate as well as enzyme levels in its regulation will aid the development of therapeutic strategies that, by lowering circulating concentrations, may also lower risk. Possible mechanisms by which elevated homocysteine levels lead to the development and progression of vascular disease include effects on platelets, clotting factors and endothelium. This review presents the clinical and basic scientific evidence supporting the risk and mechanisms of vascular disease associated with elevated homocysteine concentrations as well as the results of preliminary therapeutic trials.

Lipoprotein (a), homocysteine, and hypercoagulable states in young men with premature peripheral atherosclerosis: a prospective, controlled analysis.

PURPOSE: Elevated lipoprotein (a) (Lp[a]) lipoprotein, total homocysteine, and hypercoagulable states (HCS) have all been implicated as risk factors for premature-onset atherosclerosis. This study was performed to determine the prevalence of these abnormalities in young men with chronic lower extremity ischemia (peripheral vascular disease [PVD]) and to determine their relative strengths as risk factors for premature peripheral atherosclerosis. METHODS: We analyzed 50 young white men (aged 45 years or younger at onset of symptoms) and compared them with 45 age-matched white male control subjects. RESULTS: Atherosclerotic risk factors were similar in both groups. The mean (+/- SEM) Lp(a) lipoprotein level was 36 +/- 6 mg/dl among the study patients, compared with 14 +/- 2 mg/dl among control subjects (p = 0.02, Mann-Whitney). Twenty (40%) study patients and seven (16%) control subjects had Lp(a) lipoprotein levels of 30 mg/dl or greater (atherosclerotic risk threshold) (p = 0.01, odds ratio = 3.62, confidence interval (CI) 1.4 to 9.5). Positive HCS panels (antiphospholipid antibodies or deficiencies in antithrombin III, protein C, or protein S) were nearly twice as prevalent in study patients (n = 15, 30%) as in controls (n = 8, 18%), but this difference did not achieve statistical significance. The mean total plasma homocysteine level among the study patients was 15.9 +/- 0.9 mumol/L, which was not significantly different from the mean control value of 14.7 +/- 0.7 mumol/L. Lp(a) lipoprotein was related to risk of premature PVD through a linear logistic relationship (p = 0.003, odds ratio per each 1 mg/dl Lp(a) change was 1.03, CI 1.0 to 1.1). Multivariate analysis with stepwise logistic regression selected two variables: Lp(a) lipoprotein > or = 30 mg/dl (p = 0.01, odds ratio = 3.6, CI 1.3 to 9.9) and family history (p = 0.07, odds ratio = 2.2, CI 0.9 to 5.3). Tests of interaction demonstrated no effect between Lp(a) lipoprotein, HCS, and homocysteine. CONCLUSIONS: Lp(a) lipoprotein of 30 mg/dl or greater is an independent risk factor for premature peripheral atherosclerosis in men. None of the other examined variables exhibited a significant association with premature PVD.

Determination of total serum sulfite by HPLC with fluorescence detection.

An estimated 500,000 individuals in the US, mostly steroid-dependent asthmatics, suffer severe adverse reactions to sulfites in foods, beverages, and pharmaceutical products. In an attempt to understand the pathogenesis of sulfite hypersensitivity, we have developed an assay for the determination of total serum sulfite by utilizing: (a) reductive release of serum protein-bound sulfite; (b) derivatization of free sulfite with monobromobimane; (c) separation of sulfite-bimane from thiol-bimanes by reversed-phase HPLC; and (d) quantitation of sulfite-bimane by fluorescence detection. The detection limit of this assay was 0.44 mumol/L serum sulfite. The intra- and interassay CVs for total serum sulfite at 5.4 mumol/L were 8.1% and 22.0%, respectively. The standard addition method was used to determine total serum sulfite in normal subjects. More than 70 samples were prepared in 2-3 h, followed by automated overnight analysis. The mean concentrations (+/- SD) of total serum sulfite in female (n = 41) and male (n = 35) donors were 4.63 +/- 2.33 and 5.16 +/- 2.68 mumol/L, respectively (not statistically significant: P = 0.368). The combined mean concentration of total sulfite in both sexes was 4.87 +/- 2.49 mumol/L. There was no correlation between total serum sulfite and total serum cysteine, cysteinylglycine, homocysteine, subject age, serum cobalamin, or serum folic acid. The reference range (mean +/- 2 SD) for total serum sulfite in normal subjects is 0-9.85 mumol/L.

The dynamics of cobalamin utilization in L-1210 mouse leukemia cells: a model of cellular cobalamin metabolism.

The uptake and metabolism of cobalamin (Cbl) has been studied in L-1210 murine leukemia cells propagating in vitro. Extracellular Cbl (protein bound and free) and intracellular Cbl (protein bound and free) were determined after culturing L-1210 cells in the presence of [57Co]cyanocobalamin (CN-Cbl) bound to transcobalamin II (transcobalamin, TC). The intracellular pool of free [57Co]Cbl increased during the first 24 h of culture and a substantial fraction of this free pool was effluxed from the cell to the medium. Upon depletion of extracellular TC-[57Co]CN-Cbl, the intracellular concentration of free Cbl decreased as did the efflux of Cbl to the medium. Internalized [57Co]CN-Cbl was converted to hydroxocobalamin (OH-Cbl), methylcobalamin (Me-Cbl) and 5'-deoxyadenosylcobalamin. These Cbl forms were found in both soluble (cytoplasmic) and insoluble (membrane) fractions. Intracellular protein-bound [57Co]Cbl fractionated with methionine synthase (MS) and methylmalonyl-CoA mutase (MU) activity. The major form of Cbl associated with the two enzymes was OH-Cbl. Cells propagated in medium containing N5-methyltetrahydrofolate and homocysteine showed a substantial increase in MS activity which paralleled the increase in the intracellular concentration of Me-Cbl and the Cbl bound to the enzyme.