Book contents
- Frontmatter
- Contents
- List of Figures
- List of Tables
- Preface
- 1 The Vitamins
- 2 Vitamin A: Retinoids and Carotenoids
- 3 Vitamin D
- 4 Vitamin E: Tocopherols and Tocotrienols
- 5 Vitamin K
- 6 Vitamin B1 – Thiamin
- 7 Vitamin B2 – Riboflavin
- 8 Niacin
- 9 Vitamin B6
- 10 Folate and Other Pterins and Vitamin B12
- 11 Biotin (Vitamin H)
- 12 Pantothenic Acid
- 13 Vitamin C (Ascorbic Acid)
- 14 Marginal Compounds and Phytonutrients
- Bibliography
- Index
10 - Folate and Other Pterins and Vitamin B12
Published online by Cambridge University Press: 03 December 2009
- Frontmatter
- Contents
- List of Figures
- List of Tables
- Preface
- 1 The Vitamins
- 2 Vitamin A: Retinoids and Carotenoids
- 3 Vitamin D
- 4 Vitamin E: Tocopherols and Tocotrienols
- 5 Vitamin K
- 6 Vitamin B1 – Thiamin
- 7 Vitamin B2 – Riboflavin
- 8 Niacin
- 9 Vitamin B6
- 10 Folate and Other Pterins and Vitamin B12
- 11 Biotin (Vitamin H)
- 12 Pantothenic Acid
- 13 Vitamin C (Ascorbic Acid)
- 14 Marginal Compounds and Phytonutrients
- Bibliography
- Index
Summary
Folic acid functions in the transfer of one-carbon fragments in a wide variety of biosynthetic and catabolic reactions; it is therefore metabolically closely related to vitamin B12, which also functions in one-carbon transfer. Deficiency of either vitamin has similar clinical effects, and it seems likely that the main effects of vitamin B12 deficiency are exerted by effects on folate metabolism.
The pterins include the redox cofactors biopterin and molybdopterin, as well as various insect pigments. Folic acid is a conjugated pterin, in which the pteridine ring is linked to p-aminobenzoyl-poly-γ-glutamate; it is this linkage that renders folate a dietary essential, because it is the ability to condense p-aminobenzoate to a pteridine, rather than to synthesize the pteridine nucleus itself, which has been lost by higher animals. Biopterin (Section 10.4) and molybdopterin (Section 10.5) are coenzymes in mixed-function oxidases; they are not vitamins, but can be synthesized in the body. Rare genetic defects of biopterin synthesis render it a dietary essential for affected individuals.
Although folate is widely distributed in foods, dietary deficiency is not uncommon, and a number of commonly used drugs can cause folate depletion. Marginal folate status is a factor in the development of neural tube defects and supplements of 400 μg per day periconceptually reduce the incidence of neural tube defects significantly. High intakes of folate lower the plasma concentration of homocysteine in people genetically at risk of hyperhomo-cysteinemia and may reduce the risk of cardiovascular disease, although as yet there is no evidence from intervention studies. There is also evidence that low folate status is associated with increased risk of colorectal and other cancers and that folate may be protective.
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- Information
- Nutritional Biochemistry of the Vitamins , pp. 270 - 323Publisher: Cambridge University PressPrint publication year: 2003