Enzymatic decarboxylation and

Amino acid-derived hormones include the catecholamines, epinephrine and norepinephrine (qv), and the thyroid hormones, thyroxine and triiodothyronine (see Thyroid AND ANTITHYROID PREPARATIONS). Catecholamines are synthesized from the amino acid tyrosine by a series of enzymatic reactions that include hydroxylations, decarboxylations, and methylations. Thyroid hormones also are derived from tyrosine iodination of the tyrosine residues on a large protein backbone results in the production of active hormone. 

The result of enzymatic decarboxylation was extremely clear. While (S)-compound resulted in C-containing product, (/ )-compound gave the product with C no more than natural abundance. Apparently, the enzyme decarboxylated pro-(/ ) carboxyl group selectively and the reaction proceeds with net inversion of configuration. Thus, the presence of a planar intermediate can be reasonably postulated. Enantioface-differentiating protonation to the intermediate will give the optically active final product (Eig. 12). 

The authors chose pyruvic acid as their model compound this C3 molecule plays a central role in the metabolism of living cells. It was recently synthesized for the first time under hydrothermal conditions (Cody et al., 2000). Hazen and Deamer carried out their experiments at pressures and temperatures similar to those in hydrothermal systems (but not chosen to simulate such systems). The non-enzymatic reactions, which took place in relatively concentrated aqueous solutions, were intended to identify the subsequent self-selection and self-organisation potential of prebiotic molecular species. A considerable series of complex organic molecules was tentatively identified, such as methoxy- or methyl-substituted methyl benzoates or 2, 3, 4-trimethyl-2-cyclopenten-l-one, to name only a few. In particular, polymerisation products of pyruvic acid, and products of consecutive reactions such as decarboxylation and cycloaddition, were observed the expected tar fraction was not found, but water-soluble components were found as well as a chloroform-soluble fraction. The latter showed similarities to chloroform-soluble compounds from the Murchison carbonaceous chondrite (Hazen and Deamer, 2007). 

The low specificity of electron-donating substrates is remarkable for laccases. These enzymes have high redox potential, making them able to oxidize a broad range of aromatic compounds (e.g. phenols, polyphenols, methoxy-substituted phenols, aromatic amines, benzenethiols) through the use of oxygen as electron acceptor. Other enzymatic reactions they catalyze include decarboxylations and demethylations [66]. 

Formate metabolism is the most obscure sector of the plant C network, and the one where the genome has yielded the most surprises.3 Plants have formate pools that are important sources of Ci units,24"27 and plants also have formate dehydrogenase activity.28 31 However, the origin of formate is not clear. It may come from non-enzymatic decarboxylation of glyoxylate in leaves in the light,27 32 but this cannot be... 

Borkenhangen, J.D., Kennedy, E.P., and Fielding, L., 1961, Enzymatic formation and decarboxylation of phosphatidylserine. J. Biol. Chem., 236 PC28-29. 

We examined the effect of restricted conformation on the activation entropy by kinetic studies at various temperatures [34]. Three kinds of substrates were subjected to the reaction phenylmalonic acid as the standard compound, ortho-chlorophenylmalonic acid as a substrate with an electron-withdrawing group, and indane-l,l-dicarboxylic acid as a conformationally restricted compound. The initial rates of the enzymatic decarboxylation reaction of three compounds were measured at several substrate concentrations at 15 °C, 25 °C, and 35 °C. The kcat and values at each temperature were obtained by a Lineweaver-Burk plot,... 

Structures of Thiamin-Dependent Enzymes 4. The Variety of Enzymatic Reactions Involving Thiamin 5. Oxidative Decarboxylation and 2-Acetylthiamin Diphosphate. 6. Thiamin Coenzymes in Nerve Action 753. .. Table 14-4 Some Pyruvoyl Enzymes... 

Many additional examples of the elucidation of prostereoisomerism in biochemical reactions could be given, for example the elegant elucidation by Comforth and coworkers 111, n8,137) of the biosynthesis of squalene, which was recognized by the Nobel prize in chemistry in 1975, or the recent studies of the enzymatic decarboxylation of tyrosine 138) and histidine 139) and of the condensation of homoserine with cysteine to give lanthionine 140), but the examples already provided should illustrate the principles and techniques involved in such studies. 

Scheme 3. Reaction path of enzymatic pyruvate decarboxylation and formation of a-hydroxy ketones...

Various 3-halopyruvate derivatives have been reported to be decarboxylated and simultaneously dehalogenated, yielding acetate, carbon dioxide and a halogenide ion as the only reaction products [133,158], A similar reaction may occur upon enzymatic decarboxylation of 3-hydroxypyruvate, which is an alternative substrate and a strong competitive inhibitor of PDC [159],... 

Bjerve, K.S. (1973). The Ca2+-dependent biosynthesis of lecithin, phosphatidylethanolamine and phosphatidylserine in rat liver subcellular particles. Biochim. Biophys. Acta 296,549-562. Bloch, F., Hansen, W.W., Packard, M. (1946). Nuclear induction. Phys. Rev. 69,127. Borkenhagen, L.F., Kennedy, E.P., Fielding, L. (1961). Enzymatic formation and decarboxylation of phosphatidylserine. J. Biol. Chem. 236, PC28-PC30. 

Aliphatic hydrocarbons such as n-alkanes and n-alkenes have been successfully used to distinguish between algal, bacterial, and terrestrial sources of carbon in estuarine/coastal systems (Yunker et al., 1991, 1993, 1995 Canuel et al., 1997). Saturated aliphatic hydrocarbons are considered to be alkanes (or paraffins) and nonsaturated hydrocarbons which exhibit one or more double bonds are called alkenes (or olefins)—as indicated in the simple structures of hexadecane and 1,3-butadiene, respectively (figure 9.7). It should also be noted that, n-alkanes tend to be odd-numbered as they result from enzymatic decarboxylation of fatty acids. Long-chain n-alkanes (LCH) (e.g., C27, C29, and C31) are generally considered to be terrestrially derived, originating from epicuticular waxes... 

The decarboxylation of oc-aminoacids catalyzed by isatin in aqueous media has been studied as a model for the enzymatic decarboxylation of these compounds. As a result, phenylglycine yields benzaldehyde and benzoic acid as products, but the efficiency of isatin is far lower than that of methoxatin (PQQ), the coenzyme of several alcohol and amine... 

The interest in the mechanisms of SchifF base hydrolysis stems largely from the fact that the formation and decomposition of SchifF base linkages play an important role in a variety of enzymatic reactions, for example, carbonyl transfers involving pyridoxal phosphate, aldol condensations, /3-decarboxylations and transaminations. The mechanisms for the formation and hydrolysis of biologically important SchifF bases, and imine intermediates, have been discussed by Bruice and Benkovic (1966) and by Jencks (1969). As the consequence of a number of studies (Jencks, 1959 Cordes and Jencks, 1962, 1963 Reeves, 1962 Koehler et al., 1964), the mechanisms for the hydrolysis of comparatively simple SchifF bases are reasonably well understood. From the results of a comprehensive kinetic investigation, the mechanisms for the hydrolysis of m- and p-substituted benzylidine-l,l-dimethylethylamines in the entire pH range (see, for example, the open circles in Fig. 13) have been discussed in terms of equations (23-26) (Cordes and Jencks, 1963) ... 

No 3-carboxy-substituted TBCs, derived from L-tryptophan by the Pic-tet-Spengler route, have yet been isolated from mammalian tissues. The same is also true for the dicarboxylic acid 23a derived from the condensation of L-tryptophan with pyruvic acid (36). The 1-carboxy-substituted TBCs 37 and 38, on the other hand, occur in mammalian systems (70,71) and are metabolically decarboxylated (65,S5). Whether a direct enzymatic decarboxylation of racemic material, occurring with the (S) and (R) enantiomers at a different rate, could account for the formation of unequal amounts of the enantiomers of TBC has not been investigated so far. The pyruvic acid route to optically active TBC (Fig. 12) leading from TBC 38a to TBC 29a via DBC 34 is at tifie moment the preferred pathway (85,86,89), although the enzymes involved in the asymmetric reduction leading to TBC 29a and the hydroxylated metabolites TBCs 30a and 33a have been neither isolated nor characterized. 

The reaction of optically active carbinolamines formed by an enzymatically controlled addition of acetaldehyde to amines, illustrated in Fig. 2, may be of theoretical interest, but lacks experimental verification it also would require the presence of acetaldehyde. The more likely pyruvic acid route to optically active TIQs, however, also remains inconclusive. If it indeed proceeds through TIQ-1-carboxylic acids to DIQ intermediates by an oxidative decarboxylation (176,217,218), it requires that it be followed by an asymmetric enzymatic reduction. Although achieved in vitro (35), this reaction has not been realized in vivo. The formation of unequal amounts of the optical isomers of salsolinol and other TIQs in vivo could arise from racemic 1-carboxy-TIQ in an enzymatic decarboxylation, proceeding with (S) and (R) enantiomers at a different rate and thus affording different amounts of (5)- and (/ )-TIQ. With the availability of optically active TIQ-1-carboxylic acids, this possibility can now be tested. 

Do optically active 1-methyl-TIQs, as sketched in Fig. 32 for the synthesis of (7 )-salsolinol, originate from a Pictet-Spengler reaction of dopamine with acetaldehyde derive from ethanol, or are they the result of a Pictet-Spengler reaction of biogenic amines with pyruvic acid, as sketched in Fig. 33 Based on the accumulated data it seems reasonable to propose that optically active TIQs are formed by the pyruvic acid pathway, and that the pyruvic acids may be derived from an impaired glucose metabolism or an impaired amino acid metabolism. Whether the intermediate TIQ-1-carboxylic acids 91a,b are enzymatically decarboxylated to afford 64a,b in a different enantiomeric ratio, or whether optically active TIQs are formed by oxidative decarboxylation of TIQ 91 to DIQ 120, followed by an asymmetric reduction, remains open to question. 

The biosynthesis of serotonin is similar to that of dopamine and also involves enzymatic hydroxylation and subsequent decarboxylation (Figure 10.2b). 

As early as 1964 it was recognized that 4-ethyl phenol and 4-ethyl guaiacol were produced by yeast and bacteria during fermentation by the decarboxylation of the hydroxyciimamic acids p-coumaric and fendic acid (88). Later it was reported that among yeast only Brettanomyces species possess the metabolic ability to enzymatically decarboxylate hydroxycinnamic acids to produce ethyl derivatives (29, 89). Heresztyn was the first to identify 4-ethyl phenol and 4t-ethyl guaiacol as the major volatile phenolic compounds formed by Brettanomyces yeast (84). ... 

Aldehydes related to common amino acids (3-methylbutanal from leucine, 2-methylpropanal from valine, phenylacetaldehyde from phenylalanine) are formed by enzymatic decarboxylation of the corresponding keto acids, which in turn are reversibly related to the amino acids by transamination [i.e., the keto acids are both degradation products of amino acids 147, 148) and intermediates in their synthesis 149). A third possibility—non-enzymatic oxidation of amino acids to aldehydes by enzymatically produced o-quinones—is established 150, 151) but is not discussed here. 

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