The metabolism of inhibitor of flowering and prostaglandin biosynthesis, acetylsalicylic acid, in Pharbitis nil cotyledons

Acetylsalicylic acid, which applied to cotyledons of the short day plant Pharbitis nil prior to an inductive 16-h dark period inhibits flowering by 90 %, is converted to salicylic acid and to a lesser extent to gentisic acid in the cotyledons during this 16-h dark period. Our results confirmed that salicylic acid and gentisic acid are responsible for the inhibition of flowering. They also inhibit prostaglandin biosynthesis. This revised version was published online in July 2006 with corrections to the Cover Date.     

Abundance of mRNAs encoding HMG1/HMG2 class high-mobility-group DNA-binding proteins are differentially regulated in cotyledons of Pharbitis nil

The abundance of an mRNA encoding an HMG1/2 protein from Pharbitis nil (HMG1) has been previously shown to be regulated by light and an endogenous rhythm in cotyledons. A second Pharbitis nil HMG cDNA (HMG2) was characterized. The sequence of HMG2 was 82% and 86% identical to HMG1 at the nucleotide and amino acid level, respectively. As with HMG1, HMG2 mRNA was detected in all vegetative tissues and was most abundant in roots. However, unlike HMG1, HMG2 mRNA abundance did not increase upon transfer of cotyledons to darkness and did not exhibit regulation by an endogenous circadian rhythm when maintained in continuous darkness over a 68 h period. Similarly, while the abundance of HMG1 mRNA during a dark period that induced photoperiodically controlled flowering was dramatically affected by brief light exposure (night break), this treatment had no effect on HMG2 mRNA abundance. Collectively, these data are consistent with a role of HMG1 in contributing to the circadian-regulated and/or dark-regulated gene expression with constitutive expression of HMG2 playing a housekeeping role in the general regulation of gene expression in Pharbitis nil cotyledons.     

Changes in ATP in relation to floral induction and initiation in Pharbitis nil

No changes in metabolism of adenosine phosphates as a function of short day induction were detected in cotyledons of Pharbitis nil Chois strain Violet. A gradual increase in ATP level was detected throughout the dark period in plumules. A rapid decline of ATP pool size was observed in induced plumules shortly after floral induction. The decline occurred close to the 14th hour of the dark period, 1 to 1.5 h after the dark period length required for a 90% flowering response, which is thought to be the minimum time required for transport of the floral stimulus (and assimilates) from the induced cotyledons to the plumule. Transport of the major adenylates from the cotyledons was verified using [¹⁴C]-adenine. Estimates of the amount, and rate, of adenylate transport suggest that the cotyledons could be an important source of adenylates to re-establish the ATP pool size in evoked plumules.     

Endogenous alpha-ketol linolenic acid levels in short day-induced cotyledons are closely related to flower induction in Pharbitis nil

Alpha-ketol linolenic acid [KODA, 9,10-ketol-octadecadienoic acid, that is 9-hydroxy-10-oxo-12(Z),15(Z)-octadecadienoic acid] is a signal compound found in Lemna paucicostata after exposure to stress, such as drought, heat or osmotic stress. KODA reacts with catecholamines to generate products that strongly induce flowering, although KODA itself is inactive [Yokoyama et al. (2000) Plant Cell Physiol. 41: 110; Yamaguchi et al. (2001) Plant Cell Physiol. 42: 1201]. We examined the role of KODA in the flower-induction process of Pharbitis nil (violet). KODA was identified for the first time in seedlings of P. nil grown under a flower-inductive condition (16-h dark exposure), by means of LC-SIM and LC-MS/MS. In addition, the changes in endogenous KODA levels (evaluated after esterification of KODA with 9-anthryldiazomethane) during the flower-inductive phase in short day-induced cotyledons were closely related to flower induction. The KODA concentration sharply increased in seedlings during the last 2 h of a 16-h dark period, while the KODA level showed no significant elevation under continuous light. The increase of KODA level occurred in cotyledonal blades, but not in other parts (petiole, hypocotyls and shoot tip). When the 16-h dark period was interrupted with a 10-min light exposure at the 8th h, flower induction was blocked and KODA level also failed to increase. The degree of elevation of KODA concentration in response to 16-h dark exposure was the highest when the cotyledons had just unfolded, and gradually decreased in seedlings grown under continuous light for longer periods, reaching the basal level at the 3rd day after unfolding. Flower-inducing ability also decreased in a similar manner. These results suggest that KODA may be involved in flower induction in P. nil.     

Changes in Cotyledon mRNA during Ethylene Inhibition of Floral Induction in Pharbitis nil Strain Violet

Floral induction in seedlings of Pharbitis nil strain Violet, with one cotyledon removed, was manipulated by applying various ethylene treatments to the remaining cotyledon during a 16 hour inductive dark period. Exposure of cotyledons to ethylene (100 microliters per liter) for 4 hours at different times during the dark period inhibited flowering to some extent, with inhibition being greater towards the end of the dark period. RNA from cotyledons given a 16 hour dark period (induced) or exposed to 100 microliters per liter ethylene throughout the dark period, which completely inhibited flowering, was examined. The poly(A)⁺RNA was translated in vitro using a wheat germ system, and the resulting translation products were analyzed by two-dimensional sodium dodecyl sulfate-polyacrylamide gel electrophoresis. There were substantial qualitative and quantitative differences between the poly(A)⁺RNA extracted from induced cotyledons and that from those exposed to ethylene throughout the dark period. Some of these changes are similar to those observed when flowering was inhibited by photoperiodic treatments (M Lay-Yee, RM Sachs, MS Reid 1987 Planta. In press). The significance of these findings to our understanding of the molecular control of flower induction is discussed.     

日本牵牛光周期诱导过程中蛋白质的免疫化学研究

用从短日诱导及非诱导的日本牵牛子叶中提取的蛋白质分别免疫兔子,所得到的抗血清对诱导及非诱导子叶蛋白质进行双相免疫电泳。有22—24种高白质得到鉴定。首次发现有二种蛋白质在16小时暗期诱导后消失。没有新的特异性蛋白质在诱导过程中形成。     

长日照处理对牵牛开花抑制作用研究 Ⅱ.光周期处理与牵牛花芽分化及基因活动的关系

单个光周期暗期长度短于12h时,牵牛植株营养生长旺盛,开花受到抑制,并且出现了诱导光周期处理（ISD）子叶中没有的二种蛋白质或多肽（pI4.1,MW16.5kD;pI4.2,MW16．5kD）。连续光照处理（ICL）子叶内出现了短日照处理（ISD）子叶内没有的体外翻译蛋白质分子量为17．4kD的Poly（A~ ）mRNA。牵牛子叶内的这些变化可能与抑制牵牛花芽分化有一定的关系。     

Abundance of an mRNA encoding a high mobility group DNA-binding protein is regulated by light and an endogenous rhythm

A cDNA clone encoding an HMG1 protein from Pharbitis nil was characterized with regard to its sequence, genomic organization and regulation in response to photoperiodic treatments that control floral induction. The HMG1 cDNA contains an open reading frame of 432 nucleotides encoding a 144 amino acid protein of approximately 16 kDa. The predicted polypeptide has the characteristic conserved motifs of the HMG1 and HMG2 class of proteins including an N-terminal basic region, one of two HMG-box domains, and a polyacidic carboxy terminus. Within the HMG-box region, Pharbitis HMG1 deduced amino acid sequence shares 47%, 67% and 69% identity with its animal, maize, and soybean counterparts, respectively. Southern blot hybridization analysis suggests that HMG1 is a member of a multigene family. Analysis of mRNA abundance indicates that the HMG1 gene is expressed to higher levels in dark-grown tissue, such as roots, and at lower levels in light-grown tissue, such as cotyledons and stems. Following the transition to darkness, the levels of HMG1 mRNA in cotyledons were initially stable, however, after a lag time of 8 h or more, HMG1 mRNA increased in abundance to a peak level at 20 h. A second peak in mRNA levels was observed about 24 h later, indicating that the expression of the HMG1 gene is regulated by an endogenous circadian rhythm. Abundance of the HMG1 mRNA during a dark period was dramatically affected by brief light exposure (night break), a treatment which inhibits floral induction. These data indicate that the expression of HMG1 is regulated by both an endogenous rhythm and the light/dark cycle and are consistent with a role for HMG1 in maintaining patterns of circadian-regulated gene expression activated upon the transition from light to darkness.     

Changes in cotyledon mRNA during floral induction of Pharbitis nil CV. Violet

Floral induction in seedlings of Pharbitis nil Choisy cv. Violet, with one cotyledon removed, was manipulated by applying various photoperiodic treatments to the remaining cotyledon. Populations of polyadenylated RNA from treated cotyledons were examined to identify messages specifically involved in floral induction. The RNA was translated in vitro using a wheat-germ system, and the resulting translation products were analysed by two-dimensional polyacrylamide gel electrophoresis. Substantial qualitative and quantitative differences were found between mRNA from cotyledons of seedlings kept in continuous light (non-induced) and of seedlings given a 16-h dark period (induced). In contrast, inhibition of flowering with a night-break resulted only in one detectable, quantitative difference in mRNA.Abbreviations CL continuous light - kDa kilodalton - NB 16 h darkness+10 min red-light break, 8 h into the dark period - poly(A)⁺ RNA polyadenylated RNA (isolated by binding to a cellulose oligodeoxythymidine affinity column) - SD short day (16 h dark) - SDP short-day plant - SDS sodium dodecyl sulfate     

Involvement of signal transduction pathway components in photoperiodic flower induction in Pharbitis nil

The possible participation of several major components of the signal transduction pathway in photoperiodic flower induction was examined in Pharbitis cotyledons. Exogenous applications of GTP-γ-S (1–10 μ M ) or of the phorbol ester, phorbol 12-myristate-13-acetate (PMA, 0.1–5.0 μ M ) to Pharbitis plants held under a marginal inductive period (11.5 h dark) significantly increased their flowering response. Membrane lipid fluidity, GTP-binding and protein kinase activity were increased following a single flowering-inducing dark period of 16 h; however, a light-break of 10 min that abolished flower induction failed to reverse the dark-induced increase in these processes. Photo-inductive dark conditions significantly increased the content of diacylglycerol (DAG) and phosphoinositides in the cotyledon membranes, together with the activities of their kinases, and a light break decreased them to control levels and below. In addition, a single spraying with GTP-γ-S or PMA at 1 μ M significantly increased both the lipid content and the kinase activities. These compounds also enhanced the kinase activities in vitro. It is concluded that DAG and phosphoinositide metabolism play a role in the linking of the photoperiodic induction of the phytochrome with the flowering response in Pharbitis nil .     

Flowering Response of Pharbitis nil to Agents Affecting Cytoplasmic pH

Permeant weak acids and auxins have been shown to reduce the cytosplasmic pH in several systems. Lactic, citric, formic, butyric, salicylic, parahydroxybenzoic, propionic acid, and sodium propionate inhibited the flowering response of Pharbitis nil seedlings when applied immediately before an inductive dark period. The acidic auxins IAA, indolebutyric, and α-naphtaleneacetic acid, as well as the nonacidic auxin α-naphtaleneaceteamid, also inhibited the flowering response. Inhibition was generally more pronounced with a 12-hour than with a 16-hour dark period. Salicylic acid and sodium propionate shifted the response curve of the dark period by about 2 hours. Salicyclic acid, sodium propionate, and indolebutyric acid were inhibitory when applied during the first few hours of the dark period. The permeant weak bases NH₄Cl, procaine, and trisodium citrate enhanced the flowering response. NH₄Cl reduced the length of the critical dark period. The inhibition of flowering by acids and auxins as well as the promotion of flowering by bases was obtained even when only the cotyledons had been treated. The inhibition of floral induction by auxins may not be dependent on their effect on the cytoplasmic pH.     

Gibberellins in the control of photoperiodic flower transition in Pharbitis nil

The role of gibberellins in the photoperiodic flower induction of short-day plant Pharbitis nil has been investigated. It has been found that the endogenous content of gibberellins in the cotyledons of P. nil is low before and after a 16-h-long inductive dark period. During the inductive night the content of gibberellins is high at the beginning of darkness and about the middle of the dark period. Exogenous GA₃ when applied to the cotyledons of non-induced plants does not replace the effect of the inductive night but it can stimulate the intensity of flowering in plants cultivated on suboptimal photoperiods. GA₃ could also reverse the inhibitory effect of end-of-day far-red light irradiation on P. nil flowering. 2-Chloroethyltri-methylammonium chloride (CCC) applied to the cotyledons during the inductive night also inhibited flowering. GA₃ could reverse the inhibitory effect of CCC. The obtained results strongly suggest that gibberellins are involved in the phytochrome controlled transition of P. nil to flowering. Their effect could be additive to that of photoperiodic induction.     

Molecular cloning and expression analysis of a CONSTANS homologue,PnCOL1, from Pharbitis nil

The Arabidopsis CONSTANS (CO) gene is a key regulator of the long day (LD)-dependent flowering pathway and two CO homologous genes COL1 and COL2 are involved in the regulation of the circadian rhythm. In order to understand the role of CO and COL in short-day plants, a CO homologue, PnCOL1, was isolated and characterized from Japanese morning glory (Pharbitis nil). The deduced PnCOL1 protein of 386 amino acid residues contained two putative zinc finger motifs at the N-terminal region and a conserved CCT domain at the C-terminal region. The deduced amino acid sequence of PnCOL1 was 34% identical to that of PnCO, but 32%, 34%, and 34% identical to those of CO, COL1, and COL2, respectively. Expression of PnCOL1 was barely detected in the cotyledons of plants grown under continuous light (CL), but highly expressed in the cotyledons of plants grown under SD. Expression of PnCOL1 showed a pattern of circadian rhythm as well as daily oscillation. The overexpression of PnCOL1 by a 35S promoter did not overcome the late-flowering phenotype of Arabidopsis co mutants. The results provided in this study suggest that PnCOL1 may have a role in the circadian rhythm in Pharbitis nil.     

Stimulation of the Flowering of Pharbitis nil Chois. by Gibberellin A3 : Time Dependent Action at the Apex

Gibberellin A₃ (GA₃) stimulated flowering when it was appliedto the shoot apex of seedlings of Pharbitis nil, dwarf strainKidachi; but, not when it was applied to the cotyledons. GA₃applied to the plumule before or shortly after the start ofan inductive dark period promoted both flowering and shoot elongation;but, the later the time of application during the dark periodless the promotion of flowering, although marked promotion ofshoot elongation always took place. The variation with time in the response of flowering to GA₃indicates that early floral processes at the apex are stimulatedby GA₃, but that subsequent processes are insensitive to it.The early processes of floral stimulus produced by a 16 hr inductivedark period probably are completed within 20 hr at 28°Cafter the end of the dark period. At low temperatures, suchas 15 and 20°C, early floral processes continued for morethan 40 hr. When cotyledons were removed at various times, the export ofthe floral stimulus to the shoot apex was apparent within hoursof the generation of the floral stimulus in the cotyledons,which started with the passage of the critical 9-hr dark period. (Received February 18, 1981; Accepted March 24, 1981)     

Flowering Response in Relation to C and N Contents of Pharbitis nil Plants Cultured in Nitrogen-Poor Media

Flowering of seedlings of Pharbitis nil, strains Violet andTendan, cultured in modified White's medium, was promoted bymedium dilution, the critical dark period being shortened byabout 15 min. Dilution of the N source alone was enough to causethe medium-dilution effect. Dilution of the culture medium duringthe day before and on the day of exposure to the dark-period(a total of two days) caused the maximum dilution effect. TheC and N contents of the cotyledons and of the shoot apices changedrapidly in response to medium dilution. In 1/2-strength White'smedium with 1/1,000 strength NO₃^– which was most effectivefor flower promotion, the C-N ratio was highest. In 1/2-strengthmodified White's medium, in which flowering was lowest withthe longest critical dark period, the C-N ratio was lowest.Thus, there is a close relation between flowering response andthe C-N ratio in cotyledons or shoot apices of Pharbitis nil. (Received September 14, 1984; Accepted January 26, 1985)     

DIFFERENTIAL RNA SYNTHESIS IN THE SHOOT APEX OF PHARBITIS NIL DURING FLORAL EVOCATION

Early events in the evocation of the flower in Pharbitis nil Chois seedlings were investigated by following the incorporation of tritiated uridine into the shoot apex. The uridine was applied to the expanded cotyledons of seedlings at 8 hr into the inductive dark period. The shoot tips were fixed at 20 hr (a 12-hr labeling period). After the 12-hr labeling period there was considerable label throughout the shoot tips of both control plants (dark period interrupted with 5 min of red light at 8 hr) and plants induced to flower. Both RNase and acid hydrolysis removed the nonexchangeable label and the Azure B staining, thus leading to the conclusion that the uridine was incorporated into RNA. Induction in the cotyledons was followed quickly by an increased synthesis of RNA in the rib meristem region of the receptor bud at the time when the floral stimulus is assumed to be arriving. The increase in RNA synthesis is revealed by an increase in the rib meristem/central zone ratio of counts due to the incorporation of tritiated uridine. A comparison of counts in each of the two regions revealed that the change in ratio was due to an increase in the rib meristem and not due to a decrease in the central zone in induced shoot apices. The initial activation of the rib meristem probably occurred by 16 hr from the beginning of the dark period. Tendencies in the literature to disregard the role of the rib meristem in giving rise to part of the flower are discussed.     

Polypeptide profiles from cotyledons of developing and photoperiodically induced seedlings of the Japanese morning glory (Pharbitis [ipomoea] nil)

An unknown substance(s) produced in the cotyledons of seedlings of the Japanese morning glory (Pharbitis nil) during a defined period of darkness triggers the subsequent initiation of floral buds at apical and axillary meristems. Recent studies have concentrated on characterizing molecular changes as a possible mechanism associated with its synthesis, but these have failed to eliminate interference due to lack of development unity in the sampled population and to consider different kinetic alternatives of those potential changes. The current study demonstrates that numerous age-related changes occur in polypeptides from cotyledons during growth under noninductive conditions, but that these are minimal in older seedlings selected for improved synchrony of the floral response. Polypeptides from older seedlings sampled at various times during and after a dark inductive period were examined by two-dimensional polyacrylamide gel electrophoresis (2-D PAGE). No differences associated with floral induction could be detected. The results indicate that changes in gene expression correlated with floral-induction do not occur in the abundant polypeptide fraction within the limitations of the techniques employed.     

Polypeptide profiles from cotyledons of developing and photoperiodically induced seedlings of the Japanese morning glory (Pharbitis [ipomoea] nil)

An unknown substance(s) produced in the cotyledons of seedlings of the Japanese morning glory (Pharbitis nil) during a defined period of darkness triggers the subsequent initiation of floral buds at apical and axillary meristems. Recent studies have concentrated on characterizing molecular changes as a possible mechanism associated with its synthesis, but these have failed to eliminate interference due to lack of development unity in the sampled population and to consider different kinetic alternatives of those potential changes. The current study demonstrates that numerous age-related changes occur in polypeptides from cotyledons during growth under noninductive conditions, but that these are minimal in older seedlings selected for improved synchrony of the floral response. Polypeptides from older seedlings sampled at various times during and after a dark inductive period were examined by two-dimensional polyacrylamide gel electrophoresis (2-D PAGE). No differences associated with floral induction could be detected. The results indicate that changes in gene expression correlated with floral-induction do not occur in the abundant polypeptide fraction within the limitations of the techniques employed.