Vitamin K

Information about Vitamin K

Vitamin K₁ (phylloquinone). Both contain a functional naphthoquinone ring and an aliphatic side chain. Phylloquinone has a phytyl side chain.

Vitamin K₂ (menaquinone). In menaquinone the side chain is composed of a varying number of isoprenoid residues.

For the unrelated drug sometimes referred to in slang as vitamin K, see ketamine.

Vitamin K denotes a group of lipophilic, and hydrophobic, vitamins that are needed for the posttranslational modification of certain proteins, mostly required for blood coagulation. Chemically they are 2-methyl-1,4-naphthoquinone derivatives.

Vitamin K₂ (menaquinone, menatetrenone) is normally produced by bacteria in the intestines, and dietary deficiency is extremely rare unless the intestines are heavily damaged.

Chemical structure

Vitamin K ("Koagulation" in German) is a group name for a number of related compounds, which have in common a methylated naphthoquinone ring structure, and which vary in the aliphatic side chain attached at the 3-position (see figure 1). Phylloquinone (also known as vitamin K₁) invariably contains in its side chain four isoprenoid residues, one of which is unsaturated.

Menaquinones have side chains composed of a variable number of unsaturated isoprenoid residues; generally they are designated as MK-n, where n specifies the number of isoprenoids.

It is generally accepted that the naphthoquinone is the functional group, so that the mechanism of action is similar for all K-vitamins. Substantial differences may be expected, however, with respect to intestinal absorption, transport, tissue distribution, and bio-availability. These differences are caused by the different lipophilicity of the various side chains, and by the different food matrices in which they occur.

Physiology

Vitamin K is involved in the carboxylation of certain glutamate residues in proteins to form gamma-carboxyglutamate residues (abbreviated Gla-residues). Gla-residues are usually involved in binding calcium. The Gla-residues are essential for the biological activity of all known Gla-proteins.^[1]

At this time 14 human Gla-proteins have been discovered, and they play key roles in the regulation of three physiological processes:

blood coagulation (prothrombin (factor II), factors VII, IX, X, protein C, protein S and protein Z).^[2]
bone metabolism (osteocalcin, also called bone Gla-protein , and matrix gla protein (MGP)).^[3]
vascular biology.^[4]

Many bacteria, such as Escherichia coli found in the large intestine, can synthesize Vitamin K₂ (menaquinone),^[5] but not Vitamin K₁ (phylloquinone). In these bacteria, menaquinone will transfer two electrons between two different small molecules, in a process called anaerobic respiration.^[6] For example, a small molecule with an excess of electrons (also called an electron donor) such as lactate, formate, or NADH, with the help of an enzyme, will pass two electrons to a menaquinone. The menaquinone, with the help of another enzyme, will in turn transfer these 2 electrons to a suitable oxidant, such fumarate or nitrate (also called an electron acceptor). Adding two electrons to fumarate or nitrate will convert the molecule to succinate or nitrite + water, repectively. Some of these reactions generate a cellular energy source, ATP, in a manner similar to eukaryotic cell aerobic respiration, except that the final electron acceptor is not molecular oxygen, but say fumarate or nitrate (In aerobic respiration, the final oxidant is molecular oxygen (O₂) , which accepts four electrons from an electron donor such as NADH to be converted to water.) Escherichia coli can carry out aerobic respiration and menaquninone-mediated anaerobic respiration.

Recommended amounts

The U.S. Dietary Reference Intake (DRI) for an Adequate Intake (AI) for a 25-year old male for Vitamin K is 120 micrograms/day. No Tolerable Upper Intake Level (UL) has been set. The human body stores Vitamin K, so it is not necessary to take Vitamin K daily.

Sources of Vitamin K

Vitamin K is found in leafy green vegetables such as spinach and lettuce; Brassica vegetables such as kale, cabbage, cauliflower, broccoli, and Brussels sprouts; wheat bran; organ meats; cereals; some fruits, such as avocado, kiwifruit and bananas; meats; cow milk and other dairy products; eggs; and other soy products. Two tablespoons of parsley contains 153% of the recommended daily amount of vitamin K.^[7]

Phylloquinone (vitamin K1) is the major dietary form of vitamin K. Vitamin K₁ is found in chicken egg yolk, butter, cow liver, most cheeses, and products. It is also found in some types of mayonnaise.

Role in disease

Vitamin K-deficiency may occur by disturbed intestinal uptake (such as would occur in a bile duct obstruction), by therapeutic or accidental intake of vitamin K-antagonists or, very rarely, by nutritional vitamin K-deficiency. As a result of the acquired vitamin K-deficiency, Gla-residues are not or incompletely formed and hence the Gla-proteins are inactive. Lack of control of the three processes mentioned above may lead to the following: risk of massive, uncontrolled internal bleeding, cartilage calcification and severe malformation of developing bone, or deposition of insoluble calcium salts in the arterial vessel walls.

Biochemistry

Discovery

In the late 1920s, Danish scientist Henrik Dam investigated the role of cholesterol by feeding chickens a cholesterol-depleted diet.^[8] After several weeks, the animals developed hemorrhages and started bleeding. These defects could not be restored by adding purified cholesterol to the diet. It appeared that - together with the cholesterol - a second compound had been extracted from the food, and this compound was called the coagulation vitamin. The new vitamin received the letter K because the initial discoveries were reported in a German journal, in which it was designated as Koagulationsvitamin. Edward Adelbert Doisy (of Saint Louis University) did much of the research that led to the discovery of the structure and chemical nature of Vitamin K.^[9] Dam and Doisy shared the 1943 Nobel Prize for medicine for their work on Vitamin K. Several laboratories synthesized the compound in 1939.^[10]

For several decades the vitamin K-deficient chick model was the only method of quantitating of vitamin K in various foods: the chicks were made vitamin K-deficient and subsequently fed with known amounts of vitamin K-containing food. The extent to which blood coagulation was restored by the diet was taken as a measure for its vitamin K content.

The first published report of successful treatment with vitamin K of life-threatening hemorrhage in a jaundiced patient with prothrombin deficiency was made in 1938 at the University of Iowa Department of Pathology by Drs. Harry Pratt Smith, Emory Warner, Kenneth Brinkhous, and Walter Seegers.^[11]

Function in the cell

The precise function of vitamin K was not discovered until 1974, when three laboratories (Stenflo et al.^[12], Nelsestuen et al.^[13], and Magnusson et al.^[14]) isolated the vitamin K-dependent coagulation factor prothrombin (Factor II) from cows that received a high dose of a vitamin K antagonist, warfarin. It was shown that while warfarin-treated cows had a form of prothrombin that contained 10 glutamate amino acid residues near the amino terminus of this protein, the normal (untreated) cows contained 10 unusual residues which were chemically identified as gamma-carboxyglutamate, or Gla. The extra carboxyl group in Gla made clear that vitamin K plays a role in a carboxylation reaction during which Glu is converted into Gla.

The biochemistry of how Vitamin K is used to convert Glu to Gla has been elucidated over the past thirty years in academic laboratories throughout the world. Within the cell, Vitamin K undergoes electron reduction to a reduced form of Vitamin K (called Vitamin K hydroquinone) by the enzyme Vitamin K epoxide reductase (or VKOR).^[15] Another enzyme then oxidizes Vitamin K hydroquinone to allow carboxylation of Glu to Gla; this enzyme is called the gamma-glutamyl carboxylase^[16]^[17] or the Vitamin K-dependent carboxylase. The carboxylation reaction will only proceed if the carboxylase enzyme is able to oxidize Vitamin K hydroquinone to vitamin K epoxide at the same time; the carboxylation and epoxidation reactions are said to be coupled reactions. Vitamin K epoxide is then re-converted to Vitamin K by the Vitamin K epoxide reductase. These two enzymes comprise the so-called Vitamin K cycle.^[18] One of the reasons why Vitamin K is rarely deficient in a human diet is because Vitamin K is continually recycled in our cells.

Warfarin and other coumadin drugs block the action of the Vitamin K epoxide reductase.^[19] This results in decreased concentrations of Vitamin K and Vitamin K hydroquinone in the tissues, such that the carboxylation reaction catalyzed by the glutamyl carboxylase is inefficient. This results in the production of clotting factors with a greatly diminished or a complete absence of Gla. Without Gla on the amino termini of these factors, they no longer stablely bind to the blood vessel endothelium and cannot activate clotting to allow formation of a clot during tissue injury. As administration of Warfarin to a patient suppresses the clotting response, it must be carefully monitored to avoid over-dosing. See Warfarin.

Gla-proteins

At present, the following human Gla-containing proteins have been characterized to the level of primary structure: the blood coagulation factors II (prothrombin), VII, IX, and X, the anticoagulant proteins C and S, and the Factor X-targeting protein Z. The bone Gla-protein osteocalcin, the calcification inhibiting matrix gla protein (MGP), the cell growth regulating growth arrest specific gene 6 protein (Gas6), and the four transmembrane Gla proteins (TMGPs) the function of which is at present unknown. Gas6 can function as a growth factor that activates the Axl receptor tyrosine kinase and stimulates cell proliferation or prevents apoptosis in some cells. In all cases in which their function was known, the presence of the Gla-residues in these proteins turned out to be essential for functional activity.

Gla-proteins are known to occur in a wide variety of vertebrates: mammals, birds, reptiles, and fish. The venom of a number of Australian snakes acts by activating the human blood clotting system. Remarkably, in some cases activation is accomplished by snake Gla-containing enzymes that bind to the endothelium of human blood vessels and catalyze the conversion of procoagulant clotting factors into activated ones, leading to unwanted and potentially deadly clotting.

Another interesting class of invertebrate Gla-containing proteins is synthesized by the fish-hunting snail Conus geographus.^[20] These snails produce a venom containing hundreds of neuro-active peptides, or conotoxins, which is sufficiently toxic to kill an adult human. Several of the conotoxins contain 2-5 Gla residues.^[21]

Use on newborn babies

In some countries, injections of Vitamin K are routinely given to newborn babies. Vitamin K is used as prophylactic measure to prevent late-onset haemorrhagic disease (HDN). However, HDN is a relatively rare problem, and many parents now choose for their babies not to have such an injection.

References

1. ^ Furie B, Bouchard BA, Furie BC. Vitamin K-dependent biosynthesis of gamma-carboxyglutamic acid. Blood, 1999, 93(6):1798-808. Review
2. ^ Mann KG. Biochemistry and physiology of blood coagulation. Thrombosis and Haemostasis, 1999, 82(2):165-74. Review. PMID: 10605701
3. ^ Price PA. Role of vitamin-K-dependent proteins in bone metabolism, Annual Review of Nutrition, 1988, 8:565-83. Review. PMID: 3060178
4. ^ Berkner KL, Runge KW. The physiology of vitamin K nutriture and vitamin K-dependent protein function in atherosclerosis, Journal of Thrombosis and Haemostasis, 2004, 2(12):2118-32. Review
5. ^ Bentley, R, Meganathan, R., Biosynthesis of Vitamin K (menaquinone) in Bacteria, Bacteriological Reviews, 1982, 46(3):241-280. Review.
6. ^ Haddock, BA, Jones, CW, Bacterial Respiration, Bacteriological Reviews, 1977, 41(1):74-99. Review.
7. ^ [1]
8. ^ Dam H. The antihemorrhagic vitamin of the chick. Occurrence and chemical nature, Nature, 1935;135:652
9. ^ MacCorquodale, DW, Binkley, SB, Thayer, SA, Doisy, EA, On the constitution of Vitamin K1, Journal of the American Chemical Society, 1939, 61:1928-1929
10. ^ Fieser, LF, Synthesis of Vitamin K1, Journal of the American Chemical Society,1939, 61:3467-3475
11. ^ Warner, ED, Brinkhous, KM, Smith, HP, Proceedings of the Society of Experimental Biology and Medicine, 1938, 37:628
12. ^ Stenflo J, Fernlund P, Egan W, Roepstorff P., Vitamin K-dependent modifications of glutamic acid residues in prothrombin, Proceedings of the National Academy of Sciences, USA, 1974, 71:2730–3. PMID 4528109
13. ^ Nelsestuen GL, Zytkovicz TH, Howard JB., The mode of action of vitamin K. Identification of gamma-carboxyglutamic acid as a component of prothrombin, Journal of Biological Chemistry, 1974, 249(19):6347-50. PMID: 4214105
14. ^ Magnusson S, Sottrup-Jensen L, Petersen TE, Morris HR, Dell A, Primary structure of the vitamin K-dependent part of prothrombin. FEBS Letters, 1974, 44(2):189-93. PMID: 4472513
15. ^ Oldenburg J, Bevans CG, Muller CR, Watzka M, Vitamin K epoxide reductase complex subunit 1 (VKORC1): the key protein of the vitamin K cycle, Antioxidants and Redox Signaling, 2006, 8(3-4):347-53. Review. PMID: 16677080
16. ^ Suttie JW, Vitamin K-dependent carboxylase, Annual Review of Biochemistry,1985, 54:459-77. Review. PMID: 3896125
17. ^ Presnell SR, Stafford DW, The vitamin K-dependent carboxylase, Thrombosis and Haemostasis, 2002, 87(6):937-46. Review. PMID: 12083499
18. ^ Stafford DW, The vitamin K cycle, Journal of Thrombosis Haemostais, 2005, (8):1873-8. Review. PMID: 16102054
19. ^ Whitlon DS, Sadowski JA, Suttie JW, Mechanisms of coumarin action: significance of vitamin K epoxide reductase inhibition, Biochemistry, 1978, 17:1371–7. PMID 646989
20. ^ Terlau H, Olivera BM. Conus venoms: a rich source of novel ion channel-targeted peptides, Physiological Reviews, 2004, 84(1):41-68. Review. PMID: 14715910
21. ^ Buczek O, Bulaj G, Olivera BM, Conotoxins and the posttranslational modification of secreted gene products, Cell and Molecular Life Sciences, 2005, 62(24):3067-79. Review. PMID:16314929

External links

Jane Higdon, "Vitamin K", Micronutrient Information Center, Linus Pauling Institute
Vitamin K: Another Reason to Eat Your Greens
Vitamin K: Signs of Deficiency
Vitamin K Deficiency - from the Merck Manual
An Alternative Perspective on Vitamin K Prophylaxis
Vitamin K Content - USDA National Nutrient Database for Standard Reference, Release 19

• • [ e] Vitamins (A11)
fat soluble	Retinol (A) \| Ergocalciferol and Cholecalciferol (D) \| Tocopherol (E) \| Naphthoquinone (K)
water soluble	B vitamins (Thiamine (B₁), Riboflavin (B₂), Niacin (B₃), Pantothenic acid (B₅), Pyridoxine (B₆), Biotin (B₇), Folic acid (B₉), Cyanocobalamin (B₁₂)) \| Choline \| Ascorbic acid (C)

Lipophilicity, fat-liking, refers to the ability of a chemical compound to dissolve in fats, oils, lipids, and non-polar solvents such as hexane or toluene.^[1] These non-polar solvents are themselves lipophilic — the axiom that like dissolves like
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hydrophobicity (from the combining form of water in Attic Greek hydro- and for fear phobos) refers to the physical property of a molecule (known as a hydrophobe) that is repelled from a mass of water ^[1].
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A vitamin is a nutrient that is an organic compound required in tiny amounts for essential metabolic reactions in a living organism.^[1] The term vitamin
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Post-translational modification (PTM) is the chemical modification of a protein after its translation. It is one of the later steps in protein biosynthesis for many proteins. A protein (also called a polypeptide) is a chain of amino acids.
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Coagulation is a complex process by which blood forms solid clots. It is an important part of hemostasis (the cessation of blood loss from a damaged vessel) whereby a damaged blood vessel wall is covered by a platelet- and fibrin-containing clot to stop bleeding and begin repair of
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In chemistry, a methyl group is a hydrophobic alkyl functional group derived from methane (CH₄). It has the formula -CH₃ and is very often abbreviated as -Me in the structure of a molecule. This hydrocarbon unit can be found in many organic compounds.
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Naphthoquinone, or more precisely 1,4-naphthoquinone, is an organic compound. It forms yellow triclinic crystals and has an odor similar to benzoquinone. It is sparingly soluble in cold water, slightly soluble in petroleum ether, and freely soluble in most polar organic
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Menatetrenone (INN) is a menaquinone compound used as a hemostatic agent and as adjunctive therapy for the pain of osteoporosis. It is marketed for the latter indication in Japan by Eisai Co., under the trade name Glakay.
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Bacteria

Phyla

Actinobacteria
Aquificae
Chlamydiae
Bacteroidetes/Chlorobi
Chloroflexi
Chrysiogenetes
Cyanobacteria
Deferribacteres
Deinococcus-Thermus
Dictyoglomi
Fibrobacteres/Acidobacteria
Firmicutes
Fusobacteria
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In anatomy, the intestine is the segment of the alimentary canal extending from the stomach to the anus and, in humans and other mammals, consists of two segments, the small intestine and the large intestine.
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Methylation is a term used in the chemical sciences to denote the attachment or substitution of a methyl group on various substrates. This term is commonly used in chemistry, biochemistry, and the biological sciences.
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In chemistry, aliphatic compounds are organic compounds in which carbon atoms are joined together in straight or branched chains or in rings, that can be either saturated or unsaturated, but not aromatic.^[1] The simplest aliphatic compound is methane (CH₄).
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side chain in organic chemistry and biochemistry is a part of a molecule that is attached to a core structure. An R group is a generic label for a side chain which can be anything; however, it is typically stable and covalently linked to the adjoining atom.
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Phylloquinone is a polycyclic aromatic ketone, based on 2-methyl-1,4-naphthoquinone, with a 3-phytyl substituents. It is often called vitamin K₁.

It is a fat-soluble vitamin that is stable to air and moisture but decomposes in sunlight.
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Isoprene is a common synonym for the chemical compound 2-methylbuta-1,3-diene. It is commonly used in industry, is an important biological material, and can be a harmful environmental pollutant and toxicant when present in excess quantities.
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Carboxylation in chemistry is a chemical reaction in which a carboxylic acid group is introduced in a substrate. The opposite reaction is decarboxylation.

Carboxylation in organic chemistry

In organic chemistry many different protocols exist for carboxylation.
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Glutamic acid or glutamate (abbreviated as Glu or E; Glx or Z represents either glutamic acid or glutamine), is the protonated form of glutamate (the anion). Glutamate is one of the 20 proteinogenic amino acids.
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γ-carboxyglutamate is an uncommon amino acid introduced into proteins by a post-translational carboxylation of glutamate. This modification is found e.g. in clotting factors and other proteins of the coagulation cascade.
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92 (4): 487–511. Retrieved on 2006-09-01.
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Thrombin (activated Factor II [IIa]) is a coagulation protein that has many effects in the coagulation cascade. It is a serine protease (EC 3.4.21.5 ) that converts soluble fibrinogen into insoluble strands of fibrin, as well as catalyzing many other
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Factor VII (formerly known as proconvertin) is one of the central proteins in the coagulation cascade. It is an enzyme (EC 3.4.21.21 ) of the serine protease class.
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Factor IX (or Christmas factor or Christmas-Eve factor) is one of the serine proteases (EC 3.4.21.22 ) of the coagulation system; it belongs to peptidase family S1. Deficiency of this protein causes hemophilia B.
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Factor X, also known by the eponym Stuart-Prower factor or as thrombokinase, is an enzyme (EC 3.4.21.6 ) of the coagulation cascade. It is a serine endopeptidase (protease group S1).
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Protein C is a major physiological anticoagulant. It is a vitamin K-dependent serine protease enzyme (EC 3.4.21.69 ) that is activated by thrombin into activated protein C (APC). The activated form (with protein S as a cofactor) degrades Factor Va and Factor VIIIa.
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Protein S is a vitamin K-dependent plasma glycoprotein synthesized in the liver. In the circulation, Protein S exists in two forms: a free form and a complex form bound to complement protein C4b.
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Protein Z is a member of the coagulation cascade, the group of blood proteins that leads to the formation of blood clots. It is vitamin K-dependent, and its functionality is therefore impaired in warfarin therapy. It is a glycoprotein.
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Bones are rigid organs that form part of the endoskeleton of vertebrates. They function to move, support, and protect the various organs of the body, produce red and white blood cells and store minerals.
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Osteocalcin is a noncollagenous protein found in bone and dentin. It is secreted by osteoblasts and thought to play a role in mineralization and calcium ion homeostasis. It has been stipulated that osteocalcin may also function as a negative regulator of bone formation, although
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