Water Deficit in Pea Root Tips: Effects on the Cell Cycle and on the Production of Dehydrin-like Proteins

Dehydrin-like proteins have been detected in nuclei and cytoplasmof meristematic root tip cells from pea seedlings subjectedto slow dehydration at 90% relative humidity for 48 h or more.Evidence was gained from Western blotting and immunocytochemicalexperiments using an antibody raised against the conserved domainof dehydrin proteins. Flow cytometer analysis has shown thatcycling cells of root tip meristems from dehydrated seedlingsare mostly arrested in G2 phase. Other stress treatments thoughtto involve water depletion (osmotic stress, cold treatment)or to modulate cell response to water deficit (abscisic acid)gave less clear-cut results with all treatments lowering theproportion of cells entering the S phase, but without a definiteand persistent arrest in any preferential phase of the cycle.Possible interrelationships between G2 arrest and dehydrin productionare discussed. Cell cycle; dehydrins; flow cytometry; nuclei; pea; Pisum sativum L.; water stress     

Promotion of cell arrest in G2 in root and shoot meristems in Pisum by a factor from the cotyledons

Characterization of a factor within the cotyledons of Pisum that promotes cell arrest in G2 in mature root tissue and stationary phase root and shoot meristems is presented. Diffusion of the G2 factor into aseptic liquid and solid agar media enabled us to perform experiments focused on its cellular effect. The factor promotes cell arrest in G2 in shoots and roots of Pisum and roots of Vicia indicating a lack of species and organ specificity. In seedling roots of Pisum the factor promotes arrest in G2 in a large portion of the cell population. However, because pea cotyledons have a limited supply which is depleted 8–10 days after seed germination, cells previously responsive to the G2 factor in Pisum root meristems eventually assume preponderant arrest in G1. Once these cells arrest in G1 they are no longer influenced to arrest in G2. The G2 factor doss not promote arrest in G2 in meristem root cells of Helianthus and Triticum which normally show preponderant arrest in G1.     

Proliferation of multinucleate cells with unbalanced nuclei

When onion root meristems are treated with gamma-hexachlorocyclohexane the anaphase chromatids are distributed in discrete unbalanced groups and subsequent inhibition of cytokinesis in these cells produced a synchronous population of viable multinucleate cells with two, three of four aneuploid nuclei. When we compare the duration of G1, S and G2 periods in diploid cells with that obtained for multinucleate cells in the present study it seems clear that the differences, if they occur, are negligible. These results are consistent with the hypothesis that the cell mass/genome ratio can play an essential role in controlling cycle rate and that most of the genic requirements for interphase development must complement between the nuclei sharing a common cytoplasm, even though some factor inside every nucleus appears to be required for replicative capacity to be effective.     

CELL CYCLE KINETICS OF ENDOREDUPLICATION IN GAMMA-IRRADIATED ROOT MERISTEMS OF PISUM SATIVUM

Label and mitotic indices and microspectrophotometry of unlabeled interphase cells were used to measure the proportion of root meristem cells of Pisum sativum in each cell cycle stage after exposure to protracted gamma irradiation. Three seedling types were investigated: 1) intact seedlings, 2) seedlings with cotyledons detached and treated with lanolin paste applied to the area of cotyledon excision, and 3) seedlings with detached cotyledons and treated with a G2 Factor applied to the area of cotyledon excision in lanolin paste. In intact seedling meristems, predominant cell arrest occurred with a 4C amount of DNA while 0.30 of the cells underwent endoreduplication to arrest with an 8C amount of DNA. Only 0.07 cells arrested with a 2C amount of DNA. Polyploid cells were produced several days after the start of irradiation and were derived from a diploid cell population. In seedlings exposed to lanolin only, without cotyledons, most cells arrested with a 2C amount of DNA with no polyploid cells. In seedlings exposed to a G2 Factor in lanolin after cotyledon excision, most cells arrested with a 4C amount of DNA but no cells underwent endoreduplication. These experimental results suggest that the G2 Factor derived from cotyledons of Pisum sativum was necessary for predominant cell arrest in G2 but alone was not sufficient for the polyploidization step.     

IS THE NUCLEAR DNA CONTENT OF MATURE ROOT CELLS PRESCRIBED IN THE ROOT MERISTEM?

Cells of the mature root exhibit arrest within the G1 and G2 periods of the mitotic cycle. The number of cells arrested with a 2C or 4C DNA amount in mature tissue was compared with that in meristems of excised primary root tips deprived of carbohydrate. Results from four plant species are described. Cells in mature tissue of seedling roots of Vicia and Pisum exhibited arrest predominately at the 4C while those of Triticum and Helianthus arrested preponderantly at the 2C DNA level. The proportion of cells arrested at the 2C and 4C levels in mature root tissue was specific for each species tested. In each species the cycle stage where most cells arrested was the same in carbohydrate-deficient root meristems as in mature root tissue; consequently, most meristematic cells are preconditioned or predetermined to arrest in a specific mitotic period. A test system was developed in Pisum in which the predominant period of arrest was altered by the removal of the cotyledons. The predominant arrest period changed from 4C to 2C in both mature root tissue and carbohydrate-deficient root meristems with cotyledon removal and indicated that mature root cells are preconditioned while meristematic as to where they will eventually arrest in the mitotic cycle.     

The effect of butyrate on the cell cycle in root meristems of Pisum sativum

Sodium butyrate at 5 mM in aerated White's medium reduced the mitotic index in root meristems of seedlings of Pisum sativum to < 1% after 12 h. This effect was lessened as the butyrate concentrations were lowered. The fraction of the root meristem nuclei in G2 increased to ~ 70% after 12 h in butyrate. After 12 h exposure to butyrate, seedlings transferred lo medium without butyrate gradually re-established their normal root meristem mitotic pattern, with a burst of mitosis at 10 h after the transfer. Even a brief exposure to butyrate inhibited DNA synthesis, and nuclei released from butyrate exposure were still unable to resume normal DNA synthesis even after 12 h. This information suggests that butyrate halts progression through the cell cycle by arresting meristem nuclei in G2 and inhibiting DNA synthesis.     

Growth Substances in the Roots of Vicia faba II. THE EFFECTS OF AGEING AND EXCISION OF THE MAIN TAP-ROOT MERISTEM

A quantitative chromatographic study has been made of the changesin the activity and distribution of the main ether-soluble acidauxins of Vicia faba seedling root systems during developmentand resulting from excision of the main tap-root meristem. AnIAA-like auxin (AP (ii)) is apparently synthesized predominantlyin apical and at a lower rate in lateral meristems. Productionseems to stop when meristematic growth stops. Its concentrationin mature extended cells is much lower and may fall to zeroin old cells, suggesting active degradation by an auxin-oxidase.Excision of the main tap-root tip gradually results in a greatlyaugmented production of AP (ii) in lateral meristems, conceivablythe result of correlative growth promotion. A second auxin and root-growth inhibitor (AP (iii)) is presentat higher activity levels than AP (ii) in tap-root meristemsand at the same level in lateral meristems. In mature cellsits activity is much lower than that of AP (ii). In contrastto AP (ii) it accumulates in both tap-root meristems and maturetissue as the root system ages. It could also be produced duringmeristematic growth but is not subsequently degraded. As withAP (ii), excision of the tap-root tip brings about a great increasein its concentration in lateral tips. A third auxin and root-growth accelerator (AP (i)) (accelerator?) is present in lower concentrations in both meristem and maturetissue. Its concentration tends to decrease with ageing and,in lateral meristems, is not affected by tap-root tip excision. It is suggested that AP (ii) produced by the meristem is normallyat suboptimal levels in the extending cells and may be the principalhormone controlling extension growth. AP (iii) accumulationmay account for growth deceleration on ageing. The role of AP(i) remains obscure. It is unlikely that correlative effectsof the taproot tip on lateral root growth are exercised directlyvia these auxins.     

STUDIES ON THE GERMINATION OF SEEDS OF THE ROOT PARASITES,ALECTRA VOGELII AND STRIGA GESNERIOIDES. I. ANATOMICAL CHANGES IN THE EMBRYOS

Anatomical changes in the radicle and shoot meristems of embryos of germinating seeds of the obligate root parasites, Alectra vogelii and Striga gesnerioides were studied. When germination of seeds was stimulated by cowpea (Vigna unguiculata) root exudate, growth occurred mainly in the radicular pole of embryos and minimally in the plumular pole, resulting in seedlings with elongated radicles. Maximum radicle elongations of about 3 mm in A. vogelii and 2 mm in S. gesnerioides were recorded during a period of 8 and 11 days, respectively. Analysis of the radicular tip during the course of seed germination revealed that the activity of the meristematic tissue progressively decreased until it completely disappeared. When germinated seeds were cultured on nutrient agar media, the radicle meristem of A. vogelii continued to grow producing a normal root with a root cap. On the other hand, the radicles of cultured S. gesnerioides seeds elongated only slightly before meristematic activity ceased. During continued growth of seedlings of both species on agar media, lateral roots whose tips had typical angiosperm root topography, were initiated from the radicle.     

An improved method for the cell cycle synchronization of <Emphasis Type="Italic">Vicia faba</Emphasis> root meristem cells

Plant root meristem cells divide asynchronously which makes biochemical analysis of cell cycle regulation particularly difficult. In the present article a high level of cell cycle synchronization in Vicia faba root meristems was obtained by using a rich medium (HNS), special culture conditions and a double-block method with replication inhibitor—hydroxyurea (HU). Two HU concentrations were tested and different periods of the first and the second synchronization, and of cycle recommencement between the first and the second blockage. The level of synchronization was estimated on the basis of ³H-thymidine labeling indices, mitotic, and phase indices and indices determining the percentage of G1 and G2 cells, which were identified by cytophotometric measurements of DNA content in individual nuclei. The highest level of cell cycle synchronization was obtained after double treatment of meristems with 1.25 mM HU (18 and 12 h) separated by 6-h incubation in HNS without HU. During the second postincubation in HNS in subsequent hours: 4, 7, 10, 11, over 90% of cells in the S phase, nearly 70% in G2 phase, 86% in mitosis, and nearly 70% in G1 phase were received, respectively. The use of 2.5 mM HU in a similar experimental procedure caused disturbed divisions.     

The timing of synthesis of proteins required for mitotic spindle and phragmoplast in partially synchronized root meristems of Vicia faba L

After cycloheximide treatment (1 h, 2.5 micrograms/ml) protein synthesis was decreased by 70% and was partially restored after 7 h of postincubation (still 20% decrease). In partially synchronized root meristems of Vicia faba L. treated with cycloheximide at middle G2, a strong decrease of the mitotic index was observed. Exposure to the drug at late G2 did not modify the mitotic index; the changes in the phase indices suggested that the course of mitosis was blocked at prophase-metaphase/anaphase-telophase transitions. The use of indirect immunocytochemical staining of tubulin (second antibody labeled with peroxidase) made it possible to show a decreased number of cells with preprophase bands in cycloheximide-treated meristems and the mitotic spindles and phragmoplasts containing a reduced number of shortened bands of microtubules. As a result of these structural and functional disturbances, binucleate cells and polyploid nuclei were observed.     

Correlation of reduced chilling injury with Increased spermine and spermidine levels in zucchini squash

By means of a biparametric cytofluorimetric analysis it is possible to distribute meristematic plant cells in a variety of cell cycle sub-compartments, unidentifiable by DNA measurements alone. In this work, an asynchronous proliferating cell population of pea root meristems was divided into different sub-compartments of the cell cycle phases, i.e. G1A, G1B, S. G2A and G2B on the basis of their DNA-nuclear protein content. By means of the same biparametric analysis, differentiated mesophyll cells and quiescent cells of embryo roots, indicated as G0 and G2Q, were distinguished from cycling cells by their low nuclear protein content. These results conform to those of some analyses performed on animal cells in culture and show that it is possible to get a major insight into cell cycle kinetics and its control in a natural system such as root meristem.     

β-glucuronidase as a marker for clonal analysis of tomato lateral roots

In higher plants, the root-shoot axis established during embryogenesis is extended and modified by the development of primary and lateral apical meristems. While the structure of several shoot apical meristems has been deduced by combining histological studies with clonal analysis, the application of this approach to root apical meristems has been limited by a lack of visible genetic markers. We have tested the feasibility of using a synthetic gene consisting of the maize transposable elementActivator (Ac) inserted between a 35S CaMV promoter and the coding region of a -glucuronidase (GUS) reporter gene as a means of marking cell lineages in roots. The GUS gene was activated in individual cells byAc excision, and the resulting sectors of GUS-expressing cells were detected with the histochemical stain X-Gluc. Sectors in lateral roots originated from bothAc excision in meristematic cells and from parent root sectors that bisect the founder cell population for the lateral root initial. Analysis of root tip sectors confirmed that the root cap, and root proper have separate initials. Large sectors in the body of the lateral root encompassed both cortex and vascular tissues. The number of primary initial cells predicted from the size and arrangement of the sectors observed ranged from two to four and appeared to vary between roots. We conclude that transposon-based clonal analysis using GUS expression as a genetic marker is an effective approach for deducing the functional organization of root apical meristems.     

Salinity induced nuclear and DNA degradation in meristematic cells of soybean (Glycine max (L.)) roots

Changes in the nuclei of meristematic root cells of soybean (Glycine max (L.) Merr. cv. Acme) in response to severe salinity were studied. Root growth was inhibited by 200 mM NaCl, when 1 mM CaCl_2 was present in the culture media. Increasing CaCl_2 up to 5 mM partially prevented this inhibition. However, inhibition also occurred with 100~mM NaCl without CaCl_2. We examined the meristematic cells under a series of NaCl treatments. Nuclear deformation of the cells occurred with 24 h of 150 mM or higher NaCl, and was followed by degradation of nuclei in the apical region of the root. TEM observation and agarose gel electrophoretic analysis confirmed that root tip nuclear DNA deformed or degraded with 150 mM or higher NaCl concentrations.     

DEVELOPMENTAL ASPECTS OF ROOTS OF PISUM SATIVUM INFLUENCED BY THE G2 FACTOR FROM COTYLEDONS

A G2 Factor present in cotyledons of Pisum sativum influences several developmental events in roots. G2 Factor present in dry seeds (cotyledons and radicles) is transported to roots after germination and promotes cell arrest in G2 in about 35% of all root meristem cells. Present evidence suggests the G2 Factor promotes cell arrest in G2 only in cells that undergo normal cell differentiation (arrest) because the proportion of cells labeled with ³H-TdR after 16 hr does not differ among both seedlings or excised roots in the presence or absence of this substance. In this manner, trigonelline differs from chalones of animal tissues that usually suppress cell proliferation by cell arrest either in G1 or in G2. Experimental results suggest that cortex cells and not cells of vascular tissues in mature root tissues (20–22 mm from the meristem) are influenced by G2 Factor. Other recent publications indicate that the G2 Factor is trigonelline (N-methyl nicotinic acid) and concentrations of synthetic trigonelline from 10⁻⁵ to 10⁻⁷ m are effective in promoting cell arrest in G2 in one of the G2 Factor bioassays.     

Compartmentalizing the S period.

In order to increase the resolution of interphase analysis we have developed a method which is an alternative to cytofluometric techniques for tissues where cell flow is not applicable. The method combines the estimation of cell frequency in G1, S, G2 and mitosis after a 3H-thymidine pulse with the grouping of interphase cells according to their DNA content, as estimated by cytophotometry in Feulgen stained nuclei. By superimposing both sets of data we get three different artificial compartments within the S period. As a biological test of the resolution reached, the method readily confirmed that hydroxyurea, after one cycle time, accumulates cycling cells of Allium cepa L. root meristems in early S.     

Multinucleate plant cells : II. Requirements for nuclear DNA synthesis

A synchronous population of multinucleate cells has been experimentally induced in Allium cepa root meristems by a chemical method that involves the induction of aneuploidy in individual nuclei. Whereas all multinucleate cells as a whole present a tetraploid chromosome complement, their aneuploid nuclei constitute compartments containing only part of the parental genetic material. We analysed the degree of synchrony in the course of S period progression in the unbalanced nuclei sharing a common cytoplasm (bi-, tri- and tetranucleate cells). In most of the multinucleate cells the nuclei entered DNA replication simultaneously, but a significant proportion of cells showed labelled and unlabelled nuclei which was due to the absence of DNA synthesis in some aneuploid nuclei. These nuclei lacked replicative capacity, but did not inhibit DNA synthesis of the replicating nuclei. Our findings confirm the existence of cytoplasmic factor(s) inducing the synchronous initiation of S period, and suggest strongly the occurrence of intranuclear factor(s)—likely gene products—as a requirement for the onset of DNA synthesis itself in every nucleus.     

Immunodetection of four mitotic cyclins and the Cdc2a protein kinase in the maize root: Their distribution in cell development and dedifferentiation

Summary Cyclin proteins and cyclin-dependent kinases play a key role in the regulation of cell division. We have therefore studied the relationship of the level of four mitotic cyclin proteins and the Cdc2a kinase protein to cell division in maize root tissue with respect to cessation of division as cells leave the primary meristem region, resumption of division in formation of lateral-root primordia, and induced division following wounding. All four mitotic cyclins and Cdc2a were most abundant in dividing cells. The only examined cell cycle protein which was restricted to dividing tissue was cyclin ZmCycB1;2 (previously ZmIb) and may thus be a limiting factor for cell division. All other cyclin proteins, i.e., ZmCycB1;1 (previously ZmIa), ZmCycA1;1 (previously ZmII), and ZmCycB2;1 (previously ZmIII), and the Cdc2a kinase declined shortly after cells had ceased division. The distance from the root tip at which cells ceased division was tissue-specific and reflected the distance at which decrease of cell cycle proteins was detected. Whereas cyclin ZmCycB1;2 rapidly declined to a hardly detectable level in either nucleus or cytoplasm, in the nuclei of nondividing cells there was persistence of Cdc2a and of cyclins ZmCycB1;1, ZmCycCA1;1, and ZmCycB2;1, indicating that there are plant cyclins which are tightly linked to cell division and others that persist, especially in the nuclei, in nondividing cells. The transition from division to differentiation may thus partly be triggered and enforced by the decrease of the cell cycle proteins and especially the decline of cyclins in the cytoplasm. In the resumption of cell division, both in lateral-root formation and in wound response, high nuclear and low cytoplasmic accumulation of cyclin ZmCycB2;1 was the first visible sign of cell dedifferentiation, implying a role for cyclin ZmCycB2;1 in the G₀–G₁ phase transition. Next, cytoplasmic accumulation of cyclin ZmCycA1;1, followed by a rearrangement of cortical microtubules, was observed and since both the cyclins ZmCycA1;1 and ZmCycB2;1 were found at places of high tubulin concentration, they may function in the microtubule rearrangement for cell division. When the nuclei of dedifferentiating cells had visibly enlarged, all cyclins and Cdc2a accumulated there, possibly contributing to DNA replication and preparation for mitosis. Later, presumably during G₂ phase, cytoplasmic accumulation was observed for Cdc2a at low levels, as observed in G₂ phase cells of the primary meristem, and for cyclins ZmCycB1;1 and ZmCycB1;2 accumulation was observed above the levels found in undisturbed meristems, suggesting special contributions to late dedifferentiation processes in both wound-induced and lateral meristems.Abbreviations CDK cyclin-dependent kinase - LRP lateral-root primordium - Mt microtubule - FITC fluorescein isothiocyanate - TRITC tetramethylrhodamine isothiocyanate Dedicated to Professor Walter Gustav Url on the occasion of his 70th birthday     

THE COMPARATIVE CELL CYCLE AND METABOLIC EFFECTS OF CHEMICAL TREATMENTS ON ROOT TIP MERISTEMS. I. IOXYNIL

In this study we investigated the cell cycle response of Vicia faba and Pisum sativum root tip meristems to ioxynil treatments at two concentrations, (10^−-4m and 10^−-6m ). After 24 h of treatment at 10^−-4m concentration, O₂ uptake and ATP concentrations were significantly reduced. The mitotic index was reduced and the cell cycle population position was shifted to indicate that previously inhibited cells reformed their nuclei and became tetraploid. Prolonged treatment at this concentration resulted in cell death. Treatment with ioxynil at 10^−-6m reduced the rate of entry into mitosis. Abnormal mitotic figures in all stages were observed, and the ploidy level of mitotically inhibited cells was doubled. These observations indicated that at 10^−-6m concentration ioxynil acts as a preprophase inhibitor, that is, it does not act directly on the mitotic apparatus but does affect processes on which mitosis depends.     

Promotive and inhibitory effects of diverse arabinogalactan proteins on Daucus carota L. somatic embryogenesis

In the 3-d-old 2-mm root tip of Pisum sativum L. cv. Lincoln the percentage of actively proliferating cells is estimated to be 70%. The remaining cells are non-cycling and arrested with 2C and 4C DNA content in G₀ and in G₂Q, respectively. In this work we studied the kinetic significance of these quiescent cells, using the sorting capabilities of flow cytometry and immunofluorescence techniques to detect the proliferation marker PCNA (proliferating cell nuclear antigen) inside cells within the different cell-cycle compartments. While in animal cells, PCNA is present at a high level only in actively proliferating cells, in 3-d-old pea root tips 95% of the cells are PCNA-positive. After flow cytometry and sorting of pea non-cycling nuclear populations, all G₂Q nuclei appeared strongly PCNA-positive, indicating that these cells had recently left the cell cycle. By contrast, most G₀ nuclei showed a low level of PCNA immunofluorescence intensity, as measured by image analysis, with about 25% of the nuclei being PCNA-negative. This small percentage was found to correspond to root cap cells, as could be observed in the root tip section. These are the only cells in the root apical region which are fully differentiated and which, therefore, lack the competence to enter the cell cycle. In contrast, the more or less PCNA-positive G₀ nuclei could represent a kinetically heterogeneous population of cells competent to proliferate, but which have either recently left the cell cycle or are progressing to the G₀-G₁ transition. Received: 6 November 1996 / Accepted: 14 January 1997