Effects of red and far-red light on cell division in the shoot apex ofSilene coeli-rosa L.

Summary 28-day-old plant ofSilene coeli-rosa were exposed at 1,700 hours to 5 or 10 minutes red light, 5 or 10 minutes far-red light, red followed by far-red, far-red followed by red or maintained in darkness. Measurements of the proportions of cells with the 2 C and 4 C amounts of DNA in the shoot apex of the plants, sampled at 2,000 hours, showed that far-red light promoted an increase in the G2 proportion whereas red light resulted in an increase in the G1 proportion of the cell cycle, relative to the dark controls. Moreover these changes were red, far-red reversible. All light treatments resulted in increases in the mitotic index in the apex compared with the dark controls, suggesting increases in the growth rate. The data implicate phytochrome in a low energy response and suggest that, in the shoot apex, G1 is shortened markedly following exposure to farred light, whilst G2 is shortened the most following exposure to red light. The results are discussed in relation to flower-initiation.     

Mean rate of DNA replication and replicon size in the shoot apex ofSilene coelirosa L. During the initial 120 minutes of the first day of floral induction

Summary 28-day-old plants ofSilene coeli-rosa were exposed, at 1,700 hours, to long day (LD) conditions comprising light of low fluence rate provided by tungsten bulbs, or maintained in darkness as short day (SD) controls. All plants were exposed at 1,700 hours to tritiated-(methyl-³H)-thymidine for 30, 45, 60, 90, or 120 minutes. Apical domes were isolated and prepared as fiber autoradiographs from which replicon size and rates of DNA replication, per single replication fork were recorded. In SD, replicon size was between 15–20 m and exposure to LD conditions altered neither replicon size nor the pattern of deployment of replicons during S-phase relative to the SD controls. However, the mean rate of replication in LD was 8.7 m h^–1 compared with 5.2 m h^–1 in SD. Thus, exposure to LD resulted in a 1.7-fold increase in the rate of DNA replication relative to the SD controls. This rapid increase in replication rate, detectable within 30 minutes of the start of the LD is discussed in relation to changes known to occur to the cell cycle inSilene during the first day of floral induction.     

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     

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     

Effects of interpolated dark periods during the first long day of floral induction on the cell cycle in the shoot apex of Silene coelirosa

Seeds of Silene coeli-rosa L. were germinated and grown at 20°C in short days of 8 h light from fluorescent and tungsten (F + T) bulbs and 16 h darkness for 28 days (day 0). At 1700 h of day 0, the plants were exposed to 16 h light from T (LD) followed by 8 h F + T, or the same treatment interrupted at 1700 h of day 0 by 20 or 60 min darkness. Plants were exposed to tritiated (methyl-[³H])-thymidine for 2 h (1645–1845 h) and sampled every 2 h for 24 h. The cell cycle (percentage labelled mitoses method), and changes in cell number were measured in the shoot apical meristems. The cell cycle in the LD, 20 and 60 min dark-interrupted LD (diLD) treatments was 10, 11 and 13 h, respectively. Mean cell generation times were ca 3–5 h longer, suggesting that the shorter cell cycles were transient. The proportions of cells with 2C or 4C amounts of nuclear DNA, indicated that imposition of darkness resulted in a progressive lengthening of G1 from about 3 h in the LD to 7 h in the 60 min diLD treatment. Conversely, G2 shortened from about 4 h in the LD to 3 h in the 60 min diLD treatment. Measurements of labelling index indicated that S-phase was about 1.5 to 2 h in each treatment. The data are discussed in relation to the known inhibitory effect of the diLD treatments on flowering.     

The cell cycle in the shoot apex ofSilene during the first day of floral induction

Summary The length of the cell cycle was measured in the shoot apical meristem ofSilene coeli-rosa during the first day of an inductive photoperiod. The length of the cell cycle in the shoot apex of vegetative controls (those in short days) was about 18–20 hours. Exposure of plants to the long day resulted in an immediate shortening of the cell cycle to about 13 hours, roughly two thirds of that in short days. Measurements of the component phases of the cell cycle revealed that the shortened cycle in long days was the result of a decrease in the length of G 1 and perhaps S, whilst G 2 and M remained constant.     

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     

The blockage in the G 1 phase of the cell cycle in the dormant shoot apex of ash

The shoot apex of the terminal bud was studied in four successive physiological states: during dormancy, when dormancy breaks, during the third week after the break of dormancy, and during a later typical period of active growth. DNA content was measured in Feulgen-stained nuclei of the axial zone, of the lateral zone, and of the rib meristem. The mitotic index was established for each zone of the meristem. During the period of dormancy, all the nuclei of the meristem are in phase G ₁ of the cell cycle and are blocked at the same point common to all nuclei. When dormancy breaks, this blockage is removed simultaneously and all nuclei in the shoot apex resume their cell cycles starting at the same point. The cycles remain synchronized for awhile. In the axial zone they remain synchronized until the third week after resumption of active growth.     

Restricted cell/cell communication in the shoot apex ofSilene coeli-rosa during the transition to flowering is associated with a high mitotic index rather than with evocation

Summary Plants ofSilene coeli-rosa given 5 or more long days (LDs) flowered, even when the LDs were followed by 48 hours of darkness before their return to short days (SDs). The mitotic indices of shoot apices from induced plants shortly after induction were significantly higher than the indices of shoot apices from vegetative plants. Two major mitotic peaks were observed in the shoot apices of plants given 7 long days (LDs) on day 8. One coincided with that reported byFrancis andLyndon (1979).Cell to cell movement was tested in the shoot apices of vegetative and LD treated plants using probes with a molecular size of 749 daltons (fluorescein-hexaglycine) and 847 daltons (fluorescein-leucyl diglutamyl leucine). These probes showed some movement in the shoot apices of both short day (SD) and LD treated plants, but fluorescein-leucyl diglutamyl leucine was immobile in the induced apices of 7 LD plants on day 8 at time intervals which coincided with major mitotic activity in the shoot apex. Symplasmic restriction in the shoot apex was also observed in plants given 8 LDs (i.e., plants not returned to SDs on day 7).In plants that were placed in 48 hours of darkness after the 7 LD treatment or in plants given 5 LDs, there was no strong peak in the mitotic index, even though all these LD treatments resulted in 100% flowering. In such plants no symplasmic restriction was found in the shoot. Thus the symplasmic restriction on day 8 of 7 LD plants is associated with the high mitotic index, but neither of these phenomena is an essential part of the evocation process.Abbreviations F(Glu)₂ L-glutamylglutamic acid conjugated to fluorescein isothiocyanate isomer I (F-) - F(Gly)₆ F-hexaglycine - FLGGL F-leucyl-diglutamyl-leucine - F(PPG)₅ F-the pentamer (propyl-propyl glycine) - LD long day - LDs long days - SD short day - SDs short days     

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)     

Rates of cell division in the young prefloral shoot apex ofChrysanthemum segetum L.

Summary The rate of cell division was determined by the colchicine induced metaphase-accumulation technique in the young prefloral shoot apex of the quantitative long-day plantChrysanthemum segetum L. growing under conditions favourable to flowering (16-hour photoperiod; 124Em^–2s^–1; 22 °C). Cell cycle duration was evaluated in relation to the location of the cells in the intact apex. The cell cycle durations were 53.5 hours, 47.4 hours, and 97.7 hours in the axial, lateral and subapical central cells respectively. Compared with previous results, these data give evidence of the major role played by the early increase in cell division rate of axial cells in the new pattern of the prefloral shoot apex at its initial stage of development. By comparison with the vegetative shoot apex, the cell cycle duration was preferentially shortened in the axial zone; it was only slightly altered in the lateral zone while it was lengthened in the vacuolating subapical central cells. In the three zones within the prefloral shoot apex, the duration of mitosis was constant (3.2 to 3.3 hours) and the same as in the vegetative shoot apex.     

Transformation of plants via the shoot apex

Summary We have transformed petunia byAgrobacterium tumefaciens containing genes for kanamycin resistance and beta-glucuronidase using isolated shoot apices from seedling tissue. Regeneration of transformed plants in this model system was rapid. The technique of shoot apex transformation is an alternative for use inAgrobacterium-mediated transformation of dicotyledonous crop species for which a method of regeneration via protoplasts, leaf disks, or epidermal strips does not exist. This approach offers direct and rapid regeneration of plants and low risk of tissue-culture-induced genetic variation. Texas Agricultural Experiment Station Technical Article No. 23317.     

Identification of genes expressed in the shoot apex ofBrassica campestris during floral transition

The vegetative-to-floral transition ofBrassica campestris cv. Osome was induced by vernalization. Poly(A)+RNA was isolated from the transition shoot apex after 6 weeks of vernalization, the floral apex after 12 weeks of vernalization and the expanded leaves just before vernalization, and cDNAs were synthesized. These cDNAs were used for subtraction and differential screening to select cDNA preferentially present in the transition and floral apices. Nucleotide sequences of the resulting 14 cDNA clones were determined, and northern blot analysis was carried out on six cDNAs. Two cDNA clones which did not show significant similarity to known genes were shown to be preferentially expressed in the floral apex.     

Clonal propagation ofBougainvillea glabra ‘Magnifica’ through shoot apex culture

Shoot apices ofBougainvillea glabra ‘Magnifica’ were induced to regenerate an average of ten shoots from their bases in response to BAP (0.5 mg/l) plus IAA (1.5 mg/l). All the isolated shoots from such cultures were rooted in a medium containing 0.1 mg/l each of IBA and 2,4,5-T and lacking BAP. Plantlets were then successfully grown in potted soil where they flowered normally. NBRI, research publication no. 32/80.     

Developmental anatomy of the three-dimensional structure of the vegetative shoot apex

There have been many studies of the vegetative shoot apex, but the majority of such studies have been based on median longitudinal sections. Anatomical studies based on surface views of the apex are relatively few in number. Unfortunately, three-dimensional structures, based on surface and transverse-sectional views as well as longitudinal views, have scarcely been analyzed. However, Hara attempted such analyses (1961, 1962, 1971a, b, c, 1977). He identified radial files of cells in the peripheral meristem and recognized four or five apical sectors in the three-dimensional structure of the shoot apex. The size of the central zone and the sizes and relative positions of the sectors change rhythmically in each plastochron. Further studies on the three-dimensional structure of the shoot apex are needed if we are fully to understand the morphogenesis and histogenesis of vascular plants.     

Occurrence of two cell subpopulations with different cell-cycle durations in the central and peripheral zones of the vegetative shoot apex of Sinapis alba L.

The cell-cycle duration and the growth fraction were estimated in the vegetative shoot apical meristem of Sinapis alba L. The length of the cell cycle was about 86 h, i.e. 2.5 times shorter than the cell-doubling time (M. Bodson, 1975, Ann. Bot. 39, 547–554) and the growth fraction was between 32 to 41%. These data demonstrated that the cell population of this meristem was heterogeneous, including one subpopulation of rapidly cycling cells and one subpopulation of non-cycling cells, i.e. cells with a very long cell cycle compared with that of the rapidly cycling cells. Non-cycling cells had no particular localization within the meristem. Both the central and peripheral zones of the meristem were mosaics of rapidly cycling and non-cycling cells.Abbreviations G₁ pre-DNA-synthesis phase - G₂ post-DNA-synthesis phase - GF growth fraction - M mitosis phase - PLM pulse-labelled-mitoses method - S DNA-synthesis phase - T cell-cycle duration - TdR thymidine     

Arrangement of cortical microtubules in the shoot apex of Vinca major L.

The arrangements of cortical microtubules (MTs) and of cellulose microfibrils in the median longitudinal cryosections of the vegetative shoot apex of Vinca major L., were examined by immunofluorescence microscopy and polarizing microscopy, respectively. The arrangement of MTs was different in the various regions of the apex: the MTs tended to be arranged anticlinally in tunica cells, randomly in corpus cells, and transversely in cells of the rib meristem. However, in the inner layers of the tunica in the flank region of the apex, cells with periclinal, oblique or random arrangements of MTs were also observed. In leaf primordia, MTs were arranged anticlinally in cells of the superficial layers and almost randomly in the inner cells. Polarizing microscopy of cell walls showed that the arrangement of cellulose microfibrils was anticlinal in tunica cells, random in corpus cells, and transverse in cells of the rib meristem; thus, the patterns of arrangement of microfibrils were the same as those of MTs in the respective regions. These results indicate that the different patterns of arrangement of MTs and microfibrils result in specific patterns of expansion in the three regions. These differences may be necessary to maintain the organization of the tissues in the shoot apex.Abbreviations MT(s) microtubule(s) - lp length of the youngest leaf primordium     

大蒜分生组织培养脱病毒和快速繁殖技术

采用茎尖分生组织培养技术,获得了大蒜（Ａｌｌｉｕｍ ｓａｔｉｖｕｍ Ｌ．）的无病毒试管苗。通过基本培养基和激素配比试验,筛选出最佳的培养基组成,进行脱病毒苗的快速繁殖。结果表明：诱导愈伤组织的最适培养基为：ＭＳ＋ＢＡ０．２ｍｇ／Ｌ＋ＮＡＡ０．５ｍｇ／Ｌ,月生长率达１２．７０倍;诱导丛生芽的最适培养基为：Ｂ５＋ＢＡ０．５ｍｇ／Ｌ＋ＩＡＡ０．２ｍｇ／Ｌ,丛生芽繁殖系数高达２５．５倍,技术上达到了快速繁     

Changes in RNA levels in the shoot apex of Silene during the transition to flowering

Changes in RNA concentration in the shoot apical meristem during induction and the transition to flowering were measured histochemically in Silene coeli-rosa (L.) Godron, a long-day plant. In the apices of plants induced by 7 long days the RNA concentration increased to about 25 per cent higher than in non-induced plants. Three long days did not induce flowering but resulted in a transient rise in RNA concentration. When plants were given long days interrupted by varying numbers of short days successful induction was accompanied by a sustained increase in RNA concentration but those treatments which were not inductive gave only transient increases in RNA. Gibberellic acid had no effect on induction or apical growth rates but increased the RNA concentration by 50 per cent or more in both induced and non-induced plants. Plants induced to flower at 13° C had the same RNA concentration and growth rate at the apex as in non-induced plants at 20° C. Since changes in RNA concentration in the apex could occur without changes in growth rate and without flowering, and induction could occur without a change in RNA concentration or growth rate, it is suggested that the increase in RNA and growth rate which normally occur at the transition to flowering might not be essential for the formation of a flower but may be more closely related to the rapid growth associated with the formation of the inflorescence.Abbreviations LD long day - SD short-day     

Microspectrophotometric measurements of DNA by automated computerized scanning in cycling cells of theChrysanthemum segetum shoot apex

Summary A new technique of exploitation of the data was proposed after DNA scanning microdensitometry. By using all of the measurements obtained from the seriated sections of a single nucleus, this method made it possible to estimate six characteristic parameters during the different phases of the cell cycle in the various shoot apical cells. The cells whose rate of proliferation was the highest showed the biggest variations of their nuclear and nucleolar volumes during the cell cycle. In the axial zone, where the cells have a slow cell cycle and display the longest duration of the G₁ phase, the volume occupied by dispersed DNA was greater than in the cells of the lateral zone and of the rib meristem, where the cell cycle and the G₁ phase were short. No matter what the cell type, the proportion of the dispersed and condensed DNA varied little when the G₁ and G₂ phases were compared. In the Z phase, characterized by a decondensation of the DNA, the mean DNA amount was 3.4 C. The evolution of the nuclear density during the interphase was also estimated. It is demonstrated that the main feature of the shoot apex zonation was the decondensation of the condensed DNA in the axial zone in both the G₁ and G₂ phases.