Plantlet differentiation in leaf and root cultures of birch (Betula Pendula roth.)

The newly-formed leaves on plantlets differentiated from shoot bud cultures of Betula pendula, when excised and grown on a fresh medium produced callus from the margins or regenerated leafy shoots, roots and plantlets. After 4 weeks, upon transfer to murashige and Skoog (MS) medium supplemented with 3-indoleacetic acid (IAA) + 6-(4-hydroxy-3-methyl-trans-2-enyl)aminopurine (zeatin) + 6-aminopurine (adenine), 15–20 plantlets were produced from each explant. Likewise, the roots also showed meristematic activity at several sites, and produced nodulated callus on MS + α-naphthaleneacetic acid (NAA) + 6-(3-methyl-2-butenyl-amino)purine (2-iP) + adenine, and ultimately differentiated plantlets. Anatomical studies showed that initiation of callus takes place by meristematic activity in epidermal cells of leaves, and cortical cells of roots. Cytological investigations revealed no change in chromosomal complement.     

Non-reversion of Impatiens in the absence of meristem commitment

Purple-flowered plants of Impatiens balsamina maintained floral development on transfer from inductive short days (SD) to long days (LD), a treatment in which red-flowered plants of Impatiens are known to revert to leaf production. An investigation into the non-reverting nature of purple-flowered plants was carried out to establish whether these plants achieved meristem commitment or whether their non-reverting state was controlled by the leaves. When the leaves that had unfolded during the inductive SD treatment were removed at the time of transfer to LD, the purple-flowered plant did revert. This result suggests that, as in red-flowered Impatiens, meristem commitment is absent, but that purple-flowered plants maintain flowering in LD conditions because of a more permanent supply of signal from their leaves than occurs in red-flowered plants. A working hypothesis is proposed to explain how a signal from the leaves can retain a controlling role during flower development.Key words: Floral commitment, Impatiens, floral reversion, floricaula.      

Biosynthesis and metabolism of purine alkaloids in leaves of cocoa tea (Camellia ptilophylla)

The biosynthesis and metabolism of purine alkaloids in leaves ofCamellia ptilophylla (cocoa tea), a new tea resource in China, have been investigated. The major purine alkaloid was theobromine, with theophylline also being present as a minor component. Caffeine was not accumulated in detectable quantities. Theobromine was synthesized from [8-¹⁴C] adenine and the rate of its biosynthesis in the segments from young and mature leaves from flush shoots was approximately 10 times higher than that from aged leaves from 1-year old shoots. Neither cellfree extracts nor segments fromC. ptilophylla leaves could convert theobromine to caffeine. A large quantity of [2-¹⁴C] xanthine taken up by the leaf segments was degraded to¹⁴CO₂ via the conventional purine catabolic pathway that includes allantoin as an intermediate. However, small amounts of [2-¹⁴C] xanthine were also converted to theobromine. Considerable amounts of [8-¹⁴C] caffeine exogenously supplied to the leaf segments ofC. ptilophylla was changed to theobromine. These results indicate that leaves ofC. ptilophylla exhibit unusual purine alkaloid metabolism as i) they have the capacity to synthesize theobromine from adenine nucleotides, but they lack adequate methyltransferase activity to convert of theobromine to caffeine in detectable quantities, ii) the leaves have a capacity to convert xanthine to theobromine, probably via 3-methylxanthine.     

The Involvement of Cytokinin Oxidase/Dehydrogenase and Zeatin Reductase in Regulation of Cytokinin Levels in Pea (Pisum sativum L.) Leaves

Cytokinin metabolism in plants is very complex. More than 20 cytokinins bearing isoprenoid and aromatic side chains were identified by high performance liquid chromatography-mass spectrometry (HPLC-MS) in pea (Pisum sativum L. cv. Gotik) leaves, indicating diverse metabolic conversions of primary products of cytokinin biosynthesis. To determine the potential involvement of two enzymes metabolizing cytokinins, cytokinin oxidase/dehydrogenase (CKX, EC 1.5.99.12) and zeatin reductase (ZRED, EC 1.3.1.69), in the control of endogenous cytokinin levels, their in vitro activities were investigated in relation to the uptake and metabolism of [2−³H]trans-zeatin ([2−³H]Z) in shoot explants of pea. Trans-zeatin 9-riboside, trans-zeatin 9-riboside-5′-monophosphate and cytokinin degradation products adenine and adenosine were detected as predominant [2−³H]Z metabolites during 2, 5, 8, and 24 h incubation. Increasing formation of adenine and adenosine indicated extensive degradation of [2−³H]Z by CKX. High CKX activity was confirmed in protein preparations from pea leaves, stems, and roots by in vitro assays. Inhibition of CKX by dithiothreitol (15 mM) in the enzyme assays revealed relatively high activity of ZRED catalyzing conversion of Z to dihydrozeatin (DHZ) and evidently competing for the same substrate cytokinin (Z) in protein preparations from pea leaves, but not from pea roots and stems. The conversion of Z to DHZ by pea leaf enzyme was NADPH dependent and was significantly inhibited or completely suppressed in vitro by diethyldithiocarbamic acid (DIECA; 10 mM). Relations of CKX and ZRED in the control of cytokinin levels in pea leaves with respect to their potential role in establishment and maintenance of cytokinin homeostasis in plants are discussed.     

Changes in free IAA level in the leaves of short-and long-day tobacco during flowering and the effect of applied IAA on the transition to flowering

Changes in free IAA level were studied in the leaves of the central stem zone of short-day tobacco (Mcotianatabacum, cv. Maryland Mammoth) and long-day tobacco(Nicotiana silvestris) in inductive photoperiodic regime after 10, 20, 30 and 40 d, respectively. The leaves of SD tobacco Mammoth showed a high free IAA level in vegetative plants kept under long days but it significantly decreased (by ca. 50 %) after 10, 30 and 40 short days, respectively. After 20 short days the IAA level was as high as in the leaves of plants at the beginning of inductive treatment. The changes of freeIAA level in the leaves of LD tobacco N.silvestris were similar to those of SD Mammoth, but the IAA level in this species was significantly lower than that of Mammoth throughout the investigated period. Consequently, the changes observed in N. silvestris were much less pronounced. Plants of both tobacco species were fully induced to flowering by 30 inductive days and this was associated with differentiation of the flower organs. Application of 10 -4 M IAA during the last 10 d of the inductive treatment of 30 d significantly reduced flowering in SD tobacco Mammoth without changing the stem length and apex width. Apex length was slightly reduced. IAA application elicited almost no effect inN. silvestris. The results are discussed with respect to the possible role of IAA in flower induction in SD and LD plants.     

Changes in the Protein Composition of the Shoot Apical Bud of Sinapis alba in Transition to Flowering

Vegetative plants of Sinapis alba L. grown in short days were induced to flower by expsoure to one or continuous long days. In both inductive conditions, the first flowers were initiated about 60 h after the start of the treatment. Soluble protein extracts were prepared from apical buds and just-expanded leaves of both vegetative and induced plants. Rabbit antisera were prepared using extracts from vegetative and reproductive buds. Immunodiffusion tests were performed. Analysis of the precipitin bands indicated that: (1) one antigenic protein was present in the vegetative buds and disappeared from the buds of induced plants between 96 and 240 h after the start of the inductive treatment; (2) the concentration of a another antigenic protein increased in buds of induced plants 30 h after the start of the inductive treatment; (3) the concentration of a third antigenic proteín increased in buds of induced plants at 96 h.     

Effect of ínductive photoperiod and gibberellin treatment on peroxidase enzyme system in relation to floral induction inImpatiens balsamina L

Gibberellins A₃ and A₁₃ cause floral induction inImpatiens balsamina, a qualitative short day plant, under non-inductive 24-h photoperiods (continuous illumination). However, the influence of the two inductive factors,i.e. gibberellins and short days (8-h photoperiods) on the peroxidase enzyme system is different. The total peroxidase activity decreases under both inductive and non-inductive photoperiods, with or without gibberellin treatment. The electrophoretic pattern of isoperoxidases changes only in response to gibberellin treatment. Under 24-h photoperiods, treatment with gibberellins A₃ and A₁₃ causes the appearance in the stem of three additional isoenzymes of peroxidase (Rm 0.50, 0.71 and 0.76). These bands do not appear in the leaves, which are non-essential for gibberellin-caused floral induction in this plant. Under 8-h photoperiods also, gibberellins induce the appearance of new isoenzyme bandsi.e. two in the stem (Rm 0.50 and 0.76) and one in the leaves (Rm 0.05). These may be correlated with the synergistic increase in the number of floral buds in these plants in response to simultaneous exposure to two inductive factors.     

The role of carbohydrates in the induction of flowering in Arabidopsis thaliana: comparison between the wild type and a starchless mutant

In order to test whether an increased export of carbohydrates by leaves and starch mobilization are critical for floral transition in Arabidopsis thaliana, the Columbia ecotype as well as its starchless mutant pgm and starch-in-excess mutant sex1 were investigated. Induction of flowering was achieved by exposure of plants to either one long day (LD) or one displaced short day (DSD). The following conclusions were drawn: (i) Both the pgm and sex1 mutants have a late-flowering phenotype in days shorter than 16 h. (ii) When inductive treatments cause a large percentage of induced plants, there is always a large, early and transient increase in carbohydrate export from leaves. By contrast, when an inductive treatment results in only a low percentage of induced plants (pgm plants exposed to one DSD), the export of carbohydrates from leaves is not increased, supporting the idea that phloem carbohydrates have a critical function in floral transition. (iii) Starch mobilization is not required to obtain an increased carbohydrate export when induction is by one LD (extended period of photosynthesis), but is absolutely essential when induction is by one DSD (period of photosynthesis unaffected). (iv) Floral induction apparently increases the capability of the leaf phloem-loading system. Received: 27 August 1997 / Accepted: 6 March 1998     

Sugar uptake into Allium cepa leaf tissue: an integrated approach

Allium cepa L. leaves were subjected to enzymatic (pectolyase) and mechanical manipulation in order to ascertain the contribution made by various leaf tissues to the total sugar uptake by the leaf. In order to develop an understanding of the basic anatomy and ultrastructure of the Allium leaf and assess the integrity of the tissue before and after enzymatic and mechanical manipulation, a light- and transmission-electron-microscopy study was performed. One outcome of this study was the discovery that the chloroplasts of the bundle-sheath cells contain starch. The function of these inclusions in relation to carbohydrate pools and translocation is discussed. Kinetic curves for sucrose and fructose uptake by leaf discs derived from control and modified leaves are presented. In addition, kinetic curves for the tissues removed by the enzymatic treatment (inner parenchyma, bundle sheath and some vascular parenchyma) and the vascular bundles were also obtained. All tissues exhibited the same linear plus saturable profile as the dicotyledon, Beta vulgaris, with the exception of fructose uptake into the inner parenchyma and bundle-sheath cells; in this case the response was linear. The effect of anoxia on uptake of exogenous sucrose was also investigated. Anaerobiosis inhibited both the linear and saturable component of sucrose influx. Adenine-nucleotide levels were obtained using high-performance liquid chromatography for control (air) and anoxia-treated (N₂) leaf discs. A general loss of adenine nucleotides was observed. The results presented indicate that all tissues of the leaf retrieve exogenous sugar such that the kinetic curves derived from leaf discs cannot represent phloem loading, per se.Abbreviations Mes 2-(N-morpholino)ethanesulfonic acid - E.C. energy charge     

The in vitro metabolism of [8-14C]benzyladenine by excised organs of tomato plants

The metabolic fate of [8-¹⁴C]benzyladenine applied to the excised organs of tomato (Lycopersicon esculentum Mill. cv. Heinz 1370) was investigated after 2 and 6 h of feeding. Although the roots were the most effective at uptake of the cytokinin the leaves metabolised it the most efficiently. The predominant metabolite in all of the tissues was an unknown compound which did not have a retention time corresponding with any of the standards used. The roots contained the most extensive range of metabolites which included the unknown metabolite and compounds co-eluting with adenine, and the riboside, nucleotide and 9-glucoside of benzyladenine. The 9-glucoside was detected only in the root material. The stem yielded the highest levels of radioactivity at the retention times of benzyladenosine-5-monophosphate and benzyladenosine. The radioactivity associated with these two cytokinins was transient in the leaf extract. This organ ultimately yielded radioactivity only at the retention times of the unknown metabolite and adenine. Since only the roots and leaves contained relatively large peaks of radioactivity at the elution volume of adenine it seems that degradative metabolism was more predominant in these organs than in the stem.Abbreviations Ade adenine - Ado adenosine - BA benzyladenine - BAR benzyladenosine - BA3G 3-glucosylbenzyladenine - BA9G 9-glucosylbenzyladenine - BARMP benzyladenosine monophosphate - HPLC high performance liquid chromatography - MS mass spectrometry     

Long-term effects of blue or red light on ATP and ADP contents in primary barley leaves

Levels of ATP and ADP were studied in primary leaves of barley (Hordeum vulgare L. cv. Viner) seedlings grown under blue (BL) or red light (RL) of various irradiances. In mature leaf segments, BL stimulated a greater accumulation of adenylates than RL. Transfer of barley seedlings from RL to BL for 48 h caused about a twofold increase in the content of adenylates, probably due to de-novo synthesis of adenine nucleotides. Weak BL was found to stimulate an increase in the adenylate content and a higher irradiance enhanced the stimulatory effect. The adenylate content increased markedly from the base towards the tip of barley leaves grown under BL but not in those grown under RL. However, the adenylate content was higher in the basalmost segment of barley leaves grown under RL, indicating that the action of RL on adenylate content proceeded more rapidly than that of BL. The same conclusion could be drawn from the results of experiments with de-etiolated leaves. A linear relationship was established between the maximum rate of CO₂ fixation and the ATP or ADP content in mature segments of primary barley leaves. The possible involvement of two photoreceptors, phytochrome and cryptochrome, in the long-term light regulation of the total content of adenylates in primary barley leaves is discussed.Abbreviations BL blue light - Chl chlorophyll - RL red light     

The transition to reproductive phase inchenopodium murale L. ecotype 197 - Early flowering long-day plant

Five days of suitable continuous light induced flowering in the majority ofChenopodium murale L. ecotype 197 plants as early as at the phase of the first pair of leaves. At the time of initiation of the 2nd to 4th pairs of leaves the capacity of plants to flower was reduced, the number of flowering plants being significantly lower under the same inductive light treatment. The capacity to flower increased again at the phase of the 5th and the 6th pairs of leaves. Inductive light treatment brought about a marked growth activation of organs present before induction, shoot apex elongation, precocious formation of new leaves and activation of axillary meristems. The course of these changes in plants of different age is demonstrated. The terminal flower developed during 5 short days following inductive light treatment. The paper shows similarities and differences between long-daymutale L. ecotype 197 and short-day C.rubrum L. ecotype 374 grown under practically uniform conditions.     

Occurrence of theobromine synthase genes in purine alkaloid-free species of <Emphasis Type="Italic">Camellia</Emphasis> plants

Caffeine (1,3,7-trimethylxanthine) and theobromine (3,7-dimethylxanthine) are purine alkaloids that are present in high concentrations in plants of some species of Camellia. However, most members of the genus Camellia contain no purine alkaloids. Tracer experiments using [8-¹⁴C]adenine and [8-¹⁴C]theobromine showed that the purine alkaloid pathway is not fully functional in leaves of purine alkaloid-free species. In five species of purine alkaloid-free Camellia plants, sufficient evidence was obtained to show the occurrence of genes that are homologous to caffeine synthase. Recombinant enzymes derived from purine alkaloid-free species showed only theobromine synthase activity. Unlike the caffeine synthase gene, these genes were expressed more strongly in mature tissue than in young tissue. The nucleotide sequence data reported here have been deposited in the GenBank database under the accession numbers AB297451 (CjCS1), AB362882 (CgCS1), AB362883 (CgCS2), AB362884 (CkCS1), AB362885 (ClCS1), and AB362886 (CcCS2).     

Entomopathogenic nematodes induce components of systemic resistance in plants: Biochemical and molecular evidence

Antagonism between entomopathogenic nematodes (EPNs) and plant-parasitic nematodes (PPNs) has been documented over the past two decades but its mechanism and ecological significance remain elusive. We investigated the effects of Steinernema carpocapsae and its symbiotic bacterium, Xenorhabdus nematophila applied to the potting medium on pyrogallol peroxidase (P-peroxidase), guaiacol peroxidase (G-peroxidase) and catalase activities in Hosta sp. and Arabidopsis thaliana leaves as components of induced systemic resistance. We found that P-peroxidase activity was significantly higher in the leaves from hosta plants treated with S. carpocapsae infective juveniles (IJs) and S. carpocapsae infected insect cadavers than in the leaves from the control plants 2 weeks after treatment. The G-peroxidase activity was significantly higher in S. carpocapsae infected cadaver and X. nematophila treatments 10 and 15 days after treatment (DAT) and in S. carpocapsae IJs treatment 5 and 15 DAT. The catalase activity in hosta leaves was significantly higher in S. carpocapsae infected cadaver and X. nematophilus treatments compared with the control 5 and 15 DAT and in S. carpocapsae IJs treatment 5 and 10 DAT. Further, the catalase activity in A. thaliana leaves was significantly higher in S. carpocapsae IJs treatment than in the control 7 DAT. We also determined the effects of S. carpocapsae infected cadavers and S. carpocapsae IJs on PR1-gene expression in transgenic A. thaliana leaves through GUS (β-glucuronidase) activity assay and found that the PR1-gene was expressed in leaves from all treatments except the control. Thus, we conclude that the EPNs and their symbiotic bacteria can induce systemic resistance in plants which may explain the elusive antagonistic effect of EPNs on PPNs.     

Regeneration of garlic plants (allium sativum L., CV. “Chonan”) via cell culture in liquid medium

Summary Aiming at the genetic improvement of garlic cultivars, a cell suspension protocol was established which includes the induction of friable callus, establishment of cells in liquid medium, plating, regeneration, and bulb formation. Calluses of various textures from compact to friable and from green to yellowish were obtained by culturing explants excised from inner leaves of garlic bulbs on Marashig-Shoog (MS) medium with 2,4 dichlorophenoxy acetic acid (2,4-D), (1.1 mg/liter [5.0 μM]), picloram (1.2 mg/liter [5.0 μM]), and kinetin (2.1 mg/liter [10 μM]). Friable callus occurred on MS-A contained 2,4-D alone (1.0 mg/liter [4.52 μM]) and this callus was used to develop cell suspension cultures, which were maintained in liquid MS-B medium with a 2,4-D/benzyl adenine (BA) (0.5 mg/liter [2.25 μM]: 0.5 mg/liter [2.22 μM]) ratio. High plating efficiency was obtained on MS-C medium with different naphthalene acetic acid/BA combinations. Regeneration occurred after transfer of the caulogenic mass to MS-C medium containing 10 mg/liter (74.02 μM) and 20 mg/liter (148.04 μM) adenine for 60 days, followed by transfer to adenine-free medium. Plantlets transplanted to soil showed normal phenology. Shoots grown on modified MS medium supplemented with indolylbutryic acid (3.0 mg/liter [14.7 μM]) stimulated bulb formation by 30 days in culture.     

Direct plant regeneration from leaf explants of Plumbago species

Direct plant regeneration was achieved from leaf explants of Plumbago rosea and Plumbago zeylanica on Murashige and Skoog (MS) medium supplemented with 6.7 M 6-benzylaminopurine (BA), 1.4 M indole-3-acetic acid (IAA), 370 M adenine sulfate (Ads) and 3% (w/v) sucrose. The shoot initials developed within 2–3 weeks on the leaf margin as well as from the cut surface of the leaf. High frequency shoot-bud regeneration was achieved on similar medium in subsequent subcultures. The semi-mature leaves produced more shoot-buds as compared to the younger leaves. Mature leaves did not show any response for shoot bud initiation. More than 85% of the semi-mature explants produced shoot-buds per leaf explant within 4 weeks of culture. Shoots rooted on half-strength basal MS medium supplemented with 1.2 M indole-3-butyric acid (IBA) and 2% (w/v) sucrose; approximately 90% of the in vitro raised plantlets survived in the greenhouse. The regenerated plantlets looked morphologically similar to the mother plants. This protocol might be useful for genetic improvement programs.     

Induction of early blight resistance in tomato by <Emphasis Type="Italic">Quercus infectoria</Emphasis> gall extract in association with accumulation of phenolics and defense-related enzymes

Treatment of tomato leaves with aqueous extract (0.5%) of the galls of Quercus infectoria significantly reduced infection from subsequent inoculation with Alternaria solani, the tomato early blight pathogen. When the leaves were challenge-inoculated with A. solani 3 d after application of Q. infectoria gall extract (QIGE), the percent defoliation decreased from 33.6 to 7.3. Two to three day pre-treatment with QIGE reduced the percent defoliation by 77 percent. The biochemical responses of tomato plants to QIGE were also studied. In tomato plants treated with QIGE, phenolic content increased rapidly, reached the maximum at 2 d after treatment. Phenylalanine ammonia-lyase (PAL) activity increased significantly from 1 d after treatment and the maximum enzyme activity was recorded 2 d after treatment at which period a 3-fold increase in PAL activity was observed when compared to the control. Peroxidase (PO) activity was also significantly increased 1 d after treatment and the maximum activity was reached 2 d after treatment. Peroxidase isozyme analysis indicated that PO-1 was increased dramatically in tomato leaves 1 d after treatment and maintained at the same level throughout the experimental period of 6 d. When tomato leaves were treated with QIGE, a two-fold increase in chitinase and β-1,3-glucanase activities was recorded 2 and 3 d respectively, after treatment. The enhanced activities of defense-related enzymes and elevated levels of phenolics in QIGE-treated tomato plants between 1 and 3 d after treatment suggest that these induced biochemical defenses may be involved in the suppression of early blight by QIGE.     

伤害和挥发物对棉花花外蜜的诱导效应

植物花外蜜的分泌是一种植物间接防御反应。为了明确植食性昆虫、机械伤和机械伤诱导的挥发性气体在植物花外蜜诱导分泌中的作用,分析了咀嚼式口器昆虫棉铃虫Helicoverpa armigera(Hübner)、刺吸式口器昆虫棉蚜Aphis gossypii Glover取食、剪刀机械伤、剪刀机械伤+棉铃虫反吐物、针刺机械伤以及机械伤诱导挥发物、顺式-茉莉酮对棉花Gossypium hirsutum L.叶片花外蜜分泌量的影响。结果表明,棉铃虫取食、剪刀机械伤、剪刀机械伤+棉铃虫反吐物处理均显著增加了被处理叶片花外蜜的分泌量。棉花花外蜜的诱导效应在处理叶片上表现明显,并且在较幼嫩的第3片真叶上也有系统性增长。顺式-茉莉酮和机械伤挥发物处理1 d对棉花较幼嫩的第4、5片真叶花外蜜有诱导效应。棉花叶片花外蜜的诱导主要与植物组织损伤有关;不同口器类型的昆虫对棉花叶片花外蜜的诱导量不同,咀嚼式口器的棉铃虫对棉花花外蜜的诱导强度显著高于刺吸式口器的棉蚜;顺式-茉莉酮和机械伤诱导的挥发物能作为棉花植株间交流的信息物质诱导棉花幼嫩叶片花外蜜的分泌。     

Regeneration of plants from primary leaves of cowpea

Plants were regenerated from the in vitro cultured explants of primary leaves of cowpea (Vigna unguiculata L. Walp). Primary leaves, including the intact petiole, were excised from three-day-old seedlings and cultured on Gamborg's B5 basal medium containing 8×10^–7 M 2,4,5-trichlorophenoxyacetic acid, 1×10^–2 M L-glutamine and 1×10^–4 M adenine sulfate. Callus formed at the petiole end. Prolific shoot regeneration occurred when this callus was transferred to B5 basal medium containing 5×10^–6 M 6-benzyl-aminopurine (BAP). Regenerated shoots rooted in growth-regulator-free B5 basal medium and were established in soil.Abbreviations BAP 6-benzylaminopurine - IAA indole-3-acetic acid - NAA 1-napthalene acetic acid - 2,4,5-T 2,4,5-trichloro-phenoxyacetic acid     

L-lactate dehydrogenase from leaves of Capsella bursa-pastoris (L.) Med.

By ammonium sulfate fractionation and gel filtration an enzyme preparation which catalyzed NAD⁺-dependent L-lactate oxidation (10^-4 kat kg^-1 protein), as well as NADH-dependent pyruvate reduction (10^-3 kat kg^-1 protein), was obtained from leaves of Capsella bursa-pastoris. This lactate dehydrogenase activity was not due to an unspecific activity of either glycolate oxidase, glycolate dehydrogenase, hydroxypyruvate reductase, alcohol dehydrogenase, or a malate oxidizing enzyme. These enzymes could be separated from the protein displaying lactate dehydrogenase activity by gel filtration and electrophoresis and distinguished from it by their known properties. The enzyme under consideration does not oxidize D-lactate, and reduces pyruvate to L-lactate (the configuration of which was determined using highly specific animal L-lactate dehydrogenase). Based on these results the studied Capsella leaf enzyme is classified as L-lactate dehydrogenase (EC 1.1.1.27). It has a K_m value of 0.25 mmol l^-1 (pH 7.0, 0.3 mmol l^-1 NADH) for pyruvate and of 13 mmol l^-1 (pH 7.8, 3 mmol l^-1 NAD⁺) for L-lactate. Lactate dehydrogenase activity was also detected in the leaves of several other plants.Abbreviation FMN flavin adenine mononucleotide