Characteristics of the inhibitory action of 1,1-dimethyl-4-(phenylsulfonyl)semicarbazide (DPSS) on ethylene production in carnation (Dianthus caryophyllus L.) flowers

1,1-Dimethyl-4-(phenylsulfonyl)semicarbazide (DPSS)inhibited ethylene productionin carnation flowers during natural senescence, butdid not inhibit the ethyleneproduction induced by exogenous ethylene in carnationflowers, by indole-3-acetic acid (IAA) in mungbean hypocotylsegments and by wounding in winter squashmesocarp tissue. These findings suggested that DPSSdoes not directly inhibit ethylene biosynthesis fromL-methionine to ethylenevia S-adenosyl-L-methionine and1-aminocyclopropane-1-carboxylate. During naturalsenescence of carnation flowers, abscisic acid (ABA)was accumulated in the pistil and petals 2 days beforethe onset of ethylene production in the flower, andthe ABA content remained elevated until the onset ofethylene production. Application of exogenousABA to cut flowers from the cut stem end caused arapid increase in the ABA content in flower tissuesand promoted ethylene production in the flowers. These results were in agreement with the previousproposal that ABA plays a crucial role in theinduction of ethylene production during natural senescence incarnation flowers. DPSS preventedthe accumulation of ABA in both the pistil and petals,suggesting that DPSS exerted its inhibitory action onethylene production in naturally-senescing carnationflowers through the effect on the ABA-related process.     

1,1-Dimethyl-4-(phenylsulfonyl)semicarbazide (DPSS) does not inhibit the in vitro activities of 1-aminocyclopropane-1-carboxylate (ACC) oxidase and ACC synthase obtained from senescing carnation Dianthus caryophyllus L.) petals

The effects of 1,1-dimethyl-4-(phenylsulfonyl)semicarbazide (DPSS) on the in vitro activities of 1-aminocyclopropane-1-carboxylate (ACC) oxidase and ACC synthase isolated from senescing carnation petals were investigated. In contrast to a previous proposal, DPSS at 1 mM did not inhibit the in vitro activity of ACC oxidase. It was confirmed that DPSS does not inhibit ACC synthase activity. DPSS probably does not exert its inhibitory action on ethylene production by a direct action on ACC oxidase and ACC synthase, but by some unknown action.     

The effect of aminooxyacetic acid and cytokinin combinations on carnation flower longevity

A simplified method, which utilizes a 50% senescence value (S₅₀) for the measurement of longevity, in cut carnation flowers is used to compare flower longevity. A pulsed treatment using a combination of aminooxyacetic acid (AOA), kinetin and Triton X-100 enhanced flower vase-life relative to a water control. The mixture, however, did not exhibit synergistic effects when S₅₀ values of the individual compounds were compared. A single AOA pulse treatment was as effective as the mixture. These findings held true for three carnation cultivars. With the exception of dihydrozeatin, which greatly enhanced longevity, replacement of kinetin by a range of cytokinins did not produce significantly different results from the AOA/Triton X-100 combination. Holding solution treatments gave similar trends as pulse treatments. S₅₀ values were better units to express longevity than S₁₀₀ values.Abbreviations AOA aminooxyaceticacid - BA benzyladenine - S₅₀ 50% senescence value - STS silverthiosulphate - iP isopentenyladenize - Z zeatin - DHZ dihydrozeatin     

Inhibition of wilting and autocatalytic ethylene production in cut carnation flowers by cis-propenylphosphonic acid

The effect of cis-propenylphosphonic acid (PPOH), a structural analoge of ethylene, on flower wilting and ethylene production was investigated using cut carnation flowers which are very sensitive to ethylene. Wilting (petal in-rolling) of the flowers was delayed by continuously immersing the stems in a 5–20 mM PPOH solution. In addition, the continuous treatment with PPOH markedly reduced autocatalytic ethylene production of the petals accompanying senescence. This reduction of autocatalytic ethylene production was considered responsible for the inhibitory effect of PPOH on flower wilting. The inhibitory activity of trans-propenylphosphonic acid (trans-PPOH), on both flower wilting and the autocatalytic ethylene production accompanying senescence was markedly lower than that of PPOH, suggesting that PPOH action is stereoselective. PPOH may be of interest as a new, water-soluble inhibitor of wilting and autocatalytic ethylene production in cut carnation flowers.     

Cytokinins in cut carnation flowers. IV effects of benzyladenine on flower longevity and the role of different longevity treatments on its transport following application to the petals

A low concentration of benzyladenine (4.44 × 10^-5 M) accelerated the senescense of cut carnation flowers. This effect could be reversed by STS-treatment but not by keeping the flowers in a holding solution containing 4% ethanol. This appears to be the first report indicating that cytokinins at a specific level may actually enhance flower senescense. The higher levels tested (1.11 × 10^-4 and 2.22 × 10^-4 M) retarded senescense, being in agreement with published results. The applied cytokynin was metabolized slowly in the petals to a compound(s) which co-chromatographed with ribosylbenzyladenine when separated by TLC and when fractionated by HPLC. In the experiments applying (¹⁴C) benzyladenine to the petals, a small degree of transport of the ¹⁴C was detected in naturally senescing (control) cut flowers and when treated with ethrel. The transported ¹⁴C was detected in both the ovaries and in the stems and co-chromatographed with benzyladenine. Where flower senescense was delayed (ethanol or STS) no movement from the petals was detected. This suggests that the cytokinin moved within the assimilate stream, along with sugars.     

The role of ethylene in the senescence of carnation flowers, a review

The senescence of flower petals is a highly regulated developmental process which requires active gene expression and protein synthesis. The biochemical changes associated with petal senescence in carnation flowers include an increase in hydrolytic enzymes, degradation of macro-molecules, increased respiratory activity and a climacteric-like increase in ethylene production. It is clear that the gaseous phytohormone ethylene plays a critical role in the regulation and coordination of senescence processes. Many reviews on physiology and mode of action of ethylene are available. Molecular cloning led to the isolation of genes involved in ethylene biosynthesis and action. This review describes the current status of the studies on regulation of ethylene biosynthesis and ethylene response in carnation flowers. An overview is given of studies on senescence-related gene expression and possibilities to improve postharvest longevity by genetic engineering.Abbreviations ACC 1-aminocyclopropane-1-carboxylic acid - AIB -amino-isobutyric acid - AOA amino oxyacetic acid - AVG aminoathoxyvinyl glycine - DACP diazocyclopentadiene - EFE ethylene forming enzyme - MACC malonyl 1-aminocyclopropane-1-carboxylic acid - MTA 5-methylthio-adenosine - NBD 2,5 norbornadiene - ppb parts per billion - SAM S-adenosyl-methionine - STS silver thiosulphate     

The use of acetaldehyde to control carnation flower longevity

Acetaldehyde is the causal agent of ethanol-induced longevity increases in carnation cut flowers. It increases the vase life of cut carnation flowers by at least 50%. The capacity of acetaldehyde to regulate carnation flower senescence was therefore investigated. Ethylene formation was reduced or inhibited as a result of acetaldehyde application. There was, however, no prevention of ethylene action. The morphological development of the ovary was also inhibited, thus eliminating the movement of metabolites from the petals. The potential use of acetaldehyde as a post-harvest treatment is however impractical, due to the inefficiency of pulse treatments and ineffectiveness in preventing the action of exogenous ethylene.     

Effects of novel oxime ether derivatives of aminooxyacetic acid on ethylene formation in leaves of oilseed rape and barley and on carnation flower senescence

New derivatives of aminooxyacetic acid were tested for their ability to inhibit ethylene formation in higher plants. Treatments with {[(isopropylidene)-aminojoxy}-acetic acid-2-(methoxy)-2-oxoethyl ester, {[(isopropylidene)-aminojoxy}-acetic acid-2-(hexyloxy)-2-oxoethyl ester or {[(cyclohexylidene)-amino]oxy}-acetic acid-2-(isopropyloxy)-2-oxoethyl ester reduced ethylene evolution by leaf discs of oilseed rape and drought-stressed barley leaves. The new compounds delayed senescence of cut carnation flowers. The endogenous levels of 1-aminocyclopropane-1-carboxylic acid (ACC) and its N-malonyl conjugate were also reduced in the leaf discs of oilseed rape. This suggests that a step in the biosynthesis of ethylene, prior to the formation of ACC, is inhibited by these new compounds. A lag phase in response suggests that these compounds have to be activated most likely by the production of metabolites with a free aminooxy group.     

Ethylene biosynthetic genes are differentially expressed during carnation (Dianthus caryophyllus L.) flower senescence

Ethylene production and expression patterns of an 1-aminocyclopropane-1-carboxylic acid (ACC) oxidase (CARAO1) and of two ACC synthase (EC 4.4.1.14) genes (CARACC3 and CARAS1) were studied in floral organs of cut carnation flowers (Dianthus caryophyllus L.) cv. White Sim. During the vase life and after treatment of fresh flowers with ethylene, production of ethylene and expression of ethylene biosynthetic genes first started in the ovary followed by the styles and the petals. ACC oxidase was expressed in all the floral organs whereas, during the vase life, tissue-specific expression of the two ACC synthase genes was observed. After treatment with a high ethylene concentration, tissue specificity of the two ACC synthase genes was lost and only a temporal difference in expression remained. In styles, poor correlation between ethylene production and ACC synthase (CARAS1) gene expression was observed suggesting that either activity is regulated at the translational level or that the CARAS1 gene product requires an additional factor for activity.Isolated petals showed no increase in ethylene production and expression of ethylene biosynthetic genes when excised from the flower before the increase in petal ethylene production (before day 7); showed rapid cessation of ethylene production and gene expression when excised during the early phase of petal ethylene production (day 7) and showed a pattern of ethylene production and gene expression similar to the pattern observed in the attached petals when isolated at day 8. The interorgan regulation of gene expression and ethylene as a signal molecule in flower senescence are discussed.     

A flower senescence-related mRNA from carnation encodes a novel protein related to enzymes involved in phosphonate biosynthesis

We have isolated a cDNA clone (pSR132) representing a mRNA which accumulates in senescing carnation flower petals in response to ethylene. In vitro translation of RNA selected by hybridization with pSR132 indicated the mRNA encoded a polypeptide of approximately 36 kDa. This was confirmed by DNA sequence analysis, which predicted a peptide composed of 318 amino acids with a calculated molecular weight of 34.1 kDa. Comparison of the predicted peptide sequence of pSR132 with other proteins compiled in the NBRF data base revealed significant homology with carboxyphosphonoenolpyruvate mutase and phosphoenolpyruvate mutase from Streptomyces hygroscopicus and Tetrahymena pyriformis, respectively. These enzymes are involved in the formation of C-P bonds in the biosynthesis of phosphonates. C-P bonds are found in a wide range of organisms, but their presence or formation in higher plants has not been investigated.     

Senescence of cut carnation flowers: Ovary development and CO2 fixation

In the presence of ethylene, which enhances carnation flower senescence, carbohydrates contribute to ovary growth not only from the stem and calyx but also from the petals. With silver thiosulphate and ethanol treatments which delay flower senescence, the petals remain the active sink and ovary development is suppressed. Ethylene stimulated chloroplast development in the ovary wall. However, the calyx plus stem of all treatments showed the greater photosynthetic ability and transported a major portion of the synthesised products to the ovary.     

Effect of gibberellic acid on ACC content,EFE activity and ethylene release by floral parts of the senescing carnation flower

The application of gibberellic acid via the stem of intact preclimacteric carnation flowers inhibited the climacteric surge of ethylene evolution by the flowers. Gibberellic acid also inhibited the rate of ethylene production by all individual floral parts during both the early preclimacteric (low basal level of ethylene production) and the later climacteric stages of flower development. The extent of inhibition did however, vary from one floral part to another. The most pronounced inhibition was recorded in the petal bases between the preclimacteric and senescing stages. This suggests that the petal base is an important regulatory site for ethylene production and therefore may be involved in controlling the onset and degree of petal inrolling. In all floral parts endogenous levels of ACC were reduced with GA₃ treatment, being more pronounced in the petal bases. The potential of the flowers to convert applied ACC to ethylene was not deminished by gibberellic acid.Abbreviations GA₃ gibberellic acid - ACC 1-aminocyclopropane-1-carboxylic acid - EFE ethylene forming enzyme     

Invertase inhibitor-control of sucrose transport from carnation petals to other flower parts

An investigation was made of the distribution of metabolites in the receptacles and ovaries, and the activity of an invertase inhibitor after feeding the petals with ¹⁴C-sucrose and cycloheximide during the natural aging of cut carnation flower. The cycloheximide treatment blocked the synthesis of the invertase inhibitor in petals and maintained a relatively high level of invertase activity during flower senscence. Treatment with cycloheximide decreased the movement of radioactivity from petals to receptacles and ovaries from 7 to 10 times, compared to non-treated control flowers. IAA applied on the stigma had no influence on synthesis of the inhibitor and distribution of the radioactivity.     

Efficient transformation and regeneration of carnation cultivars usingAgrobacterium

We have developed an efficient method for transformation and regeneration of plants from carnation,Dianthus caryophyllus L. Whole leaves fromin vitro shoot cultures were mixed withAgrobacterium, cocultivated for 5 days and then plated on 2 µg/l chlorsulfuron (CS). Regenerated shoots and shoot clusters were divided into smaller sections and plated on 3 µg/l CS for selection to produce fully transformed shoots. Geneticin (G418) and kanamycin used were not as effective selective agents as CS. All regenerated shoots were vitrified. These were normalized, rooted and transferred to the greenhouse. 100% of regenerated plants were transformed based on rooting assay, GUS assay, PCR and Southern analysis.     

Roles of pollination and short-chain saturated fatty acids in flower senescence

Pollination induced an immediate increase in ethylene production in Dianthus caryophyllus and Petunia hybrida. In Cymbidium, a lag of several hours was observed. In all three species, pollination induced premature flower senescence. Treatment of the stigmatic surface with aminoethoxyvinylglycine prior to pollination effectively blocked the increase in ethylene production and alleviated the detrimental effect of pollination on flower life.In all three tested species, octanoic and decanoic acids, when applied to the stigmatic surface, had no effect on ethylene production and flower life. In isolated Cymbidium lips placed with their cut base in solutions containing these fatty acids, no effects on red colouration, ethylene production, and ethylene forming enzyme activity were observed. In addition, ethylene sensitivity of isolated lips was not affected. The putative regulatory role of short-chain saturated fatty acids in (pollination-induced) flower senescence is discussed.     

Vitrification of carnation in vitro: Changes in ethylene production,ACC level and capacity to convert ACC to ethylene

Carnation tissue was allowed to vitrify in liquid culture and ethylene production, ACC content and capacity to convert ACC to ethylene were measured in comparison to tissue developing normally on solid medium. Flask atmospheres of liquid cultures accumulated ethylene at a higher rate during the first four days. Daily ethylene production by vitrifying material decreased later. Ethylene emission by vitrifying tissues always remained above controls when subcultured daily to fresh medium. Explants and microsomal preparations from vitrifying carnations converted ACC to ethylene at a higher degree from the first day in liquid medium. ACC level markedly increased in vitrifying tissues during the first two days of liquid culture. Raising the level of ethylene in the atmosphere of solid cultures did not induce vitrification symptoms nor did use of inhibitors of ethylene biosynthesis in liquid cultures prevent the process. The role of ethylene in vitrification is reappraised.