Mitotic Activities and Levels of Nuclear DNA in the Apical Meristem of Silene armeria (strain SI.2) Following Application of Gibberellin A3

Strain S1.2 of Silene armeria was grown under an 8h-photoperiodand treated with GA₃ every day for 20 days. This growth substancecaused stem elongation, but no flowering in this long-day plant.Changes in the mitotic index and DNA content of cells in thevarious zones of the apical meristem before, during and afterGA₃ treatment were described. Mitotic activity and increasein the proportion of nuclei at the 4C level (S+G₂ phase of thecell cycle) were strongly stimulated in the rib-meristem, andto a lesser extent in the lateral zone, but not in the axialzone. This stimulation of apical activity reached a peak aftertwo GA₃ treatments and then declined gradually, so that after20 days the activity in GA₃-treated meristems was lower thanthat in untreated controls; at this point most cells were inthe G₁ phase. When the GA₃ treatment was discontinued, there was a gradualincrease in the mitotic activity which ultimately reached thesame level as that in controls. Stem elongation ceased and leavesformed aerial rosettes. It is concluded that in vegetative plants of strain S1.2 ofSilene armeria GA₃ acts mainly on the rib-meristem cells whichresults in stem elongation. Lack of response in the axial cellsexplains why GA₃ fails to induce flowering in this strain ofSilene armeria. (Received June 18, 1983; Accepted August 3, 1983)     

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     

Effect of OA-inhibitor of protein phosphatases PP1 and PP2A — on initiation of DNA replication and mitosis in <Emphasis Type="Italic">Vicia faba</Emphasis> root meristems

According to the principal control point (PCP) hypothesis, experiments with excised, carbohydrate-starved stationary root meristems of Vicia faba var. minor have demonstrated that cells which previously divided asynchronously were preferentially blocked in G₁ (PCP1) and G₂ (PCP2) phases. When stationary phase meristems are supplied with exogenous carbohydrate (2 % sucrose), the G1- and G2-arrested cells start out DNA replication and mitotic divisions, respectively. The resumption of DNA synthesis and mitosis is not immediate and the delays of G₁- and G₂-arrested cells are found different. Using this model, we examined the effects of 4 pulse incubations with okadaic acid (OA), a specific inhibitor of PP1 and PP2A, on the duration of intervals elapsing between the provision of sucrose and the first appearance of S- and M-phase cells. We have found that depending on the period during which OA had been applied, the release from G1 and G2 phase arrest-points becomes prolonged, showing different time-course modifications. The obtained data provide evidence that activation of PP1 and PP2A is required to allow the cells for both PCP1→S and PCP2→M transitions in root meristems of V. faba.     

THE EARLY ACTION OF THE FLORAL STIMULUS ON MITOTIC ACTIVITY AND DNA SYNTHESIS IN THE APICAL MERISTEM OF XANTHIUM STRUMARIUM

Vegetative plants of Xanthium strumarium (a short-day species) were induced to flower by exposure to a single 16-hr long night. By cutting off the induced leaf (half-expanded leaf) at various times, it was established that, by 8 hr after the end of the long night, a sufficient amount of floral stimulus had reached the meristem to induce a flowering response. The following sequence of events occurred in both the peripheral and central zones of the apical meristem of induced plants: 1) a rise in the mitotic index beginning at 28 hr after the end of the long night and culminating at 36 and 56 hr; 2) a stimulation of DNA synthesis starting at 32–36 hr and reaching a maximum at 60 hr; 3) an increase in nucleolus diameter starting at 32 hr. The cell population in the meristems of both vegetative and induced plants displayed a similar distribution, with about 80 % of the nuclei with the 2C amount of DNA. The comparison of the kinetic data concerning the mitotic index and DNA synthesis indicated that one of the early effects of the floral stimulus in the peripheral and central zones was the release in mitosis of cells whose nuclei were in the postsynthetic (G₂) phase of the mitotic cycle. In the pith-rib meristem, the following events were recorded: 1) a stimulation of DNA synthesis starting at 20 hr; 2) a rise of the mitotic index beginning at 28 hr; 3) the vacuolation and elongation of cells starting at 48 hr. All these events occurred well before the initiation of bract and flower primordia, which began at 96 and 136 hr, respectively. Neither stimulation of mitotic activity nor flowering occurred in the meristems of plants subjected to a long night interrupted at its midpoint by a 5-min light break. The results are discussed in relation to the early events which are known to occur in the meristems of other photoperiodic species in transition to flowering.     

High sensitivity of DNA replication to 5-aminouracil in the middle of the S period

Summary Cell distribution in different compartments of the cell cycle (G₁, early, middle and late S, G₂ and mitosis) has been studied during treatment with 0.5 mM 5-aminouracil and recovery inAllium cepa L. root meristems by cytophotometric and autoradiographic methods. At optimum conditions for obtaining mitotic synchronization, 5-aminouracil gives rise to cell accumulation in the S period, preferentially in its middle zone where the relative DNA content is 2.8 ± 0.1 C. After a 14-hour treatment 33% of the proliferative population is accumulated in this particular region.During recovery, a drastic reduction of the S phase and a clear increase of the mitotic frequency are the most important events observed. Apparently, the removal of the drug frees the blockage and the accumulated cells complete their interphase making up the mitotic wave.     

Variation in the Rate of Cell Division in the Apical Meristem of Sinapis alba During Transition to Flowering

Rates of cell division in the central and the peripheral zonesof vegetative and evoked meristems of Sinapis alba have beenmeasured by accumulation of metaphases after colchicine treatment.The cells of the central zone had a longer cycle than the cellson the flanks of both kinds of meristems. The duration of thecell cycle was shortened in both zones of the meristem duringtransition to flowering. It was shown that the mitotic indicesof the two regions of the meristem were closely comparable totheir rates of cell division and therefore could be consideredrepresentative of the rates of cell division.     

Regulation of cell division in the subapical shoot meristem of dwarf watermelon seedlings by gibberellic acid and polyethylene glycol 4000

The stimulatory effects of gibberellic acid (GA₃) and the inhibitory effects of polyethylene glycol 4000 (PEG) on hypocotyl elongation and cell cycle kinetics in subapical pith cells of dwarf watermelon seedlings (Citrullus lanatus [Thunb.] Matsu and Nakai) were investigated. Mitotic indices (MI) were determined from direct counts of pith cells stained by a modified Feulgen technique. Labeling indices (LI) were determined from direct counts of labeled pith cells sampled 1.5 h after apical applications of³H-thymidine. Root application of 0.32 mM GA₃ at 96, 120, or 144 h after sowing resulted in significant increases in both mitotic and labeling indices within 4.5 to 7.5 h following treatment. A single mitotic peak at 13.5 h occurred in all three treatment periods. Labeling peaks were often less defined than mitotic peaks; however, a relatively high proportion of labeled nuclei were usually observed between 7.5 and 9 h after GA₃ treatment and at 16.5 h, the latter period coinciding with progression of cells into S phase from the peak period of mitosis. The results suggest that GA₃ increases the proportion of rapidly dividing cells in the subapical meristem by increasing the probability that slowly cycling or nonproliferative cells in both 2C and 4C DNA states will enter the proliferative pool. The addition of PEG (200 g/l, = 1.5 mPA) to the rooting medium of dwarf watermelon seedlings inhibited hypocotyl elongation and reduced both mitotic and labeling indices simultaneously within 4.5 h after treatment. Within 24–28 h after PEG treatment, mitotic and labeling indices approached 0. Seedlings transferred from PEG to either water or GA₃ exhibited rapid recovery of cell division and hypocotyl elongation. Mitotic and labeling indices increased within 4.5–7.5 h into the recovery period in either water or GA₃ and reached control values within 10.5 h. GA₃ hastened the recovery from PEG-induced stress. It is concluded that water stress imposed by PEG 4000 causes arrest of cell division in meristematic cells of watermelon seedlings in both G₁ and G₂ periods. PEG and GA treatments resulted in only a partial and transitory synchronization of the cell cycle.     

EFFECTS OF NEAR ULTRAVIOLET AND VISIBLE RADIATIONS ON CELL CYCLE KINETICS IN EXCISED ROOT MERISTEMS OF PISUM SATIVUM

Near-ultraviolet and visible radiations increased the duration of the mitotic cycle in excised pea root meristems primarily by lengthening the duration of the pre-DNA synthetic period (G₁). All radiations tested shortened the duration of the post-DNA synthetic period (G₂). The most pronounced effects were exhibited by green radiation, which lengthened the duration of the cell cycle, G₁, DNA synthesis (S), and mitosis (M), and shortened the duration of G₂. Progression of cells arrested by starvation in G₁ and G₂ into DNA synthesis and mitosis was also affected by light treatments. Green radiation appeared to arrest a group of cells in DNA synthesis as well as in G₁ and G₂. Meristems receiving green and near-ultraviolet radiations exhibited the most rapid progression of G₁ cells through S and G₂.     

GA3和Spd对杜鹃开花期光合特性和抗氧化系统的影响

为探讨GA_3和Spd对杜鹃(Rhododendron simsii)开花花期和开花品质的影响,研究了外源GA_3和Spd对杜鹃开花期光合特性和抗氧化系统的变化。结果表明,外源GA_3对花期有显著的提前作用,Spd对花期有明显的延迟作用,但两者均使花期延长、花径增大且成花率提高。GA_3和Spd处理提高了花期叶片的光合色素含量和净光合速率(Pn)、气孔导度(Gs)和胞间CO_2浓度(Ci);GA_3处理提高了叶片的蒸腾速率(Tr),而Spd使叶片的Tr下降,两者均有效缓解了末花期叶绿素含量的下降。GA_3和Spd处理显著降低了花瓣MDA含量,提高了抗氧化酶SOD、POD和CAT活性,并减缓了末花期SOD的下降,有效延缓了衰老进程,延长花期。以1 600 mg L~(–1) GA_3和0.10 mmol L~(-1) Spd处理效果较好,能有效提高杜鹃花的观赏品质。     

VARIATION IN CELL-CYCLE TIME AND NUCLEAR DNA CONTENT IN THE APICAL MERISTEM OF HELIANTHUS ANNUUS L. DURING THE TRANSITION TO FLOWERING

The mitotic cycle in the apical meristem of Helianthus annuus L. has been investigated during the transition to flowering. Towards the end of the strictly vegetative phase 8 days after sowing the average cell-cycle time, measured by colchicine-induced metaphase accumulation, was 37 hr in the peripheral zone, 83 hr in the central zone and 118 hr in the rib meristem. By Day 12 the cycle had shortened in all zones. By the time of floral initiation on Day 16 the cycle time had returned to its original value in the peripheral zone and the rib meristem, while in the central zone it continued to shorten to 33 hr, approaching the cycle time of the peripheral zone. Cytophotometric measurements of nuclear DNA showed that mitotic activation of the central zone was not associated with any reduction in the proportion of nuclei with a 4 C DNA content. It was calculated that the spatial and temporal variation in cell-cycle time was mainly a function of the length of the G₁/G₀ phase which lasted about 19 hr in the peripheral zone, 82 hr in the rib meristem, and declined from 55 to 21 hr in the central zone.     

Response of meristem cells to hyperoxygenation

Cycle parameters were estimated in Allium cepa L meristems proliferating under steady state conditions in tap water aerated with either 21 or 100% O₂ and containing 7.9 and 39.0 mg/1 of dissolved oxygen, respectively. Cycle time was slightly but consistently reduced under hyperoxygenation, as shown in synchronous cells labelled as binucleate following a short treatment with 5 mM caffeine. By autoradiography after ³H-thymidine treatment followed by microdensitometry of unlabelled interphases it was determined that cellular frequencies at the last third of the S period (S₃) were statistically different (P<0.05) in control and hyperoxygenated conditions. Estimation of absolute timing confirmed that S₃ duration was nearly halved under the increased O₂ tension. Finally, G₁ time was not modified by hyperoxygenation, though this cycle stage lengthened under hypoxia.     

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.     

The mode of action of a morphactin,fluoren-9-carboxylic acid

Fluoren-9-carboxylic acid acts not only as an auxin but also as an gibberellin-antagonist. In the standard pea straight test (S₅ section) for auxin it stimulated elongation, the optimum concentration being 10 mg/l. On the other hand, it inhibited elongation at 0.1 mg/l. This inhibitory effect was more marked when younger tissue (S₁ section) which also responds to gibberellin was used. Interaction of FCA and IAA in the S₅ section has shown that at higher concentration of IAA there seemed to be a suppraoptimal effect, indicating that FCA acted as an auxin. However, in the S₁ section, the stimulating effect of GA₃ was markedly inhibited by 0.1 mg/l FCA; 10 mg/l FCA was either additive or less than additive to GA₃. In the cucumber hypocotyl test FCA itself was inactive up to 100 μg/plant, but it inhibited the GA₃-induced elongation. This inhibition was overcome by increasing the dosage of GA₃. In the same material, the IAA-induced elongation was not affected by FCA. These results indicate that whether FCA acts as an auxin or a gibberellin-antagonist depends on whether the tissue is sensitive to gibberellin and/or auxin.     

Cellular parameters of the shoot apical meristem in Arabidopsis.

The shoot apical meristem (SAM) is a small group of dividing cells that generate all of the aerial parts of the plant. With the goal of providing a framework for the analysis of Arabidopsis meristems at the cellular level, we performed a detailed morphometric study of actively growing inflorescence apices of the Landsberg erecta and Wassilewskija ecotypes. For this purpose, cell size, spatial distribution of mitotic cells, and the mitotic index were determined in a series of optical sections made with a confocal laser scanning microscope. The results allowed us to identify zones within the inflorescence SAM with different cell proliferation rates. In particular, we were able to define a central area that was four to six cells wide and had a low mitotic index. We used this technique to compare the meristem of the wild type with the enlarged meristems of two mutants, clavata3-1 (clv3-1) and mgoun2 (mgo2). One of the proposed functions of the CLV genes is to limit cell division rates in the center of the meristem. Our data allowed us to reject this hypothesis, because the mitotic index was reduced in the inflorescence meristem of the clv3-1 mutant. We also observed a large zone of slowly dividing cells in meristems of clv3-1 seedlings. This zone was not detectable in the wild type. These results suggest that the central area is increased in size in the mutant meristem, which is in line with the hypothesis that the CLV3 gene is necessary for the transition of cells from the central to the peripheral zone. Genetic and microscopic analyses suggest that mgo2 is impaired in the production of primordia, and we previously proposed that the increased size of the mgo2 meristem could be due to an accumulation of cells at the periphery. Our morphometric analysis showed that mgo2 meristems, in contrast to those of clv3-1, have an enlarged periphery with high cell proliferation rates. This confirms that clv3-1 and mgo2 lead to meristem overgrowth by affecting different aspects of meristem function.     

Effect of Gibberellin Biosynthesis Inhibitors on Native Gibberellin Content, Growth and Floral Initiation in Sorghum bicolor

CCC, uniconazol, ancymidol, prohexadione-calcium (BX-112), and CGA 163′935, which represent three groups of gibberellin (GA) biosynthesis inhibitors, were applied as a soil drench to Sorghum bicolor cultivars 58M (phyB-1, phytochrome B-deficient mutant) and 90M (phyB-2, equivalent phenotypically to wild type, PHYB, except for small differences in flowering dates). The inhibitors that block steps before GA₁₂ (CCC, uniconazol, and ancymidol) lowered the concentrations of all endogenous early-C13α-hydroxylation pathway GAs found in sorghum: GA₁₂, GA₅₃, GA₄₄, GA₁₉, GA₂₀, GA₁, and GA₈. In contrast, the inhibitors that block the conversion of GA₂₀→ GA₁, (CGA 163′935 and BX-112) drastically reduced GA₁ and GA₈ levels, but they either did not change or caused accumulation of intermediates from GA₁₂ to GA₂₀. Combinations of pre-GA₁₂ inhibitors and GA₃ plus GA₁ strongly reduced GAs other than GA₁ and GA₃. Each of these compounds inhibited shoot growth in both cultivars and delayed floral initiation in 90M. Floral initiation of 58M was also delayed by CCC, uniconazol, and ancymidol but not by CGA 163`935 and BX-112. This separation of shoot elongation from floral initiation in sorghum is novel. Both inhibition of shoot growth and delayed floral initiation were almost completely relieved by a mixture of GA₃ and GA₁ in both 58M and 90M. This observation, plus the much lower levels of endogenous GA₃ than of GA₁ observed in these experiments, implies that GA₁ is the major endogenous GA active in shoot elongation. CGA 163′935 and BX-112 also failed to promote tillering in 58M, whereas inhibitors active before GA₁₂ did so. The possibility that the GA₂₀→ GA₁ inhibitors fail to block flowering and promote tillering in 58M because biosynthetic intermediates between GA₁₂ and GA₂₀ accumulate and/or because 58M is altered in GA metabolism in this same region of the biosynthetic pathway is discussed. Received April 7, 1998; accepted July 31, 1998     

Effects of Ring D-Modified Gibberellins on Gibberellin Levels and Development in Selected Sorghum bicolor Maturity Genotypes

Plants of early flowering mutant and wild type genotypes of Sorghum bicolor were treated with ring D-modified gibberellins (GAs), and the effects on endogenous GA levels were determined. The growth and timing of floral initiation in 58M plants grown under 18-h days (which significantly delays floral initiation in this short day plant) following treatment with these compounds, relative to GA₃ and GA₅ treatments, were also investigated. Application of the endo-isomer of C16,17-dihydro-GA₅ (endo-DiHGA₅), the exo-isomer of C16,17-dihydro-GA₅ (exo-DiHGA₅), and C16α,17-dichloromethanodihydro-GA₅ (DMDGA₅) altered GA levels in both genotypes. Each ring D-modified GA significantly inhibited shoot growth while significantly decreasing levels of GA₁ and increasing levels of its immediate precursor, GA₂₀. Gibberellin A₈ levels also decreased. Tillering was not affected by any treatment. For the early flowering genotype 58M, grown under noninductive long days, both dihydro-GA₅ isomers promoted floral initiation while shoot growth was strongly inhibited, and floral development was strongly advanced beyond floral stage 4. Gibberellin A₃ and GA₅, applied under the same conditions, promoted shoot growth slightly and gave ``floral-like' apical meristems that did not develop past floral stage 1. These results suggest that the reduced shoot growth of sorghum, which follows application of those ring D-modified GAs, is due to their inhibiting the 3β hydroxylation of GA₂₀ to GA₁, thereby reducing the GA₁ content. That floral initiation was hastened and floral development promoted in genotype 58M by application of both isomers of DiHGA₅ are in contrast to the effects of other GA biosynthesis inhibitors, which act earlier in the GA biosynthesis pathway, but are consistent with results seen for long day grasses. This suggests that endo-DiHGA₅ and exo-DiHGA₅ may be acting directly in promoting floral initiation and subsequent floral apex development of this short day plant under long day conditions. Received October 3, 1996; accepted January 22, 1997     

Gibberellins, Endogenous and Applied, in Relation to Flower Induction in the Long-Day Plant Lolium temulentum

Changes in endogenous gibberellin-like substances (GAs) and related compounds in the shoot apices of Lolium temulentum during and after flower induction by one long day was examined for plants grown in three consecutive years. The total GA level in the shoot apical tissue was high (up to 42 micrograms per gram dry weight, or 3 × 10⁻⁵ molar GA₃ equivalents), increasing several-fold on the day after the long day and then declining. Of the many GA-like substances present, the putative polyhydroxylated components—with HPLC retention times between those of GA₈ (three hydroxyls) and GA₃₂ (four hydroxyls), and accounting for about a quarter of the total GA activity—were most consistent and striking in their changes. Their level in the apices increased 3- to 5-fold on the day after the long day and then subsided. When various GAs were applied to plants in noninductive short days, flower initiation was induced by several, most notably by GA₃₂, GA₅, 2,2-dimethyl GA₄, GA₃, and GA₇. GA₃₂ was most like one long day in eliciting a strong flowering response while having little effect on stem growth, whereas GA₁ had the opposite effect. It is suggested that highly hydroxylated C-19 GAs may play a central role in the induction of flowering in this long-day plant.     

Fluctuation in levels of endogenous plant hormones in ovules of normal and mutant cotton during flowering and their relation to fiber development

The contents of indole-3-acetic acid (IAA), gibberellins (GAs), abscisic acid (ABA), and cytokinins were determined in ovules of normal cotton (Tm-1) and a kind of fiber differentiation mutant (Xin) before and after flowering by enzyme-linked immunosorbent assays. It was found that 24 h before flowering, a peak of IAA content was observed in ovules of Tm-1, whereas in ovules of Xin, a low level of IAA was determined. From –1 day (1 day before flowering) to +3 days (3 days after flowering), GA₁₊₃ levels in ovules of Xin were 40–70% lower than those of Tm-1; GA₄₊₇ levels were very low, and there was no visible difference in GA₄₊₇ content between normal and mutant cotton. The ABA content in ovule of Tm-1 decreased by 70% 3 days after flowering, whereas that of Xin only decreased by 20%. The levels of cytokinins in ovules of Tm-1 decreased after flowering, and those of Xin kept up a steady increase.Abbreviations IAA indole-3-acetic acid - GA gibberellin - ABA abscisic acid - ELISA enzyme-linked immunosorbent assay - FW fresh weight - PBS phosphate-buffered saline - iPA isopentenyladenosine - ZR zeatin riboside - DHZR dihydrozeatin riboside - CTK cytokinin     

Micronucleus frequency and lipid peroxidation in <Emphasis Type="Italic">Allium sativum</Emphasis> root tip cells treated with gibberellic acid and cadmium

Gibberellic acid (GA₃) is a very potent hormone whose natural occurrence in plants controls their development. Cadmium is a particularly dangerous pollutant due to its high toxicity and great solubility in water. In this study, the effect of GA₃ on Allium sativum root tip cells was investigated in the presence of cadmium. A. sativum root tip cells were exposed to CdNO₃ (50, 100, 200 μM), GA₃ (10-3 M), both CdNO₃ and GA₃. Cytogenetic analyses were performed as micronucleus (MN) assay and mitotic index (MI). Lipid peroxidation analysis was also performed in A. sativum root tip cells for determination of membrane damage. MN exhibited a dose-dependent increase in Cd treatments in A. sativum. GA₃ significantly reduced the effect of Cd on the MN frequency. MN was observed in GA₃ and GA₃ + 50 μm Cd treatments at very low frequency. MI slightly decreased in GA₃ and GA₃ + Cd treatments. MI decreased more in high concentrations of Cd than combined GA₃ + Cd treatments. The high concentrations of cadmium induce MN, lipid peroxidation and lead to genotoxicity in A. sativum. Current work reveals that the effect of Cd on genotoxicity can be partially restored with GA₃ application.     

Replication and G2 checkpoints: their response to caffeine

Under long hydroxyurea treatments, evidence was obtained for the sequential activation of four checkpoints located between the onset of S phase and mitosis in Allium cepa L. root meristems. Bi-parametric flow cytometry (Br-DNA/total DNA) showed that cells initially accumulated at early S phase but, after a delay, they resumed replication and paused again at mid S phase. Cells not only overrode this second replication block but also any G₂ checkpoint they encountered. Thus, a late mitotic wave was produced in the presence of hydroxyurea. The wave was formed by cells that had apparently completed their replication (normal mitoses), while others displayed anaphases/telophases with less than the expected DNA content and with chromosomal breaks (aberrant mitoses). The presence of aberrant mitoses is direct evidence for the undue override of the two G₂ checkpoints responsible for surveillance of completion of DNA synthesis and repair, respectively. Caffeine selectively abrogated the G₂ block produced by the checkpoint that controls post-replication DNA repair, as it advanced the entry of cells into an aberrant mitosis. However, caffeine proved not to be the universal checkpoint-evading agent as postulated. Caffeine did not modify the spontaneous override of the replication checkpoints. Moreover, it seems to enforce the checkpoint that controls the completion of DNA synthesis, as the appearance of the late wave of normal mitoses produced in the presence of hydroxyurea was prevented by the use of caffeine. Received: 21 February 2000 / Accepted: 31 July 2000