Effect of radiation on the biosynthesis of L-Tryptophan from 14C-Anthranilic acid in kohlrabi (Brassica oleracea L., var.gongylodes L.)

The metabolism of¹⁴C-anthranilic acid (¹⁴C-AA) in kohlrabi (Brassica oleracea L. var.gongylodes L.) and the effect of radiation gamma⁶⁰Co on this metabolism was investigated. In hypocotylar segmnents of seven days old etiolated seedlings¹⁴C-AA was metabolised par, tially to its detoxication product¹⁴C-β-glucoside of AA. Simultaneously L-tryptophan was also formed, which in these plants is a precursor of indolic glucosinolates glucobrassicin and neoglucobrassicin. The metabolism of¹⁴C-AA was followed for 97 h. Radiation, applied both to seeds and to seven days old plants did not affect the metabolism of¹⁴C-AA substantially. The intermediary reaction AA → L-tryptophan in the biosynthesis of L-tryptophan is not a radiosensitive part of the synthesis of this amino acid. A not too high radiation sensitivity (max. 45%) was observed in the metabolic pathway leading from L-tryptophan to glucobrassicin.     

alpha-linolenic acid biosynthesis in Cyanidium caldarium.

Although α-linolenic acid is nearly absent from Cyanidium caldarium cultured at 53 °C, it is the most abundant unsaturated fatty acid in 20 °C-grown cells. A sudden growth temperature shift of 55 to 25 °C does not stimulate the immediate biosynthesis of α-linolenic acid. However, after an induction period of 48 h, synthesis of α-linolenic acid from acetate can be detected, and the fatty acid accumulates in phosphatidyl choline and sulfolipid. The newly synthesized α-linolenic acid appears to be formed primarily by de novo synthesis and to a much lesser extent from the elongation of a previously formed hexadecatrienoic acid precursor. On the other hand, when a cell-free algal preparation was presented with a hexadecatrienoic acid precursor in the presence of [¹⁴C] malonyl-CoA, the α-linolenic acid formed demonstrated a synthesis by elongation of the precursor. While the cell appears enzymatically capable of α-linolenic acid biosynthesis by both the de novo and elongation processes, de novo synthesis of α-linolenic acid appears to be the more significant mode of synthesis.     

Participation of C6C1 unit in the biosynthesis of ephedrine in Ephedra

Feeding of benzoic acid-[7-¹⁴C], benzaldehyde-[7-¹⁴C] and cinnamic acid-[3-¹⁴C] to Ephedra distachya resulted in efficient incorporations of ¹⁴C into the α-carbon atom of the side chain of l-ephedrine. Thus ephedrine was shown to be biosynthesized by the condensation of a C₆C₁ portion which is derived from phenylalanine via cinnamate and an unidentified C₂-N fragment.     

The interconversion of glycine and serine by plant tissue extracts

1. Extracts prepared from a variety of higher-plant tissues by ammonium sulphate fractionation were shown to catalyse the interconversion of glycine and serine. This interconversion had an absolute requirement for tetrahydrofolate and appeared to favour serine formation. 2. The biosynthesis of serine from glycine was studied in more detail with protein fractionated from 15-day-old wheat leaves. Synthesis of [¹⁴C]serine from [¹⁴C]glycine was not accompanied by labelling of glyoxylate, glycollate or formate. 3. The synthesis of serine from glycine was stimulated by additions of formaldehyde, and [¹⁴C]formaldehyde was readily incorporated into C-3 of serine in the presence of tetrahydrofolate. 4. The results are interpreted as indicating that serine biosynthesis involves a direct cleavage of glycine whereby the α-carbon is transferred via N⁵N¹⁰-methylenetetrahydrofolate to become the β-carbon of serine.     

Polyprenyl quinones and α-tocopherol in Calendula officinalis

In various cellular subfractions of Calendula officinalis leaves a study was made of the distribution of polyprenyl quinones and α-tocopherol and the dynamics of their labelling with ¹⁴CO₂ and acetate-[1-¹⁴C] and incorporation of mevalonate-[2-¹⁴C] after 3 hr. It was confirmed that plastoquinone occurs only in the chloroplasts, ubiquinone only in the mitochondria and α-tocopherol in both these subfractions. Phylloquinone was found in the chloroplast and mitochondrial fractions as well as in the post-mitochondrial supernatant. Studies of the dynamics of radioactive precursor incorporation indicated that α-tocopherol is metabolized more rapidly than the polyprenyl quinones studied; the incorporation of mevalonate-[2-¹⁴C] suggests that the side chain of plastoquinone can be synthesized in the cytoplasm and transported to the chloroplasts.     

In Vitro Characterization of Echinomycin Biosynthesis: Formation and Hydroxylation of L-Tryptophanyl-S-Enzyme and Oxidation of (2S,3S) β-Hydroxytryptophan

Quinoxaline-2-carboxylic acid (QXC) and 3-hydroxyquinaldic acid (HQA) feature in quinomycin family and confer anticancer activity. In light of the significant potency against cancer, the biosynthetic gene clusters have been reported from many different Streptomyces strains, and the biosynthetic pathway were proposed mainly based on the in vivo feeding experiment with isotope labeled putative intermediates. Herein we report another gene cluster from Streptomyces griseovariabilis subsp. bandungensis subsp. nov responsible for the biosynthesis of echinomycin (a member of quinomycin family, also named quinomycin A) and presented in vitro evidence to corroborate the previous hypothesis on QXC biosynthesis, showing that only with the assistance of a MbtH-like protein Qui5, did the didomain NRPS protein (Qui18) perform the loading of a L-tryptophan onto its own PCP domain. Particularly, it was found that Qui5 and Qui18 subunits form a functional tetramer through size exclusion chromatography. The subsequent hydroxylation on β-carbon of the loaded L-tryptophan proved in vitro to be completed by cytochrome P450-dependent hydroxylase Qui15. Importantly, only the Qui18 loaded L-tryptophan can be hydroxylated by Qui15 and the enzyme was inactive on free L-tryptophan. Additionally, the chemically synthesized (2S,3S) β-hydroxytryptophan was detected to be converted by the tryptophan 2,3-dioxygenase Qui17 through LC-MS, which enriched our previous knowledge that tryptophan 2,3-dioxygenase nearly exclusively acted on L-tryptophan and 6-fluoro-tryptophan.     

Biosynthesis of pteroside B in Pteridium aquilinum var. Latiusculum,proof of the sesquiterpenoid origin of the pterosides

Pteroside B was isolated in radioactive form after administration of [2-¹⁴C]mevalonate to Pteridium aquilinum var. latiusculum, demonstrating that the biosynthesis of the aglycone proceeds through the ordinary pathway to sesquiterpenoids. Kuhn-Roth oxidation of the radioactive aglycone was carried out to examine the distribution of the radioactivity among the 3 methyls of the aglycone. The biosynthetic implications of these results are discussed.     

The biosynthesis of flavonoid pigments: On the incorporation of phloroglucinol and phloroglucinyl cinnamate into rutin in Fagopyrum esculentum

The problem of whether phloroglucinol is a direct biosynthetic precursor of flavonoids was reinvestigated. Phloroglucinol-2,4,6-¹⁴C was found to be incorporated into rutin in Buckwheat (Fagopyrum esculentum) but most of the activity was found in the sugar moiety, the remainder being approximately equally distributed among the A- and B-rings of the aglycone, quercetin. This indicates extensive degradation of the added phloroglucinol prior to its utilization in the biosynthesis of the flavonoid. The hypothesis of a bio-Fries rearrangement of phloroglucinyl cinnamate to a chalcone, and hence to flavonoids, was also eliminated by comparing the efficiency of incorporation of ¹⁴C-labelled phloroglucinyl cinnamate and those of labelled phloroglucinol and cinnamic acid.     

Biosynthesis of nicotianamine in the suspension-cultured cells of tobacco (Nicotiana megalosiphon)

Summary Seven kinds of suspension cell cultures from five species ofNicotiana were screened for the occurrence of nicotianamine. Nicotianamine was detected in the cultured cells ofN. megalosiphon andN. plumbaginifolia.l-[l-¹⁴C]Methionine, which is the precursor of the mugineic-acid-family phytosiderophores and nicotianamine in barley plants, was incorporated into nicotianamine by the cultured cells ofN. megalosiphon both in vivo and in vitro. The advantage of the cultured tobacco cells for the study of the biosynthesis of nicotianamine and the mugineic-acid-family phytosiderophores is discussed.     

Synthesis of [3-14C]-2′-methylreticuline and its incorporation into alkaloid fractions of Papaver somniferum

[3-¹⁴C]-2′-Methylreticuline has been synthesized by standard methods. This modified opium alkaloid precursor is efficiently incorporated by aberrant biosynthesis into alkaloid fractions of Papaver somniferum, particularly into a highly purified codeine fraction.     

Transformation of14C labelled plant components in soil in relation to immobilization and remineralization of15N fertilizer

Summary Uniformly¹⁴C labelled glucose, cellulose and wheat straw and specifically¹⁴C labelled lignin component in corn stalks were aerobically incubated for 12 weeks in a chernozem soil alongwith¹⁵N labelled ammonium sulphate. Glucose was most readily decomposed, followed in order by cellulose, wheat straw and corn stalk lignins labelled at methoxyl-, side chain 2-and ring-C. More than 50% of¹⁴C applied as glucose, cellulose and wheat straw evolved as CO₂ during the first week. Lignin however, decomposed relatively slowly. A higher proportion of¹⁴C was transformed into microbial biomass whereas lignins contributed a little to this fraction.After 12 weeks of incubation nearly 60% of the lignin¹⁴C was found in humic compounds of which more than 70% was resistant to hydrolysis with 6N HCl. Maximum incorporation of¹⁵N in humic compounds was observed in cellulose amended soil. However, in this case more than 80% of the¹⁵N was in hydrolysable forms.Immobilization-remineralization of applied¹⁵N was most rapid in glucose treated soil and a complete immobilization followed by remineralization was observed after 3 days. The process was much slow in soil treated with cellulose, wheat straw or corn stalks. More than 70% of the newly immobilized N was in hydrolysable forms mainly reepresenting the microbial component.Serial hydrolysis of soil at different incubation intervals showed a greater proportion of 6N HCl hydrolysable¹⁴C and¹⁵N in fractions representing microbial material.¹⁴C from lignin carbons was relatively more uniformly distributed in different fractions as compared to glucose, cellulose and wheat straw where a major portion of¹⁴C was in easily hydrolysable fractions.     

Biosynthesis of monoterpenes by Ceratocystis moniliformis

Ceratocystis moniliformis produced and excreted monoterpenes when grown on potato-dextrose broth. Geraniol, nerol, citronellol, linalol, α-terpineol, geranial and neral were identified by GC-MS. Their production commenced with the depletion of nitrogen in the growth medium and their combined concentration peaked at about 50 μg/ml on the 5th day of growth. The pathway for the biosynthesis of the identified monoterpenes was studied by supplying the radioactive precursors mevalonic acid-[2-¹⁴C], l-leucine-[4,5-³H(N)], and acetate- [2-¹⁴C] to C. moniliformis. For each precursor, the extent of incorporation into the above monoterpenes and the distribution of radioactivity in geraniol was determined. It was concluded that monoterpenes were formed via the mevalonate pathway, previously established for higher terpenes in other organisms. This represents the first information available on the biosynthetic pathway for free monoterpenes in a microbial system.     

l-Ascorbic Acid Metabolism in Vitaceae: Conversion to (+)-Tartaric Acid and Hexoses

The metabolic fate of l-ascorbic acid-1-¹⁴C and -6-¹⁴C has been investigated in two species in two genera of Vitaceae. Results suggest that ascorbic acid metabolism in the Vitaceae involves splitting the 6-carbon chain into 4- and 2-carbon fragments. The former, corresponding to C1 through C4 of ascorbic acid, is further oxidized to tartaric acid while the latter, corresponding to C5 and C6, is recycled into hexose phosphate metabolism. Comparison of these findings with previous observations on the conversion of ascorbic acid to (+)-tartaric acid in Pelargonium crispum clearly reveals two distinct processes of tartaric acid biosynthesis in those plants identified as tartaric acid accumulators.     

NMR study of silk I structure of Bombyx mori silk fibroin with 15N- and 13C-NMR chemical shift contour plots

The metastable state silk I structures of Bombyx mori silk fibroin in the solid state were studied on the basis of ¹⁵N- and ¹³C-nmr chemical shifts of Ala, Ser, and Gly residues. The ¹⁵N cross-polarization magic angle spinning (CP/MAS) nmr spectra of the precipitated fraction after chymotrypsin hydrolysis of B. mori silk fibroin with the silk I and silk II forms were measured to determine the ¹⁵N chemical shifts of Gly, Ala, and Ser residues. For comparison, ¹⁵N CP/MAS nmr chemical shifts of Ala were measured for [¹⁵N] Ala Philosamia cynthia ricini silk fibroin with antiparallel β-sheet and α-helix forms. The ¹³C CP/MAS nmr chemical shifts of Ala, Ser, and Gly residues of B. mori silk fibroin with the silk I and silk II forms, as well as ¹³C CP/MAS nmr chemical shifts of Ala residue of P. c. ricini silk fibroin with β-sheet and α-helix forms, are used for the examination of the silk I structure. Both silk I and α-helix peaks are shifted to a lower field than silk II (β-sheet) for the Cα carbons of the Ala residues, while both Cβ carbon peaks are shifted to higher field. However, the silk I peak of the ¹⁵N nucleus of the Ala residue is shifted to lower field than the silk II peak, but the α-helix peak is shifted to high field. Thus, the difference in the structure between the silk I and α-helix is reflected in a different manner between the ¹³C and ¹⁵N chemical shifts. The Cα and Cβ chemical shift contour plots for Ala and Ser residues, and the Cα plot for the Gly residue, were prepared from the Protein Data Bank data obtained for 12 proteins and used for discussing the silk I structure quantitatively from the conformation-dependent chemical shifts. The plots reported by Le and Oldfield for ¹⁵N chemical shifts were also used for the purpose. All these chemical shift data support Fossey's model (Ala: ϕ = −80°, φ = 150°, Gly: ϕ = −150°, φ = 80°) and do not support Lotz and Keith's model (Ala: ϕ = −104.6°, φ = 112.2°, Gly: ϕ = 79.8°, φ = 49.7° or Ala: ϕ = −124.5°, φ = 88.2°, Gly: ϕ = −49.8°, φ = −76.1°) as the silk I structure. © 1997 John Wiley & Sons, Inc.     

Biosynthesis of triacylglycerols containing very long chain monounsaturated acyl moieties in developing seeds

Particulate (15,000g) fractions from developing seeds of honesty (Lunaria annua L.) and mustard (Sinapis alba L.) synthesize radioactive very long chain monounsaturated fatty acids (gadoleic, erucic, and nervonic) from [1-¹⁴C]oleoyl-CoA and malonyl-CoA or from oleoyl-CoA and [2-¹⁴C]malonyl-CoA. The very long chain monounsaturated fatty acids are rapidly channeled to triacylglycerois and other acyl lipids without intermediate accumulation of their CoA thioesters. When [1-¹⁴C]oleoyl-CoA is used as the radioactive substrate, phosphatidylcholines and other phospholipids are most extensively radiolabeled by oleoyl moieties rather than by very long chain monounsaturated acyl moieties. When [2-¹⁴C]malonyl-CoA is used as the radioactive substrate, no radioactive oleic acid is formed and the newly synthesized very long chain monounsaturated fatty acids are extensively incorporated into phosphatidylcholines and other phospholipids as well as triacylglycerols. The pattern of labeling of the key intermediates of the Kennedy pathway, e.g. lysophosphatidic acids, phosphatidic acids, and diacylglycerols by the newly synthesized very long chain monounsaturated fatty acids is consistent with the operation of this pathway in the biosynthesis of triacylglycerols.     

In vivo Biosynthesis of isopentenylacetophenones in Eupatorium rugosum

The biosynthesis of dehydrotremetone in Eupatorium rugosum has been investigated by feeding radioactive precursors to intact plants. The carbon atoms of acetate-[1-¹⁴C] and acetate-[2-¹⁴C] were identified in dehydrotremetone by degradation of the molecule. From the pattern of labeling it was concluded that the acetophenone moiety was derived from acetate via the polyacetate pathway. From the incorporation of mevalonate it appeared that the furan ring and its side chain were formed from an isoprenoid compound. Potential aromatic intermediates were chemically synthesized and also fed to plants but only tremetone was found to be efficiently incorporated into dehydrotremetone. Neither 4-hydroxyacetophenone nor 4-hydroxy-3[isopenten-(2)-yl]-acetophenone were efficiently incorporated into dehydrotremetone.     

Biosynthesis of avenic acid A in oat cv. Onward: studies with 14C or 15N labeled compounds

The precursory role of avenic acid A (AVA) in the biosynthesis of the mugineic acid family (MAs) of phytosiderophores was studied by feeding ¹⁴C or ¹⁵N labeled compounds into iron-deficient oat roots (Avena sativa L. cv. Onward). Carbon-14 of methionine was incorporated into AVA and 2-deoxymugineic acid (DMA) in the oat roots, while ¹⁴C of homoserine was not incorporated into either AVA or DMA. The molar radioactivity of DMA was higher than that of AVA. Incorporation of ¹⁵N into MAs was examined by feeding ¹⁵N-ammonium sulfate into oat roots. The value of ¹⁵N atom-% excess of DMA was higher than that of AVA.These results indicate that methionine, rather than homoserine, is the direct precursor of MAs in oat, which is similar to that in barley, and that AVA is not the precursor of the other MAs.     

Biosynthetic origin of the saw-toothed profile in δC and δΗ of n-alkanes and systematic isotopic differences between n-, iso- and anteiso-alkanes in leaf waxes of land plants

The n-fatty acids containing an even number of carbons (ECN-n-FAs) in higher plants are biosynthesised by repetitive addition of a two carbon unit from malonyl-ACP. The n-alkanes containing an odd number of carbon atoms (OCN-n-alkanes) are generally formed by the decarboxylation of ECN-n-FAs, but it is unknown how the less abundant even-carbon-numbered alkanes (ECN-n-alkanes) are biosynthesised in higher plants.There is a distinctive compositional pattern of incorporation of stable carbon (¹³C) and hydrogen (²H) isotopes in co-existing ECN- and OCN-n-alkanes in leaves of higher plants, such that the OCN n-alkanes are relatively enriched in ¹³C but relatively depleted in ²H against the ECN-n-alkanes. This is consistent with the OCN-n-fatty acids having a propionate precursor which is derived from reduction of pyruvate. A tentative pathway is presented with propionate produced by enzymatic reduction of pyruvate which is then thio-esterified with CoSH (coenzyme A thiol) in the chloroplast to form the terminal precursor molecule propionyl-CoA. This is then repetitively extended/elongated with the 2-carbon unit from malonyl-ACP to form the long chain OCN-n-fatty acids.The anteiso- and iso-alkanes in Nicotiana tabacum leaf waxes have previously been found to be systematically enriched in ¹³C compared with the n-alkanes by Grice et al. (2008). This is consistent with the isotopic composition of their putative respective precursors (pyruvate as precursor for n-alkanes, valine for iso-alkanes and isoleucine for anteiso-alkanes). The current study complements that of Grice et al. (2008) and looks at the distribution of hydrogen isotopes. The n-alkanes were found to be more enriched in deuterium (²H) than the iso-alkanes which in turn were more enriched than the anteiso-alkanes. We propose therefore that the depletion of ²H in the iso-alkanes, relative to the n-alkanes is the consequence of accepting highly ²H-depleted hydrogen atoms from NADPH during their biosynthesis. The anteiso-alkanes are further depleted again because there are three NADPH-derived hydrogen atoms in their precursor isoleucine, as compared with only one NADPH-derived hydrogen in valine, the precursor of the iso-alkanes.     

Studies of the Biochemical Background to Differences in Glucosinolate Content in Brassica napus L. II. Administration of Some Sulphur-35 and Carbon-14 Compounds and Localization of Metabolic Blocks

The aim of the investigation was to study the differences in the metabolism of substances that are utilized in the synthesis of glucosinolates between the Brassica napus cv. Bronowski, which is very low in glucosinolate content, and a cultivar (cv. Regina II) that contains approximately average amounts of these compounds. By experiments in which the plants were grown in nutrient solutions supplied with sulphate-³⁵S, it was shown that the rate of sulphate uptake was similar in the two cultivars. No accumulation of intermediate metabolites could be demonstrated by autoradiography in Bronowski. Sulphate-³⁵S, methionine-³⁵S, methionine-2-¹⁴C, 2-amino-6-(methylthio)caproic acid-2-¹⁴C, and S-(β-d -glucopyranosyl)-4-pentenethiohydroximic acid (desulpho-3-butenylglucosinolate) (glucose-U-¹⁴C or ³⁵S) were fed to shoots of the two cultivars. After incubation, the plant material was extracted with methanol. The extracts were separated into various fractions, and in some experiments glucosinolates or derivatives of their degradation products were isolated. When measuring the radioactivity of the various fractions or isolated products, the incorporation of radioactivity into glucosinolates was found to be poor in Bronowski from sulphate, methionine, and 2-amino-6-(methylthio)caproic acid. Desulpho-3-butenyl-glucosinolate was an efficient precursor of 3-butenylglucosinolate in Bronowski, but a poor precursor of 2-hydroxy-3-bute-nylglucosinolate, which suggests a metabolic block at the hydroxylation step in this cultivar. In Regina II desulpho-3-butenylglucosinolate was a good precursor of both 3-butenylglucosinolate and of 2-hydroxy-3-butenylglucosinolate, which demonstrates that these glucosinolates may be synthesized without prior formation of the corresponding co-methylthioalkyl glucosinolates and that the hydroxylation can take place after the formation of desulpho-3-butenylglucosinolate. The results indicate that the low glucosinolate content of Bronowski is caused by block(s) in the separate pathway leading to the biosynthesis of glucosinolates.     

Biosynthesis of gallic and ellagic acids with14C-labeled compounds inAcer andRhus leaves

The biosynthetic pathway for gallic and ellagic acids in young, mature and autumn leaves ofAcer buergerianum andRhus succedanea was examined by tracer experiments, and also by isotope competition, withd-shikimic acid-¹⁴C,l-phenylalanine-U-¹⁴C,l-phenyllactic acid-U-¹⁴C, gallic acid-G-¹⁴C and their unlabeled compounds. In young leaves of both plants, the incorporation rate of labeled shikimic acid into gallic acid was significantly higher than that of labeled phenylalanine, whereas in the mature and autumn leaves the latter was a good precursor rather than the former for the gallic acid biosynthesis. Therefore, two pathways for gallic acid formation, through β-oxidation of phenylpropanoid and through dehydrogenation of shikimic acid, could be operating inAcer andRhus leaves, and the preferential pathway is altered by leaf age. In both plants, the incorporation rate of labeled phenyllactic acid during a 24 hr metabolic period was almost the same as that of labeled phenylalanine. The incorporation ofd-skikimic acid-G-¹⁴C,l-phenylalanine-U-¹⁴C andl-phenyllactic acid-U-¹⁴C into ellagic acid was very similar to the case of the radioactive gallic acid formation. Furthermore, regardless of the presence of unlabeled shikimic acid and/or phenylalanine, incorporation of the radioactivity of labeled gallic acid into ellagic acid occurred at a very high rate, suggesting the reciprocal radical reaction of gallic acid for the ellagic acid formation. The incorporation of labeled compounds into ellagitanins was also examined and their biosynthesis discussed further.