A radiometric assay for 5-enolpyruvylshikimate-3-phosphate synthase

A new assay for 5-enolpyruvylshikimate-3-phosphate synthase is described. This enzyme of the shikimate pathway of aromatic amino acid biosynthesis generates 5-enolpyruvylshikimate 3-phosphate and orthophosphate from phosphoenolpyruvate and shikimate 3-phosphate. The shikimate pathway is present in bacteria and plants but not in mammals. The assay employs a paper-chromatographic separation of radiolabeled substrate from product. The method is specific, is sensitive to 50 pmol of product, and is suitable for use in crude extracts of bacteria. This enzyme appears to be the primary target site of the commercial herbicide glyphosate (N-phosphonomethyl glycine). A procedure for the enzymatic synthesis of [¹⁴C]shikimate 3-phosphate from the commercially available precursor [¹⁴C]shikimic acid is also described.     

Characterization of shikimate dehydrogenase homologues of Corynebacterium glutamicum

The function of three Corynebacterium glutamicum shikimate dehydrogenase homologues, designated as qsuD (cgR_0495), cgR_1216, and aroE (cgR_1677), was investigated. A disruptant of aroE required shikimate for growth, whereas a qsuD-deficient strain did not grow in medium supplemented with either quinate or shikimate as sole carbon sources. There was no discernible difference in growth rate between wild-type and a cgR_1216-deficient strain. Enzymatic assays showed that AroE both reduced 3-dehydroshikimate, using NADPH as cofactor, and oxidized shikimate, the reverse reaction, using NADP⁺ as cofactor. The reduction reaction was ten times faster than the oxidation. QsuD reduced 3-dehydroquinate using NADH and oxidized quinate using NAD⁺ as cofactor. Different from the other two homologues, the product of cgR_1216 displayed considerably lower enzyme activity for both the reduction and the oxidation. The catalytic reaction of QsuD and AroE was highly susceptible to pH. Furthermore, reduction of 3-dehydroshikimate by AroE was inhibited by high concentrations of shikimate, but neither quinate nor aromatic amino acids had any effect on the reaction. Expression of qsuD mRNA was strongly enhanced in the presence of shikimate, whereas that of cgR_1216 and aroE decreased. We conclude that while AroE is the main catalyst for shikimate production in the shikimate pathway, QsuD is essential for quinate/shikimate utilization.     

The shikimate pathway regulates programmed cell death

Programmed cell death (PCD) is essential for both plant development and stress responses including immunity. However, how plants control PCD is not well-understood. The shikimate pathway is one of the most important metabolic pathways in plants, but its relationship to PCD is unknown. Here, we show that the shikimate pathway promotes PCD in Arabidopsis. We identify a photoperiod-dependent lesion-mimic mutant named Lesion in short-day (lis), which forms spontaneous lesions in short-day conditions. Map-based cloning and whole-genome resequencing reveal that LIS encodes MEE32, a bifunctional enzyme in the shikimate pathway. Metabolic analysis shows that the level of shikimate is dramatically increased in lis. Through genetic screenings, three suppressors of lis (slis) are identified and the causal genes are cloned. SLISes encode proteins upstream of MEE32 in the shikimate pathway. Furthermore, exogenous shikimate treatment causes PCD. Our study uncovers a link between the shikimate pathway and PCD, and suggests that the accumulation of shikimate is an alternative explanation for the action of glyphosate, the most successful herbicide.     

The Site of the Inhibition of the Shikimate Pathway by Glyphosate: II. INTERFERENCE OF GLYPHOSATE WITH CHORISMATE FORMATION IN VIVO AND IN VITRO

In the presence of the nonselective herbicide glyphosate (N-[phosphonomethyl]glycine), buckwheat (Fagopyrum esculentum Moench) hypocotyls and cultured cells of Galium mollugo L. accumulate an organic acid, which was identified as shikimate by mass-spectroscopy of its methyl ester. After growth in 0.5 millimolar glyphosate for 10 days, G. mollugo cells contained shikimate in amounts of up to 10% of their dry weight. Synthesis of chorismate-derived anthraquinones in G. mollugo was blocked by glyphosate. Chorismate and o-succinylbenzoate (an anthraquinone precursor) alleviated the inhibition. The conclusion drawn from these experiments, that glyphosate inhibits a step in the biosynthetic sequence from shikimate to chorismate, was substantiated by the finding that glyphosate is a powerful inhibitor of the conversion of shikimate to chorismate in cell-free extracts from Aerobacter aerogenes 62-1.     

Metabolic engineering of Corynebacterium glutamicum for shikimate overproduction by growth-arrested cell reaction

Corynebacterium glutamicum with the ability to simultaneously utilize glucose/pentose mixed sugars was metabolically engineered to overproduce shikimate, a valuable hydroaromatic compound used as a starting material for the synthesis of the anti-influenza drug oseltamivir. To achieve this, the shikimate kinase and other potential metabolic activities for the consumption of shikimate and its precursor dehydroshikimate were inactivated. Carbon flux toward shikimate synthesis was enhanced by overexpression of genes for the shikimate pathway and the non-oxidative pentose phosphate pathway. Subsequently, to improve the availability of the key aromatics precursor phosphoenolpyruvate (PEP) toward shikimate synthesis, the PEP: sugar phosphotransferase system (PTS) was inactivated and an endogenous myo-inositol transporter IolT1 and glucokinases were overexpressed. Unexpectedly, the resultant non-PTS strain accumulated 1,3-dihydroxyacetone (DHA) and glycerol as major byproducts. This observation and metabolome analysis identified glyceraldehyde-3-phosphate dehydrogenase (GAPDH)-catalyzed reaction as a limiting step in glycolysis. Consistently, overexpression of GAPDH significantly stimulated both glucose consumption and shikimate production. Blockage of the DHA synthesis further improved shikimate yield. We applied an aerobic, growth-arrested and high-density cell reaction to the shikimate production by the resulting strain and notably achieved the highest shikimate titer (141 g/l) and a yield (51% (mol/mol)) from glucose reported to date after 48 h in minimal medium lacking nutrients required for cell growth. Moreover, comparable shikimate productivity could be attained through simultaneous utilization of glucose, xylose, and arabinose, enabling efficient shikimate production from lignocellulosic feedstocks. These findings demonstrate that C. glutamicum has significant potential for the production of shikimate and derived aromatic compounds.     

Molecular Characterization of Quinate and Shikimate Metabolism in Populus trichocarpa

The shikimate pathway leads to the biosynthesis of aromatic amino acids essential for protein biosynthesis and the production of a wide array of plant secondary metabolites. Among them, quinate is an astringent feeding deterrent that can be formed in a single step reaction from 3-dehydroquinate catalyzed by quinate dehydrogenase (QDH). 3-Dehydroquinate is also the substrate for shikimate biosynthesis through the sequential actions of dehydroquinate dehydratase (DQD) and shikimate dehydrogenase (SDH) contained in a single protein in plants. The reaction mechanism of QDH resembles that of SDH. The poplar genome encodes five DQD/SDH-like genes (Poptr1 to Poptr5), which have diverged into two distinct groups based on sequence analysis and protein structure prediction. In vitro biochemical assays proved that Poptr1 and -5 are true DQD/SDHs, whereas Poptr2 and -3 instead have QDH activity with only residual DQD/SDH activity. Poplar DQD/SDHs have distinct expression profiles suggesting separate roles in protein and lignin biosynthesis. Also, the QDH genes are differentially expressed. In summary, quinate (secondary metabolism) and shikimate (primary metabolism) metabolic activities are encoded by distinct members of the same gene family, each having different physiological functions.     

Functional analysis of the essential bifunctional tobacco enzyme 3-dehydroquinate dehydratase/shikimate dehydrogenase in transgenic tobacco plants

In plants, the shikimate pathway occurs in the plastid and leads to the biosynthesis of aromatic amino acids. The bifunctional 3-dehydroquinate dehydratase/shikimate dehydrogenase (DHD/SHD) catalyses the conversion of dehydroquinate into shikimate. Expression of NtDHD/SHD was suppressed by RNAi in transgenic tobacco plants. Transgenic lines with <40% of wild-type activity displayed severe growth retardation and reduced content of aromatic amino acids and downstream products such as cholorogenic acid and lignin. Dehydroquinate, the substrate of the enzyme, accumulated. However, unexpectedly, so did the product, shikimate. To exclude that this finding is due to developmental differences between wild-type and transgenic plants, the RNAi approach was additionally carried out using a chemically inducible promoter. This approach revealed that the accumulation of shikimate was a direct effect of the reduced activity of NtDHD/SHD with a gradual accumulation of both dehydroquinate and shikimate following induction of gene silencing. As an explanation for these findings the existence of a parallel extra-plastidic shikimate pathway into which dehydroquinate is diverted is proposed. Consistent with this notion was the identification of a second DHD/SHD gene in tobacco (NtDHD/SHD-2) that lacked a plastidic targeting sequence. Expression of an NtDHD/SHD-2-GFP fusion revealed that the NtDHD/SHD-2 protein is exclusively cytosolic and is capable of shikimate biosynthesis. However, given the fact that this cytosolic shikimate synthesis cannot complement loss of the plastidial pathway it appears likely that the role of the cytosolic DHD/SHD in vivo is different from that of the plastidial enzyme. These data are discussed in the context of current models of plant intermediary metabolism.     

High-level De novo biosynthesis of arbutin in engineered Escherichia coli

Arbutin is a hydroquinone glucoside compound existing in various plants. It is widely used in pharmaceutical and cosmetic industries owing to its well-known skin-lightening property as well as anti-oxidant, anti-microbial, and anti-inflammatory activities. Currently, arbutin is usually produced by plant extraction or enzymatic processes, which suffer from low product yield and expensive processing cost. In this work, we established an artificial pathway in Escherichia coli for high-level production of arbutin from simple carbon sources. First, a 4-hydroxybenzoate 1-hydroxylase from Candida parapsilosis CBS604 and a glucosyltransferase from Rauvolfia serpentina were characterized by in vitro enzyme assays. Introduction of these two genes into E. coli led to the production of 54.71 mg/L of arbutin from glucose. Further redirection of carbon flux into arbutin biosynthesis pathway by enhancing shikimate pathway genes enabled production of 3.29 g/L arbutin, which is a 60-fold increase compared with the initial strain. Final optimization of glucose concentration added in the culture medium was able to further improve the titer of arbutin to 4.19 g/L in shake flasks experiments, which is around 77-fold higher than that of initial strain. This work established de novo biosynthesis of arbutin from simple carbon sources and provided a generalizable strategy for the biosynthesis of shikimate pathway derived chemicals. The high titer achieved in our engineered strain also indicates the potential for industrial scale bio-manufacturing of arbutin.     

Pathway-based Screening Strategy for Multitarget Inhibitors of Diverse Proteins in Metabolic Pathways

Many virtual screening methods have been developed for identifying single-target inhibitors based on the strategy of “one–disease, one–target, one–drug”. The hit rates of these methods are often low because they cannot capture the features that play key roles in the biological functions of the target protein. Furthermore, single-target inhibitors are often susceptible to drug resistance and are ineffective for complex diseases such as cancers. Therefore, a new strategy is required for enriching the hit rate and identifying multitarget inhibitors. To address these issues, we propose the pathway-based screening strategy (called PathSiMMap) to derive binding mechanisms for increasing the hit rate and discovering multitarget inhibitors using site-moiety maps. This strategy simultaneously screens multiple target proteins in the same pathway; these proteins bind intermediates with common substructures. These proteins possess similar conserved binding environments (pathway anchors) when the product of one protein is the substrate of the next protein in the pathway despite their low sequence identity and structure similarity. We successfully discovered two multitarget inhibitors with IC₅₀ of <10 µM for shikimate dehydrogenase and shikimate kinase in the shikimate pathway of Helicobacter pylori. Furthermore, we found two selective inhibitors (IC₅₀ of <10 µM) for shikimate dehydrogenase using the specific anchors derived by our method. Our experimental results reveal that this strategy can enhance the hit rates and the pathway anchors are highly conserved and important for biological functions. We believe that our strategy provides a great value for elucidating protein binding mechanisms and discovering multitarget inhibitors.     

Function of serotonin in seeds of walnuts

In plants serotonin (5-hydroxytryptamine) may function as a hormone and as a protective agent against predation. A role for serotonin as a secondary plant product involved in ammonia detoxification in seeds of walnuts (Juglans regia) is now also proposed. Serotonin is formed from tryptophan synthesized via the constitutive enzymes of the shikimate pathway localized in the plastids, and is stored in protein bodies developed in the cotyledons during maturation. By the accumulation of serotonin in these protein bodies, the seeds, which have no vacuoles for storage or excretion of hydrophilic secondary plant products, are able to detoxify ammonia by the synthesis of serotonin.     

High-resolution structure of shikimate dehydrogenase from Thermotoga maritima reveals a tightly closed conformation

Shikimate dehydrogenase (SDH), which catalyses the NADPH-dependent reduction of 3-dehydroshikimate to shikimate in the shikimate pathway, is an attractive target for the development of herbicides and antimicrobial agents. Structural analysis of a SDH from Thermotoga maritima encoded by the Tm0346 gene was performed to facilitate further structural comparisons between the various shikimate dehydrogenases. The crystal structure of SDH from T. maritima was determined at 1.45 Å by molecular replacement. SDH from T. maritima showed a monomeric architecture. The overall structure of SDH from T. maritima comprises the N-terminal α/β sandwich domain for substrate binding and the C-terminal domain for NADP binding. When the T. maritima SDH structure was compared with those of the SDHs from other species, the SDH from T. maritima was in a tightly closed conformation, which should be open for catalysis. Notably, α7 moves toward the active site (∼5 Å), which forces the SDH of T. maritima in a more closed form. Four ammonium sulfate (AMS) ions were identified in the structure. They were located in the active site and appeared to mimic the role of the substrate in terms of the enzyme activity and stability. The new high resolution structural information reported in this study, including the AMS binding sites as a potent inhibitor binding site of SDHs, is expected to supplement the existing structural data and will be useful for structure-based antibacterial discovery against SDHs.     

Shikimate kinase from spinach chloroplasts : purification, characterization, and regulatory function in aromatic amino Acid biosynthesis

Shikimate kinase was purified to near homogenity from spinach Spinacia oleracea L. chloroplasts and found to consist of a single 31 kilodalton polypeptide. The purified enzyme was unstable, but could be stabilized by a variety of added proteins, including oxidized and reduced thioredoxins. Whereas the isolated enzyme was stimulated by mono- and dithiol reagents, the enzyme in intact chloroplasts was unaffected by added thiols and showed only minor response to dark/light transitions. These results indicate that the previously reported stimulation of shikimate kinase activity by reduced thioredoxins is due to enzyme stabilization rather than to activation. In the current study, the purified enzyme was inhibited by added ADP and showed a strong response to energy charge. When intact chloroplasts were incubated in the dark in presence of shikimate, phosphoenolpyruvate and a source of ATP (dihydroxyacetone phosphate or ATP itself under appropriate conditions), aromatic amino acids were formed: phenylalanine and tyrosine. The data indicate that energy charge plays a role in regulating shikimate kinase, thereby controlling the shikimate pathway. An unidentified enzyme of the latter part of the pathway, leading from shikimate-3-phosphate to phenylalanine, appears to be activated by light.     

Identification of Polyketide Inhibitors Targeting 3-Dehydroquinate Dehydratase in the Shikimate Pathway of Enterococcus faecalis

Due to the emergence of resistance toward current antibiotics, there is a pressing need to develop the next generation of antibiotics as therapeutics against infectious and opportunistic diseases of microbial origins. The shikimate pathway is exclusive to microbes, plants and fungi, and hence is an attractive and logical target for development of antimicrobial therapeutics. The Gram-positive commensal microbe, Enterococcus faecalis, is a major human pathogen associated with nosocomial infections and resistance to vancomycin, the “drug of last resort”. Here, we report the identification of several polyketide-based inhibitors against the E. faecalis shikimate pathway enzyme, 3-dehydroquinate dehydratase (DHQase). In particular, marein, a flavonoid polyketide, both inhibited DHQase and retarded the growth of Enterococcus faecalis. The purification, crystallization and structural resolution of recombinant DHQase from E. faecalis (at 2.2 Å resolution) are also reported. This study provides a route in the development of polyketide-based antimicrobial inhibitors targeting the shikimate pathway of the human pathogen E. faecalis.     

Purification and properties of hydroxycinnamoyl CoA quinate hydroxycinnamoyl transferase from potatoes

A rapid method for the purification of hydroxycinnamoyl CoA quinate hydroxycinnamoyl transferase (CQT) from potato tubers which had been stored at low temperatures is described. The method involves affinity chromatography on Blue Sepharose with biospecific desorption of CQT with its substrate, CoA. Elution of the Blue Sepharose column with a gradient of CoA leads to the resolution of CQT, a protein with MW of ca 41500, into 3 peaks of activity; the largest peak elutes first. This fraction is purified × 1440 and gives a single band of protein after PAGE which suggests a high degree of purity. The properties of the 3 fractions of CQT, with respect to substrates and to a number of inhibitors, are described. The first and last eluting CQT fractions are specific for quinate and show no activity towards shikimate. The second peak, however, shows a small activity towards shikimate but this is thought to be due to an underlying peak of a shikimate specific enzyme. The major peak of CQT activity found in potatoes stored at 0° is absent from those stored at 10° throughout the period after harvest.     

Biochemical and structural characterisation of dehydroquinate synthase from the New Zealand kiwifruit Actinidia chinensis

One of the novel aspects of kiwifruit is the presence of a high level of quinic acid which contributes to the flavour of the fruit. Quinic acid metabolism intersects with the shikimate pathway, which is responsible for the de novo biosynthesis of primary and secondary aromatic metabolites. The gene encoding the enzyme which catalyses the second step of the shikimate pathway, dehydroquinate synthase (DHQS), from the New Zealand kiwifruit Actinidia chinensis was identified, cloned and expressed. A. chinensis DHQS was activated by divalent metal ions, and was found to require NAD⁺ for catalysis. The protein was crystallised and the structure was solved, revealing a homodimeric protein. Each monomer has a NAD⁺ binding site nestled between the distinct N- and C-terminal domains. In contrast to other microbial DHQSs, which show an open conformation in the absence of active site ligands, A. chinensis DHQS adopts a closed conformation. This is the first report of the structure of a DHQS from a plant source.