N′-isopropylnornicotine: Its formation from nicotine in aged leaves of Nicotiana tabacum

An aqueous solution of nicotine-[2′-¹⁴C] was painted on the leaves of 4-month-old tobacco plants (Nicotiana tabacum) which were harvested 3 weeks later. This tracer was similarly applied to excised tobacco leaves which were allowed to dry in air for 4 weeks. The alkaloids, were extracted with the addition of N′-isopropylnornicotine, a compound which has been previously isolated from air-cured tobacco. Radioactive nicotine and nornicotine were isolated from the intact plants with only minute activity in the N′-isopropylnornicotine. All three of these alkaloids were radioactive from the air-cured leaves, and degradation of the labelled N'-isopropylnornicotine indicated that all the activity was located at the C-2′ position. A higher level of activity was found in N′-isopropylnornicotine which was obtained from excised leaves which were fed the nicotine- [2′- ¹⁴C] in aqueous acetone, and were treated on subsequent days with aqueous acetone. These results are consistent with the hypothesis that N′-isopropylnornicotine is produced in the curing of tobacco leaves by reaction of nornicotine (formed by the demethylation of nicotine) with acetoacetate, followed by decarboxylation and reduction. The ¹³C NMR chemical shifts of the methyl groups of N′-isopropylnornicotine and related 1-isopropylpyrrolidines which have chirality at the α-position of the pyrrolidine ring, are significantly different (up to 7.5 ppm).     

Enantioselective Demethylation of Nicotine as a Mechanism for Variable Nornicotine Composition in Tobacco Leaf

Nicotine and its N-demethylation product nornicotine are two important alkaloids in Nicotiana tabacum L. (tobacco). Both nicotine and nornicotine have two stereoisomers that differ from each other at 2′-C position on the pyrrolidine ring. (S)-Nicotine is the predominant form in the tobacco leaf, whereas the (R)-enantiomer only accounts for ∼0.2% of the total nicotine pool. Despite considerable past efforts, a comprehensive understanding of the factors responsible for generating an elevated and variable enantiomer fraction of nornicotine (EF_nnic of 0.04 to 0.75) from the consistently low EF observed for nicotine has been lacking. The objective of this study was to determine potential roles of enantioselective demethylation in the formation of the nornicotine EF. Recombinant CYP82E4, CYP82E5v2, and CYP82E10, three known tobacco nicotine demethylases, were expressed in yeast and assayed for their enantioselectivities in vitro. Recombinant CYP82E4, CYP82E5v2, and CYP82E10 demethylated (R)-nicotine 3-, 10-, and 10-fold faster than (S)-nicotine, respectively. The combined enantioselective properties of the three nicotine demethylases can reasonably account for the nornicotine composition observed in tobacco leaves, which was confirmed in planta. Collectively, our studies suggest that an enantioselective mechanism facilitates the maintenance of a reduced (R)-nicotine pool and, depending on the relative abundances of the three nicotine demethylase enzymes, can confer a high (R)-enantiomer percentage within the nornicotine fraction of the leaf.     

Spermidine: an indirect precursor of the pyrrolidine rings of nicotine and nornicotine in Nicotiana glutinosa

Spermidine, which was labeled asymmetrically in its four-carbon moiety ([6-¹⁴C]-1,5,10-triazadecane), was administered to Nicotiana glutinosa plants. After 7 days the plants were harvested, yielding radioactive nicotine (0.43 % incorporation) and nornicotine (0.07 % inc.). A systematic degradation of the alkaloids indicated that they were labelled equally at C-2′ and C-5′ of their pyrrolidine rings. These results are consistent with the hypothesis that spermidine is degraded to putrescine prior to its incorporation into the pyrrolidine rings of nicotine and nornicotine.     

Fast track to the trichome: induction of N-acyl nornicotines precedes nicotine induction in Nicotiana repanda

 Nicotiana repanda Wildenow ex Lehmann acylates nornicotine in its trichomes to produce N-acyl-nornicotine (NacNN) alkaloids which are dramatically more toxic than nicotine is to the nicotine-adapted herbivore, Manduca sexta. These NacNNs, like nicotine, were induced by methyl jasmonate (MeJA) and wounding, but the 2-fold increase in NacNN pools was much faster (within 6 h) than the MeJA-induced increase in nornicotine pools (24 h to 4 d), its parent substrate. When ¹⁵NO₃ ⁻ pulse-chase experiments with intact and induced plants were used to follow the incorporation of ¹⁵N into alkaloids in different plant parts over the plant's lifetime, it was found that the root nicotine pool was most rapidly labeled, followed by the shoot nornicotine and NacNN pools. After 3 d, 3.12% of ¹⁵N acquired was in nicotine (0.93%), nornicotine (0.32%) and NacNNs (1.73%) while only 0.14% was in anabasine. Once NacNNs are externalized to the leaf surface, they are not readily re-distributed within the plant and are lost with senescing leaves. The wound- and MeJA-induced N-acylation of nornicotine is independent of induced changes in nornicotine pools and the rapidity of the response suggests its importance in defense against herbivores. Received: 3 July 1999 / Accepted: 17 September 1999     

The incorporation of [5,6-13C2]Nicotinic acid into the tobacco alkaloids examined by the use of 13C nuclear magnetic resonance

[5,6-¹⁴C,¹³C₂]Nicotinic acid was prepared from [¹⁴C,¹³C]methyl iodide via nitromethane, 2-nitroacetaldehyde oxime, 3-nitroquinoline, 3-aminoquinoline, and quinoline in 20% overall yield. Administration of this material to Nicotiana tabacum and N. glauca afforded labeled anabasine, anatabine, nicotine, and nornicotine. Qualitative and quantitative incorporation (0.07–4.5% specific incorporation) was determined by radioactive assay and by examination of the ¹³C NMR spectra of these alkaloids. Satellites due to spin-spin coupling of the incorporated contiguous ¹³C atoms were observed at the resonances due to C-5 and C-6 in anabasine, nicotine, and nornicotine. In anatabine, satellites were found at C-5, C-6, C-5′, and C-6′.     

Phytochemical Studies on the Tobacco Alkaloids

Duplicate feeding experiments of dl-ornithine-2-¹⁴C to the excised tobacco root culture were made, and the radioactive nornicotine was isolated. Approximately two thirds of the radioactivity was located in the 2-position of the pyrrolidine of the nornicotine in these experiments. This fact indicates that there are two modes in nornicotine biosynthesis: exclusive incorporation to the C-2 and equal incorporation to C-2 and C-5 from C-2 of ornithine.

On the basis of this finding, biosynthetic route was discussed.

dl-Ornithine-2-¹⁴C, dl-methionine-¹⁴CH₃ and partially racemized l-nornicotine-2,5-¹⁴C were administered to aseptically grown excised roots (N. rustica var. Brasilia). Incorporation of their radioactivity to nicotine was compared. The extent of their radioactive incorporation to nicotine was high in the order of ornithine, methionine and nornicotine; incorporation of radioactivity of nornicotine to nicotine was extraordinarily low. ¹⁵N-Labeled nornicotine was also fed to the same materials and ¹⁵N distribution was examined. Most of ¹⁵N still remained in the nornicotine reisolated. Marked amounts of ¹⁵N were located in the ethanol-insoluble fraction, the amino acid fraction and the substances having chromatographic R_F value close to that of nicotine. Only small amount of ¹⁵N was incorporated to the isolated nicotine.

Nornicotine is generally accepted to be a direct precursor of nicotine in tobacco plants. From these findings, however, it can be said that the biosynthesis of nicotine can occur through other routes without going through nornicotine.     

Localization of cytokinin biosynthetic sites in pea plants and carrot roots

The biosynthesis of cytokinins was examined in pea (Pisum sativum L.) plant organs and carrot (Daucus carota L.) root tissues. When pea roots, stems, and leaves were grown separately for three weeks on a culture medium containing [8-¹⁴C]adenine without an exogenous supply of cytokinin and auxin, radioactive cytokinins were synthesized by each of these organs. Incubation of carrot root cambium and noncambium tissues for three days in a liquid culture medium containing [8-¹⁴C]adenine without cytokinin demonstrates that radioactive cytokinins were synthesized in the cambium but not in the noncambium tissue preparation. The radioactive cytokinins extracted from each of these tissues were analyzed by Sephadex LH-20 columns, reverse phase high pressure liquid chromatography, paper chromatography in various solvent systems, and paper electrophoresis. The main species of cytokinins detectable by these methods are N⁶-(Δ²-isopentyl_adenine-5′-monophosphate, 6-(4-hydroxy-3-methyl-2-butenyl-amino)-9-β-ribofuranosylpurine-5′- monophosphate, N⁶-(Δ²-isopentenyl)adenosine, 6-(4-hydroxy-3-methyl-2-butenylamino)-9-β-ribofuranosylpurine, N⁶-(Δ²-isopentenyl)adenine, and 6-(4-hydroxy-3-methyl-2-butenylamino)purine. On the basis of the amounts of cytokinin synthesized per gram fresh tissues, these results indicate that the root is the major site, but not the only site, of cytokinin biosynthesis. Furthermore, cambium and possibly all actively dividing tissues are responsible for the synthesis of this group of plant hormones.     

Metabolism of nicotine in Nicotiana glauca

A mixture of (?)-nicotine-[2′-³H] and (±)-nicotine-[2′-¹⁴C] was administered to Nicotiana glauca plants for 3 days, resulting in the formation of radioactive nornicotine (49·5% incorporation) and myosmine (2·05% incorporation). Negligible activity was detected in anabasine, cotinine, or 3-acetylpyridine, the last two compounds being added as carriers to the harvested plants. The radioactive nornicotine consisted of 48% (?)-nornicotine-[2′-¹⁴C,³H] and 52% (+)-nornicotine-[2′-¹⁴C]. Thus if (+)-nornicotine is formed from (?)-nicotine the transformation must involve loss of the hydrogen from C-2′. Myosmine is presumably formed from nicotine via nornicotine. However by feeding myosmine-[2′-¹⁴C] to N. glauca it was shown that the dehydrogenation is not reversible, no activity being detected in nornicotine. Nicotinic acid (0·14% incorporation) was a metabolite of myosmine-[2′-¹⁴C]. Essentially all the activity of the nicotinic acid was located on its carboxyl group, indicating that myosmine was a direct precursor.     

The Only African Wild Tobacco,Nicotiana africana: Alkaloid Content and the Effect of Herbivory

Herbivory in some Nicotiana species is known to induce alkaloid production. This study examined herbivore-induced defenses in the nornicotine-rich African tobacco N. africana, the only Nicotiana species indigenous to Africa. We tested the predictions that: 1) N. africana will have high constitutive levels of leaf, flower and nectar alkaloids; 2) leaf herbivory by the African bollworm Helicoverpa armigera will induce increased alkaloid levels in leaves, flowers and nectar; and 3) increased alkaloid concentrations in herbivore-damaged plants will negatively affect larval growth. We grew N. africana in large pots in a greenhouse and exposed flowering plants to densities of one, three and six fourth-instar larvae of H. armigera, for four days. Leaves, flowers and nectar were analyzed for nicotine, nornicotine and anabasine. The principal leaf alkaloid was nornicotine (mean: 28 µg/g dry mass) followed by anabasine (4.9 µg/g) and nicotine (0.6 µg/g). Nornicotine was found in low quantities in the flowers, but no nicotine or anabasine were recorded. The nectar contained none of the alkaloids measured. Larval growth was reduced when leaves of flowering plants were exposed to six larvae. As predicted by the optimal defense theory, herbivory had a localized effect and caused an increase in nornicotine concentrations in both undamaged top leaves of herbivore damaged plants and herbivore damaged leaves exposed to one and three larvae. The nicotine concentration increased in damaged compared to undamaged middle leaves. The nornicotine concentration was lower in damaged leaves of plants exposed to six compared to three larvae, suggesting that N. africana rather invests in new growth as opposed to protecting older leaves under severe attack. The results indicate that the nornicotine-rich N. africana will be unattractive to herbivores and more so when damaged, but that potential pollinators will be unaffected because the nectar remains alkaloid-free even after herbivory.     

The Catabolism of (+/-)-Abscisic Acid by Excised Leaves of Hordeum vulgare L. cv Dyan and Its Modification by Chemical and Environmental Factors

Excised light-grown leaves and etiolated leaves of Hordeum vulgare L. cv Dyan catabolized applied (±)-[2-¹⁴C]abscisic acid ([±]-[2-¹⁴C]ABA) to phaseic acid (PA), dihydrophaseic acid (DPA), and 2′-hydroxymethyl ABA (2′-HMABA). Identification of these catabolites was made by microchemical methods and by combined capillary gas chromatographymass spectrometry (GC-MS) following high dose feeds of nonlabeled substrate to leaves. Circular dichroism analysis revealed that 2′-HMABA was derived from the (−) enantiomer of ABA. By selecting tissue samples in which endogenous catabolites were undetectable by gas chromatography, it was possible to identify unequivocally ABA catabolites by GC-MS without the need to employ deuteriated substrate to distinguish the (±)-ABA catabolites from the same endogenous compounds. Refeeding studies were used to confirm the catabolic route. The methyl ester of (±)-[2¹⁴C]-ABA was hydrolyzed efficiently by light-grown leaves of H. vulgare. Leaf age played a significant role in (±)-ABA catabolism, with younger leaves being less able than their older counterparts to catabolize this compound. The catabolism of (±)-ABA was inhibited markedly in water-stressed Hordeum leaves which was characterized by a decreased incorporation of label into 2′-HMABA, DPA, and conjugates. The specific, mixed function oxidase inhibitor, ancymidol, did not inhibit, dramatically, (±)-ABA catabolism in light-grown leaves of Hordeum whereas the 80s ribosome, translational inhibitor, cycloheximide, inhibited this process markedly. The 70s ribosome translational inhibitors, lincomycin and chloramphenicol, were less effective than cycloheximide in inhibiting (±)-ABA catabolism, implying that cytoplasmic protein synthesis is necessary for the catabolism of (±)-ABA in Hordeum leaves whereas chloroplast protein synthesis plays only a minor role. This further suggests that the enzymes involved in (±)-ABA catabolism in this plant are cytoplasmically synthesized and are `turned-over' rapidly, although the enzyme responsible for glycosylating (±)-ABA itself appeared to be stable.     

Binding specificity and stability of duplexes formed by modified oligonucleotides with a 4096-hexanucleotide microarray

The binding of oligodeoxynucleotides modified with adenine 2′-O-methyl riboside, 2,6-diaminopurine 2′-O-methyl riboside, cytosine 2′-O-methyl riboside, 2,6-diaminopurine deoxyriboside or 5-bromodeoxyuridine was studied with a microarray containing all possible (4096) polyacrylamide-bound hexadeoxynucleotides (a generic microchip). The generic microchip was manufactured by using reductive immobilization of aminooligonucleotides in the activated copolymer of acrylamide, bis-acrylamide and N-(2,2-dimethoxyethyl) acrylamide. The binding of the fluorescently labeled modified octanucleotides to the array was analyzed with the use of both melting profiles and the fluorescence distribution at selected temperatures. Up to three substitutions of adenosines in the octamer sequence by adenine 2′-O-methyl ribosides (A^m), 2,6-diaminopurine 2′-O-methyl ribosides (D^m) or 2,6-diaminopurine deoxyribosides (D) resulted in increased mismatch discrimination measured at the melting temperature of the corresponding perfect duplex. The stability of complexes formed by 2′-O-methyl-adenosine-modified oligodeoxynucleotides was slightly decreased with every additional substitution, yielding ~4°C of total loss in melting temperature for three modifications, as followed from microchip thermal denaturation experiments. 2,6-Diaminopurine 2′-O-methyl riboside modifications led to considerable duplex stabilization. The cytosine 2′-O-methyl riboside and 5-bromodeoxyuridine modifications generally did not change either duplex stability or mismatch resolution. Denaturation experiments conducted with selected perfect duplexes on microchips and in solution showed similar results on thermal stabilities. Some hybridization artifacts were observed that might indicate the formation of parallel DNA.     

Hydroxylation of the Herbicide Isoproturon by Fungi Isolated from Agricultural Soil

Several asco-, basidio-, and zygomycetes isolated from an agricultural field were shown to be able to hydroxylate the phenylurea herbicide isoproturon [N-(4-isopropylphenyl)-N′,N′-dimethylurea] to N-(4-(2-hydroxy-1-methylethyl)phenyl)-N′,N′-dimethylurea and N-(4-(1-hydroxy-1-methylethyl)phenyl)-N′,N′-dimethylurea. Bacterial metabolism of isoproturon has previously been shown to proceed by an initial demethylation to N-(4-isopropylphenyl)-N′-methylurea. In soils, however, hydroxylated metabolites have also been detected. In this study we identified fungi as organisms that potentially play a major role in the formation of these hydroxylated metabolites in soils treated with isoproturon. Isolates of Mortierella sp. strain Gr4, Phoma cf. eupyrena Gr61, and Alternaria sp. strain Gr174 hydroxylated isoproturon at the first position of the isopropyl side chain, yielding N-(4-(2-hydroxy-1-methylethyl)phenyl)-N′,N′-dimethylurea, while Mucor sp. strain Gr22 hydroxylated the molecule at the second position, yielding N-(4-(1-hydroxy-1-methylethyl)phenyl)-N′,N′-dimethylurea. Hydroxylation was the dominant mode of isoproturon transformation in these fungi, although some cultures also produced traces of the N-demethylated metabolite N-(4-isopropylphenyl)-N′-methylurea. A basidiomycete isolate produced a mixture of the two hydroxylated and N-demethylated metabolites at low concentrations. Clonostachys sp. strain Gr141 and putative Tetracladium sp. strain Gr57 did not hydroxylate isoproturon but N demethylated the compound to a minor extent. Mortierella sp. strain Gr4 also produced N-(4-(2-hydroxy-1-methylethyl)phenyl)-N′-methylurea, which is the product resulting from combined N demethylation and hydroxylation.     

Phytochemical Studies on the Tobacco Alkaloids. XII. Identification of gamma-Methylaminobutyraldehyde and its Precursor Role in Nicotine Biosynthesis

γ-Methylaminobutyraldehyde (N-methylpyrroline) labeled with ¹⁴C was isolated from tobacco roots which had metabolized ornithine-2-¹⁴C. It was labeled most strongly 4 hours after adding ornithine-2-¹⁴C to the root, also labeled by putrescine-1,4-¹⁴C and methionine-¹⁴CH₃, and observed in the root but not in the aerial portions of tobacco plants. γ-Methyl-aminobutyraldehyde when added back to the root was an efficient precursor of nicotine. Identity of γ-methylaminobutyraldehyde from tobacco roots was confirmed by comparison with the authentic compound.     

5-Hydroxytryptamine metabolism by the nuclear fraction of rat-liver homogenate

1. The metabolism of 5-hydroxy[1′-¹⁴C]tryptamine creatinine sulphate in the nuclear fraction of rat-liver homogenate was studied. In the incubation mixture five metabolites were found. 2. Two metabolites were not radioactive; one of them was identified as 5-hydroxyindole-3-carboxylic acid and the second tentatively as 5-hydroxyindole-3-aldehyde. 3. 5-Hydroxyindol-3-ylacetic acid, 1′-N-acetyl-5-hydroxytryptamine and 5-hydroxytryptophol were not precursors of 5-hydroxyindolealdehyde and 5-hydroxyindolecarboxylic acid. 4. It was shown that the metabolism of 5-hydroxytryptamine in the nuclear fraction involves monoamine oxidase, the precursor of 5-hydroxyindolealdehyde and 5-hydroxyindolecarboxylic acid being most probably 5-hydroxyindol-3-ylacetaldehyde.     

Inositol Metabolism in Plants. IV. Biosynthesis of Apiose in Lemna and Petroselinum

The biosynthesis of apiose was investigated in cell wall polysaccharide of Lemna gibba G3 (duckweed) and in detached leaves of Petroselinum crispum (parsley). Lemna grown either in short days or in continuous light incorporated ¹⁴C from a medium containing myo-inositol-2-¹⁴C into d-apiosyl and d-xylosyl units of cell wall polysaccharides. Labeled d-apiose was characterized by paper chromatography, by formation of labeled crystalline di-O-isopropylidene d-apiose, and by gas chromatography of trimethylsilyl derivatives of apiose and of its sodium borohydride reduction product, apiitol. Periodate oxidation of labeled apiose revealed 86 to 94% of the ¹⁴C was located in formaldehyde fragments corresponding to C3′ and C4. Comparison of this result with work reported by Grisebach and Doebereiner and by Beck and Kandler supports the conclusion that myo-inositol-2-¹⁴C was converted to d-apiose labeled specifically at C4.     

Studies on the presence of adenosine cyclic 3':5'-monophosphate in oat coleoptiles

The incorporation of adenosine-8-¹⁴C into adenosine cyclic 3′:5′-monophosphate in coleoptile-first leaf segments of Avena sativa L. was investigated. Homogenates of segments incubated in adenosine-8-¹⁴C for either 4 or 10 hours were partially purified by thin layer chromatography followed by paper electrophoresis. A radioactive fraction, less than 0.06% of the ¹⁴C present in the original homogenate, migrated as adenosine cyclic 3′:5′-monophosphate during electrophoresis. Upon treatment with cyclic nucleotide phosphodiesterase, however, less than 10% of this radioactive fraction appeared as 5′-AMP. Deamination with NaNO₂ as well as further chromatographical purification also suggested that only a small fraction of the ¹⁴C in the partially purified samples could be in adenosine cyclic 3′:5′-monophosphate. The data suggest that levels of this nucleotide can probably be no greater than 7 to 11 picomoles per gram of fresh weight in oat coleoptiles. Treatment of such coleoptiles with physiologically active concentrations of indoleacetic acid, furthermore, had no significant effect on the ¹⁴C radioactivity in marker adenosine cyclic 3′:5′-monophosphate-containing fractions at any stage of purification during several experiments.     

Direct demonstration of duvatrienediol biosynthesis in glandular heads of tobacco trichomes

Biosynthesis of the diterpenes, α and β 4,8,13-duvatriene-1,3-diol, has been observed in detached, intact glandular heads from trichomes of Nicotiana tabacum, Tobacco Introduction 1068. This result shows directly that the glandular head portion of the trichome is capable of duvatrienediol biosynthesis. In additional experiments, all of the [¹⁴C] duvatrienediol formed from sodium [2-¹⁴C]acetate by leaf midrib sections was recovered with trichome exudate and surface washes. None was found in trichome stalk, epidermal or subepidermal tissue extracts. Also, removal of glandular heads and exudate from midrib sections reduced or eliminated duvatrienediol biosynthetic capacity. Together these results strongly suggest that glandular heads are the primary, and perhaps the only, site of duvatrienediol biosynthesis in this plant.

Incubation of detached, intact glandular heads with sodium [¹⁴C]acetate in the dark or incubation in the light in the presence of DCMU reduced incorporation into duvatrienediols by 97%. These results suggest that chloroplasts which are abundant in glandular heads are involved in the biogenesis of these compounds.

     

Common Sequence at the 5′ Ends of the Segmented RNA Genomes of Influenza A and B Viruses

Guanylyl- and methyltransferases, isolated from purified vaccinia virus, were used to specifically label the 5′ ends of the genome RNAs of influenza A and B viruses. All eight segments were labeled with [α-³²P]guanosine 5′-triphosphate or S-adenosyl[methyl-³H]methionine to form “cap” structures of the type m⁷G(5′)pppN^m-, of which unmethylated (p)ppN- represents the original 5′ end. Further analyses indicated that m⁷G(5′)pppA^m, m⁷G(5′)pppA^mpGp, and m⁷G(5′)pppA^mpGpUp were released from total and individual labeled RNA segments by digestion with nuclease P1, RNase T1, and RNase A, respectively. Consequently, the 5′-terminal sequences of most or all individual genome RNAs of influenza A and B viruses were deduced to be (p)ppApGpUp. The presence of identical sequences at the ends of RNA segments of both types of influenza viruses indicates that they have been specifically conserved during evolution.     

Cytokinin Biosynthesis in Mutants of the Moss Physcomitrella patens

Three cytokinin-over-producing mutants of the moss, Physcomitrella patens, have been shown to convert [8-¹⁴C]adenine to N⁶-[¹⁴C](Δ²-isopentenyl)adenine, the presence of which was confirmed by thin layer chromatography, high performance liquid chromatography, and recrystallization to constant specific radioactivity. The labeled cytokinin was detected in the culture medium within 6 hours and the tissue itself appears to contain both labeled N⁶-(Δ²-isopentenyl)adenine and N⁶-(Δ²-isopentenyl)adenosine monophosphate.     

Metabolism of 2'-carboxyarabinitol in leaves

Results presented here indicate that 2′-carboxyarabinitol (CA) is the in vivo precursor and product of 2′-carboxyarabinitol 1-phosphate (CA1P) metabolism in leaves. When [2-¹⁴C]CA was fed in the light to leaves of five species known to be highly active in CA1P metabolism (Phaseolus vulgaris, Lycopersicon esculentum, Helianthus annuus, Petunia hybrida, and Beta vulgaris), [¹⁴C]CA1P was formed in the dark. Reillumination of a Phaseolus leaf caused this [¹⁴C]CA1P to be rapidly metabolized to [¹⁴C]CA (t_½ = 1 min). The epimer 2′-carboxyribitol could not substitute for CA in the dark synthesis of CA1P, and CA in the anionic form was a better substrate than CA in the lactone form. In leaves of Phaseolus vulgaris, the active CA pool size used in the dark synthesis of CA1P is between about 70 and 110 nanomoles per milligram of chlorophyll. The photosynthetic electron transport inhibitor diuron did not affect the dark synthesis of [¹⁴C]CA1P, but did greatly reduce the rate of its subsequent light degradation (t_½ = approximately 10 min). Dark synthesis of [¹⁴C]CA1P was inhibited by dithiothreitol and NaF. From the present data, we suggest that CA1P and CA participate in a metabolic substrate cycle in vivo.