Jürgen Geisel

DACH-LIGA Homocystein (German, Austrian and Swiss Homocysteine Society): Consensus Paper on the Rational Clinical Use of Homocysteine, Folic Acid and B-Vitamins in Cardiovascular and Thrombotic Diseases: Guidelines and Recommendations

Abstract About half of all deaths are due to cardiovascular disease and its complications. The economic burden on society and the healthcare system from cardiovascular disability, complications, and treatments is huge and getting larger in the rapidly aging populations of developed countries. As conventional risk factors fail to account for part of the cases, homocysteine, a “new” risk factor, is being viewed with mounting interest. Homocysteine is a sulfur-containing intermediate product in the normal metabolism of methionine, an essential amino acid. Folic acid, vitamin B12, and vitamin B6 deficiencies and reduced enzyme activities inhibit the breakdown of homocysteine, thus increasing the intracellular homocysteine concentration. Numerous retrospective and prospective studies have consistently found an independent relationship between mild hyperhomocysteinemia and cardiovascular disease or all-cause mortality. Starting at a plasma homocysteine concentration of approximately 10 μmol/l, the risk increase follows a linear dose-response relationship with no specific threshold level. Hyperhomocysteinemia as an independent risk factor for cardiovascular disease is thought to be responsible for about 10% of total risk. Elevated plasma homocysteine levels (>12 μmol/l; moderate hyperhomocysteinemia) are considered cytotoxic and are found in 5 to 10% of the general population and in up to 40% of patients with vascular disease. Additional risk factors (smoking, arterial hypertension, diabetes, and hyperlipidemia) may additively or, by interacting with homocysteine, synergistically (and hence over-proportionally) increase overall risk. Hyperhomocysteinemia is associated with alterations in vascular morphology, loss of endothelial anti-thrombotic function, and induction of a procoagulant environment. Most known forms of damage or injury are due to homocysteinemediated oxidative stress. Especially when acting as direct or indirect antagonists of cofactors and enzyme activities, numerous agents, drugs, diseases, and lifestyle factors have an impact on homocysteine metabolism. Folic acid deficiency is considered the most common cause of hyperhomocysteinemia. An adequate intake of at least 400 μg of folate per day is difficult to maintain even with a balanced diet, and highrisk groups often find it impossible to meet these folate requirements. Based on the available evidence, there is an increasing call for the diagnosis and treatment of elevated homocysteine levels in high-risk individuals in general and patients with manifest vascular disease in particular. Subjects of both populations should first have a baseline homocysteine assay. Except where manifestations are already present, intervention, if any, should be guided by the severity of hyperhomocysteinemia. Consistent with other working parties and consensus groups, we recommend a target plasma homocysteine level of <10 μmol/l. Based on various calculation models, reduction of elevated plasma homocysteine concentrations may theoretically prevent up to 25% of cardiovascular events. Supplementation is inexpensive, potentially effective, and devoid of adverse effects and, therefore, has an exceptionally favorable benefit/risk ratio. The results of ongoing randomized controlled intervention trials must be available before screening for, and treatment of, hyperhomocysteinemia can be recommended for the apparently healthy general population.

Abnormal High-Density Lipoprotein Induces Endothelial Dysfunction via Activation of Toll-like Receptor-2

Endothelial injury and dysfunction (ED) represent a link between cardiovascular risk factors promoting hypertension and atherosclerosis, the leading cause of death in Western populations. High-density lipoprotein (HDL) is considered antiatherogenic and known to prevent ED. Using HDL from children and adults with chronic kidney dysfunction (HDL(CKD)), a population with high cardiovascular risk, we have demonstrated that HDL(CKD) in contrast to HDL(Healthy) promoted endothelial superoxide production, substantially reduced nitric oxide (NO) bioavailability, and subsequently increased arterial blood pressure (ABP). We have identified symmetric dimethylarginine (SDMA) in HDL(CKD) that causes transformation from physiological HDL into an abnormal lipoprotein inducing ED. Furthermore, we report that HDL(CKD) reduced endothelial NO availability via toll-like receptor-2 (TLR-2), leading to impaired endothelial repair, increased proinflammatory activation, and ABP. These data demonstrate how SDMA can modify the HDL particle to mimic a damage-associated molecular pattern that activates TLR-2 via a TLR-1- or TLR-6-coreceptor-independent pathway, linking abnormal HDL to innate immunity, ED, and hypertension.

Monocyte heterogeneity in obesity and subclinical atherosclerosis.

AIMS Monocytes and monocyte-derived macrophages have been recognised as the cellular hallmark of atherosclerosis decades ago. Recently, they have also been shown to play a pivotal role in obesity. Monocytes display immunophenotypic heterogeneity with functionally distinct subpopulations. We initiated the I LIKE HOMe study to examine monocyte heterogeneity in obesity and subclinical atherosclerosis. METHODS AND RESULTS We assessed carotid intima media thickness (IMT), body mass index (BMI), and other cardiovascular risk factors in 622 healthy volunteers. Using flow-cytometry, we differentiated monocytes into CD14(++)CD16(-) and CD16(+) cells, which we further subdivided into CD14(++)CD16(+) and CD14((+))CD16(+) cells. Body mass index was significantly correlated with carotid IMT. High CD16(+) monocyte counts were significantly associated with both higher BMI and increased carotid IMT. Adjustment for CD16(+) monocyte counts weakened the correlation between BMI and carotid IMT, suggesting that the increase in CD16(+) monocyte numbers in obesity may partly explain the association between obesity and IMT. CONCLUSION Our results reveal a significant univariate association between CD16(+) monocytes and both obesity and subclinical atherosclerosis in low-risk individuals. They are in line with recent observations that CD16(+) monocytes show high endothelial affinity and a potent capacity to invade vascular lesions and to transform into pro-inflammatory cytokine producing macrophages.

Functional vitamin B12 deficiency and determination of holotranscobalamin in populations at risk.

Abstract Background: The prevalence of a sub-clinical functional vitamin B12 deficiency in the general population is higher than previously expected. Total serum vitamin B12 may not reliably indicate vitamin B12 status. To get more specificity and sensitivity in diagnosing vitamin B12 deficiency, the concept of measuring holotranscobalamin II (holoTC), a sub-fraction of vitamin B12, has aroused great interest. HoloTC as a biologically active vitamin B12 fraction promotes a specific uptake of its vitamin B12 by all cells. In this study we investigated the diagnostic value of storage (holoTC) of vitamin B12 and functional markers (methylmalonic acid (MMA)) of vitamin B12 metabolism in populations who are at risk of vitamin B12 deficiency. Subjects and Methods: Our study included 93 omnivorous German controls, 111 German and Dutch vegetarian subjects, 122 Syrian apparently healthy subjects, 127 elderly Germans and finally 92 German pre-dialysis renal patients. Serum concentrations of homocysteine (Hcy) and MMA were measured by gas chromatographymass spectrometry, folate and vitamin B12 by chemiluminescence immunoassay, and holoTC by utilizing a RIA test. Results: High Hcy (>12 μmol/l), high MMA (>271 nmol/l) resp. low holoTC (vitamin B12) in serum were detected in 15%, 8% resp. 13% (1%) of German controls, 36%, 60%, resp. 72% (30%) of vegetarians, 42%, 48% resp. 50% (6%) of Syrians, 75%, 42%, resp. 21% (7%) of elderly subjects and 75%, 67% resp. 4% (2%) of renal patients. The lowest median levels of holoTC were observed in vegetarians, followed by the Syrian subjects (23 and 35 pmol/l, respectively). Renal patients had significantly higher levels of holoTC compared to the German controls (74 vs. 54 pmol/l). In the vitamin B12 range between 156 pmol/l (conventional cut-off level) and 241 pmol/l, both mean concentrations of holoTC and MMA were in the pathological range. HoloTC was the earliest marker for vitamin B12 deficiency followed by MMA. Vitamin B12 deficiency causes folate trapping. A higher folate level is required to keep Hcy normal. The relationship between MMA and holoTC seemed dependent on renal function. In renal patients with a glomerular filtration rate below 36 ml/min, a significantly lower mean level of MMA was detected within the highest tertile of holoTC concentration, compared to the lowest tertile. Thus, in renal patients, a higher serum concentration of circulating holoTC is required to deliver sufficient amounts of holoTC into the cells. Conclusion: Our data support the concept that the measurement of holoTC and MMA provides a better index of cobalamin status than the measurement of total vitamin B12. HoloTC is the most sensitive marker, followed by MMA. The use of holoTC and MMA enables us to differentiate between storage depletion and functional vitamin B12 deficiency. Renal patients have a higher requirement of circulating holoTC. In renal dysfunction, holoTC cannot be used as a marker of vitamin B12 status.

Hyperhomocysteinemia in high-aged subjects : relation of B-vitamins, folic acid, renal function and the methylenetetrahydrofolate reductase mutation

Moderate hyperhomocysteinemia is an atherogenic risk factor and plays an important role in geriatrics. Here, we have investigated the role of hyperhomocysteinemia in two elderly groups: 104 longeval subjects of 85-102 years, 100 seniors aged 65-75 years, and 75 controls of 19-60 years. Elevated homocysteine levels were found in 58% of longeval subjects in comparison with 32% in seniors. The homocysteine level in serum correlated positively with age as well as serum creatinine, and inversely with serum folate, but there was no correlation with serum B-vitamins. The frequency of vitamin B deficiency in serum of longeval subjects compared to seniors was as follows: vitamin B6 43% vs. 22%, vitamin B12 20% vs. 8%, and folic acid 1% in both groups. Increased serum creatinine levels (> 1.1 mg/dl) were found in 63% of the longeval subjects and in 32% of seniors. The 677-missense mutation in the methylenetetrahydrofolate reductase (MTHFR) gene, responsible for moderate homocysteine elevation, was found in 35, 37 and 27% of alleles in longeval persons, senior subjects and younger controls, respectively, showing no significant difference in frequency distributions of the MTHFR gene mutation. It can be concluded that hyperhomocysteinemia is very common with increased age. Its importance as an atherogenic risk factor with advanced age has to be clarified.

The usefulness of holotranscobalamin in predicting vitamin B12 status in different clinical settings

Serum concentrations of homocysteine (Hcy) and methylmalonic acid (MMA) become increased in B12-deficient subjects and are therefore, considered specific markers of B12 deficiency. Serum level of holotranscobalamin (holoTC) becomes decreased before the development of the metabolic dysfunction. We investigated the usefulness of holoTC in diagnosing B12 deficiency in some clinical settings. We measured serum concentrations of holoTC, MMA, Hcy and total B12 in omnivores, vegetarians, elderly people and haemodialysis patients. Our results indicated that the incidence of holoTC <35 pmol/L was highest in the vegans (76%). Low holoTC and elevated MMA were detected in 64% of the vegans and 43% of the lacto- and lacto-ovovegetarians. An elevated MMA and a low holoTC were found in subjects with total serum B12 as high as 300 pmol/L. The distribution of holoTC in elderly people was similar to that in younger adults (median holoTC 55 pmol/L in both groups). A low holoTC and an elevated MMA were found in 16% of the elderly group. An elevated MMA and a normal holoTC were found in 20% of the elderly group who had a relatively high median serum concentration of creatinine (106.1 micromol/L). Serum concentrations of holoTC in dialysis patients were considerably higher than all other groups (median 100 pmol/L). This was also associated with severely increased serum levels of MMA (median 987 nmol/L). From these results it can be concluded that serum concentration of holoTC is a much better predictor of B12 status than total B12. This was particularly evident in case of dietary B12 deficiency. Serum concentrations of holoTC as well as MMA can be affected by renal dysfunction. Elevated MMA and normal holoTC in patients with renal insufficiency may not exclude vitamin B12 deficiency. HoloTC seems not to be a promising marker in predicting B12 status in renal patients.

Vegetarian lifestyle and monitoring of vitamin B-12 status

Vegetarians are at risk to develop deficiencies of some essential nutrients, especially vitamin B-12 (cobalamin). Cobalamin occurs in substantial amounts only in foods derived from animals and is essential for one-carbon metabolism and cell division. Low nutritional intake of vitamin B-12 may lead to negative balance and, finally, to functional deficiency when tissue stores of vitamin B-12 are depleted. Early diagnosis of vitamin B-12 deficiency seems to be useful because irreversible neurological damages may be prevented by cobalamin substitution. The search for a specific and sensitive test to diagnose vitamin B-12 deficiency is ongoing. Serum vitamin B-12 measurement is a widely applied standard method. However, the test has poor predictive value. Optimal monitoring of cobalamin status in vegetarians should include the measurement of homocysteine (HCY), methylmalonic acid (MMA), and holotranscobalamin II. Vitamin B-12 deficiency can be divided into four stages. In stages I and II, indicated by a low plasma level of holotranscobalamin II, the plasma and cell stores become depleted. Stage III is characterized by increased levels of HCY and MMA in addition to lowered holotranscobalamin II. In stage IV, clinical signs become recognizable like macroovalocytosis, elevated MCV of erythrocytes or lowered haemoglobin. In our investigations, we have found stage III of vitamin B-12 deficiency in over 60% of vegetarians, thus underlining the importance of cobalamin monitoring in this dietary group.

Clinical use and rational management of homocysteine, folic acid, and B vitamins in cardiovascular and thrombotic diseases.

Etwa die Hälfte aller Todesfälle sind auf Herz-Kreislauf-Erkrankungen bzw. deren Komplikationen zurückzuführen. Volkswirtschaft und Gesundheitswesen werden zusätzlich durch gewaltige Kosten für Arbeitsausfälle, Folgeerkrankungen und -behandlungen belastet, besonders unter dem Aspekt einer raschen Zunahme älterer Bevölkerungsschichten. Nachdem die konventionellen Risikofaktoren einen Teil der Fälle nicht erklären können, wird dem „neuen“ Risikofaktor Homocystein großes Interesse entgegen gebracht. Homocystein ist ein schwefelhaltiges Intermediärprodukt im Stoffwechsel der essentiellen Aminosäure Methionin. Defizite der Vitamine Folsäure, Vitamin B12 und B6 sowie eingeschränkte Enzymaktivitäten führen durch Abbauhemmung zur intrazellulären Konzentrationserhöhung von Homocystein. Zahlreiche retrospektive und prospektive Studien finden übereinstimmend eine unabhängige Beziehung zwischen bereits leicht erhöhtem Homocystein und kardiovaskulären Erkrankungen sowie der Gesamtmortalität. Eine Risikoerhöhung ist ab einem Homocysteinwert von etwa 9 μmol/l in einer linearen Dosis-Wirkungsbeziehung ohne Schwellenwert darstellbar. Die Hyperhomocysteinämie als unabhängiger Risikofaktor für Herz-Kreislauf-Erkrankungen wird für etwa 10% des Gesamtrisikos verantwortlich gemacht. Erhöhte Konzentrationen (moderate Hyperhomocysteinämie, > 12 μmol/l) gelten als zelltoxisch und werden bei 5–10% der Allgemeinbevölkerung und bei bis zu 40% der Patienten mit Gefäßerkrankungen gemessen. Zusätzliche Risikofaktoren (Rauchen, arterieller Hypertonus, Diabetes und Hyperlipidämie) können das Gesamtrisiko additiv oder durch Interaktion mit Homocystein synergistisch und überproportional erhöhen. Bei Hyperhomocysteinämie kommt es neben Veränderungen der Gefäßmorphologie zu einem Verlust der antithrombotischen Endothelfunktion und zur Induktion eines prokoagulatorischen Milieus. Den meisten der bekannten Schädigungen liegen Homocystein-vermittelte oxidative Stressbelastungen zugrunde. Zahlreiche Wirkstoffe, Medikamente, Erkrankungen und Lebensstilfaktoren beeinflussen den Homocystein-Stoffwechsel, zumeist als direkte oder indirekte Antagonisten von Kofaktoren und Enzymaktivitäten. Als häufigste Ursache erhöhter Homocysteinwerte gilt der Folsäuremangel. Die ausreichende Versorgung mit mindestens 400 μg Folat/Tag ist auch bei ausgewogener Ernährung schwierig und besonders für Risikogruppen häufig nicht realisierbar. Aufgrund der bereits vorliegenden Erkenntnisse wird zunehmend die Bestimmung und Behandlung erhöhter Homocysteinkonzentrationen bei Hochrisikogruppen und besonders von Patienten mit manifesten Gefäßerkrankungen gefordert. In beiden Fällen sollte zunächst eine Homocysteinbestimmung durchgeführt werden (Ausgangswert). Außer bei Manifestationen richtet sich das weitere Vorgehen nach dem Befund (Grafik). In Übereinstimmung mit anderen Arbeits- und Konsensusgruppen ist als Therapieziel ein Homocysteinspiegel < 10 μmol/l anzustreben. Durch Senkung erhöhter Homocysteinspiegel könnten, basierend auf verschiedenen Berechnungsgrundlagen, theoretisch bis zu 25% der kardiovaskulären Ereignisse vermieden werden. Auf Grund der billigen, potentiell effektiven und nebenwirkungsfreien Therapiemöglichkeit besteht ein außerordentlich günstiger Kosten-Nutzen-Quotient. Vor einer möglichen Empfehlung für die generelle Bestimmung und Behandlung erhöhter Homocysteinwerte bei Gesunden müssen erst die Ergebnisse derzeit laufender kontrolliert-randomisierter Interventionsstudien bekannt sein. About half of all deaths are due to cardiovascular disease and its complications. The economic burden on society and the healthcare system from cardiovascular disability, complications, and treatments is huge and becoming larger in the rapidly aging populations of developed countries. As conventional risk factors fail to account for part of the cases, homocysteine, a “new” risk factor, is being viewed with mounting interest. Homocysteine is a sulfur-containing intermediate product in the normal metabolism of methionine, an essential amino acid. Folic acid, vitamin B12, and vitamin B6 deficiency and reduced enzyme activities inhibit the breakdown of homocysteine, thus increasing the intracellular homocysteine concentration. Numerous retrospective and prospective studies have consistently found an independent relationship between mild hyperhomocysteinemia and cardiovascular disease or all-cause mortality. Starting at a plasma homocysteine concentration of approximately 10 μmol/l, the risk increase follows a linear dose-response relationship with no specific threshold level. Hyperhomocysteinemia as an independent risk factor for cardiovascular disease is thought to be responsible for about 10 percent of total risk. Elevated plasma homocysteine levels (> 12 μmol/l; moderate hyperhomocysteinemia) are considered cytotoxic and are found in 5 to 10 percent of the general population and in up to 40 percent of patients with vascular disease. Additional risk factors (smoking, arterial hypertension, diabetes, and hyperlipidemia) may additively or, by interacting with homocysteine, synergistically (and hence overproportionally) increase overall risk. Hyperhomocysteinemia is associated with alterations in vascular morphology, loss of endothelial antithrombotic function, and induction of a procoagulant environment. Most known forms of damage or injury are due to homocysteine-mediated oxidative stresses. Especially when acting as direct or indirect antagonists of cofactors and enzyme activities, numerous agents, drugs, diseases, and life style factors have an impact on homocysteine metabolism. Folic acid deficiency is considered the most common cause of hyperhomocysteinemia. An adequate intake of at least 400 μg of folate per day is difficult to maintain even with a balanced diet, and high-risk groups often find it impossible to meet these folate requirements. Based on the available evidence, there is an increasing call for the diagnosis and treatment of elevated homocysteine levels in high-risk individuals in general and patients with manifest vascular disease in particular. Subjects of both populations should first have a baseline homocysteine assay. Except where manifestations are already present, intervention, if any, should be guided by the severity of hyperhomocysteinemia. Consistent with other working parties and consensus groups, we recommend a target plasma homocysteine level of < 10 μmol/l. Based on various calculation models, reduction of elevated plasma homocysteine concentrations may theoretically prevent up to 25 percent of cardiovascular events. Supplementation is inexpensive, potentially effective, and devoid of adverse effects and, therefore, has an exceptionally favorable benefit/risk ratio. The results of ongoing randomized controlled intervention trials must be available before screening for and treatment of hyperhomocysteinemia can be recommended for the apparently healthy general population.

The impact of vegetarianism on some haematological parameters

Abstract: Objective : Subjects adopting a vegetarian diet are liable to vitamin B12 and iron deficiencies. Co‐existing vitamin B12 and iron deficiencies may give an equivocal haematological picture, which may, in turn, delay making an early diagnosis. The current work was undertaken to investigate some haematological parameters in relation to vitamin B12 and iron status in vegetarians. Subjects and methods : Twenty‐nine vegans, 64 lacto‐ and lacto‐ovo‐vegetarians, in addition to 20 occasional meat eaters, were enrolled for this study. The total group included 49 males and 64 females aged [mean (SD) = 46(15) yr]. Complete blood count, methylmalonic acid (MMA), homocysteine (HCY), ferritin, and transferrin concentrations and percentage transferrin saturation were assayed, using conventional methods. Results : Vegans displayed the highest MMA and HCY levels (median MMA = 708 nmol L −1 ; HCY = 12.8 µmol L −1 ). A lower lymphocyte count and a higher mean corpuscular volume (MCV) were found in vegans compared with lacto‐ or lacto‐ovo‐vegetarians (median = 1.51 × 10 9 vs. 1.83 × 10 9  L −1 ; 92 vs. 89 fL, respectively). Vitamin B12‐deficient subjects in the higher range of transferrin saturation percentage had higher MCV than vitamin B12‐deficient subjects in the lower transferrin saturation range (mean MCV = 92 vs. 89 fL). A lower platelet count was found in the highest quartile of MMA (mean = 211 × 10 9  L −1 ) and in the highest quartile of HCY (mean = 215 × 10 9  L −1 ), compared with the other quartiles. Lower lymphocyte and platelet counts and higher MCV were found in subjects with elevated MMA and HCY, compared to those with normal metabolites. Factors that explained the variations in MCV were red blood cell count, ferritin, transferrin saturation, and methylmalonic acid levels. Conclusion : vitamin B12 and iron status were compromised by a vegetarian diet. Variations in mean corpuscular volume were determined by iron and vitamin B12 status. Lower lymphocyte and platelet count were accompanied by metabolic evidence that indicated vitamin B12 deficiency.

Genetic defects as important factors for moderate hyperhomocysteinemia

Abstract The genes for the enzymes methylenetetrahydrofolate reductase (MTHFR), methionine synthase (MS), methionine synthase reductase (MSR) and cytathionine-Β-synthase (CBS) play an important role in homocysteine metabolism. Rare mutations in these genes cause severe hyperhomocysteinemia and clinical symptoms. Growing interest has focused on common mutations with moderate effects on homocysteine levels. We studied 280 subjects of different age groups for the following mutations: MTHFR677C→T and 1298A→C, MS2756A→G, MSR66A→G and the 68 bp insertion in the CBS gene. The median value for homocysteine increased significantly with age (median homocysteine levels: 7.5, 12.4 and 16.5 μmol/l in the age groups 20–43, 65–75 and 85–96 years, respectively). The genotypes of the MTHFR677C→T mutation were associated with differences in plasma homocysteine levels, but without reaching significance. Individuals homozygous for the MTHFR677C→T mutation had a 2.3 μmol/l higher median homocysteine level compared to individuals with the wild-type allele. This effect was pronounced in combination with low folate levels and abolished with higher folate in plasma. For the other three mutations no association with homocysteine values could be determined. The analysis of homocysteine metabolite cystathionine by backward regression analysis revealed a significant correlation of the MS2756A→G mutation with cystathionine level. This increase could indicate a disturbed remethylation. In summary, larger and homogeneous study populations are necessary to quantify the small effects of common mutations on homocysteine levels. This may also be the reason that no effects of genetic interactions between two genotypes were observed.