Quantification of cyanamide contents in herbaceous plants

Cyanamide (NH2CN) is found in nature, although it has long been recognized as an industrial product. Distribution of cyanamide in the plant kingdom was investigated using a direct quantitative determination method to detect and measure cyanamide by stable isotope dilution gas chromatography-mass spectrometry (the SID-GC-MS method). The SID-GC-MS method proved to be a robust way to quantify cyanamide contents in the extracts of 101 species of herbaceous plants. The average recovery of cyanamide from all plants tested was 55.6+/-20.3%. Vicia villosa and V. cracca contained cyanamide at 369-498 microg/gFW and 3,460-3,579 microg/gFW respectively, while the other 99 species contained no detectable cyanamide (<1 microg/gFW). This result suggests that distribution of cyanamide in the plant kingdom is limited and uneven.     

Quantification of Cyanamide Contents in Herbaceous Plants

Cyanamide (NH₂CN) is found in nature, although it has long been recognized as an industrial product. Distribution of cyanamide in the plant kingdom was investigated using a direct quantitative determination method to detect and measure cyanamide by stable isotope dilution gas chromatography–mass spectrometry (the SID–GC–MS method). The SID–GC–MS method proved to be a robust way to quantify cyanamide contents in the extracts of 101 species of herbaceous plants. The average recovery of cyanamide from all plants tested was 55.6±20.3%. Vicia villosa and V. cracca contained cyanamide at 369–498 μg/gFW and 3,460–3,579 μg/gFW respectively, while the other 99 species contained no detectable cyanamide (<1 μg/gFW). This result suggests that distribution of cyanamide in the plant kingdom is limited and uneven.     

Limited distribution of natural cyanamide in higher plants: occurrence in Vicia villosa subsp. varia, V. cracca, and Robinia pseudo-acacia

Cyanamide (NH2CN) has recently been proven to be a natural product, although it has been synthesized for over 100 years for agricultural and industrial purposes. The distribution of natural cyanamide appears to be limited, as indicated by our previous investigation of 101 weed species. In the present study, to investigate the distribution of natural cyanamide in Vicia species, we monitored the cyanamide contents in V. villosa subsp. varia, V. cracca, and V. amoena during their pre-flowering and flowering seasons. It was confirmed that V. cracca was superior to V. villosa subsp. varia in accumulating natural cyanamide, and that V. amoena was unable to biosynthesize this compound under laboratory condition examined. The localization of cyanamide in the leaves of V. villosa subsp. varia seedlings was also clarified. In a screening study to find cyanamide-biosynthesizing plants, only Robinia pseudo-acacia was found to contain cyanamide among 452 species of higher plants. We have investigated 553 species to date, but have so far found the ability to biosynthesize cyanamide in only three species, V. villosa subsp. varia, V. cracca and R. pseudo-acacia.     

Quantification of cyanamide in young seedlings of Vicia species, Lens culinaris, and Robinia pseudo-acacia by gas chromatography-mass spectrometry

We quantified the cyanamide content of young leaves of nine Vicia species, Lens culinaris, and Robinia pseudo-acacia using a modified analytical procedure that made it possible to measure the cyanamide content of a single leaf. Recent molecular phylogenetic analysis suggests that cyanamide is present in V. benghalensis, which is placed in a monophyletic group with cyanamide-biosynthesizing plants, V. villosa and V. cracca; this suggestion was verified.     

Quantification of Cyanamide in Young Seedlings of Vicia Species,Lens culinaris,and Robinia pseudo-acacia by Gas Chromatography-Mass Spectrometry

We quantified the cyanamide content of young leaves of nine Vicia species, Lens culinaris, and Robinia pseudo-acacia using a modified analytical procedure that made it possible to measure the cyanamide content of a single leaf. Recent molecular phylogenetic analysis suggests that cyanamide is present in V. benghalensis, which is placed in a monophyletic group with cyanamide-biosynthesizing plants, V. villosa and V. cracca; this suggestion was verified.     

Cyanamide mode of action during inhibition of onion (Allium cepa L.) root growth involves disturbances in cell division and cytoskeleton formation

Cyanamide is an allelochemical produced by hairy vetch (Vicia villosa Roth.). Its phyotoxic effect on plant growth was examined on roots of onion (Allium cepa L.) bulbs. Water solution of cyanamide (2-10 mM) restricted growth of onion roots in a dose-dependent manner. Treatment of onion roots with cyanamide resulted in a decrease in root growth rate accompanied by a decrease in accumulation of fresh and dry weight. The inhibitory effect of cyanamide was reversed by its removal from the environment, but full recovery was observed only for tissue treated with this chemical at low concentration (2-6 mM). Cytological observations of root tip cells suggest that disturbances in cell division may explain the strong cyanamide allelopathic activity. Moreover, in cyanamide-treated onion the following changes were detected: reduction of mitotic cells, inhibition of proliferation of meristematic cells and cell cycle, and modifications of cytoskeleton arrangement.     

Expression of a fungal cyanamide hydratase in transgenic soybean detoxifies cyanamide in tissue culture and in planta to provide cyanamide resistance

Embryogenic tissue cultures of soybean were transformed by particle bombardment with a vector pCHZ-II that carries the coding sequence for cyanamide hydratase (Cah), an enzyme that converts toxic cyanamide to urea, from the soil fungus Myrothecium verrucaria. The Cah gene was driven by the constitutive Arabidopsis thaliana actin-2 promoter and terminated with its cognate terminator. This vector also carries the hygromycin phosphotransferase gene (hpt) driven by the potato (Solanum tuberosum) ubiquitin-3 promoter. Twelve individual lines of transgenic plants that were obtained under hygromycin selection expressed Cah mRNA and exhibited resistance to hygromycin in leaf tissue culture, while the untransformed tissues were sensitive. Cah enzyme activity was present in extracts of transformed leaves and embryogenic tissue cultures when measured by a colorimetric assay and the presence of the Cah protein was confirmed by enzyme-linked immunosorbent assay (ELISA). Cah expression detoxified cyanamide in leaf callus and embryogenic cultures as well as in whole plants as shown by cyanamide resistance. The Cah-expressing plants grew and set seeds normally indicating that the Cah enzyme activity did not affect soybean plant metabolism. We also describe a test whereby callus was formed on cultured leaf tissue in the presence of hygromycin or cyanamide only if the hpt or Cah gene was expressed, respectively. This test is a convenient and cost-effective way to follow the marker gene in the primary regenerated plants and subsequent generations, which is particularly reliable for the hpt gene expression using hygromycin.     

The metabolic activation of cyanamide to an inhibitor of aldehyde dehydrogenase is catalyzed by catalase

The inhibition of aldehyde dehydrogenase by cyanamide is dependent on an enzyme catalyzed conversion of the latter to an active metabolite. The following results suggest that catalase is the enzyme responsible for this bioactivation. The elevation of blood acetaldehyde elicited by cyanamide after ethanol administration to rats was attenuated more than 90 percent by pretreatment with the catalase inhibitor, 3-amino-1,2,4-triazole. This attenuation was dose dependent and was accompanied by a reduction in total hepatic catalase activity. Although hepatic catalase was also inhibited by cyanamide, a positive correlation between blood acetaldehyde and hepatic catalase activity was observed. In vitro, the activation inhibitor, 3-amino-1,2,4-triazole. This attenuation was dose dependent and was accompanied by a reduction in total hepatic catalase activity. Although hepatic catalase was also inhibited by cyanamide, a positive correlation between blood acetaldehyde and hepatic catalase activity was observed. In vitro, the activation of cyanamide was catalyzed by a) the rat liver mitochondrial subcellular fraction, b) the 50-65% ammonium sulfate mitochondrial fraction and c) purified bovine liver catalase. Cyanamide activation was inhibited by sodium azide. Since much of the hepatic catalase is localized in the peroxisomes and since peroxisomes and mitochondria cosediment, the cyanamide activating enzyme, catalase, is likely of peroxisomal and mitochondrial origin.     

Effect of acetaldehyde and cyanamide on the metabolism of formaldehyde by hepatocytes, mitochondria, and soluble supernatant from rat liver

Formaldehyde can be metabolized primarily by two different pathways, one involving oxidation by the low-Km mitochondrial aldehyde dehydrogenase, the other involving a specific, glutathione-dependent, formaldehyde dehydrogenase. To estimate the roles played by each enzyme in formaldehyde metabolism by rat hepatocytes, experiments with acetaldehyde and cyanamide, a potent inhibitor of the low-Km aldehyde dehydrogenase were carried out. The glutathione-dependent oxidation of formaldehyde by 100,000g rat liver supernatant fractions was not affected by either acetaldehyde or by cyanamide. By contrast, the uptake of formaldehyde by intact mitochondria was inhibited 75 to 90% by cyanamide. Acetaldehyde inhibited the uptake of formaldehyde by mitochondria in a competitive fashion. Formaldehyde was a weak inhibitor of the oxidation of acetaldehyde by mitochondria, suggesting that, relative to formaldehyde, acetaldehyde was a preferred substrate. In isolated hepatocytes, cyanamide, which inhibited the oxidation of acetaldehyde by 75 to 90%, produced only 30 to 50% inhibition of formaldehyde uptake by cells as well as of the production of 14CO2 and of formate from [14C]formaldehyde. The extent of inhibition by cyanamide was the same as that produced by acetaldehyde (30-40%). In the presence of cyanamide, acetaldehyde was no longer inhibitory, suggesting that acetaldehyde and cyanamide may act at the same site(s) and inhibit the same formaldehyde-oxidizing enzyme system. These results suggest that, in rat hepatocytes, formaldehyde is oxidized by cyanamide- and acetaldehyde-sensitive (low-Km aldehyde dehydrogenase) and insensitive (formaldehyde dehydrogenase) reactions, and that both enzymes appear to contribute about equally toward the overall metabolism of formaldehyde.     

Allelopathy in the natural and agricultural ecosystems and isolation of potent allelochemicals from Velvet bean (Mucuna pruriens) and Hairy vetch (Vicia villosa).

We have studied on allelopathy of plants and developed methods to identify the effective substances in root exudates, leaf leacheate, and volatile chemicals emitted from plants. We found traditional cover plants that show allelopathic activity are useful for weed control. It could eliminate the use of synthetic chemicals for this purpose. Allelopathy is a natural power of plants to protect themselves by producing natural organic chemicals. Some endemic plants in Asia, already known by farmers in the region, as either cover crops used in intercropping, hedgerow, or agroforestry, were found to possess strong allelopathic abilities. Our group identified several allelochemicals from these plants. These allelopathic cover crops, mostly leguminous plants, provide protein rich food, and grow easily without artificial fertilizers, herbicides, insecticides and fungicides. In this regards, these allelopathic cover crops could save food shortage in rural area, and are useful for environmental conservation. Screenings of allelopathic plants by specific bioassays and field tests have been conducted. Hairy vetch (Vicia villosa) and Velvet bean (Mucuna pruriens) are two promising species for the practical application of allelopathy. An amino acid, L-DOPA, unusual in plants, plays an important role as allelochemical in Velvet bean (Mucuna pruriens). Hairy vetch is the most promising cover plant for the weed control in orchard, vegetable and rice production and even for landscape amendment in abandoned field in Japan. We have isolated "cyanamide", a well known nitrogen fertilizer, from Hairy vetch. This is the first finding of naturally produced cyanamide in the world.     

Acyclic cyanamide-based inhibitors of cathepsin K

Conversion of the proline-derived cyanamide lead to an acyclic cyanamide capable of forming an additional hydrogen bond with cathepsin K resulted in a large increase in inhibitory activity. An X-ray structure of a co-crystal of a cyanamide with cathepsin K confirmed the enzyme interaction. Furthermore, a representative acyclic cyanamide inhibitor 6r was able to attenuate bone resorption in the rat calvarial model.     

Site-Directed Mutagenesis,Heterologous Expression of Cyanamide Hydratase Gene and Antimicrobial Activity of Cyanamide

Site-directed mutagenesis on a recombinant plasmid, pUC8, that contained the cah gene, was conducted and confirmed by sequence analysis. Single base substitution, G to A at nucleotide position 81 or T to C at nucleotide position 84 of cah gene does not change the amino acid sequence of cah enzyme but eliminates the HindIII site. The wild-type cah and its mutants were cloned and overexpressed in pQE-60 Escherichia coli expression system. Western blot analysis confirmed the production of 27.7-kDa cah enzyme by all the recombinants. The mutated cah gene devoid of HindIII site was used to generate a recombinant plant transformation vector (pCAMBIA-cah). Agrobacterium-mediated transformation was performed in Nicotiana tabaccum cv. Samsun plants by employing the leaf-disc method. The integration and expression of cah gene in transgenic plants were confirmed by polymerase chain reaction, Southern and Western blot analyses. Antimicrobial activity of cyanamide against phytopathogenic fungi and bacteria was determined. Cyanamide can be used as fertilizer as well as an antimicrobial salt against phytopathogenic fungi and bacteria. The present investigation reports the heterologous expression of the cah marker gene. Due to its innate ability to convert cyanamide to urea and the broad-spectrum antimicrobial activity of cyanamide, the cah gene can be used to facilitate plant growth promotion and biocontrol of phytopathogens.     

石灰氮催芽对葡萄芽内源物质含量的影响(英文)

用15%石灰氮对巨峰葡萄(Kyoho grapevine)进行催芽后,于葡萄休眠解除过程中对芽内源激素含量、蛋白质含量以及淀粉酶活性的动态变化进行测定分析,以探讨石灰氮解除葡萄休眠的生理机制.结果显示:(1)用15%石灰氮催芽5 d后葡萄芽解除休眠而萌发,比对照提前5～8 d,处理21 d后休眠已经被打破;(2)处理后葡萄芽内ABA含量急剧下降了86.48%,而GA_3、ZR和IAA分别升高了461.70%、107.24%和1 020.41%;(3)IAA的急剧升高,伴随着淀粉酶活性加强,加速淀粉降解为可溶性糖;而蛋白质含量则先下降后升高.可见,石灰氮催芽后,葡萄芽内的生长抑制类激素ABA含量降低的同时生长促进类激素IAA、ZR和GA_3含量急剧增加,内源激素平衡被打破,加强了葡萄芽内有机物质的代谢,为葡萄芽的萌发提供了物质基础.因此,石灰氮处理促进葡萄休眠芽萌发的主要原因可能是调节了葡萄芽内各种激素平衡关系,从而加速了葡萄芽内有机物质的代谢而最终解除芽体休眠.     

Analysis of responses to glyceryl trinitrate and sodium nitrite in the intact chest rat

Responses to glyceryl trinitrate/nitroglycerin (GTN), S-nitrosoglutathione (GSNO), and sodium nitrite were compared in the intact chest rat. The iv injections of GTN, sodium nitrite, and GSNO produced dose-dependent decreases in pulmonary and systemic arterial pressures. In as much as cardiac output was not reduced, the decreases in pulmonary and systemic arterial pressures indicate that GTN, sodium nitrite, and GSNO have significant vasodilator activity in the pulmonary and systemic vascular beds in the rat. Responses to GTN were attenuated by cyanamide, but not allopurinol, whereas responses to nitrite formed by the metabolism of GTN were attenuated by allopurinol and cyanamide. The results with allopurinol and cyanamide suggest that only mitochondrial aldehyde dehydrogenase is involved in the bioactivation of GTN, sodium nitrite, and GSNO, whereas both pathways are involved in the bioactivation of nitrite anion in the intact rat. The comparison of vasodilator activity indicates that GSNO and GTN are more than 1000-fold more potent than sodium nitrite in decreasing pulmonary and systemic arterial pressures in the rat. Following administration of 1H-[1,2,4]-oxadizaolo[4,3-]quinoxaline-1-one (ODQ), responses to GTN were significantly attenuated, indicating that responses are mediated by the activation of soluble guanylyl cyclase. These data suggest that the reduction of nitrite to nitric oxide formed from the metabolism of GTN, cannot account for the vasodilator activity of GTN in the intact rat and that another mechanism; perhaps the formation of an S-NO, may mediate the vasodilator response to GTN in this species.     

不同熏蒸剂对草莓连作土壤养分和微生物群落的影响

【背景】草莓连年栽培导致土传病害问题突出,施用熏蒸剂进行土壤消毒因效果显著得以广泛应用。但不同熏蒸剂对土壤病原微生物的影响存在较大差异,同时对非靶标微生物和土壤理化性质也会有不同程度的影响。【目的】明确不同熏蒸剂对草莓连作土壤养分和土壤细菌、真菌群落结构的影响,为合理选择熏蒸剂提供科学依据。【方法】以连作土壤为材料设置5个处理：未熏蒸、石灰氮熏蒸、石灰熏蒸、棉隆熏蒸、威百亩熏蒸,测定熏蒸处理后土壤养分含量;采用PacBio测序平台分析土壤微生物多样性的变化。【结果】石灰氮和威百亩处理均增加了碱解氮含量,降低了有机质、有效磷和速效钾含量;棉隆处理土壤中各养分含量均增加;石灰处理除有机质含量增加外,碱解氮、有效磷和速效钾含量均降低;棉隆、石灰和威百亩处理显著降低pH值。5个处理草莓连作土壤样本中获得了1 164个细菌OTU和444个真菌OTU。细菌多样性和丰富度分析发现,4种熏蒸剂处理均增加了土壤细菌群落的丰富度,石灰氮、石灰和威百亩处理增加了土壤细菌菌落的多样性。4种熏蒸剂处理真菌菌落的丰富度低于对照;石灰、棉隆处理真菌菌落的多样性高于对照和石灰氮、威百亩处理低于对照,但差异不显著。在物种组成分析中,从门水平看,变形菌门(Proteobacteria)和芽单胞菌门(Gemmatimonadetes)为优势细菌门;与对照相比,石灰氮、石灰、棉隆处理变形菌门相对丰度增高,威百亩处理相对丰度降低。4种处理均降低了芽单胞菌门的相对丰度。其他门类中,4种处理均增加了浮霉菌门(Planctomycetota)、疣微菌门(Verrucomicrobia)的相对丰度。优势细菌群落分析表明土壤熏蒸减少了芽单胞菌属(Gemmatimonas)、藤黄单胞菌属(Luteimonas)、中慢生根瘤菌属(Mesorhizobium)等细菌的相对丰度,增加了噬几丁质菌属(Chitinophaga)、苍白杆菌属(Ochrobactrum)的相对丰度。子囊菌门(Ascomycota)为优势真菌,石灰氮、石灰、棉隆、威百亩4种处理均增加了子囊菌门的相对丰度。另外还检测到引起草莓根部土传病害的枝孢属(Cladosporium)和镰刀菌属(Fusarium)病菌,熏蒸处理后均降低了枝孢属和镰刀菌属的相对丰度,其中枝孢属在石灰氮、石灰、棉隆、威百亩处理中分别降低了1.35%、1.11%、0.90%和1.31%,镰刀菌属分别降低了0.71%、0.85%、0.19%和0.65%,但差异不显著。4种土壤熏蒸剂均增加了有益真菌毛壳菌属(Chaetomium)的相对丰度。【结论】采用熏蒸剂处理连作土壤改变了微生物群落构成,减少或灭杀土壤中的大部分致病菌属,起到有效防治草莓土传病害的作用,但不能灭杀所有病菌,而且对有益菌和土壤理化性质有不同程度的影响,因此处理后补充有益微生物非常关键。根据对病原菌的灭杀效果,石灰氮、威百亩处理的效果优于其他处理,可作为轮换施用的熏蒸剂,本试验条件下,棉隆是一种弱的处理剂。     

Effect of the expression of cyanamide hydratase on metabolites in cyanamide-treated soybean plants kept in the light or dark

Metabolite profiling of untransformed and cyanamide hydratase- (Cah) transformed (denoted 1C) soybean (Glycine max [L.] Merrill) leaves revealed only small differences in plants grown in the greenhouse or in the dark for 24 h, indicating that the Cah enzyme that converts cyanamide to urea has no substrates in soybean leaves and does not affect metabolism. Untransformed leaves sprayed with 0.5% cyanamide developed necrotic lesions within 2 h in the light but not in the dark. The sprayed 1C leaves showed little visible damage and accumulated high concentrations of urea, amino acids, and some sugars, but sucrose decreased over a 24 h period. The untransformed necrotic leaves also accumulated some urea and amino acids apparently due to cyanamide degradation, while sucrose and some organic acids decreased. Sprayed 1C leaves in the dark for 24 h contained very little urea and lower sugar levels. The untransformed sprayed leaves accumulated some organic acids, some sugars including sucrose, and urea and total amino acids. Unsprayed plants of both lines placed in the dark for 24 h showed increases in some amino acids and phosphate, and decreases in other amino acids, sugars, and organic acids. Thus the Cah enzyme can detoxify cyanamide by conversion to urea that is converted to amino acids. Other metabolic changes associated with leaf necrosis and darkness are also described. Principal component analysis confirmed the similarities and differences observed. Comparison of the GC-MS metabolic profiling analysis of amino acids with a dedicated system shows large differences, indicating a limitation of the former system.     

Carbonic anhydrase catalyzes cyanamide hydration to urea: is it mimicking the physiological reaction?

 The interaction of human carbonic anhydrase (hCA) isozymes I and II with cyanamide, a linear molecule isoelectronic with the main physiological substrate of the enzyme, CO₂, was investigated through spectroscopic, kinetic, and X-ray crystallographic studies. We show here that cyanamide is hydrated to urea in the presence of CAs, and that it also acts as a weak non-competitive inhibitor (K _I=61±3 mM and 238±9 mM for hCA II and hCA I, respectively) towards the esterasic activity of these enzymes, as tested with 4-nitrophenyl acetate. Changes in the spectrum of the Co(II)-hCA II derivative observed in the presence of cyanamide suggest that it likely binds the metal ion within the CA active site, adding to the coordination sphere, not substituting the metal-bound solvent molecule. It thereafter undergoes a nucleophilic attack from the metal-bound hydroxide ion, forming urea which remains bound to the metal, as observed in the X-ray crystal structure of hCA II soaked in cyanamide solutions for several hours. The urea molecule is directly coordinated to the active site Zn(II) ion through a protonated nitrogen atom. Several hydrogen bonds involving active site residues Thr199 and Thr200 as well as three water molecules (Wat99, Wat122, and Wat123) further stabilize the urea-hCA II adduct. Kinetic studies in solution further proved that urea acts as a tight binding inhibitor of the two isozymes hCA I and hCA II, with very slow binding kinetics (k _on=2.5×10^–5s^–1M^–1). A mechanism to explain the hydration process of cyanamide by CAs, as well as the tight binding of urea in the active site, is also proposed based on the hypothesis that urea is deprotonated when bound to the enzyme. Cyanamide is thus the first true suicide substrate of this enzyme for which binding has been documented by means of X-ray crystallographic and spectroscopic studies. Received: 26 February 1999 / Accepted: 25 May 1999     

Glutathione Content in Peach Buds in Relation to Development and Release of Rest

Glutathione content was determined in buds of one-year-old pottedpeach (Prunus persica L.) trees during rest development andrelease from rest. The content of reduced (GSH) and oxidizedglutathione (GSSG) changed with the accumulation of chillingunits. GSH and GSSG content decreased in the early phases ofrest, and then increased at maximum rest. GSH content continuedto increase and peaked on 1 Dec at 860 chill units, and thendropped during the quiescent stage. It appears that the increaseof GSH during chilling was closely associated with the breakingof rest. In contrast, GSSG showed only slight increase fromOct to Dec. Glutathione levels induced by the rest-breakingchemical, hydrogen cyanamide, were also studied throughout therest period. Five concentrations of cyanamide (0, 0.125, 0.25,0.5, and 1.0 M) were applied on 1 Oct, 15 Oct, 1 Nov, 15 Nov,1 Dec, and 15 Dec, 1990. Cyanamide treatments caused a depletionof GSH within 12 h followed by a large increase 24 h after treatment,whereas the untreated plants showed a relatively constant levelof GSH and GSSG during this time. The changes in GSH contentinduced by cyanamide were inversely related to the cyanamideconcentration applied. It appears that the extent of GSH changewas dependent on both the physiological status of the bud andthe cyanamide concentration. At maximum rest, the plants weremore resistant to cyanamide treatment and this coincided withthe highest level of cyanamide-induced GSH. ¹ Present address: Research Center in Food and Development,Apartado Postal 1735, Hermosillo, Sonora 83200, Mexico.     

Effect of Hydrogen Cyanamide on Amino Acid Profiles in Kiwifruit Buds during Budbreak

Buds, and resultant shoots, were collected from kiwifruit (Actinidia deliciosa [A. Chev.] CF Liang et AR Ferguson var deliciosa cv Hayward) vines from late autumn until late spring with and without hydrogen cyanamide treatment. Those samples were weighed and analyzed for total nitrogen and free amino acids. By 7 days after hydrogen cyanamide treatment, the amount of proline had risen to nearly one-quarter of the total amino acid pool in the treated buds and that proportion was maintained for at least 14 days before it declined. The maximum concentration detected in treated buds was 25.8 micromoles per gram dry weight, 6.6 times that detected in untreated buds. By 95 days after treatment, the relative amounts of proline were not significantly different.