Biosynthesis,cDNA and amino acid sequences of a precursor of conglutin δ, a sulphur-rich protein from Lupinus angustifolius

The biosynthesis of conglutin has been studied in developing cotyledons of Lupinus angustifolius L. Precursors of conglutin formed the major sink for [³⁵S]-cysteine incorporated by developing lupin cotyledons, and these precursors were rapidly sequestered into the endoplasmic reticulum. The sequence of a cDNA clone coding for one such precursor of conglutin was determined. The structure of the precursor polypeptide for conglutin predicted from the cDNA sequence contained an N-terminal leader peptide of 22 amino acids directly preceding a subunit polypeptide of M _r 4520, together with a linking region of 13 amino acids and a subunit polypeptide of M _r 9558 at the C-terminus. The amino acid sequence predicted from the cDNA sequence showed minor variations from that established by sequencing of the protein purified from mature dried seeds (Lilley and Inglis, 1986). These were consistent with the existence of a multi-gene family coding for conglutin . Comparison of the sequences of conglutin with those of other 2S storage proteins showed that the cysteines involved in internal disulphide bridges between the mature subunits of conglutin , were maintained throughout this family of proteins but that little else was conserved either at the protein or DNA level.     

Biosynthesis and defensive function of Nδ-acetylornithine, a jasmonate-induced Arabidopsis metabolite

Since research on plant interactions with herbivores and pathogens is often constrained by the analysis of already known compounds, there is a need to identify new defense-related plant metabolites. The uncommon nonprotein amino acid N(δ)-acetylornithine was discovered in a targeted search for Arabidopsis thaliana metabolites that are strongly induced by the phytohormone methyl jasmonate (MeJA). Stable isotope labeling experiments show that, after MeJA elicitation, Arg, Pro, and Glu are converted to Orn, which is acetylated by NATA1 to produce N(δ)-acetylornithine. MeJA-induced N(δ)-acetylornithine accumulation occurs in all tested Arabidopsis accessions, other Arabidopsis species, Capsella rubella, and Boechera stricta, but not in less closely related Brassicaceae. Both insect feeding and Pseudomonas syringae infection increase NATA1 expression and N(δ)-acetylornithine accumulation. NATA1 transient expression in Nicotiana tabacum and the addition of N(δ)-acetylornithine to an artificial diet both decrease Myzus persicae (green peach aphid) reproduction, suggesting a direct toxic or deterrent effect. However, since broad metabolic changes that are induced by MeJA in wild-type Arabidopsis are attenuated in a nata1 mutant strain, there may also be indirect effects on herbivores and pathogens. In the case of P. syringae, growth on a nata1 mutant is reduced compared with wild-type Arabidopsis, but growth in vitro is unaffected by N(δ)-acetylornithine addition.     

Biosynthesis of Di-myo-Inositol-1,1′-Phosphate,a Novel Osmolyte in Hyperthermophilic Archaea

Biosynthesis of di-myo-inositol-1,1′-phosphate (DIP) is proposed to occur with myo-inositol and myo-inositol 1-phosphate (I-1-P) used as precursors. Activation of the I-1-P with CTP and condensation of the resultant CDP-inositol (CDP-I) with myo-inositol then generates DIP. The sole known biosynthetic pathway of inositol in all organisms is the conversion of d-glucose-6-phosphate to myo-inositol. This conversion requires two key enzymes: l-I-1-P synthase and I-1-P phosphatase. Enzymatic assays using ³¹P nuclear magnetic resonance spectroscopy as well as a colorimetric assay for inorganic phosphate have confirmed the occurrence of l-I-1-P synthase and a moderately specific I-1-P phosphatase. The enzymatic reaction that couples CDP-I with myo-inositol to generate DIP has also been detected in Methanococcus igneus. ¹³C labeling studies with [2,3-¹³C]pyruvate and [3-¹³C]pyruvate were used to examine this pathway in M. igneus. Label distribution in DIP was consistent with inositol units formed from glucose-6-phosphate, but the label in the glucose moiety was scrambled via transketolase and transaldolase activities of the pentose phosphate pathway.Di-myo-inositol-1,1′-phosphate (DIP) is an unusual inositol derivative that has been identified as a major solute in hyperthermophilic archaea including Pyrococcus woesei (22), Pyrococcus furiosus (16), Methanococcus igneus (5), and several eubacteria of the order Thermotogales (15). Intracellular DIP increases with increasing extracellular concentrations of NaCl in both M. igneus (5) and P. furiosus (16). DIP also increases dramatically at supraoptimal growth temperatures (>80°C for M. igneus and 98 to 101°C for P. furiosus). The unusual intracellular high concentration of K⁺ ions and the extreme optimal growth temperatures (100 to 104°C) of P. woesei (30) suggested the role of DIP as a main counterion of K⁺ with a possible thermostabilizing action. Scholz et al. (22) demonstrated that among several salts, the potassium salt of DIP provided optimum enzyme stabilization when the activity of glyceraldehyde-3-phosphate dehydrogenase of P. woesei was tested at 105°C under anaerobic conditions.Since de novo synthesis of DIP occurs in response to external levels of NaCl and temperature, there must be regulatory biosynthetic mechanisms linked to osmotic pressure and temperature. To study the regulation, the enzymes and/or other proteins responsible for synthesis of this compatible solute must be isolated. This requires knowledge of the biosynthetic pathways involved in the synthesis of DIP. The sole known pathway for inositol biosynthesis in all other organisms is the conversion of d-glucose-6-phosphate to l-myo-inositol 1-phosphate (l-I-1-P) via l-myo-inositol 1-monophosphate (I-1-P) synthase and hydrolysis of I-1-P to myo-inositol via a specific phosphatase, I-1-P phosphatase (13, 14). Similar enzymes are likely to exist in methanogens. A logical pathway for the biosynthesis of DIP would then use myo-inositol and I-1-P as precursors. Activation of the I-1-P with CTP and condensation of the resultant CDP-inositol (CDP-I) with myo-inositol would generate DIP. As summarized in Fig. ​Fig.1,1, DIP biosynthesis requires four key enzymes: I-1-P synthase (step 1), I-1-P phosphatase (step 2), CTP:I-1-P cytidylyltransferase (step 3), and DIP synthase (step 4). The enzymes that catalyze steps 1 and 2 have been well studied in plants, yeasts, and mammalian tissues. However, the enzymes invoked for steps 3 and 4 are novel activities, although based on similar chemical transformations in cells. Open in a separate windowFIG. 1Proposed biosynthetic pathway for DIP showing the four key enzymatic activities. Based on similar transformations in other organisms, cofactors are indicated for several of the steps.This work describes the use of ³¹P nuclear magnetic resonance (NMR) and colorimetric assays to verify the existence of three of these activities in cell extracts of M. igneus. Specific labeling of DIP with [¹³C]pyruvate was also used to probe the DIP biosynthetic pathway. The pattern of ¹³C label incorporation from [3-¹³C]pyruvate and [2,3-¹³C]pyruvate coupled with the known stereochemistry of DIP provided evidence that M. igneus also has enzymes of the pentose phosphate pathway (transaldolase and transketolase) that scramble label in glucose-6-phosphate.     

Biosynthesis of D-glucaric acid in mammals: a free-radical mechanism?

In the presence of iron salts and hydrogen peroxide, D-glucuronic acid was converted into D-glucaric acid. The reaction was strongly inhibited by free-radical scavengers and is ascribed to the action of the hydroxyl radical. The formation of D-glucarate was dependent upon pH and occurred in the presence of some iron-complexing agents. The first product of oxidation was a lactone that was a strong inhibitor of beta-D-glucuronidase and assumed to be D-glucaro-1,5-lactone. Microsomal preparations in the presence of NADPH also produced D-glucarate from D-glucuronic acid, presumably due to formation of hydrogen peroxide, and the product was an inhibitor of beta-D-glucuronidase. Superoxide did not produce D-glucarate from D-glucuronate. The cytochrome P450 system is more likely than "glucuronolactone dehydrogenase" to be responsible for the production of D-glucaric acid in vivo.     

Structural Characterization of CalS8, a TDP-α-d-Glucose Dehydrogenase Involved in Calicheamicin Aminodideoxypentose Biosynthesis

Classical UDP-glucose 6-dehydrogenases (UGDHs; EC 1.1.1.22) catalyze the conversion of UDP-α-d-glucose (UDP-Glc) to the key metabolic precursor UDP-α-d-glucuronic acid (UDP-GlcA) and display specificity for UDP-Glc. The fundamental biochemical and structural study of the UGDH homolog CalS8 encoded by the calicheamicin biosynthetic gene is reported and represents one of the first studies of a UGDH homolog involved in secondary metabolism. The corresponding biochemical characterization of CalS8 reveals CalS8 as one of the first characterized base-permissive UGDH homologs with a >15-fold preference for TDP-Glc over UDP-Glc. The corresponding structure elucidations of apo-CalS8 and the CalS8·substrate·cofactor ternary complex (at 2.47 and 1.95 Å resolution, respectively) highlight a notably high degree of conservation between CalS8 and classical UGDHs where structural divergence within the intersubunit loop structure likely contributes to the CalS8 base permissivity. As such, this study begins to provide a putative blueprint for base specificity among sugar nucleotide-dependent dehydrogenases and, in conjunction with prior studies on the base specificity of the calicheamicin aminopentosyltransferase CalG4, provides growing support for the calicheamicin aminopentose pathway as a TDP-sugar-dependent process.     

Biosynthesis and cell-wall deposition of a pectin–xyloglucan complex in pea

Golgi-enriched enzyme preparations prepared from etiolated pea epicotyls incorporated [U–¹⁴C]galactose from UDP-[U–¹⁴C]galactose into the 1,4--galactan sidechains of a pectin–xyloglucan complex. This complex could bind to paper and was degraded both by pectin-degrading enzymes and by a xyloglucan-specific endoglucanase. Gel permeation chromatography was used to assess the molecular size of the complex and of enzymically-degraded, galactan-containing fragments of it. Etiolated pea stems were labelled with [U–¹⁴C]sucrose for 1 h, and the newly-synthesised cell wall polysaccharides were extracted with EDTA or NaOH and fractionated by ion-exchange chromatography. The NaOH-extracted, acidic radioactive polysaccharides obtained in this way were also degraded both by pectin-degrading enzymes and by xyloglucan-specific endoglucanase. Analysis of the radioactive sugar composition indicated that neutral sugars characteristic of both pectin and xyloglucan were present. Analysis of the total non-radioactive, neutral sugar composition of the NaOH-extracted, acidic cell-wall polysaccharides indicated that pectin–xyloglucan complexes were a general feature of the cell wall in this tissue     

Biosynthesis of β-glucans in fungi

Glucans are the most abundant polysaccharides present in fungi. The present review provides updated information on the structure and synthesis of -glucans in fungal cells. Synthesis of these polymers made up of B1,3 chains with a variable degree of B1,6 branching involves several reactions: initiation, chain elongation and branching, of which the most studied one is the elongation step. This reaction, catalyzed by the so-called glucan synthetases, utilizes UDPG as sugar donor. Properties of glucan synthetases are extremely variable depending on the fungal species, and their developmental stage. Because of the importance of these polysaccharides it is anticipated that comprehension of their mechanism of synthesis, is important for the understanding of cell wall assembly and cell growth and morphogenesis, as well as for the design of specific antifungal drugs.Abreviations UDPG uridine-diphospho-glucose - GDPG guanosine-diphospho-glucose - ADPG adenosine-diphospho-glucose - MW molecular weight - mic minimal inhibitory concentration - d.p. degree of polymerization - PAGE polyacrylamide gel electrophoresis - SDS sodium dodecyl sulfate     

Biosynthesis of peptides containing α-aminoadipic acid and cysteine in extracts of a Cephalosporium sp

1. Three intracellular peptides found in small amount in a Cephalosporium sp. were rapidly labelled when dl-[(14)C]valine was added to a shaken suspension of the organism. More (14)C was incorporated into peptide P3, delta-(l-alpha-aminoadipyl)-l-cysteinyl-d-valine, than into peptide P2 (containing alpha-aminoadipic acid, cysteine, valine and glycine) or peptide P1 (containing beta-hydroxyvaline in place of the valine in peptide P2). 2. Peptides P3 and P2, but not peptide P1 were formed in a broken-cell system from the Cephalosporium sp. in the presence of delta-(l-alpha-aminoadipyl)-l-cysteine and dl-[(14)C]valine. No synthesis was observed in the presence of delta-(d-alpha-aminoadipyl)-l-cysteine or of dl-alpha-amino[(14)C]adipic acid and l-cysteinyl-l-valine or l-cysteinyl-d-valine. 3. The biosynthesis of these peptides was catalysed by the particulate fraction of the broken-cell system, whereas that of glutathione was catalysed by the supernatant fraction. 4. These results are discussed in relation to penicillin N and cephalosporin C biosynthesis.     

Biosynthesis,isolation, purification and separation of nivalenol,fusarenone — X and zearalenone

Fusarium, graminearum KF 370 isolate is able to simultaneous biosynthesis of three toxic metabolites, namely: fusarenone-X (FUS), nivalenol (NIV) and zearalenone (F-2). After metabolites extraction with methanol — water (3:1) and defatting with n-heptane toxins were partitioned into chloroform layer. Purification of the? compounds was performed on Celite 545 — charcoal — Aluminiumoxid 90 column then metabolites were separated on Kieselgel 60 (200–300 mesh) column with developing solvent chloroform — methanol. This way FUS, NIV and F-2 were obtained as crystalline or high purity standards.     

Biosynthesis of β-lactam nuclei in yeast

We have engineered brewer's yeast as a general platform for de novo synthesis of diverse β-lactam nuclei starting from simple sugars, thereby enabling ready access to a number of structurally different antibiotics of significant pharmaceutical importance. The biosynthesis of β-lactam nuclei has received much attention in recent years, while rational engineering of non-native antibiotics-producing microbes to produce β-lactam nuclei remains challenging. Benefited by the integration of heterologous biosynthetic pathways and rationally designed enzymes that catalyze hydrolysis and ring expansion reactions, we succeeded in constructing synthetic yeast cell factories which produce antibiotic cephalosporin C (CPC, 170.1 ± 4.9 μg/g DCW) and the downstream β-lactam nuclei, including 6-amino penicillanic acid (6-APA, 5.3 ± 0.2 mg/g DCW), 7-amino cephalosporanic acid (7-ACA, 6.2 ± 1.1 μg/g DCW) as well as 7-amino desacetoxy cephalosporanic acid (7-ADCA, 1.7 ± 0.1 mg/g DCW). This work established a Saccharomyces cerevisiae platform capable of synthesizing multiple β-lactam nuclei by combining natural and artificial enzymes, which serves as a metabolic tool to produce valuable β-lactam intermediates and new antibiotics.     

Biosynthesis of α- and β-ionone, prominent scent compounds, in flowers of Osmanthus fragrans

Carotenoid derived volatiles are important fragrance compounds, which contribute to the scents of flowers from diverse taxa. A famous example is represented by the flowers of Osmanthus fragrans where apocarotenoids account for more than 20% of all volatiles. In the recent years, bio-degradation of carotenoids has been shown to be an important route for apocarotenoids formation. Here, we report on the contribution the O. fragrans carotenoid cleavage dioxygenase 1 to the synthesis of the two predominant C(13)-apocarotenoids, α- and β-ionone, derived from α-and β-carotene, respectively.     

Biosynthesis of the storage polysaccharide from the snail Biomphalaria glabrata,identification and specificity of a branching β1→6 galactosyltransferase

Adult snails synthesize in their albumen glands a storage polysaccharide called galactan which is utilized by the developing embryos. With [6-³H]-uridine 5diphosphogalactose the incorporation of labelled d-galactose into the polysaccharide can be traeed in freshly removed glands maintained in a bathing buffer. After centrifugation of homogenized glands, galactosyltrasferase activity is only found in the insoluble fraction. Chaps extracts of this material retain almost all of their activity and can be used for comparison of the incorporation rates into different native galactans or in various oligosaccharides. A highly efficient -(16) galactosyltransferase was detected when methyl 3-O-(-d-galactopyranosyl)--d-galactopyranoside was offered as acceptor. The substitution at the penultimate residue resulted in a branched trisaccharide as demonstrated by ¹H-NMR-spectroscopy and permethylation analysis of the reaction product. Comparable results were obtained with various oligosaccharides containing an internal galactose unit glycosidically linked 13. Attempts to separate and purify the various enzymes involved resulted in the isolation of a fraction which is able to transfer d-Gal exclusively to native galactan, but not to oligosaccharides. A further fraction was obtained from a different resin with activity for native galactan and 6-O-(-d-galactopyranosyl)-d-galactopyranose. but without any for methyl-3-O-(-d-galactopyranosyl)--d-galactopyranose. It is thus concluded that at least three different enzymes are involved in the biosynthesis of this snail galactan.Abbreviation Gal galactose - glc gas-liquid chromatography - Gro glycerol - tlc thin layer chromatography     

PqsBC,a Condensing Enzyme in the Biosynthesis of the Pseudomonas aeruginosa Quinolone Signal: CRYSTAL STRUCTURE,INHIBITION, AND REACTION MECHANISM*?

Pseudomonas aeruginosa produces a number of alkylquinolone-type secondary metabolites best known for their antimicrobial effects and involvement in cell-cell communication. In the alkylquinolone biosynthetic pathway, the β-ketoacyl-(acyl carrier protein) synthase III (FabH)-like enzyme PqsBC catalyzes the condensation of octanoyl-coenzyme A and 2-aminobenzoylacetate (2-ABA) to form the signal molecule 2-heptyl-4(1H)-quinolone. PqsBC, a potential drug target, is unique for its heterodimeric arrangement and an active site different from that of canonical FabH-like enzymes. Considering the sequence dissimilarity between the subunits, a key question was how the two subunits are organized with respect to the active site. In this study, the PqsBC structure was determined to a 2 Å resolution, revealing that PqsB and PqsC have a pseudo-2-fold symmetry that unexpectedly mimics the FabH homodimer. PqsC has an active site composed of Cys-129 and His-269, and the surrounding active site cleft is hydrophobic in character and approximately twice the volume of related FabH enzymes that may be a requirement to accommodate the aromatic substrate 2-ABA. From physiological and kinetic studies, we identified 2-aminoacetophenone as a pathway-inherent competitive inhibitor of PqsBC, whose fluorescence properties could be used for in vitro binding studies. In a time-resolved setup, we demonstrated that the catalytic histidine is not involved in acyl-enzyme formation, but contributes to an acylation-dependent increase in affinity for the second substrate 2-ABA. Introduction of Asn into the PqsC active site led to significant activity toward the desamino substrate analog benzoylacetate, suggesting that the substrate 2-ABA itself supplies the asparagine-equivalent amino function that assists in catalysis.     

Biosynthesis,properties and potential of natural–synthetic hybrids of polyhydroxyalkanoates and polyethylene glycols

Chemical conjugation with poly(ethylene glycols) (PEGs) are established procedures to facilitate solubilisation of hydrophobic compounds. Such techniques for PEGylation have been applied to polyhydroxybutyrate. ‘BioPEGylation’ of such polyhydroxyalkanoates (PHAs) to form natural–synthetic hybrids has been demonstrated through the addition of PEGs to microbial cultivation systems. The strategic addition of certain PEGs not only supports hybrid synthesis but may also provide a technique for control of PHA composition and molecular mass, and by extension, their physico-mechanical properties. PHA composition and molecular mass control by PEGs is dependent upon the polyethers’ molecular mass, loading in the cultivation system, time of introduction and microbial species. Hybrid characterisation studies are in their infancy, but results to date suggest that PHA–PEG hybrids have subtle, but significant, differences in their physiochemical and material properties as a consequence of the PEGylation.     

Biosynthesis of a β-(1 → 4)-mannan in fenugreek seedlings

A particulate enzymatic preparation, extracted from fenugreek seedlings (Trigonella foenum-graecum) catalyses the transfer of mannose from guanosine diphosphate-[U-¹⁴C]mannose and its incorporation into an alkali-soluble polysaccharide. Chemical and enzymatic study of this polysaccharide reveals the presence of only one type of osidic linkage, namely β-(1 → 4)-s-mannopyranosyl. The influence of some factors on this biosynthesis was studied, as well as the MW of the polysaccharide and the existence of an endogenous acceptor.     

Biosynthesis,processing, and extracellular release of α-l-fucosidase in lymphoid cell lines of different genetic origins

In humans, the quantity of α-l-fucosidase in serum is determined by heredity. The mechanism controlling levels of the enzyme in serum is unknown. Lymphoid cell lines derived from individuals with either low, intermediate, or high α-l-fucosidase in serum were established. Steady-state levels of intracellular and extracellular α-l-fucosidase as well as rates of synthesis and secretion of enzyme overlapped among the cell lines. Thus,_vivo} serum phenotypes were not expressed in this system. No appreciable differences in the qualitative processing of newly made α-l-fucosidase were observed among these lymphoid cell lines. Cells pulse-labeled with³⁵S-methionine from 0.25 to 2 hr had an intracellular form of enzyme with aM _r=58,000. Cells pulsed for 1.5 hr and chased for 21 hr with unlabeled methionine had an intracellular form ofM _r=60,000 and an extracellular form ofM _r=62,000. All three enzyme forms were glycoproteins with a common polypeptide chain ofM _r=52,000 but with different carbohydrate moieties. No evidence for a high molecular mass precursor form of α-l-fucosidase was found. Fucosidosis is a rare, inherited disease in which α-l-fucosidase activity in tissues and body fluids is low or absent. The mutations for fucosidosis and the serum polymorphism map separately. Lymphoid cells from two siblings with fucosidosis had 8-fold to 341-fold less intracellular α-l-fucosidase protein with 11-fold to 56-fold lower specific activities than control cells. Residual mutant enzyme was a glycoprotein with a polypeptide chain virtually the same size (M _r=52,000) as control enzyme. However, residual mutant enzyme was hypoglycosylated and hypersecreted as compared to control enzyme. This research was supported by National Institutes of Health Grant DK 32161.     

Biosynthesis of phloroglucinol compounds in microorganisms—review

Phloroglucinol derivatives are a major class of secondary metabolites of wide occurrence in biological systems. In the bacteria kingdom, these compounds can only be synthesized by some species of Pseudomonads. Pseudomonas spp. could produce 2,4-diacetylphloroglucinol (DAPG) that plays an important role in the biological control of many plant pathogens. In this review, we summarize knowledge about synthesis of phloroglucinol compounds based on the DAPG biosynthetic pathway. Recent advances that have been made in understanding phloroglucinol compound biosynthesis and regulation are highlighted. From these studies, researchers have identified the biosynthesis pathway of DAPG. Most of the genes involved in the biosynthesis pathway have been cloned and characterized. Additionally, heterologous systems of the model microorganism Escherichia coli are constructed to produce phloroglucinol. Although further work is still required, a full understanding of phloroglucinol compound biosynthesis is almost within reach. This review also suggests new directions and attempts to gain some insights for better understanding of the biosynthesis and regulation of DAPG. The combination of traditional biochemistry and molecular biology with new systems biology and synthetic biology tools will provide a better view of phloroglucinol compound biosynthesis and a greater potential of microbial production.     

Biosynthesis regulation of the β-glucosidase produced by a yeast strain transformed by genetic engineering

The biosynthesis of the -glucosidase enzyme was studied in a transformed yeast obtained by cloning in Saccharomyces cerevisiae the structural gene coding for -glucosidase in Kluyveromyces fragilis. The enzyme biosynthesis was found to be non-adaptative, and repressed by glucose. These features are similar to those observed in K. fragilis. -Glucosidase activity in the transformed yeast was much higher than in K. fragilis. We attempted to ferment cellobiose with the transformed yeast: practically no cellobiose was consumed, growth and ethanol production were negligible. Warburg experiments showed that cellobiose fermentation did not occur when the respiratory chain was not functioning.     

Biosynthesis of phytoquinones. Homogentisic acid: a precursor of plastoquinones, tocopherols and α-tocopherolquinone in higher plants, green algae and blue–green algae

1. By means of (14)C tracer experiments and isotope competition experiments the roles of d-tyrosine, p-hydroxyphenylpyruvic acid, p-hydroxyphenylacetic acid, phenylacetic acid, homogentisic acid and homoarbutin (2-methylquinol 4-beta-d-glucoside) in the biosynthesis of plastoquinones, tocopherols and alpha-tocopherolquinone by maize shoots was investigated. It was established that d-tyrosine, p-hydroxyphenylpyruvic acid and homogentisic acid can all be utilized for this purpose, whereas p-hydroxyphenylacetic acid, phenylacetic acid and homoarbutin cannot. Studies on the mode of incorporation of d-tyrosine, p-hydroxyphenylpyruvic acid and homogentisic acid showed that their nuclear carbon atoms and the side-chain carbon atom adjacent to the nucleus give rise (as a C(6)-C(1) unit) to the p-benzoquinone rings and nuclear methyl groups (one in each case) of plastoquinone-9 and alpha-tocopherolquinone and the aromatic nuclei and nuclear methyl groups (one in each case) of gamma-tocopherol and alpha-tocopherol. 2. By using [(14)C]-homogentisic acid it has been shown that homogentisic acid is also a precursor of plastoquinone, tocopherols and alpha-tocopherolquinone in the higher plants Lactuca sativa and Rumex sanguineus, the green algae Chlorella pyrenoidosa and Euglena gracilis and the blue-green alga Anacystis nidulans.