Pyridoxal 5 -phosphate Pyridoxamine

The usable range for T. pyriformis is from 0.3-300 mug/ml. The organism utilizes pyridoxal, pyridoxamine pyridoxine, and pyridoxal-5-phosphate. Pyridoxamine + pyridoxal yielded the best growth approximately 120 times more pyridoxine is required to yield the same growth as pyridoxamine (Fig. 4). As with nicotinic acid and its amide, when these compounds are added together in the same concentration, the increment of growth is less than the sum of the individual increments. Upon an intramuscular load dose of 100 mg of pyridoxine, peak vitamin Bs levels are reached 2 hours after injection. The curves for 4 normal individuals are illustrated in Fig. 5. 

Pyridoxal (5 -phosphate), pyridoxamine (S -phos-phate) see vitamin B. ... 

Pyridoxine (B ) Pyridoxal phosphate Pyridoxamine phosphate Amino acid transformations... 

Pyridoxine (65) Pyridoxal phosphate Pyridoxamine phosphate Carriers of amino and carboxyl groups... 

Pyridoxine, pyridoxal, pyridoxamine, pyridoxal phosphate, pyridoxamine phosphate, and 4-pyridoxic acid were baseline resolved and detection limits of -C1 pmol were obtained on a C g column (A = 328nm, ex 393 nm, em) using a 0/100 -> 100/0 (at lOmin hold lOmin) IPA/water (33mM phosphate buffer pH 2.2 with lOmM octanesulfonic acid) gradient [327]. Excellent quantitative results from spinal fluid samples were also obtained. 

PALPO PAMPO pyridoxal phosphate pyridoxamine phosphate... 

An absolute requirement for pyridoxal phosphate was found for the Neurospora enzyme, none for the E. coli enzyme. The failure to observe this in the latter may be connected with the difficulty of obtaining dehydrase preparations free of pyridoxal phosphate.Pyridoxamine phosphate could not substitute for the pyridoxal phosphate. That there is a requirement for pyridoxal phosphate is supported by the fact that the threonine dehydrase activity is strongly inhibited by 5 X 10 M hydroxylamine and cyanide. 

FIGURE 14.22 Glutamate aspartate aminotransferase, an enzyme conforming to a double-displacement bisnbstrate mechanism. Glutamate aspartate aminotransferase is a pyridoxal phosphate-dependent enzyme. The pyridoxal serves as the —NH, acceptor from glntamate to form pyridoxamine. Pyridoxamine is then the amino donor to oxaloacetate to form asparate and regenerate the pyridoxal coenzyme form. (The pyridoxamine enzyme is the E form.)... 

The mechanism of the first part of transamination is shown in Figure 29.14. The process begins with reaction between the a-amino acid and pyridoxal phosphate, which is covalently bonded to the aminotransferase by an iminc linkage between the side-chain -NTI2 group of a lysine residue and the PLP aldehyde group. Deprotonation/reprotonation of the PLP-amino acid imine in steps 2 and 3 effects tautomerization of the imine C=N bond, and hydrolysis of the tautomerized imine in step 4 gives an -keto acid plus pyridoxamine... 

In general, pyridoxamine and pyridoxin are more stable than pyridoxal. All vitamers are relatively heat-stable in acid media, but heat labile in alkaline media. All forms of vitamin B6 are destroyed by UV light in both neutral and alkaline solution. The majority of vitamin B6 in the human body is stored in the form of pyridoxal phosphate in the muscle, bound to glycogen phos-phorylase. 

In nature, aminotransferases participate in a number of metabolic pathways [4[. They catalyze the transfer of an amino group originating from an amino acid donor to a 2-ketoacid acceptor by a simple mechanism. First, an amino group from the donor is transferred to the cofactor pyridoxal phosphate with formation of a 2-keto add and an enzyme-bound pyridoxamine phosphate intermediate. Second, this intermediate transfers the amino group to the 2-keto add acceptor. The readion is reversible, shows ping-pong kinetics, and has been used industrially in the production ofamino acids [69]. It can be driven in one direction by the appropriate choice of conditions (e.g. substrate concentration). Some of the aminotransferases accept simple amines instead of amino acids as amine donors, and highly enantioselective cases have been reported [70]. 

Figure 7-4. Ping-pong mechanism for transamination. E—CHO and E—CHjNHj represent the enzyme-pyridoxal phosphate and enzyme-pyridoxamine complexes, respectively. (Ala, alanine Pyr, pyruvate KG, a-ketoglutarate Glu, glutamate).

Six compounds have vitamin Bg activity (Figure 45-12) pyridoxine, pyridoxal, pyridoxamine, and their b -phosphates. The active coenzyme is pyridoxal 5 -phos-phate. Approximately 80% of the body s total vitamin Bg is present as pyridoxal phosphate in muscle, mostly associated with glycogen phosphorylase. This is not available in Bg deficiency but is released in starvation, when glycogen reserves become depleted, and is then available, especially in liver and kidney, to meet increased requirement for gluconeogenesis from amino acids. 

Figure 3. Addition, of the GOT coenzymes pyridoxal and pyridoxamine phosphates in concentrations up to 200 /tg/ml lias no effect on human serum GOT but activates bu 45% the pig heart GOT activity of VersatoUE, a commercial reference serum...

FIGURE 10.2 Structural formula of vitamin and related compounds. 1 — pyridoxine, 2 — pyridoxal, 3 — pyridoxamine, 4 — 4-pyridoxic acid 5 — pyridoxal-5 -phosphate. 

Solvent System (v/v) Pyridoxal Pyridoxine Pyridoxic Acid Pyridoxic Acid Lactone Pyridoxamine Pyridoxal Phosphate... 

Pyridoxal Phosphate.—Analogues of pyridoxal and pyridoxamine 5 -phosphates have frequently been used to probe the size and shape of the active sites of a number of enzymes. For example, the apoenzyme of a tryptophanase from Bacillus alvei will bind pyridoxal 5 -phosphate as well as the 2-nor, 2 -methyl, 2 -hydroxy, 6-methyl, and A-oxide analogues.27 No analogue that has been modified at C-4 binds to the enzyme, confirming the absolute requirement for Schiff-base formation between the... 

Identification of pyridoxal phosphate as coenzyme suggested the aldehyde group on pyridoxine might form an intermediate Schiff s base with the donor amino acid. Pyridoxamine phosphate thus formed would in turn donate its NH2 group to the accepting a-ketonic acid, a scheme proposed by Schlenk and Fisher. 15N-labeling experiments and, later, the detection of the Schiff s base by its absorption in UV, confirmed the overall mechanism. Free pyridoxamine phosphate however does not participate in the reaction as originally proposed. Pyridoxal phosphate is invariably the coenzyme form of pyridoxine. 

Vitamin Bg a family of molecules having vitamin Be activity these include pyridoxal, pyridoxine, and pyridoxamine precursors to the coenzyme pyridoxal phosphate. 

The terminology vitamin Bg covers a number of structurally related compounds, including pyridoxal and pyridoxamine and their 5 -phosphates. Pyridoxal 5 -phosphate (PLP), in particular, acts as a coenzyme for a large number of important enzymic reactions, especially those involved in amino acid metabolism. We shall meet some of these in more detail later, e.g. transamination (see Section 15.6) and amino acid decarboxylation (see Section 15.7), but it is worth noting at this point that the biological role of PLP is absolutely dependent upon imine formation and hydrolysis. Vitamin Bg deficiency may lead to anaemia, weakness, eye, mouth, and nose lesions, and neurological changes. 

We have just noted the role that pyridoxal phosphate plays as a coenzyme (cofactor) in transamination reactions (see section 15.6). Pyridoxal 5 -phosphate (PLP) is crucial to a number of biochemical reactions. PLP, together with a number of closely related materials that are readily converted into PLP, e.g. pyridoxal, pyridoxine and pyridoxamine, are collectively known as vitamin Bg, which is essential for good health. 

Pyridoxal phosphate (4) is the most important coenzyme in amino acid metabolism. Its role in transamination reactions is discussed in detail on p. 178. Pyridoxal phosphate is also involved in other reactions involving amino acids, such as decarboxylations and dehydrations. The aldehyde form of pyridoxal phosphate shown here (left) is not generally found in free form. In the absence of substrates, the aldehyde group is covalently bound to the e-amino group of a lysine residue as aldimine ( Schiffs base ). Pyridoxamine phosphate (right) is an intermediate of transamination reactions. It reverts to the aldehyde form by reacting with 2-oxoacids (see p. 178). 

Among the NH2 transfer reactions, transaminations (1) are particularly important. They are catalyzed by transaminases, and occur in both catabolic and anabolic amino acid metabolism. During transamination, the amino group of an amino acid (amino acid 1) is transferred to a 2-oxoacid (oxoacid 2). From the amino acid, this produces a 2-oxo-acid (a), while from the original oxoacid, an amino acid is formed (b). The NH2 group is temporarily taken over by enzyme-bound pyridoxal phosphate (PLP see p. 106), which thus becomes pyridoxamine phosphate. 

This pyridoxal-phosphate-dependent enzyme [EC 2.6.1.30] catalyzes the reaction of pyridoxamine with pyruvate to produce pyridoxal and L-alanine. 

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 B6 occurs naturally in three related forms pyridoxine (6.26 the alcohol form), pyridoxal (6.27 aldehyde) and pyridoxamine (6.28 amine). All are structurally related to pyridine. The active co-enzyme form of this vitamin is pyridoxal phosphate (PLP 6.29), which is a co-factor for transaminases which catalyse the transfer of amino groups (6.29). PLP is also important for amino acid decarboxylases and functions in the metabolism of glycogen and the synthesis of sphingolipids in the nervous system. In addition, PLP is involved in the formation of niacin from tryptophan (section 6.3.3) and in the initial synthesis of haem. 

Cyclic interconversion of pyridoxal phosphate and pyridoxamine phosphate during the aspartate aminotransferase reaction. 

Vitamin B6 is a collective term for pyridoxine, pyridoxal, and pyridox amine, all derivatives of pyridine. They differ only in the nature of the functional group attached to the ring (Figure 28.10). Pyridoxine occurs primarily in plants, whereas pyridoxal and pyridoxamine are found in foods obtained from animals. All three compounds can serve as precur sors of the biologically active coenzyme, pyridoxal phosphate. Pyridoxal phosphate functions as a coenzyme for a large number of enzymes, par ticularly those that catalyze reactions involving amino acids. 

Vitamin B6 Pridoxine Pyridoxamine Pyridoxal Pyridoxal phosphate Cotacior for enzymes, particularly in 1 amino acid metabolism J. 

Vitamin B6 (pyridoxine, pyridoxamine, and pyridoxal) has the active form, pyridoxal phosphate. It functions as a cofactor for enzymes, particularly in amino acid metabolism. Deficiency of this vitamin is rare, but causes glossitis and neuropathy. The deficiency can be induced by isoniazid, which causes sensory neuropathy at high doses. 

---