Anthranilic acid shikimate pathway

The route of formation of the carbazole nucleus is still far from understood, and has been variously considered to arise from 3-prenylquinolone via a pathway involving shikimic acid (394) and mevalonic acid (MVA) (400) (Scheme 3.1) (1,112,362-366), anthranilic acid (397) and prephenic acid (404) via a pathway involving shikimic acid (394) (Scheme 3.2) (367), and also tryptophan (408) involving the mevalonate (400) pathway (Scheme 3.3) (133). All of these pathways lack experimental proof. However, based on the occurrence of the diverse carbazole alkaloids derived from anthranilic acid (397) in the family Rutaceae, the pathway... 

Alkaloids derived from L-tryptophan hold the indole nucleus in a ring system. The ring system originates in the shikimate secondary compounds building block and the anthranilic acid pathway. It is known that the shikimate block. 

Phenylalanine and tyrosine acts as precursor for opium alkaloid biosynthesis. Tryptophan is a significant source of Vinca alkaloids. Alkaloids are derived from anthranilic acid, which is an intermediate in biosynthesis of tryptophan. Some alkaloids are derived from acetate, terpene or shikimic acid. Shikimic acid is a significant metabolite as most of the aromatic constituents are derived from shikimic acid pathway. 

The indole moiety of the terpenoid indole alkaloids originates from tryptophan, an aromatic amino acid, which is derived from chorismate via anthranilate. Chorismate is a major branching point in plant primary and secondary metabolism. Here the shikimate pathway (Fig. 6) branches into different pathways (Fig. 7), among others leading to the aromatic amino acids tyrosine, phenylalanine, and tryptophan. 

Biosynthesis Like other aromatic amino acids, e.g., Phe and Tyr, Trp is formed on the shikimic acid pathway. There is a branching point at chorismic acid one branch leads to Phe and Tyr, the other to Trp choris-mic acid - anthranilic acid (anthranilic acid synthase, EC 4.1.3.27)- A-(5 -0-phosphoribosyl)-anthranilic acid (anthranilic acid phosphoribosyl transferase, EC 2.4.2.18)- 1 -o-carboxyphenylamino-1 -deoxyribu-lose 5-phosphate [A-(5 -phosphoribosyl)anthranilic acid isomerase]- indole-3-glycerol phosphate (in-dole-3-glycerol phosphate synthase, EC 4.1.1.48) - indole (tryptophan synthase, EC 4.2.1,20)+serine - Trp. Many biologically active indole compounds are derived from Trp, e. g., 5-hydroxytryptophan, 5-hydroxy-tryptamine ( serotonin), and melatonin as well as many indole alkaloids. 

Plants contain shikimate dehydrogenase (shikimate NADP oxidoreduc-tase) which reversibly interconverts dehydroshikimate and shikimate [Fig. 2 (4)]. The enzyme has been detected in a number of plant sources (Balinsky and Davies, l%la Yoshida, 1969). Unlike the microbial enzyme which is specific for NAD, the plant enzyme is specific for NADP (Balinsky and Davies, 1961b). Anthranilic acid and hydroxybenzoic acids inhibit the reaction in the direction of shikimate dehydrogenation (Balinsky and Davies, 1961b). The significance of the inhibition in controlling the activity of the pathway is unknown. 

Alkaloid biosynthesis needs the substrate. Substrates are derivatives of the secondary metabolism building blocks the acetyl coenzyme A (acetyl-CoA), shikimic acid, mevalonic acid, and 1-deoxyxylulose 5-phosphate (Figure 2.1). The synthesis of alkaloids starts from the acetate, shikimate, mevalonate, and deoxyxylulose pathways. The acetyl coenzyme A pathway (acetate pathway) is the source of some alkaloids and their precursors (e.g., piperidine alkaloids or anthranilic acid as aromatized CoA ester, anthraniloyl-CoA). Shikimic acid is a product of the glycol5dic and pentose phosphate pathways, a construction facilitated by parts of phosphoenolpyr-uvate and erythrose 4-phosphate (Figure 2.1). The shikimic acid pathway is the source of such alkaloids as quinazoline, quinoline, and acridine. 

In the biosynthesis of rutacridone, it is proposed that 1,3-dihydroxyacri-done is first formed from anthranilic acid and three C2 units, then the N-10 nitrogen is methylated to form 1,3-dihydroxy-N-methylacridone. Next, a C5 unit, IPP or DMAPP, is attached to 1,3-dihydroxy-N-methylacridone to fc>rm glycocitrine II, which is probably oxidized to produce an as-yet-uniden-tified epoxide. The epoxide is cyclized and dehydrated to give rutacridone [4]. Though rutacridone is a small molecule, as in the case of the quinoline alkaloids, three main biosynthetic precursors are involved in the biosynthesis of this alkaloid. Namely, the shikimic acid, the polyketide, and probably the iso-prenoid pathways all provide precursors for the biosynthesis of rutacridone. 

Most aromatic compounds in plants are derived from shikimic acid metabolism many of these substances are phenols. Compounds derived from this pathway are extensively modified and considered under other classes of plant secondary metabolites. Although many types of secondary compounds are produced from intermediates of the shikimic acid pathway (e.g., certain naphthoquinones and anthraquinones discussed in Chapter 6), most are derived from four aromatic amino acids phenylalanine, tyrosine, anthranilic acid, and tryptophan. Aromatic compounds that arise from the shikimic acid pathway usually can be distinguished from those of other origins by their substitution patterns and by a knowledge of the compounds with which they co-occur. 

Phenazines compounds based on the phenazine ring system (Table). All known naturally occurring P. are produced only by bacteria, which excrete them into the growth medium. Both six-membered carbon rings of P. are biosynthesized in the shikimate pathway of aromatic biosynthesis, via chorismic acid (not from anthranilate, as reported earlier). The earliest identified biosynthetic intermediate after chorismate is phenazine 1,6-dicarboxylate, which has been isolated from Pseudomonas phenazinium and from non-... 

Aromatic compounds are synthesized from carbohydrate precursors. These form a 7-carbon compound that cyclizes and loses water (or phosphate) and is reduced to shikimic acid. Shikimic acid is converted via unknown intermediates into three groups of compounds. One pathway leads to phenylalanine and tyrosine, the second forms anthranilic acid, which is a precursor of indole, and the third produces p-aminobenzoic acid and related compounds (I). Many of the individual steps in these pathways have been described in the last few years. 

With chorismic acid an important junction in the shikimic acid pathway has been reached. For as the Greek name implies (chorizo = split), the synthetic route divides into two branches after this substance. One branch leads via anthranilic acid to tryptophan, and from it to the... 

Anthranilic acid (or o-amino-benzoic acid) is an aromatic acid with the formula C H NO, which consists of a substituted benzene ring with two adjacent, or "ortho- functional groups, a carboxylic acid, and an amine (Fig. 14.1). Anthranilic acid is biosynthesized from shikimic acid (for shikimic acid biosynthesis, see Chapter 10) following the chorismic acid-mediated pathway [1]. Based on its biosynthetic mechanism, shikimate is transformed to shikimate 3-phosphate with the consumption of one molecule of ATP, catalyzed by shikimate kinase. 5-Enolpyruvylshikimate-3-phosphate (EPSP) synthase is then catalyze the addition of phosphoenolpyruvate to 3-phospho-shikimate followed by the elimination of phosphate, which leads to EPSP. EPSP is further transformed into chorismate by chorismate synthase. Chorismate reacts with glutamine to afford the final product anthranilate and glutamate pyruvate catalyzed by anthranilate synthase (Fig. 14.1). 

Phosphorylation of 3-hydroxyl group of shikimate by shikimate kinase (EC 2.7.1.71) with ATP as a cosubstrate initiates the biosynthesis pathway of anthranilic acid [2], This step also presents the first step of the shikimate pathway, which is a metabolic route used by bacteria, fungi, and plants for the biosynthesis of many aromatic products such as lignins, alkaloids, flavonoids, benzoic acid, and plant hormones, in addition to the aromatic amino acids (phenylalaiune, tyrosine, and tryptophan). The sequential EPSP synthesis is catalyzed by EPSP synthase (EC 2.5.1.19) through the addition of phosphoenolpyruvate to 3-phospho-shikimate followed elimination of phosphate. EPSP synthase belongs to the family of transferases, specifically to those transferring aryl... 

The labeling pattern of the non-tryptophan derived portion of (1) is most easily explained by a modified shikimate pathway leading to a substituted anthranilic acid (36) which condenses with a four-carbon diacid [e.g. oxaloacetic acid (37)] derived via the citric acid cycle. The anthranilate carboxyl group is presumably lost in cyclization and aroma-tization to the quinoline. Since glycolysis would have converted (35) to l,2- C2-acetyl CoA (38), its conversion to (37) via the intermediacy of symmetrical succinic acid (39) would then yield the labeling pattern observed for C-6, C-2-3, C4 of the labeled (1). 

---