Early effects of floral induction on cell division in the shoot apex of Silene

The changes in cell number, the relative proportions of interphase nuclei with different amounts of DNA, mitotic index and labelling index have been investigated in the shoot apex of Silene coeli-rosa L. (a long-day plant) during the first long day of photoinduction, and compared with the corresponding changes in plants in short days. 3 h after the start of induction the proportion of nuclei in the G2 phase of the cell cycle had increased, the mitotic index tended to be higher, and the labelling index was lower than in plants in short days. 8–9 h later the values for plants in the long day had become similar to those for plants in short days. No evidence was obtained for a synchronisation of cells in one phase of the cell cycle as a result of photoinduction. The results obtained were consistent with a temporary shortening of the cell cycle in the induced apices over the first long day which resulted in a greater increase in cell number by the end of the first day of photoinduction than in plants in short days.Abbreviations LD long day - SD short day     

Synchronisation of cell division in the shoot apex of Silene in relation to flower initiation

In plants of Silene coeli-rosa, induced to flower by 7 LD, synchronisation of cell division in 20 per cent or more of the cells in the shoot apical dome was found on the 8th and 9th days after the beginning of induction, during the plastochron before sepal initiation. Synchronisation was inferred from the changes in the proportions of cells with the 2C and 4C amounts of DNA, and changes in mitotic index and labelling index. From the peaks of mitotic index a cell cycle of 10 h was measured for the synchronised cells, half that of cells in the apices of uninduced plants in short days. The faster cell cycle and synchronisation in the induced plants was associated with a shortening, of both G1 and G2, suggesting two control points, while S and M remained unchanged. These results are compared with those from other plants in which synchronisation occurs at the beginning rather than the end of evocation.Abbreviations LD long day(s) - SD short day(s) - S DNA synthesis phase of cell cycle - G1 pre-S interphase - G2 post-S interphase - M mitosis     

Location of cell cycle changes in relation to morphological changes in the shoot apex ofSilene coeli-rosa immediately before sepal initiation

Summary Changes in morphology, the mitotic index and the proportions of cells in G₁ and G₂ were measured in shoot meristems ofSilene coeli-rosa immediately before floral morphogenesis in order to determine whether the known changes to the cell cycle at this time are restricted to a particular region of the apex. Twenty-eight day-old plants were given either 7 long days (LD) plus 2 short days (SD) (day 8 of the LD treatment) or 9 SD [day 8 of the SD control (SDC) treatment]. Plants were sampled on day 8 every 2 h for 12 h and the various cell cycle measurements were performed on sections of the apical meristem. In the inductive LD treatment there was a peak in the mitotic index at 13.00 h and, possibly, the start of another at 19.00 h. At 21.00 h all meristems in this treatment initiated sepals. The mitotic activity at 13.00 and 19.00 h in the LD treatment was a result of significant increases in the mitotic index in the axial, lateral and central sub-axial areas of the apex compared with the corresponding zones in the SDC treatment. At 13.00 h of day 8, 80% of cells were in G₂ phase in the axial region in the LD treatment whilst 85% of cells were in G₁ in the axial zone in the SDC treatment. In the other zones significantly more cells were in G₂ in the LD compared with the SDC treatment as was the case at 19.00 h although not to the same extent as the axial zone at 13.00 h. Thus these data emphasize, for the first time, the mitotic activation and predominance of the G₂ population of cells particularly in the axial zone of shoot meristems in the LD treatment. These data are discussed in relation to the synchronisation of cell division which could occur in the prefloral shoot meristem at this time, affecting each shoot apical zone.Abbreviations LD long day - SD short day - SDC short day control     

The differential effects of C-16,17-dihydro gibberellins and related compounds on stem elongation and flowering in Lolium temulentum

Plants of Lolium temulentum L. cv. Ceres grown under short days (SDs) can be induced to initiate inflorescences either by exposure to one long day (LD) or by single applications of some gibberellins (GAs), which also enhance the flowering response to one LD. Single doses of up to 25 μg per plant of C-16, 17-dihydro-GA₅ were about as effective as GA₅ for promoting flowering after one LD but inhibited stem elongation by up to 40% over three weeks. The promotion of flowering but not the inhibition of elongation by 16, 17-dihydro-GA₅ was reduced in SDs or in LDs low in far-red (FR) radiation. With shoot apices cultured in vitro, 16, 17-dihydro-GA₅ was more florigenic than GA₃ for apices excised after one LD of 14 h or more, but less florigenic for apices excised from plants in shorter days. 16, 17-Dihydro-GA₅ was ineffective compared with GA₁, GA₃ and GA₅ for α-amylase production by half-seeds of Lolium, a response concordant with its effect on stem elongation. As with GA₅, 16, 17-dihydro derivatives of GA₁, GA₃, GA₂₀ and several other GAs were more effective for flowering and less effective for stem elongation than the GAs from which they were derived. Hydroxylation at C-17 and/or C-16 generally reduced the effectiveness of 16, 17-dihydro-GA₅ for flowering. These results extend the known features of GA structure which favour flowering relative to stem elongation in L. temulentum. Moreover, C-16, 17-dihydro-GA₅ mimics, in its daylength- and wavelength-dependence and lack of stem elongation, characteristics of the LD stimulus in L. temulentum.     

Ageing of theSilene coeli-rosa L. shoot apex under non-inductive conditions: Changes in morphology,mitotic index,and polypeptide composition

Summary Ageing was studied in the shoot apex of the long day plant,Silene coeli-rosa by maintaining it in non-inductive short day conditions for 170 days. The dimensions, the zonation, and the polypeptidic pattern of the shoot apex, and the rate of leaf initiation were altered in 170-day-old plants compared with young plants grown under the same conditions (28 days). In aged plants, the number of cells increased in all shoot apical zones and, notably, the mitotic index increased in the axial zone; however, the rate of leaf initiation slowed down. These changes showed some similarities to those during the intermediate phase in quantitative photoperiodic species. The two-dimensional mini-gel electrophoretic study of protein extracts from shoot apices of young and ageing plants maintained in non-inductive conditions revealed 489 common polypeptidic spots, 13 unique to the young state and 24 new ones specific to aged plants. The spots characteristic for each state represented only 3.6% of the total identified polypeptides, but apical development under non-inductive conditions was characterized by qualitative changes in the polypeptide complement.Abbreviations C nuclear DNA complement - 1D gel first dimension gel - LD long day - NEPHGE non equilibrium pH gradient electrophoresis - SD short day - SDS sodium dodecyl sulfate - TCA trichloracetic acid     

Effect of Intercalated Long Days and Light Interruption of Dark Period on Flowering, Extension Growth and Senescence of impatiens balsamina

Plants of Impatiens balsamina L. grown under long days were divided into 5 lots to receive 1, 2, 4, 8 and 16 consecutive short day (SD) cycles respectively. Each lot was divided into 5 groups to receive 1, 2, 4, 8 and 16 long day (LD) cycles subsequent to SD regime and the cycles were repeated till the end. Observations on the number, position and time of emergence of floral buds, flowers and extension growth were recorded. The floral buds are initiated and these develop into flowers even when Individual SDs are intercalated with 16 LD cycles, showing that the sub-threshold stimulus is not wiped off but becomes effectively summated through a long non-inductive period. The floral bud initiation in lots receiving less than 4 and flowering in those receiving less than 8 consecutive SD cycles are delayed with decreasing number of consecutive SDs and increasing number of intercalating LDs. This progressive delay is probably due to the delay that is caused by these treatments in the completion of requisite number of SD cycles. The first node to show floral bud initiation is shifted up with increasing intercalated LDs only in plants receiving less than 4 SD cycles and not in those receiving more. Some of the lower floral buds in plants receiving less than 8 consecutive SD cycles either abort or revert to vegetative growth. The first node to flower is, therefore, shifted up. The number of such buds increases either with a decrease in the number of consecutive SDs or an increase in the number of intercalated LDs. The number of floral buds produced in plants receiving 2 or more and flowers in those receiving 4 or more consecutive SD cycles does not differ much with the number of intercalated LDs, but decreases in those receiving less number of SDs. Some nodes bear more than one floral bud and flower. Such nodes are observed in plants receiving individual SD cycles only when intercalated with individual LDs but in all groups in plants receiving 16 consecutive SD cycles. The rate of extension growth increases with an increase in the number of consecutive SDs. The rate in plants receiving individual SDs closely resembles that of plants grown under continuous LDs and that of consecutive 16 SDs with that of control SD plants. The attainment of maximum and the consequent steep fall preceding senescence is successively delayed with an increase in the number of intercalated LDs in plants receiving 16 consecutive SD cycles. Light interruption of the dark period inhibits both the initiation of floral buds and their development Into flowers. showing that in this plant. short days are necessary both for the initiation of floral buds and their development into flowers.     

Changes in the Pattern of Cell Division in the Shoot and Root Meristems of Lolium perenne during the Transition from Vegetative to Floral Growth

For Lolium perenne cv. Cropper, a system which resulted in 100%flowering comprised 90 short days (SD) at 4 ?C (vernalization)and 30 SD at 18 ?C followed by 8 long days (LD). The mitoticindex and G1 and G2 percentages were measured in the shoot androot apices of plants following 2, 5 or 8 LD and in SD controlssampled at the beginning and end of induction. Identical measurementswere made in plants given 48 SD at 18 ?C followed by 2, 5 or8 LD; plants remained vegetative in response to this treatmentlacking vernalization. Significant increases in both mitoticindex and meristem size occurred in the shoot apex in LD followingthe vernalizing, but not the non-vernalizing, treatment. A clusterof mitoses in the apical dome of the shoot apex was unique tothe vernalized plants given 5 or 8 LD. However, an increasein root meristem size occurred regardless of vernalization,but a significant increase in the mitotic index was limitedto vernalized plants given 5 or 8 LD. Whilst the vernalization-LDtreatment resulted in an increase in the G2 percentage in theshoot apex following 2, 5 or 8 LD, no such alteration was observedin the root meristem. Thus, the changes to the cell cycle whichcorrelated with flowering were increased mitotic indices andG2 percentages in the shoot apex at each sampling time and increasedmitotic indices in the root apex following 5 and 8 LD. Key words: Cell division, flowering, Lolium perenne L.     

Determination of floral organ type in cultured Silene shoot apices

Shoot apices of the long day plant, Silene coeli-rosa , were cultured on a basal medium (+3% sucrose) in non-inductive short days (SD) following their excision from plants which had been exposed to long day (LD) treatments in order to examine the period for determination of each floral whorl. In response to the inductive LD treatments, the pattern of whorl formation in vitro reflected their normal appearance in Silene : sepals, stamens 1–5, petals, stamens 6–10 and carpels, although the number of apices initiating each whorl was lower in vitro compared with apices in vivo. However, supplementing the medium with 7 instead of 3% sucrose corrected this deficiency and, for the first time, resulted in apices initiating floral whorls in SD. The interval between the shortest treatment to result in whorl initiation in vitro, 4 LD (which also resulted in 50% flowering in vivo), and the treatment which gave 50% initiation of the corresponding whorl in vitro, was taken to be the period for determination of that whorl. The determination times on the 3% medium were: sepals (2 days), stamens 1–5 (3 days), petals (3 days), stamens 6–10 (4 days) and carpels (4 days); all of these periods shortened to about 1 day on the 7% medium. Tissue culture did not perturb the pattern of initiation of each whorl since apices excised and cultured from plants which had received 7 LD + 2 SD, exhibited each whorl over the same time scale as those of intact plants which received the same treatment. The data are consistent with a sequential determination and initiation of each whorl in the order that they appear normally in Silene . Synchronisation of cell division, as represented by peaks of the mitotic index and G₂/G₁ ratios on day 8 (7 LD + 2 SD), did not occur in vitro but the mitotic index did not descend to zero, further emphasising that tissue culture did not perturb the Silene apex.     

Cell Cycle Responses to Red or Far-red Light, or Darkness, in the Shoot Apex of Silene coeli-rosa L. During Floral Induction

Twenty-eight-day-old plants of Silene coeli-rosa L. were maintainedin short days (SD) for 9 d (0–8) or exposed to 7 longdays (LD), or 7 SD with a 5 min exposure at 1700 h of each dayto far-red (FR), red (R) or 5 min FR/5 min R, or 7 dark-interrupted(di = 1700–1720 h) LD. Treatments were followed by twofurther SD. The mitotic index and G1 and G2 proportions weremeasured in the shoot apices of plants sampled at 2000 h ofeach day of each replicated treatment. Exposure to 7 LD (= 100per cent flowering) resulted in significant increases, relativeto the SD controls, in both the G2 proportion and the mitoticindex on d 0 to 3, 7 and 8. Five minute FR (= 0 per cent flowering)resulted in cell cycle responses similar to those in LD onlyfrom d 0 to 2. R and FR/R (both = 0 per cent flowering) didnot result in any increases in the G2 proportion in the apexapart from d 3 of FR/R. However 5 min FR/5 min R, and to a lesserextent 5 min R, did result in significant increases in the mitoticindex on d 0, 1, 7, and 8. diLD (= 8–10 per cent flowering)also prevented any significant increases in the G2 proportionon d 0 to 3, and 5 to 8 but the mitotic index was again higheron these days compared with control data. Thus the transitionto floral growth for 90 per cent of the plants is associatedwith changes in the cell cycle in the shoot apex measured asincreases in the G2 proportion at 2000 h of LD 0 to 3 and 7to 8. Silene coeli-rosa L., cell cycle, flowering, phytochrome, shoot apex     

Photoperiod-induced changes in gibberellin metabolism in relation to apical growth and senescence in genetic lines of peas (Pisum sativum L.)

In an early-flowering line of pea (G2) apical senescence occurs only in long days (LD), while growth in short days (SD) is indeterminate. In SD, G2 plants are known to produce a graft-transmissible substance which delays apical senescence in related lines that are photoperiod-insensitive with regard to apical senescence. Gibberellic acid (GA₃) applied to the apical bud of G2 plants in LD delayed apical senescence indefinitely, while N⁶-benzyladenine and -naphthaleneacetic acid were ineffective. Of the gibberellins native to pea, GA₉ had no effect whereas GA₂₀ had a moderate senescence-delaying effect. [³H]GA₉ metabolism in intact leaves of G2 plants was inhibited by LD and was restored by placing the plants back in SD. Leaves of photoperiod-insensitive lines (I-types) metabolized GA₉ readily regardless of photoperiod, but the metabolites differed qualitatively from those in G2 leaves. A polar GA₉ metabolite, GA_E, was found only in G2 plants in SD. The level of GA-like substances in methanol extracts from G2 plants dropped about 10-fold after the plants were moved from SD to LD; it was restored by transferring the plants back to SD. A polar zone of these GA-like materials co-chromatographed with GA_E. It is suggested that a polar gibberellin is synthesized by G2 plants in SD; this gibberellin promotes shoot growth and meristematic activity in the shoot apex, preventing senescence.Abbreviations GA gibberellin - GA₃ gibberellic acid - SD short days - LD long days     

Stem elongation and changes in the levels of gibberellins in shoot tips induced by differential photoperiodic treatments in the long-day plant Silene armeria

The effects of differential photoperiodic treatments applied to shoot tips and mature leaves of the long-day (LD) plant Silene armeria L. on growth and flowering responses, and on the levels of endogenous gibberellins (GAs), were investigated. Gibberellins were analyzed by gaschromatography-mass spectrometry and the use of internal standards. Exposure of mature leaves to LD, regardless of the photoperiodic conditions of the shoot tips, short days (SD), LD, or darkness, promoted elongation of the stems and of the immature leaves. Long-day treatment of the mature leaves modified the levels of endogenous GAs in shoot tips kept under LD, SD, or darkness. In shoot tips kept in LD or darkness the levels of GA₅₃ were reduced, whereas the levels of GA₁₉ and GA₂₀ were increased. The contents of GA₁ were increased in all three types of shoots: SD twofold, LD fivefold, and darkness eightfold. Dark treatment of the shoot tips on plants of which the mature leaves were grown in SD promoted elongation of the immature etiolated leaves and increased the GA₁ content of the shoot tips threefold. However, this treatment did not cause stem elongation. The different photoperiodic treatments applied to the shoot tips did not change the levels of GAs in mature leaves. These results indicate that both LD and dark treatments result in an increase in GA₁ in shoot tips. In addition, it is proposed that LD treatment induces the formation of a signal that is transmitted from mature leaves to shoot tips where it enhances the effect of GA on stem elongation.Abbreviations GA_n gibberellin A_n - LD long day(s) - SD short day(s) We thank Dr. L.N. Mander, Australian National University, Canberra, for providing [²H]-gibberellins and Dr. D.A. Gage, MSU-NIH Mass Spectrometry Facility, East Lansing, for advice with mass spectrometry. This work was supported, in part, by a fellowship from the Spanish Ministry of Agriculture (Instituto Nacional de Investigaciones Agrarias) to M.T., by the U.S. Department of Energy grant No. DE-FG02-91ER20021, and by the U.S. Department of Agriculture grant No. 88-37261-3434 to J.A.D.Z.     

Cellular changes induced by exogenous and endogenous gibberellins in shoot tips of the long-day plant Silene armeria

Stem elongation and flowering are two processes induced by long-day (LD) treatment in Silene armeria L. Whereas photoperiodic control of stem growth is mediated by gibberellins (GAs), the flowering response cannot be obtained by GA applications. Microscopic observations on early cellular changes in the shoot meristem following LD induction or GA treatment in short days (SD) were combined with GA analyses of stem sections at various distances below the shoot apex. The earliest effects of both LD and GA induction on the subapical meristem were an increase in the number of cells per cell file and a reduction of cell length in the meristematic tissue approx. 1.0–3.0 mm below the shoot apex. Within 8 d after the beginning of LD induction or after GA application, the cells in the subapical meristem were oriented in long files. In induced tips, cellulose deposition occurred mostly in longitudinal walls, indicating that many transverse cell divisions had taken place which, in turn, increased the length of the stem. In contrast to LD induction, GA treatments did not promote the transition from the vegetative to the floral stage. Endogenous GAs were analyzed by selected ion monitoring (SIM), using labeled internal standards, in extracts from transverse sections of the tip at various distances below the apical meristem. In control plants, the levels of the six 13-hydroxy GAs studied (GA₅₃, GA₄₄, GA₁₉, GA₂₀, GA₁, and GA₈) decreased as the distance from the apical meristem increased. Except for GA₅₃, GA levels were higher in tips of LD-induced plants, particularly in the meristematic zone approx. 0.5–1.5 mm below the apical meristem. In comparison with SD, the highest increase observed was for GA₁, the content of which increased 30-fold in the zone 0.5–3.5 mm below the shoot apex. These data indicate a spatial correlation between the accumulation of GA₁ and its precursors, and the enhanced mitotic activity which occurs in the subapical meristem of elongating Silene apices.Abbreviations GA_n gibberellin A_n - LD long day(s) - SD short day(s) We thank Dr. L.N. Mander, Australian National University, Canberra, for providing [²H]- gibberellins, Dr. B.O. Phinney, University of California, Los Angeles, USA, for [¹³C]GA₈, Dr. D.A. Gage, MSU-NIH Mass Spectrometry Facility, for advice with mass spectrometry, and Mr. M. Chassagne, I.N.R.A. C.R. Bordeaux, for the photography. This work was supported, in part, by a fellowship from the Spanish Ministry of Agriculture (Instituto Nacional de Investigaciones Agrarias) to M.T., by the U.S. Department of Energy under contract DE-ACO2-76ERO-1338, and by the U.S. Department of Agriculture grant No. 88-37261-3434 to J.A.D.Z.     

Gibberellins and the photoperiodic control of stem elongation in the long-day plant Agrostemma githago L.

Agrostemma githago is a long-day rosette plant in which transfer from short days (SD) to long days (LD) results in rapid stem elongation, following a lag phase of 7–8 d. Application of gibberellin A₂₀ (GA₂₀) stimulated stem elongation in plants under SD, while 2-isopropyl-4-dimethylamino-5-methylphenyl-1-piperidine-carboxylate methyl chloride (AMO-1618, an inhibitor of GA biosynthesis) inhibited stem elongation in plants exposed to LD. This inhibition of stem elongation by AMO-1618 was overcome by simultaneous application of GA₂₀, indicating that GAs play a role in the photoperiodic control of stem elongation in this species. Endogenous GA-like substances were analyzed using reverse-phase high-performance liquid chromatography and the d-5 corn (Zea mays L.) assay. Three zones with GA-like activity were detected and designated, in order of decreasing polarity, as A, B, and C. A transient, 10-fold increase in the activity of zone B occurred after 8–10 LD, coincident with the transition from lag phase to the phase of rapid stem elongation. After 16 LD the activity in this zone had returned to a level similar to that under SD, even though the plants were elongating rapidly by this time. However, when AMO-1618 was applied to plants after 11 LD, there was a rapid reduction in the rate of stem elongation, indicating that continued GA biosynthesis was necessary following the transient increase in activity of zone B, if stem elongation was to continue under LD. It was concluded that control of stem elongation in A. githago involves more than a simple qualitative or quantitative change in the levels of endogenous GAs, and that photoperiodic induction alters both the sensitivity to GAs and the rate of turnover of endogenous GAs.Abbreviations AMO-1618 2-isopropyl-4-dimethylamino-5-methylphenyl-1-piperidine-carboxylate methyl chloride - GA(s) gibberellin(s) - LD long day(s) - LDP long-day plant(s) - SD short day(s)     

Flowering of the grass Lolium perenne: effects of vernalization and long days on gibberellin biosynthesis and signaling

Almost 50 years ago, it was shown that gibberellin (GA) applications caused flowering in species normally responding to cold (vernalization) and long day (LD). The implication that GAs are involved with vernalization and LD responses is examined here with the grass Lolium perenne. This species has an obligatory requirement for exposure to both vernalization and LD for its flowering (inflorescence initiation). Specific effects of vernalization or LD on GA synthesis, content, and action have been documented using four treatment pairs: nonvernalized or vernalized plants exposed to short days (SDs) or LDs. Irrespective of vernalization status, exposure to two LDs increased expression of L. perenne GA 20-oxidase-1 (LpGA20ox1), a critical GA biosynthetic gene, with endogenous GAs increasing by up to 5-fold in leaf and shoot. In parallel, LD led to degradation of a DELLA protein, SLENDER (within 48 h of LD or within 2 h of GA application). There was no effect on GA catabolism or abscisic acid content. Loss of SLENDER, which is a repressor of GA signaling, confirms the physiological relevance of increased GA content in LD. For flowering, applied GA replaced the need for LD but not that for vernalization. Thus, GAs may be an LD, leaf-sourced hormonal signal for flowering of L. perenne. By contrast, vernalization had little impact on GA or SLENDER levels or on SLENDER degradation following GA application. Thus, although vernalization and GA are both required for flowering of L. perenne, GA signaling is independent of vernalization that apparently impacts on unrelated processes.     

Effect of varying number of short days, gibberellic acid and ascorbic acid on the flowering of soybean

Both the cultivars of soybean, namely E.C. 2579 and Punjab I,studied were found to be qualitative short day plants. Evenone SD was sufficient to cause flower bud initiation in E.C.2579, although flower opening required 3 SDs. Pb. I did notshow flower bud initiation with less than 10 SDs. In Pb. I thenumber of flowers with 20 SDs was higher than continuous SD,indicating the favourable effect of long days prior to induction. Exogenous application of GA₃ and AA singly and in combinationsubstituted for the additional photoperiodic requirements ofincompletely induced plants of Pb. I, but were ineffective undercontinuous LDs. Treatment with these regulators of plants havingreceived 8 SDs resulted in initiation of flower buds, whichfailed to open into flowers. In plants subjected to 10 SDs flower buds were initiated withall these treatments except control. Floral buds did not openinto flowers with any treatment or combination not containingGA₃. (Received March 28, 1970; )     

Proteomic analysis of shoot tissue during photoperiod induced growth cessation in <Emphasis Type="Italic">V. riparia</Emphasis> Michx. grapevines

Background  

Growth cessation, cold acclimation and dormancy induction in grapevines and other woody perennial plants native to temperate continental climates is frequently triggered by short photoperiods. The early induction of these processes by photoperiod promotes winter survival of grapevines in cold temperate zones. Examining the molecular processes, in particular the proteomic changes in the shoot, will provide greater insight into the signaling cascade that initiates growth cessation and dormancy induction. To begin understanding transduction of the photoperiod signal, Vitis riparia Michx. grapevines that had grown for 35 days in long photoperiod (long day, LD, 15 h) were subjected to either a continued LD or a short photoperiod (short day, SD, 13 h) treatment. Shoot tips (4-node shoot terminals) were collected from each treatment at 7 and 28 days of LD and SD for proteomic analysis via two-dimensional (2D) gel electrophoresis.     

Inhibition of growth and synchronised cell division in the shoot apex in relation to flowering in Silene

When plants of Silene coeli-rosa (L.) Godron were induced by seven long days, then exposed to darkness for 48 h before being returned to short days, they went on to initiate flowers with a delay of about 2 d. The synchronisation of cell division which normally occurs before flower initiation was suppressed, showing that it is not essential for flowering. Periods of darkness of up to 240 h inhibited apical growth and leaf initiation but did not prevent eventual flowering in short days. The commitment of the apex to flower was therefore maintained while apical growth was inhibited.Abbreviations SD short day(s) - LD long day(s)     

Photoperiodism and Crassulacean acid metabolism

Measurements of net CO₂ exchange, malate accumulation, properties and capacity of phosphoenolpyruvate carboxylase (PEPC, EC 4.1.1.31) in leaves of different ages of two short-day dependent Crassulacean acid metabolism (CAM) plants (Kalanchoe blossfeldiana v. Poelln. Tom thumb and K. velutina Welw.) show that, in both species: a) young leaves from plants grown under long days display a CO₂ exchange pattern typical of C₃ plants; b) leaf aging promotes CAM under long-day conditions; c) short-day treatment induces CAM in young leaves to a higher degree than aging under long days; d) at least in K. blossfeldiana, the PEPC form developed with leaf aging under long days and the enzyme form synthetized de novo in young leaves grown under short days were shown to have similar properties. Short days also promote CAM in older leaves though at a lesser extent than in young leaves: The result is that this photoperiodic treatment increases the general level of CAM performance by the whole plant. The physiological meaning of the control of PEPC capacity by photoperiodism could be to afford a precisely timed seasonal increase in CAM potentiality, enabling the plant to immediately optimize its response to the onset of drought periods.Abbreviations CAM Crassulacean acid metabolism - PEP phosphoenolpyruvate - PEPC phosphoenolpyruvate carboxylase (EC 4.1.1.31) - LD long day - SD short day