The Quiescent Centre and Rates of Mitosis in the Root Meristem of Allium sativum

The root apices of Allium sativum have been examined by continuous-and pulse-labelling with tritiated thymidine and by colchicinetreatment to measure the time parameters of the mitotic cyclein various parts of the meristem. There is a quiescent centre of 30–50 cells whose averagerate of mitosis is low because the G₁ period is extended toabout 140 h compared with about 4 h in the othe regions of themeristem. The stele just above the quiescent centre and at 200microns above it and the cap initials just below the quiescentcentre are very similar in their mitotic cycles, the total lengthsof which are about 30 h of which nearly half is taken up byDNA synthesis. Allium thus differs from Zea in having root capinitials whose mitotic cycle is not telescoped by the eliminationof the G₁ phase. These facts are discussed in relation to theradiosensitivity of the meristem.     

X-Irradiation of Root Meristems

When roots of Zea mays are given heavy doses of X-rays the averagerate of mitosis at first falls in the normally meristematiccells and increases in the quiescent centre. Proliferation inthe quiescent centre gives rise to a new meristem which continuesthe growth of the root and which acquires a quiescent centreof its own. Observations on the micronuclei produced after irradiationsuggest that the quiescent centre is less sensitive to X-raysthan the rest of the meristem. It is probably this lower sensitivitycombined with the initial difference in time at which the radiationdamage to cell viability occurs that gives the quiescent centreits role in the recovery of the meristem.     

The Meristem and Quiescent Centre in Cultured Root Apices of the gib-l Mutant of Tomato (Lycopersicon esculentum Mill.)

Cultured root apices of tomato bearing the gib-I mutation, whichreduces the levels of endogenous gibberellins, grew slower andwere thicker than wild-type contols. This was the result ofshorter and broader cells in the menstem of the mutant. Cellsof both cortex and stele were affected, but this did not causeany alteration to the volume fraction occupied by these twotissues in the root meristem. Root caps were longer in the mutantand there were also more layers of rhizodermis. All these effectscould be reproduced in wild-type roots by addition of 0.1µM2S, 3S paclobutrazol (an inhibitor of gibberellin biosynthesis)to the culture medium and could be normalized in mutant rootsby 0.1 µM GA₃. Cell doubling times in the proximal regionof the meristem were similar in mutant and wild-type roots,but were faster in both the quiescent centre (QC) and the capmeristem of the mutant. This latter feature of the mutant rootsis likely to be the cause of their longer caps, while the fasterrate of division in the QC accounts for the additional tiersof cells that were found to build up in the cortical portionof this zone These additional tiers failed to form in mutantroots grown in GA₃, but they could be induced in wild-type rootsby 2S, 3S paclobutrazol. These results suggest that endogenousgibberellins may be partly responsible for the slow rate ofcell growth and proliferation in the QC. Gibberellins, gib-I mutation, Lycopersicon esculentum, meristem, roots, 2S, 3S paclobutrazol, quiescent centre, tomato     

Flow Cytometric Determination of Relative Nuclear DNA Contents in Bicellulate and Tricellulate Pollen

Nuclear DNA content in mature pollen was measured with a flowcytometer Pollen of Lilium longiflorum, Dendranthema grandiflora(syn Chrysanthemum monfolium) and Zea mays was chopped and stainedwith the DNA fluorochrome DAPI DNA levels, expressed as arbitraryC values, were compared with those of nuclei isolated from leafor root material of the same plants In mature tricellulate pollen the generative cell is dividedafter second pollen mitosis into two sperm cells Tricellulatepollen from maize and chrysanthemum gave rise to one large 1Cpeak and, only in the case of chrysanthemum, a much smallerone at the 2C level These results suggest that the haploid nucleiof the vegetative as well as both sperm cells in tricellulatepollen are arrested in the G₁ stage of nuclear division Thesmall 2C peak in the case of chrysanthemum probably arose froma fraction of pollen with the sporophytic chromosome number(2n pollen) In contrast to this, mature bicellulate lily pollengave rise to two identical peaks at the 1C and the 2C levelFrom this result it was concluded that in bicellulate pollen,the 1C peak is caused by the signal of the haploid vegetativenucleus arrested in the G₁ stage of nuclear division, whereasthe 2C peak originates from the haploid generative nucleus whichhas already undergone DNA synthesis and is arrested in G₂ Lilium longiflorumThunb, lily, Dendranthema grandiflora Tzelev (syn Chrysanthemum morifolium Ramat ), chrysanthemum, Zea maysL, maize, male gametophytic cells, vegetative cells, generative cells, sperm cells, unreduced pollen, sporophytic cells, relative nuclear DNA contents, replication stage     

In Vitro Transformation of Root meristem to Shoot and Plantlets in Vanilla planifolia

A study is reported of histogenesis and organogenesis duringthe processes leading up to plantlet formation in tip culturesof aerial roots of Vanilla planifolia. Young root tips excisedfrom aerial roots, less than 15 cm long, when cultured in liquidMS medium containing IAA and KN showed gravitropic responseuntil cap lysis began. With the collapse of the distal halfof the cap, the cells of the quiescent centre divided forminga hemispherical mass of cells. Further localized divisions onthe periphery of the hemisphere resulted in a number of meristemoidseach of which differentiated into a shoot meristem with leafprimordia. Procambium differentiated first beneath the apicalmeristem after two to three leaf primordia had formed and thenat the base of the leaves. After a few leaves have been formeda root meristem differentiated in close lateral proximity tothe basal end of the shoot procambium. Formation of a plateof vasculature at the nodal region of the first formed leaf,procambialization of the root and the bridging up of the shootand root vasculature with the nodal plate are described. Vanilla planifolia, root tip, in vitro, quiescent centre, meristemoid, plantlet     

The Response of the Primary Root Meristem of Zea mays L. to Various Periods of Cold

Primary roots of maize (Zea mays L.) grown in nutrient solutionat 5?C elongate at about 1% of the rate found at 20?C. The apicalmeristem becomes shorter and shows little proliferative activityat 5?C, but following transfer to 20?C mitoses increase in frequencyand the meristem regrows to its original length. Both the amountby which the meristem shortens and the time for its completeregrowth are related to the period spent at 5?C. The shorteningof the meristem suggests that at the lower temperature the balancewhich normally exists between cell production and differentiationis altered, the latter continuing at a relatively faster ratethan the former. A new, steady-state balance between the twoprocesses is re-established during the recovery period. Themeristem recovers as a result not only of its own mitotic activitybut also through stimulation of cell division in the quiescentcentre. The degree to which the quiescent centre is activated,as judged by its mitotic index and the number of nuclei labelledby feeding with tritiated thymidine, increases as the durationof the preceding cold treatment increases. The close relationshipbetween proliferative activity in the quiescent centre and theminimum length of the meristem following the cold treatmentsuggests that there is communication between these two zoneswhich co-ordinates their respective rates of cell productionand helps to maintain a normal meristem structure. The resultsemphasize the importance of the quiescent centre as a reservoirof cells that can re-establish a meristem rendered non-functionalthrough the impact of unfavourable environmental conditions. Key words: Meristem, quiescent centre, root, temperature, Zea mays     

Gibberellin does not accelerate rates of cell division in the dwarf pea shoot apical meristem

Although GA₃ doubled the numbers of cells in dwarf pea internodes,it caused no significant acceleration of cell division ratesin the apical meristem, estimated using cell doubling times,mitotic indices, or percentage labelled mitoses data. Increasedcell numbers in GA₃-treated pea stems must be generated withinthe extending internodes. Key words: Cell division cycle, gibberellin, pea, Pisum, shoot apical meristem     

The Difference Between Open and Closed Meristems

An open and a closed root meristem have been compared by investigatingthe cell kinetics of small regions of the apices of Helianthusand Zea. The cells of the stelar pole are quiescent in both and thereis no exchange of cells between stele and cortex or stele andcap. The immediately distal cells in the closed meristem (Zea)are also quiescent and the few divisions that do occur can betransverse or longitudinal. In the open meristem (Helianthus)these cells are not quiescent, but they go out of cycle transiently,prolonging the potential cell-doubling time. Their divisionsare transverse. It is a consequence of these differences thatclosed meristems form root caps discrete from the cortex whereasopen meristems force instability in the boundary between theperipheral part of the cap and the cortex. Another consequencein roots with open meristems is a succession of columella complexestransversely displaced from each other by the state of fluxin the meristem during the non-cycling phase of the proximaltier of cells, those immediately distal to the stelar pole. The results are discussed in relation to the ontogenetic onsetof quiescence and the evidence for switches between open andclosed operation of meristems. meristem, root apex, Helianthus annuus, Zea mays L.     

Organelle DNA Synthesis in the Quiescent centre of Arabidopsis thaliana (Col.)

The behaviour of cell nuclei and organelle nucleoids (organellenuclei) was studied in the root apical meristem of 3-d-old seedlingsof Arabidopsis thaliana (Col.). Samples were embedded in Technovit7100 resin, cut into thin sections and stained with 4'-6-diamidino-2-phenylindole(DAPI) for observation of DNA. DNA synthesis in cell nucleiand organelle nucleoids was investigated using the incorporationof [³H] thymidine or 5-bromo-2'-deoxyuridine (BrdU). Incorporated[³H] thymidine and BrdU were detected by microautoradiographyor immunofiuorescence microscopy, respectively. Central cellsand cells just above the central cells of the quiescent centre(QC) showed an extremely low activity of DNA synthesis. However,DNA synthesis occurred in at least one organelle nucleoid ofall cells in the QC within 24 h. This suggests the cells inthe QC are quiescent with regard to nuclear DNA synthesis, butnot with regard to the organelle nucleoids. Key words: Arabidopsis thaliana, quiescent centre, root apical meristem, mitochondrial nucleoid (nuclei), plastid nucleoid (nuclei)     

Inhibition of RNA Synthesis and the Relationship between Nucleolar and Mitotic Cycles in Zea mays Root Meristems

The relationship between nucleolar and mitotic cycles has beendetermined after treatment of root apices of Zea mays with ethidiumbromide. In the meristematic regions of the stele the two cyclesare not much displaced in relation to each other except fora delay in the onset of the disorganization phase. A few nucleolipersist into metaphase and a few nuclei undergo an amitoticdivision. In the cap initials the drug greatly delays the onsetof disorganization of the nucleolus, which normally occurs beforeprophase in this region. It also delays the completion of reorganizationso that fully organized nucleoli are no longer available duringthe last half of telophase. In the quiescent centre the onsetof disorganization and the end of reorganization of the nucleoliare also delayed in relation to mitosis. There is no evidencefor a delay in the onset of reorganization in any region ofthe meristem. Some cells form multiple micronucleoli and this aberrant behaviouroccurs more often in the cap initials than elsewhere as doesamitotic division.     

Duration of the Mitotic Cycle in a Meristem

The length of the mitotic cycle and the time spent in mitosisare calculated for six regions of the apical meristem of rootsof Zea. The two methods used are the measurement of the ratesof labelling nuclei with radioactive thymidine and the ratesof accumulation of metaphases in roots grown in colchicine.The mitotic cycle lasts from 12 hours in the cap initials toabout 200 hours in the quiescent centre of the same roots. Somepoints about the organization of apices are discussed in thelight of these estimates.     

Meristems under Continuous Irradiation

Root tips of Vicia faba and Zea mays have been subjected tocontinuous irradiation from radium or cobalt-60 for long periodsat various dose rates. The rates of mitosis and the damage tothe chromosomes (assessed as percentages of cells with micronulei)have been measured in four regions of the meristems. In Zearates of mitosis are reduced under chronic irradiation, exceptin the quiescent centre, and the cap initials are particularlysensitive. In Vicia the main change in mitosis is that the quiescentcentre increases its rate, but at 12°C there is a slightstimulation of division all over the meristem. In Vicia increasingthe dose rate or lowering the temperature increases the nucleardamage. At 19° C there is an increase in damage with accumulateddose percell cycle, but the data at 12°C do not fall onthe 19°C curve, suggesting that there may be a temperatureeffect on damage other than that caused by changing the durationof the cell cycle. The differences in radiosensitivity betweenthe different regions of the meristem are due solely to differencesin the rates of mitosis of the cells.     

Nuclear and Cell Sizes in Different Regions of Root Meristems of Zea mays L.

Nuclear volumes and cell areas were determined for seven regionsof the meristem of roots of Zea mays. Roots were fixed in 10per cent neutral buffered formalin, in 3 per cent glutaraldehydeor in acetic acid/alcohol; they were prepared as sections oralls were teased apart. Mean volumes of interphase nuclei weresimilar in all regions of the root except the vascular tissueof the stele. Mean nuclear volumes and the overall range ofvolumes were similar in sub-populations of cells with differentproportions of G¹, S and G² cells, e.g. in row I of root capinitials, whose cells lack a G¹ phase, and in quiescent centrecells, which are mainly in G¹. Nuclear volume does not appearto be closely correlated with DNA content. Nuclear volumes covereda 6 to 12-fold range within a meristem and even within specificregions, in which cells are part of the same cell lineages,there was a 4- to 9-fold range. Nuclear volumes were comparedin sister cells in rows I and II of the root cap initials. In10 per cent of the pairs, sister nuclei had identical volumes;the other pain had different volumes and mean difference was68 µm³. Mechanisms by which this variability could begenerated are discussed, particularly asymmetry, at mitoses,of factors that regulate nuclear growth. Zea mays L., nuclear volume, cell size, root mcristem, DNA content, mitosis     

Experimental control of the activity of the quiescent centre in excised root tips of Zea mays

Summary Quiescent centres have been demonstrated in cultured excised root tips of both Pisum sativum and Zea mays. Upon addition of sucrose to Zea roots which have been deprived of carbohydrate, the cells of the quiescent zone as well as those of the rest of the meristem undergo DNA synthesis. Following the onset of proliferative activity in the meristem, DNA synthesis in the quiescent-centre cells is again arrested. It is suggested that the dividing cells of the meristem are responsible for the maintenance of the quiescent centre. It has also been shown that DNA-synthesising cells do occur within the quiescent centre and that they appear to be localised in specific regions.     

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)     

Modeling action potential generation and propagation in NRK fibroblasts

Normal rat kidney (NRK) fibroblasts change their excitability properties through the various stages of cell proliferation. The present mathematical model has been developed to explain excitability of quiescent (serum deprived) NRK cells. It includes as cell membrane components, on the basis of patch-clamp experiments, an inwardly rectifying potassium conductance (G_Kir), an L-type calcium conductance (G_CaL), a leak conductance (G_leak), an intracellular calcium-activated chloride conductance [G_Cl(Ca)], and a gap junctional conductance (G_gj), coupling neighboring cells in a hexagonal pattern. This membrane model has been extended with simple intracellular calcium dynamics resulting from calcium entry via G_CaL channels, intracellular buffering, and calcium extrusion. It reproduces excitability of single NRK cells and cell clusters and intercellular action potential (AP) propagation in NRK cell monolayers. Excitation can be evoked by electrical stimulation, external potassium-induced depolarization, or hormone-induced intracellular calcium release. Analysis shows the roles of the various ion channels in the ultralong (30 s) NRK cell AP and reveals the particular role of intracellular calcium dynamics in this AP. We support our earlier conclusion (De Roos A, Willems PH, van Zoelen EJ, and Theuvenet AP. Am J Physiol Cell Physiol 273: C1900–C1907, 1997) that AP generation and propagation may act as a rapid mechanism for the propagation of intracellular calcium waves, thus contributing to fast intercellular calcium signaling. The present model serves as a starting point to further analyze excitability changes during contact inhibition and cell transformation. Hodgkin-Huxley model; intracellular calcium dynamics; L-type calcium conductance; inward rectifier; calcium-activated chloride conductance; gap junctional coupling     

Effect of Radiation and Temperature on Efficiency of Cereal Leaves during Grain Growth

Grain: leaf ratio, G (the ratio of grain yield to leaf areaduration between ear emergence and maturity), in 15 experimentson wheat and barley in different seasons (Group A experiments)was highly correlated with mean daily radiation, R, mean dailytemperature, T_µ, and mean daily maximum temperature, T_max,during the grain growth period. The regression of G on R accountedfor 81 per cent of the variance of G, and introducing T_µto the regression significantly increased this to 88 per cent.The regression of G on T_max alone accounted for 87 per cent,perhaps because T_max effectively integrates radiation and temperature. When R was varied artificially by shades in two experimentson wheat in different years (Group B experiments) the relationshipbetween G and R was approximately linear in both, but the slopeof the line was less in one year, when R and temperature wereless, than in the other. For this second year, when R and temperatureswere about the middle of the ranges found in Group A experiments,the calculated relationship agrees with the Group A resultsafter correcting values of G for differences of Tu from itsvalue in the shading experiment. A formula relating G and Rderived from the results of both Group B experiments and theobserved correlation of R and temperature in the field, assumingthat the regression of G on R depends on temperature, agreeswith the relationship between G and R in the Group A experiments. It is concluded that differences in radiation and temperatureare about equally responsible for the differences in G foundbetween seasons. The positive effect of temperature on G suggeststhat factors other than leaf photosynthesis, e.g. translocationrate or capacity of the grain to accumulate carbohydrate, areimportant in determining G.     

Potassium channel expression level is dependent on the proliferation state in the GH3 pituitary cell line

Previously, we showed that the peakdensity of the transient outward K⁺ current(I_to) expressed in GH3 cells was different inthe S phase than in other phases of the cell cycle. Using cellsynchronization, we show here that I_to dropsprecisely at the quiescent (G₀ phase)/proliferating transition. This change is not due to a modification in the voltage dependence of I_to, but rather to a modificationin its inactivation kinetics. Molecular determination of K⁺channel subunits showed that I_to required theexpression of Kv1.4, Kv4.1, and Kv4.3. We found that the increase inI_to density during the quiescent state wasaccompanied by an increase in Kv1.4 protein expression, whereas Kv4.3expression remained unchanged. We further demonstrate that the linkbetween I_to expression and cell proliferation isnot mediated by variations in cell excitability. These results providenew evidence for the cell cycle dependence ofI_to expression, which could be relevant inunderstanding the mechanisms leading to pituitary adenomas.

     

Determination of Stelar Elements in Roots of Pisum sativum L.

Cytochemical studies of esterase activity in 0.5 mm segmentsfrom root tips of Pisum sativum explanted for up to 9 days inbasal culture medium containing 2 per cent sucrose showed retentionof this activity. During this time, all segments from the secondand third 0.5 mm segments of the root tip developed xylem elementsas did the proximal end of the first segment. No xylem elementswere found in the 12–14 cells behind the quiescent centre.It is concluded that the central group of meristem cells aregenerally programmed to form tissues of the stele immediatelyon leaving the quiescent centre, and that the programming forxylem and phloem elements occurs as a second step. Pisum sativum L., garden pea, determination, histochemistry, esterases, stele, root