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Transamination condensations intermediates

A key step in the synthesis of the spiroketal subunit is the convergent union of intermediates 8 and 9 through an Evans asymmetric aldol reaction (see Scheme 2). Coupling of aldehyde 9 with the boron enolate derived from imide 8 through an asymmetric aldol condensation is followed by transamination with an excess of aluminum amide reagent to afford intermediate 38 in an overall yield of 85 % (see Scheme 7). During the course of the asymmetric aldol condensation... [Pg.496]

Benzannulated NHPs are straightforwardly accessible from AUV-disubsti luted o-phenylenediamines either via base-induced condensation with substituted dichlorophosphines [25] or PC13 [26], or via transamination with tris(dialkylamino) phosphines [13, 14, 27], respectively. An analogous NH-substituted derivative was obtained in low yield via transamination of o-phcnylcncdiaminc with ethoxy-bis(diethylamino)phosphine [28], and condensation of o-phenylenediamine with excess tris(diethylamino)phosphine furnished a l,3-bis(phosphino)-substituted heterocycle [29], Intermediates with one or two NH functions were detectable by spectroscopy but could not be isolated in pure form under these conditions. However, 2-chloro-benzo-l,3,2-diazaphospholene and the corresponding 1-phenyl derivative were prepared in acceptable yield via condensation of PC13 with o-phenylenediamine under microwave irradiation [30], or with A-phenyl-o-phenylenediamine under reflux [27], respectively, in the absence of additional base. The formation of tetrameric benzo-NHPs during transamination of A-alkyl-o-phenylenediamines with P(NMe2)3 has already been mentioned (cf. the section entitled 1,3,2-Diazaphospholes and 1,3,2-Diazaphospholides ). [Pg.70]

NMR studies have been carried out on Schiff bases derived from pyridoxal phosphate and amino acids, since they have been proposed as intermediates in many important biological reactions such as transamination, decarboxylation, etc.90 The pK.d values of a series of Schiff bases derived from pyridoxal phosphate and a-amino adds, most of which are fluorinated (Figure 11), have been derived from H and19F titration curves.91 The imine N atom was found to be more basic and more sensitive to the electron-withdrawing effect of fluorine than the pyridine N atom. Pyridoxal and its phosphate derivative are shown in Figure 12a. The Schiff base formation by condensation of both with octopamine (Figure 12b) in water or methanol solution was studied by 13C NMR. The enolimine form is favoured in methanol, while the ketoamine form predominates in water.92... [Pg.726]

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) ... [Pg.337]

The normal mechanism for the transamination reaction is shown in Fig. 4.24 (R=H) and involves the condensation of alanine and pyridoxal phosphate to give an imine. A proton is lost from the imine to give a dihydropyridine intermediate. This reaction is catalysed by a basic amino acid provided by the enzyme as well as the electron withdrawing effects of the protonated pyridine ring. The dihydropyridine structure now formed is hydrolysed to give the products. [Pg.42]

The syntheses of valine, leucine, and isoleucine from pyruvate are illustrated in Figure 14.9. Valine and isoleucine are synthesized in parallel pathways with the same four enzymes. Valine synthesis begins with the condensation of pyruvate with hydroxyethyl-TPP (a decarboxylation product of a pyruvate-thiamine pyrophosphate intermediate) catalyzed by acetohydroxy acid synthase. The a-acetolactate product is then reduced to form a,/3-dihydroxyisovalerate followed by a dehydration to a-ketoisovalerate. Valine is produced in a subsequent transamination reaction. (a-Ketoisovalerate is also a precursor of leucine.) Isoleucine synthesis also involves hydroxyethyl-TPP, which condenses with a-ketobutyrate to form a-aceto-a-hydroxybutyrate. (a-Ketobutyrate is derived from L-threonine in a deamination reaction catalyzed by threonine deaminase.) a,/3-Dihydroxy-/3-methylvalerate, the reduced product of a-aceto-a-hydroxybutyrate, subsequently loses an HzO molecule, thus forming a-keto-/kmethylvalerate. Isoleucine is then produced during a transamination reaction. In the first step of leucine biosynthesis from a-ketoisovalerate, acetyl-CoA donates a two-carbon unit. Leucine is formed after isomerization, reduction, and transamination. [Pg.470]

The most versatile of the coenzymes is perhaps pyridoxal phosphate (PEP). The PEP containing enzymes catalyze a wide variety of reactions such as racemization, transamination, [3- and a-decarboxylation, and interconversion of side chains. The first step of all these reactions is the transition between an internal aldimine intermediate to an external aldimine intermediate, which involves the condensation of PEP with an external amino acid substrate to form a Schiff base. The internal aldimine intermediate can then either undergo a-decarboxylation to convert the amino acid substrate into amines and aldehydes, or lose the a-hydrogen... [Pg.667]

Alanine and aspartate can be synthesized directly from glutamate by transamination of pyruvate and oxaloacetate, respectively. Glutamate is the common intermediate that serves as the amino group donor in these reactions. (a-Ketoglutarate, the side product, can condense veith another molecule of ammonia to regenerate the glutamate for further transamination reactions.)... [Pg.440]

Figure 11.13 Reactions at a-carbon of a-amino acids catalyzed by pyridoxal enzymes All three substituents at C are subject to labilization in the three types of a-carbon reactions. The hydrogen is labilized in recemization reactions, the amino group is labUized in the transamination and the carboxyl group is labilized in decarboxylation. a-Amino acid condenses with pyridoxal phosphate to yield pyridoxylidene imino acid (an aldimine). The common intermediate, aldimine and distinct ketimines leading to the production of oxo-acid (in transamination), amino acid (in racemization) and amine (in decarboxylation) are shown. The catalytic acid (H-A-) and base (-B ) are symbolic both can be from the same residue such as Lys258 in aspartate aminotransferase. Figure 11.13 Reactions at a-carbon of a-amino acids catalyzed by pyridoxal enzymes All three substituents at C are subject to labilization in the three types of a-carbon reactions. The hydrogen is labilized in recemization reactions, the amino group is labUized in the transamination and the carboxyl group is labilized in decarboxylation. a-Amino acid condenses with pyridoxal phosphate to yield pyridoxylidene imino acid (an aldimine). The common intermediate, aldimine and distinct ketimines leading to the production of oxo-acid (in transamination), amino acid (in racemization) and amine (in decarboxylation) are shown. The catalytic acid (H-A-) and base (-B ) are symbolic both can be from the same residue such as Lys258 in aspartate aminotransferase.
The biosynthesis of lysine in higher plants involves the formation of a, e-diaminopimelate from aspartate and pyruvate. Transamination of this intermediate to the diketo compound and reduction of one carboxyl group to an aldehyde function may produce a compound capable of cyclization via aldol condensation, i.e., the C4 -I- C3 pathway. ... [Pg.655]

Transamination between oxo- and amino-acids is one of the enzymatic reactions that can be duplicated in metal ion model systems (1-4). The reactive intermediates appear to be "mixed complexes in which it is thought the ligands are condensed as Schiff bases. Recently, ways of applying pH-titration techniques to these systems and analyzing the data using high speed computers have been proposed (5). This earlier study (5) which concerned the Ni(II)-pyruvate-glycinate system has been extended to an examination of the Ca(II), Mn(II) and Zn(II) systems at 25 . An attempt was also made to obtain the heats and entropies of formation of the Mn(II), Ni(Il) and Zn(II) complexes from additional titrimetric data at 10 and 40 . [Pg.429]

Basically, the shikimic acid pathway involves initial condensation of phosphoenolpyruvate (PEP) from the glycolysis process with erythrose-4-phosphate derived from the oxidative pentose phosphate cycle. A series of reactions leads to shikimic acid, which is then phosphorylated. The phosphorylated shikimic acid combines with a second molecule of PEP to yield prephenic acid via chorismic acid intermediate. Prephenic acid is then decarboxylated to form phenyl-pyruvate or p-hydroxyphenylpyruvate. On transamination, these two compounds yield phenylalanine and tyrosine, respectively. [Pg.461]

L-Tyrosine biosynthesis starts with the condensation of phosphoenolpyruvate (PEP) and erythrose-4-phosphate (E4P), the intermediates of the glycolytic pathway and pentose phosphate pathway, respectively, which is catalyzed by 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase (DAHPS aroE/aroG/aroH). The resultant 3-deoxy-D-arabino-heptulosonate (DAHP) is converted into chorismate through the shikimate pathway with seven reactions. In plants, prephenate (PPA) is converted into L-arogenate by transamination whereas in E. coli, PPA is converted to p-hydroxyphenylpyruvate (HPP) by prephenate dehydrogenase, which is a bifunctional enzyme that behaves as chorismate mutase/prephenate... [Pg.18]

Another significant function of the citrate cycle is its central location between various degradative and synthetic pathways. The first connection with the metabolism of amino acids is found in ketoglutarate, which is a very general reaction partner in transamination. A second branch point is provided by succinyl-CoA, which can unite with glycine to form jS-aminolevulinate the latter condenses to form porphobilinogen, a key intermediate in the biosynthesis of the hemin ring system (cf. Chapt. IX). [Pg.319]

Oxaloacetate is an intermediate of many metabolic pathways. It also plays a role in the malate-aspartate shuttle, which transfers high energy electrons into mitochondria. Citrate is formed by the condensation of oxaloacetate with acetyl CoA. A transamination reaction transfers an amino group from an amino acid to an a-keto acid. Transfer of the amino group from aspartate to a-ketoglutarate forms oxaloacetate and glutamate. In gluconeogenesis, pyruvate is carboxylated in mitochondria to form oxaloacetate. After transfer to the cytosol, the enzyme phosphoenolpyruvate carboxykinase catalyses the conversion of oxaloacetate to phosphoenolpyruvate. [Pg.70]

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See also in sourсe #XX -- [ Pg.307 , Pg.309 ]



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