Phenylpropanoids synthesis

Many secondary phenolic compounds are derived from the amino acids phenylalanine and tyrosine and therefore contain an aromatic ring and a three-carbon side chain (see Fig. 3.3). Phenylalanine is the primary substrate for phenylpropanoid synthesis in most higher vascular plants, with tyrosine being used to a lesser extent in some plants. Because of their common structure, compounds derived from these amino acids are collectively called phenylpropanoids. 

Matern, U., Wendorff, H., Hamerski, D., Pakusch, A.E. and Kneusel, R.E. (1988) Elicitor-induced phenylpropanoid synthesis in Apiaceae cell cultures. Bull. Liaison Groupe Polyphenols, 14,173-84. 

It has been detected that the plants increase the phenylpropanoids synthesis in different situations, like, defense against herbivores protection of microorganism attack or invasion by other species. Besides, some external factors that can increase the free radicals levels, such as stress, high light (more UV incidence), low temperatures, pathogen infections, nutrient deficiency [5], drought or ozone exposition [6], can induce a higher production of PPG by the plants. 

STUDIES ON THE REGULATION OF ENZYMES INVOLVED IN PHENYLPROPANOID SYNTHESIS... 

In the following, two examples will be given of the use of AOA and AOPP in studies on the regulation of the level of enzymes involved in phenylpropanoid synthesis. 

Plant metabolism can be separated into primary pathways that are found in all cells and deal with manipulating a uniform group of basic compounds, and secondary pathways that occur in specialized cells and produce a wide variety of unique compounds. The primary pathways deal with the metabolism of carbohydrates, lipids, proteins, and nucleic acids and act through the many-step reactions of glycolysis, the tricarboxylic acid cycle, the pentose phosphate shunt, and lipid, protein, and nucleic acid biosynthesis. In contrast, the secondary metabolites (e.g., terpenes, alkaloids, phenylpropanoids, lignin, flavonoids, coumarins, and related compounds) are produced by the shikimic, malonic, and mevalonic acid pathways, and the methylerythritol phosphate pathway (Fig. 3.1). This chapter concentrates on the synthesis and metabolism of phenolic compounds and on how the activities of these pathways and the compounds produced affect product quality. 

Precursors of phenylpropanoids are synthesized from two basic pathways the shikimic acid pathway and the malonic pathway (see Fig. 3.1). The shikimic acid pathway produces most plant phenolics, whereas the malonic pathway, which is an important source of phenolics in fungi and bacteria, is less significant in higher plants. The shikimate pathway converts simple carbohydrate precursors into the amino acids phenylalanine and tyrosine. The synthesis of an intermediate in this pathway, shikimic acid, is blocked by the broad-spectrum herbicide glyphosate (i.e., Roundup). Because animals do not possess this synthetic pathway, they have no way to synthesize the three aromatic amino acids (i.e., phenylalanine, tyrosine, and tryptophan), which are therefore essential nutrients in animal diets. 

Flavonoids are the largest class of phenylpropanoids in plants. The basic flavonoid structure is two aromatic rings (one from phenylalanine and the other from the condensation of three malonic acids) linked by three carbons (Fig. 3.6). Chalcone is converted to naringenin by the enzyme chalcone isomerase, which is a key enzyme in flavonoid synthesis. This enzyme, like PAL and chalcone synthase (CHS), is under precise control and is inducible by both internal and external signals. Naringenin is the... 

The 4-coumarate CoA ligase (4CL EC 6.2.1.12) enzyme activates 4-coumaric acid, caffeic acid, ferrulic acid, and (in some cases) sinapic acid by the formation of CoA esters that serve as branch-point metabolites between the phenylpropanoid pathway and the synthesis of secondary metabolites [46, 47]. The reaction has an absolute requirement for Mg " and ATP as cofactors. Multiple isozymes are present in all plants where it has been studied, some of which have variable substrate specificities consistent with a potential role in controlling accumulation of secondary metabolite end-products. Examination of a navel orange EST database (CitEST) for flavonoid biosynthetic genes resulted in the identification of 10 tentative consensus sequences that potentially represent a multi-enzyme family [29]. Eurther biochemical characterization will be necessary to establish whether these genes have 4CL activity and, if so, whether preferential substrate usage is observed. 

Validation of the role of femloyl-CoA in the synthesis of the vanillin precursor will be detection of the appropriate intermediates and/or enzyme activities in placental extracts that could account for the production of the predicted levels of capsaicinoids. The presence of low levels of monolignol intermediates could be explained by lignin biosynthesis. An alternate route from phenylalanine to vanillin has been considered by some investigators Orlova et al. [68] demonstrated the role of the benzenoid pathway in petunia flowers for the biosynthesis of phenylpropanoid/benzenoid volatiles. 

The functions of phenylpropanoid derivatives are as diverse as their structural variations. Phenylpropanoids serve as phytoalexins, UV protectants, insect repellents, flower pigments, and signal molecules for plant-microbe interactions. They also function as polymeric constituents of support and surface structures such as lignins and suberins [1]. Therefore, biosynthesis of phenylpropanoids has received much interest in relation to these functions. In addition, the biosynthesis of these compounds has been intensively studied because they are often chiral, and naturally occurring samples of these compounds are usually optically active. Elucidation of these enantioselective mechanisms may contribute to the development of novel biomimetic systems for enantioselective organic synthesis. 

A four-year study of field-grown commercial carrot roots revealed that recently harvested, unprocessed carrot roots contained 24 ppm falcarinol and 65 ppm falcarindiol (8). 6-Methoxymellein (6-MM) had not been identified by Yates al (8) at that time, and was not measured in that study. Reexamination of data revealed that 6-MM was absent from most samples, but present in a few at concentrations of 2 to 8 ppm. Myristicin, 1 ppm, was detected in only one sample. Wulf et 1978, reported that myristicin was present in supermarket carrots. Other studies have shown that certain brands of supermarket carrots contain myristicin while others do not (Yates, unpub.). The presence of myristicin in some samples from the supermarket and its absence in unprocessed carrots analyzed as soon after harvest as possible suggests that myristicin formation is induced during some stage of processing. Since light is known to be an elicitor of a plant system that results in the synthesis of phenylpropanoid compounds, a study of the effect of light on harvested carrot roots was undertaken. 

Myristicin content of some carrot samples was increased two-to five-fold over nonirradiated controls (Table I). The increase in concentration of myristicin is presumed to be via the phenylpropanoid pathway phenylalanine ammonia-lyase, an enzyme of that system, is activated by light (9). Failure of some samples exposed to UV light to synthesize myristicin may be due to the absence or inhibition of a key enzyme needed for myristicin synthesis. 

Phenylalanine Ammonia-Lyase. The building units of lignin are formed from carbohydrate via the shikimic acid pathway to give aromatic amino acids. Once the aromatic amino acids are formed, a key enzyme for the control of lignin precursor synthesis is phenylalanine ammonia-lyase (PAL) (1). This enzyme catalyzes the production of cinnamic acid from phenylalanine. It is very active in those tissues of the plant that become lignified and it is also a central enzyme for the production of other phenylpropanoid-derived compounds such as flavonoids and coumarins, which can occur in many parts of the plant and in many different organs (35). Radioactive phenylalanine and cinnamic acid are directly incorporated into lignin in vascular tissue (36). 

In higher plants aromatic amino acids are required not only for protein synthesis, but as precursors for hormones, and a vast diversity of phenylpropanoid or other secondary metabolites. Thus, the availability of aromatic amino acids in a number of the spatially separate compartments of the plant-cell microenvironment is essential. 

The tightly regulated pathway specifying aromatic amino acid biosynthesis within the plastid compartment implies maintenance of an amino acid pool to mediate regulation. Thus, we have concluded that loss to the cytoplasm of aromatic amino acids synthesized in the chloroplast compartment is unlikely (13). Yet a source of aromatic amino acids is needed in the cytosol to support protein synthesis. Furthermore, since the enzyme systems of the general phenylpropanoid pathway and its specialized branches of secondary metabolism are located in the cytosol (17), aromatic amino acids (especially L-phenylalanine) are also required in the cytosol as initial substrates for secondary metabolism. The simplest possibility would be that a second, complete pathway of aromatic amino acid biosynthesis exists in the cytosol. Ample precedent has been established for duplicate, major biochemical pathways (glycolysis and oxidative pentose phosphate cycle) of higher plants that are separated from one another in the plastid and cytosolic compartments (18). Evidence to support the hypothesis for a cytosolic pathway (1,13) and the various approaches underway to prove or disprove the dual-pathway hypothesis are summarized in this paper. 

Awale, S. et al., Facile and regioselective synthesis of phenylpropanoid-substituted flavan-3-ols, Org. Lett., 4, 1707, 2002. 

One of the major features of phenylpropanoid metabolism is the diversity of end products. The set of enzymic reactions leading from phenylalanine to 4-coumaroyl coenzyme A is common to pathways which lead to these diverse end products and is known as the general phenylpropanoid pathway (Fig. 1). Those biochemical reactions which lead to the synthesis of specialised products are known as branch pathways. 

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