[14C]-Assimilate partitioning in photoperiodically induced seedlings of Pharbitis nil. The effect of benzyladenine

Partitioning of [¹⁴C]-labeled assimilates was studied in relation to photoperiodic floral induction and evocation in one-week-old Pharbitis nil Choisy cv. 'Violet' seedlings. In plants kept under 16 h photoperiods, one 15 h night induced 100% axillary flowering whereas a 24 h night induced both terminal and axillary flowering. A 15 min night break of red light given 8 h after the beginning of the dark period inhibited flowering. Total [¹⁴C]-assimilate distribution among major sinks (plumules + epicotyl and roots + hypocotyl) from a single source cotyledon was unchanged by one inductive night; however, import of [¹⁴C]-assimilates into shoot apices was increased in induced plants compared to vegegative controls. This increase was several-fold in plants subjected to a 24 h night. N⁶-Benzyladenine (BA) application to cotyledons or plumules under non-saturating night lengths increased the number of floral buds per plant without affecting the position of the first floral bud (i.e. the speed of induction). The same treatment caused increased label accumulation in induced apices, while it only slightly affected non-induced ones. The mode of action of BA on flowering through growth stimulation and resulting assimilate mobilization is discussed.     

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     

RNA metabolism in apices of Pharbitis nil daring floral induction

RNA metabolism was studied in apices of Pharbitis nil duringand after floral induction. In continuous light ³H-uridine accumulatedin RNA at a constant rate over an 18 hr period. In darkness,however, the rate of accumulation of label into RNA was constantuntil the 10th hour at which time a rapid burst of accumulationoccurred, peaking at the 14th hour of darkness and followedby a net loss of label. The RNA involved in this burst is probablymRNA due to its size and poly(A) content. This phenomenon doesnot seem to be associated with floral induction, since the siteof perception is the apex, and it also occurs under conditionswhere floral initiation is inhibited by a brief light interruptionof the dark period. Immediately after floral induction by a16-hr dark period the rate of RNA synthesis was suppressed about14%. This suppression lasts for about 12 hr and was followedby a twofold increase in the rate of RNA synthesis, comparedto non-induced apices, at 64 hr after the beginning of the inductivedark period. These post-induction changes were found to occurin all RNA fractions. ¹Present address: Department of Radiation Biology and Biophysics,University of Rochester School of Medicine and Dentistry, Rochester,N.Y. 14642, U.S.A. (Received March 15, 1976; )     

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.     

Inhibition of stem growth and flower formation in Pharbitis nil with N,N-dimethylaminosuccinamic acid (B 995)

Summary In the short-day plant Pharbitis nil, strain Violet, flower formation is inhibited by application of the growth retardant N,N-dimethylaminosuccinamic acid (B 995) via the roots for a period of 24 hours prior to one inductive long night. Terminal flower bud formation is suppressed by a B 995 concentration of 100 mg/l, but for complete suppression of all axillary flower buds 2000 mg/l is required. Inhibition of flower formation is also caused by B 995 application via plumules or cotyledons, even if made at the end of the inductive night. B 995 treatment always results in short, thick internodes and dark-green leaves.Transport of ¹⁴C-labeled B 995 from cotyledons to plumules and roots takes place during a 16-hour dark period. However, very little label moves from a treated to an untreated cotyledon. Application of B 995 to one of the two cotyledons results in flower inhibition, although the untreated cotyledon produces sufficient flower hormone to induce optimal flower formation. It is concluded therefore that in the short-day plant Pharbitis B 995 does not affect flower hormone production, but rather inhibits floral initiation by interfering with the action of the hormone in the shoot apex.Inhibition of flower formation by B 995 can be completely overcome by application of gibbrellin A₃ to the plumulus before the long nigh. A dose of 0.01 g GA₃/apex is sufficient to re-establish flowering, but much more GA₃ is required to restore internode length equal to that of the control. Indole-3-acetic acid and naphthalene acetic acid are totally inactive in overcoming B 995 inhibition of flower formation and growth.The growth rate of Pharbitis plants treated with B 995 and continuously grown in long-day conditions is initially low, but reaches the same level as in untreated plants approximately 25 days after treatment. ¹⁴C-labeled B 995 applied to cotyledons accumulates to a high degree in roots and in the basal part of the shoots. ¹⁴C-B 995 is metabolized very slowly and persists therefore in Pharbitis plants for prolonged periods of time.     

Involvement of Calcium in the Photoperiodic Flower Induction Process of Pharbitis nil

EGTA, a specific Ca(2+) chelator, inhibited the flowering response of Pharbitis nil when applied to the cotyledons immediately before the inductive dark period. Calcium sprayed 30 minutes after the EGTA blocked the effect of EGTA. The length of the critical dark period was increased both by EGTA and by LaCl(3). The calmodulin antagonists W-7 and chlorpromazine also reduced the flowering response. On the other hand, A23187, a calcium ionophore, increased the flowering response. Both EGTA and A23187 were effective at certain times of the photoperiod but had almost no effect when applied at other times. The results indicate that the level of endogenous Ca(2+) may be limiting for floral induction in Ph. nil. Ca(2+) seems to play a role during the early stages of the inductive dark period.     

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.     

The Relationship Between Flowering Induction and the Level of Adenosine Triphosphate in Pharbitis nil

A study has been made on the changes of ATP and protein content in cotyledons and apices of Pharbitis nil after flowering induction. Protein content of the cotyledons which have just got through the induction is 68% higher than that of the control, but the difference trends to disappear there after. The. difference of protein content between the induced and uninduced apices is not so obvious in the first three days after induction, but quite evident on the fourth day (30% higher in the induced apices) suggesting that there is some relationship between protein metabolism and flowering induction both in the cotyledons and in the apices. Just after the seedlings have been induced, ATP content of the cotyledons is getting much (134%) higher than that of the control and the tendency is retained towards the fourth day after induction. Generally ATP content in apices is one order of magnitude higher than that in cotyledons. Although ATP content in the apices is only slightly higher than that of the control soon after induction, it gains quite a lot in the second day until the fifth day the end of our experiment. In the third day after induction ATP level in the apices reaehs to the maximum (20.6×10-2 μmol/g, apices) which is 37% higher than that of the control. The results show that flowering induction is bound to be followed by increase of proteins and ATP both in apices and in cotyledoms. It also. shows both formation of the stimulus in induced cotyledons and evocation in the apices might be all concerned in expression of some genes and synthesis of new RNA and protein. According to the maximum peak of ATP in the apices and cotyledons appeared in 3rd to 4th day after induction, it seems that the inductive effect both in the cotyledons and apices might continue for some time under the following uninduced condition.     

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)     

Effect of plumule and radicle on somatic embryogenesis in the cultures of ginseng zygotic embryos

Immature zygotic embryos of ginseng produced somatic embryos on MS medium without growth regulators. However, in the culture of mature zygotic embryos, excision of the embryo was required for somatic embryo induction. Somatic embryos formed only on excised cotyledons without an embryo axis or on excised embryos without the plumule and radicle of the axis. This observation suggests that the axis tip of the embryo might suppress somatic embryo production although the cotyledon tissues have predetermined embryogenic competency. To clarify the role of the embryo axis on somatic embryo formation, excised plumules or radicles were placed in direct contact with the basal cut-ends of cotyledons. The adhesion of plumules or radicles highly suppressed somatic embryo formation from cotyledon explants. When an agar block containing exudate from excised plumules or radicles was placed in contact with the cut end of the cotyledon, a similar inhibition was observed. These results suggest that embryogenic competence is suppressed by endogenous inhibitors present in the axis tip of the zygotic embryo.     

Transport of Salicylic Acid in Tobacco Necrosis Virus-Infected Cucumber Plants

The transport of salicylic acid (SA) was studied in cucumber (Cucumis sativus L.) using 14C-labeled benzoic acid that was injected in the cotyledons at the time of inoculation. Primary inoculation with tobacco necrosis virus (TNV) on the cotyledons led to an induction of systemic resistance of the first primary leaf above the cotyledon against Colletotrichum lagenarium as early as 3 d after inoculation. [14C]SA was detected in the phloem or in the first leaf 2 d after TNV inoculation, whereas [14C]benzoic acid was not detected in the phloem during the first 3 d after TNV inoculation of the cotyledons, indicating phloem transport of [14C]SA from cotyledon. In leaf 1, the specific activity of [14C]SA decreased between 1.7 and 8.6 times compared with the cotyledons, indicating that, in addition to transport, leaf 1 also produced more SA. The amount of SA transported after TNV infection of the cotyledon was 9 to 160 times higher than in uninfected control plants. Thus, SA can be transported to leaf 1 before the development of systemic acquired resistance, and SA accumulation in leaf 1 results both from transport from the cotyledon and from synthesis in leaf 1.     

Changes in membrane potential inChenopodium rubrum during the course of photoperiodic flower induction

Electrophysiological processes were investigated in the reception organ of photoperiodism, cotyledons and first leaves, in a model short-day plantChenopodium rubrum L. (selection 374) within the dark inductive cycle for flowering. Membrane potential (E_m) was measured in cotyledon and first leaf mesophyll of intact plants. The E_m time-course was fairly similar during inductive dark or postinductive light period or in non-inductive continuous light and had a character of irregular oscillations. The most distinct oscillations were found during the postinductive light period. Changes in light régime at the beginning (light off) and the end of inductive dark period (light on) triggered marked transient E_m changes having a character of damped oscillations. Cortical root cells in intact plants did not react to switching light and darkness. Changes in E_m in reception organs during the inductive cycle could not be correlated with the formation and transport of floral stimulus or with reaching the induced state. Thus, the electrophysiological nature of floral stimulus has not been confirmed.     

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。     

Adenine nucleotide metabolism in isolated chicken hepatocytes.

The turnover of the adenine nucleotide pool, the pathway of the degradation of AMP and the occurrence of recycling of adenosine were investigated in isolated chicken hepatocytes, in which the adenylates had been labelled by prior incubation with [14C]adenine. Under physiological conditions, 85% of the IMP synthesized by the 'de novo' pathway (approx. 37 nmol/min per g of cells) was catabolized directly via inosine into uric acid, and 14% was converted into adenine nucleotides. The latter were found to turn over at the rate of approx. 5 nmol/min per g of tissue. Inhibition of adenosine deaminase by 1 microM-coformycin had no effect on the formation of labelled uric acid, indicating that the initial degradation of AMP proceeds by way of deamination rather than dephosphorylation. Inhibition of adenosine kinase by 100 microM-5-iodotubercidin resulted in a loss of labelled ATP, demonstrating that adenosine is normally formed from AMP but is recycled. Unexpectedly, 5-iodotubercidin did not decrease the total concentration of ATP, indicating that the loss of adenylates caused by inhibition of adenosine kinase was nearly completely compensated by formation of AMP de novo. Anoxia induced a greatly increased catabolism of the adenine nucleotide pool, which proceeded in part by dephosphorylation of AMP. On reoxygenation, the formation of AMP de novo was increased 8-fold as compared with normoxic conditions. The latter results indicate the existence of adaptive mechanisms in chick liver allowing, when required, channelling of the metabolic flux through the 'de novo' pathway, away from the uricotelic catabolic route, into the synthesis of adenine nucleotides.     

Rhythmic changes in ribonuclease activity in relation to nucleic acid synthesis in cotyledons ofChenopodium rubrum L. and to floral induction of the plants

Ribonuclease (RNAse) activity was investigated in cotyledons ofChenopodium rubrum plants subjected to various conditions of illumination (photoperiodic induction, continuous light, induction cancelled by interrupting the dark period by a light-break). At the end of the dark period of the single inductive cycles RNAse activity of induced plants was inferior to that of plants grown in continuous light. At the end of the first two cycles the activity was lowest after the interruption of the dark period by light. The investigation of the enzyme in 6h intervals showed rhythmic changes in activity to occur in induced plants. Enzyme activity followed a pattern opposed to this of nucleic acid (NA) synthesis in the cotyledons. In plants from continuous light the enzyme activity did not show any rhythm and in plants having obtained a light-break during the inductive period the rhythm was less distinct than in the induced ones. The period length of the endogenous rhythm of NA synthesis in the cotyledons is about half as long as this of flowering and the peaks of flowering coincide with the throughs of NA synthesis.     

Nucleic acid synthesis and effect of glucose on its kinetics in cotyledons ofChenopodium rubrum l. during photoperiodic induction

In cotyledons ofChenopodium rubrum L. polydisperse RNA is synthesized in the region of the low molecular weight RNAs during photoperiodic induction. After short-time labelling the rate of 4s RNA synthesis was always higher in induced plants than in plants having obtained a light-break in the middle of the dark period. When glucose was added to the nutrient medium during the dark period of a single photoperiodic cycle the rate of nucleic acid (NA) synthesis was higher in non-induced plants than in induced ones at the termination of the dark period. In plants induced by two cycles in the absence of glucose the rate of NA synthesis at the termination of the second dark period was higher in induced than in non-induced plants. This difference is due to the differential kinetics of NA synthesis during darkness. In plants induced in the presence of glucose the peak of the rhythm in NA synthesis was advanced by 4 h relative to that found in plants induced in the absence of sugar. Thus, the termination of the dark period coincided with the negative slope of the oscillation in plants induced in the presence of glucose, while in plants having obtained a light-break NA synthesis decreased only slightly after having attained its peak. In plants induced in the absence of glucose the termination of the dark period coincided with the peak in the rhythm in NA synthesis. The rhythm in NA synthesis of the cotyledons during the dark period of an inductive cycle is out of phase with the rhythm in flower initiation.     

Indirect Action of Benzyladenine and Other Chemicals on Flowering of Pharbitis nil Chois: Action by Interference with Assimilate Translocation from Induced Cotyledons

Benzyladenine (BA) brushed on the cotyledons of 4-day-old seedlings of Pharbitis nil Chois. markedly stimulates flowering. Greates response is obtained for concentrations between 44 and 440 micromolar. The action of BA is on processes in the cotyledon as shown by the response to its site of application, to the dosage applied and to the requirement for its application prior to the dark period. There was little or no effect of BA treatment on either the time measurement processes of photoperiodic induction or on the generation of floral stimulus. Transport of photosynthetic assimilate from the cotyledons to the shoot apex was altered.     

Adenylate Levels, Energy Charge, and Phosphorylation Potential during Dark-Light and Light-Dark Transition in Chloroplasts, Mitochondria, and Cytosol of Mesophyll Protoplasts from Avena sativa L

The compartmentation of cellular energy relations during dark-light and light-dark transitions was studied by means of a newly developed technique to fractionate oat (Avena sativa L., var. Arnold) mesophyll protoplasts. Using an improved microgradient system with hydrophobic and hydrophilic layers of increasing density, a pure plastid pellet (up to 90% of total chloroplasts) could be separated from an interphase of only slightly contaminated mitochondria (70 to 80% of total mitochondria), and a cytoplasmic supernatant could be obtained within 60 seconds. Appropriate controls indicate that, under the conditions employed, metabolic interconversions of adenylates can be kept to a minimum and, thus, be determined and corrected for. Cross contamination of the fractions, as well as liberation of organelles to the supernatant, was assessed by specific markers, and the metabolite levels recorded were corrected accordingly. Using this technique, we found that, during dark-light transition, the chloroplastic and cytosolic ATP exhibits a rapid increase, while the mitochondrial ATP level decreases. In all compartments, ADP levels mirror alterations of the ATP pool in the opposite way, at least to some extent. To compensate fully for the rise in ATP, chloroplastic and mitochondrial AMP levels change accordingly, indicating that, due to the more or less unchanged level of total adenylates, there is no net flux of adenylates between the compartments. In contrast to the organelles, no AMP could be detected within the cytosol. When the light is turned off, a decrease of ATP coincides between chloroplast stroma and the cytosol for only about 30 seconds. Under prolonged dark treatment, cytosolic ATP rises again, while stroma ATP levels exhibit a further decrease. After about 60 seconds of darkness, the cytosolic ATP level is back to its initial value. This obviously is due to the immediate rise in mitochondrial ATP upon darkening, which cumulates after about 60 seconds; then, caused by an ATP/ADP exchange with the cytosol, it levels off again at the state before changing the conditions, as soon as the cytosolic ATP is also back to its original level. All of these events are closely mirrored by the change in the ATP/ADP ratio and the energy charge within the compartments. While the values for chloroplasts exhibit considerable differences between dark and light, those calculated for mitochondria and the cytosol exhibit only transient changes. These are limited to about 60 seconds of undershoot or overshoot, with respect to the cytosol, and then return to nearly the levels observed before changing the conditions. Adenylate kinase was found to be exclusively associated with chloroplasts (90% of total activity level) and mitochondria. Isotonic liberation of vacuoles did not point toward a significant association of adenylates with this compartment.     

The Role of Cotyledons in Flower Initiation of Pharbitis nil at Low Temperatures

Seedlings of Pharbitis nil, Strains Violet, Tendan and Kidachi,initiated floral buds under Continuous light when exposed totemperatures lower than 15, 15 and 21?C, respectively, throughoutthe experimental period, or to 13–14?C for a minimum durationof 10, 8 and 4 days, respectively. Cotyledons were necessaryfor floral initiation when the seedlings at the start of coldtreatment were 8 days old (10 days old for Kidachi) or younger,although neither cotyledons nor foliage leaves were necessarywhen the plants were older. When the cotyledons in young seedlingswere removed immediately after exposure to cold temperature(13–14?C) for 14 (Violet), 12 (Tendan) or 8 (Kidachi)days (cold treatment begun when the cotyledons had just unfolded),only a few plants initiated floral buds under continuous light.However, when the cotyledons were left attached for 2 more daysat 23?C, the plants produced as many flower buds as those withintact cotyledons, suggesting that cotyledons exposed to coldtemperature produce a floral stimulus which can be translocatedto buds even after the end of the cold treatment. (Received October 14, 1981; Accepted January 20, 1982)