Pyridoxine vitamin coenzyme form

Not all vitamin coenzymes need to be in the form of a nucleotide (base, sugar, phosphate). For example thiamine biotin pyridoxine vitamin B12. 

All aminotransferases have the same prosthetic group and the same reaction mechanism. The prosthetic group is pyridoxal phosphate (PLP), the coenzyme form of pyridoxine, or vitamin B6. We encountered pyridoxal phosphate in Chapter 15, as a coenzyme in the glycogen phosphorylase reaction, but its role in that reaction is not representative of its usual coenzyme function. Its primary role in cells is in the metabolism of molecules with amino groups. 

Pyridoxal-5 -phosphate is the coenzyme form of vitamin B6, and has the structure shown in figure 10.3. The name vitamin B6 is applied to any of a group of related compounds lacking the phosphoryl group, including pyridoxal, pyridoxamine, and pyridoxine. 

A second clue to the catalytic mechanism of phosphorylase is its requirement for pyridoxal phosphate (PLP), a derivative of pyridoxine (vitamin B5, Section 8.6.1). The aldehyde group of this coenzyme forms a Schiff base with a specific lysine side chain of the enzyme (Figure 21.7). The results of structural studies indicate that the reacting... 

The vitamin Bg group comprises three natural forms pyridoxine (pyridoxol) (PA/), pyridoxamine (PM), and pyridoxal (PL), which are 4-substituted 2-methyl-3-hydroxyl-5-hydroxymethyl pyridines (Figure 30-13). During metabolic conversions, each vitamer becomes phosphorylated at the 5-hydroxymethyl substituent. Although both pyridox-amine-5 -phosphate (PMP) and pyridoxal-S -phosphate (PLP, P-5 -P) interconvert as coenzyme forms during aminotransferase (transaminase)-catalyzed reactions, PLP is the coenzyme form that participates in the large number of Bg-dependent enzyme reactions. 

Uptake and Metabolism. The vitamin Bg family consists of pyridoxine, pyridoxal, pyridoxamine, pyridoxine phosphate, pyridoxal phosphate (PLP), and pyridoxamine phosphate (Fig. 8.33). The commercial form is pyridoxine. Pyridoxal phosphate is the coenzyme form. It and pyridoxamine phosphate are from animal tissues. Pyridoxine is from plant tissues. All phosphorylated forms are hydrolyzed in the intestinal tract by phosphatases before being absorbed passively. Conversion to the phosphorylated forms occurs in the liver. Notice that niacin (NAD) and riboflavin (FMN, FAD) are required for interconversion among the vitamin Bq family. The phosphorylated forms are transported to the cells where needed. The major excretory product is 4-pyr-idoxic acid. 

There is reason to conclude that vitamin deficiency might contribute to arteriosclerosis. There is a correlation between elevated homocysteine levels and incidence of cardiovascular disease (59). There is debate as to whether homocysteine contributesto the dam e of cells on the interior of blood vessel or whether homocysteine is a marker of intensive cell repair and formation of replacement cells. Nevertheless, administration of pyridoxine, folic acid, and (yanocobalamin are being recommended along with the two antioxidant vitamins, a-tocopherol and ascorbic acid for arteriosclerosis. Vitamin Bg is required for two of the steps in the catabolism of homocysteine to succinyl CoA (Fig. 8.52). Note in Fig. 8.52 (bottom) that biotin and a coenzyme form of cobalamin also are required for... 

Pyridoxal phosphate The coenzyme that is required for transaminase (aminotransferase) reactions, as weU as other enzymes. It is the active form of pyridoxine (vitamin B ). 

Transamination reactions require the coenzyme pyridoxal-5 -phosphate (PLP), which is derived from pyridoxine (vitamin B6). PLP is also required in numerous other reactions of amino acids. Examples include racemizations, decarboxylations, and several side chain modifications. (Racemizations are reactions in which mixtures of l- and D-amino acids are formed.) The structures of the vitamin and its coenzyme form are illustrated in Figure 14.2. 

Description. There are six forms of vitamin Bgi pyridoxal (PL), pyridoxine (PN), pyridoxamine (PM), and their phosphate derivatives pyridoxal 5 -phosphate (PLP), pyridoxine 5 -phosphate (PNP), and pyridoxamine 5 -phosphate (PMP). PLP is the active coenzyme form and has the most importance in human metabolism. ... 

Riboflavin in its coenzyme forms (FMN and FAD) plays key metabolic roles in biological oxidation-reduction reactions involving carbohydrates, amino acids and lipids, and in energy production via the respiratory chain. These coenzymes also act in cellular metabolism of other water-soluble vitamins through the production and activation of folate and pyridoxine (vitamin Bg) to their respective coenzyme forms and in the synthesis of niacin (vitamin B3) from tryptophan. In addition, some neurotransmitters and other amines require FAD for their metabolism. Recently, Chocano-Bedoya et al. (2011) suggested a possible benefit of high intakes of riboflavin (about 2.5 mg/ day) from food sources on the reduction of incidence of premenstrual syndrome. 

With a mobile phase of 0.2 M ammonium phosphate buffer (pH 5.1) in a reversed-phase system, folate, pyridoxine, nicotinamide, and thiamine could be separated, in this order, within 20 min, followed by vitamin Bn and riboflavin (17). The latter two compounds eluted after a step gradient to 30% aqueous methanol. This procedure has the advantage of completely separating at least nine coenzyme forms of water-soluble vitamins, including TPP. A similar mobile phase, composed of methanol-water (50 50) was used in connection with a LiCh-rosorb RP-18 column to separate thiamine, pyridoxine, vitamin and riboflavin in 3 min, as shown in Figure 4 (23). The detection limit at 254 nm is 5 ng (15 pmol) for thiamine and 10 to 20 ng for the other three vitamins, with a coefficient of variation of <4%. 

Deamination is usually accomplished by a transamination reaction in which the NH2 group of the amino acid is exchanged with the keto group of a-ketoglutarate, forming a new a-keto acid plus glutamate. The overall process occurs in two parts, is catalyzed hy aminotransferases, and involves participation of the coenzyme pyridoxal phosphate, abbreviated PLP, a derivative of pyridoxine (vitamin Bg). Different aminotransferases differ in their specificity for amino acids, but the mechanism remains the same. 

Riboflavin, also called vitamin B2, is stmcturally composed of an isoafloxazine ring with a ribityl side chain at the nitrogen at position 10. This vitamin functions metabol-icafly as the essoitial component of two flavin coenzymes, flavin adenine dinucleotide (FAD) and flavin mononucleotide (FMN), complexed with proteins, which act as intmnediaries in transfers of electrons in biological oxidation-reduction reactions. Both FAD and FMN function as coenzymes for flavoproteins of flavoenzymes. Flavoproteins are essoitial for the metabolism of carbohydrates, amino acids, and lipids and for pyridoxine and folate conversion to their respective coenzyme forms. 

FIGURE 5 The vitamin Be (pyridoxine) famiiy pyridoxoi, pyri-doxai, pyridoxamine, and the coenzyme forms pyridoxai and pyri-doxamine phosphates. 

Vitamin Ba (pyridoxine, pyridoxal, pyridoxamine) like nicotinic acid is a pyridine derivative. Its phosphorylated form is the coenzyme in enzymes that decarboxylate amino acids, e.g., tyrosine, arginine, glycine, glutamic acid, and dihydroxyphenylalanine. Vitamin B participates as coenzyme in various transaminations. It also functions in the conversion of tryptophan to nicotinic acid and amide. It is generally concerned with protein metabolism, e.g., the vitamin B8 requirement is increased in rats during increased protein intake. Vitamin B6 is also involved in the formation of unsaturated fatty acids. 

Vitamin Bg is a mixture of six interrelated forms pyridoxine (or pyridoxol) (Figure 19.23), pyri-doxal, pyridoxamine, and their 5 -phosphates derivatives. Interconversion is possible between all forms. The active form of the vitamin is pyridoxal phosphate, which is a coenzyme correlated with the function of more than 60 enzymes involved in transamination, deamination, decarboxylation, or desulfuration reactions. 

Vitamin Bg (8.47, pyridoxine) is a pyridine-alcohol, but its biologically active forms are pyridoxal 5-phosphate and the corresponding pyridoxamine. Like all the members of the vitamin B complex, it occurs in yeast, bran, wheat germ, and liver. It is a coenzyme of... 

Pyridoxine, pyridoxal, and pyridoxamine, which occur in foodstuffs, are collectively known as vitamin Bg. In the body, all three are converted to pyridoxal phosphate which is the coenzyme for amino-acid decarboxylase and for transaminase. The structures of the three active forms of vitamin Bg and the pyridoxal phosphate, are shown below (55). 

Homocysteine is metabolized in the liver, kidney, small intestine and pancreas also by the transsulfuration pathway [1,3,89]. It is condensed with serine to form cystathione in an irreversible reaction catalyzed by a vitamin B6-dependent enzyme, cystathionine-synthase. Cystathione is hydrolyzed to cysteine that can be incorporated into glutathione or further metabolized to sulfate and taurine [1,3,89]. The transsulfuration pathway enzymes are pyridoxal-5-phosphate dependent [3,91]. This co-enzyme is the active form of pyridoxine. So, either folates, cobalamin, and pyridoxine are essential to keep normal homocysteine metabolism. The former two are coenzymes for the methylation pathway, the last one is coenzyme for the transsulfuration pathway [ 1,3,89,91 ]. 

Most vitamins function either as a hormone/ chemical messenger (cholecalciferol), structural component in some metabolic process (pantothenic acid), or a coenzyme (phytonadi-one, thiamine, riboflavin, niacin, pyridoxine, biotin, folic acid, cyanocobalamin). At least one vitamin has more than one biochemical role. Vitamin A as an aldehyde (retinal) is a structural component of the visual pigment rhodopsin and, in its acid form (retinoic acid), is a regulator of cell differentiation. The precise biochemical functions of ascorbic acid and a-tocopherol still are not well defined. 

Vitamin B6 has been shown to be essential in many biochemical reactions that occur in plants and animals. Although it may occur in any one of the three forms listed above, the compound usually acts as the phosphate ester, pyridoxine phosphate. Pyridoxine phosphate functions as a coenzyme in the transformation of amino acids, the building blocks from which proteins are made. A coenzyme is a chemical compound that works with an enzyme to catalyze some essential chemical reaction in the body. Pyridoxine phosphate appears to be necessary for the synthesis of proteins from amino acids as well as the metabolism of amino acids to produce energy needed for normal body functioning. 

Pyridoxol 210 (pyridoxine, 3-hydroxy-4,5-bis(hydroxymethyl)-2-methylpyridine, vitamin B6) was formerly known as adermine (Kuhn 1938) because vitamin B5 deficiency causes skin diseases in animals. Pyridoxal (211, R = CHO) and pyridoxamine (211, R = CH2NH2) also belong to the vitamin B group. Pyridoxal phosphate 212 is a coenzyme for many of the enzymes involved in the metabolism of amino acids. Nicotinamide adenine dinucleotide 213 (NAD , reduced form NADH) is a component of oxidoreductases (for its action see p 293, synthesis see p 131). 

The B0 vitamins (pyridoxal, pyridoxamine, and pyridoxine and their phos-phorylated forms, which are the coenzymes) are involved in the transfer of amino groups from one molecule to another, an important step in the biosynthesis of amino acids (Figure 7.20). In the reaction, the amino group is transferred from the donor to the coenzyme and then from the coenzyme to the ultimate acceptor (Figure 7.21). 

Ans. In order to accomplish these operations, the protein portion of an enzyme lacking catalytic properties, called an apoenyme, combines transiently with specialized small molecules called cofactors or coenzymes to form the catalytic holoenzyme. Cofactors are ions such as K+, Mg +, or Zn +. Vitamins such as nicotinic acid (niacin), riboflavin, thiamin, and pyridoxine (B ), serve as coenzymes in enzymatic redox, decarboxylation, and group transfer reactions. 

The vitamin Be group of coenzymes consists of pyridoxine, pyridoxal, and pyridoxamine and their metabolically active phosphorylated forms. They are striking for the variety of enzymic reactions in which they are important, and many amino acid transformations, including various transaminations and decarboxylations, are vitamin B dependent. Compounds with vitamin B activity are apparently not stored in the body in large amounts, and biochemical evidence of B deficiency can develop quickly if intake is inadequate (S4). 

Vitamin Bg (pyridoxine also known as pyridoxol, 118) is an essential growth factor in the diet of many organisms and animals. It forms part of a coenzyme (pyridoxylphosphate) and it is a cofactor for a class of enzymes known as transaminases. A transaminase or an aminotransferase is an enzyme that catalyzes a type of reaction between an amino acid and an a-keto acid. The presence of elevated transaminase levels can be an indicator of liver damage. Vitamin Bg has both an aldehyde form (pyridoxal, 119) and an amine form (pyridoxamine, 120), and it is known that pyridoxal phosphate is a carrier of amino groups and sometimes amino acids. ... 

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