PHOTOCONTROL OF THE ORIENTATION OF CELL DIVISION IN ADIANTUM. I. EFFECTS OF THE DARK AND RED PERIODS IN THE APICAL CELL OF GAMETOPHYTES

When protonemata of Adiantum capillus-veneris L. which had been grown filamentously under continuous red light were transferred to continuous white light, the apical cell divided transversely twice, but the 3rd division was longitudinal. An intervening period of darkness lasting from 0 to 90 hr either between the 1st and the 2nd cell division or between the 2nd and the 3rd one did not affect the number of protonemata in which the 3rd cell division was longitudinal. The insertion of red light instead of darkness greatly decreased the percentage of 1st longitudinal divisions occurring at the 3rd division, and increased the number of transverse divisions. Fifty percent reduction of induction of 1st longitudinal division was caused by ca. 50 hr exposure to red light between 1st and 2nd division and by ca. 20 hr between 2nd and 3rd division, and total loss was induced by an exposure of ca. 100 hr or longer to red light in the former and by ca. 40 hr longer in the latter. Thus, by using an appropriate intervening dark period or exposure to red light, the orientation and timing of cell division could be controlled in apical cell of the fern protonemata.     

Action Spectrum for the Timing of Photo-Induced Cell Division in Adiantum Gametophytes

The photo-induced cell division in single-celled protonemata of the fern Adiantum capillus-veneris was studied. When the protonemata were exposed to monochromatic light at 50 nm intervals between 350 and 750 nm, irradiations in the blue and near-ultraviolet regions effectively induced cell division, while wavelengths longer than 550 nm showed no such effect. As reciprocity between duration and intensity was observed within the range of incident energy used, the action spectrum for the frequency of the photo-induced cell divisions 24 h after irradiation was determined between 360 and 510 nm at 10 nm intervals. Furthermore, the previously known effect of phytochrome on the timing of the cell division was minimized by a short exposure to red light given immediately after the monochromatic irradiation. The resulting action spectra showed a peak in the neighborhood of 460 nm with shoulders and another peak in the near-ultraviolet region.     

Phytochrome action on the timing of cell division in adiantum gametophytes

When filamentous protonemata of Adiantum capillus-veneris L. precultured under continuous red light were transferred to the dark, the apical cell divided about 24 to 36 hours thereafter. The time of the cell division was delayed for several hours by a brief exposure to far red light given before the dark incubation. The effect of far red light was reversed by a small dose of red light given immediately after the preceding far red light. The effects of red and far red light were repeatedly reversible, indicating that the timing of cell division was regulated by a phytochrome system. When a brief irradiation with blue light was given before the dark incubation, the cell division occurred after 17 to 26 hours in darkness. A similar red far red reversible effect was also observed in the timing of the blue light-induced cell division. Thus, the timing of cell division appeared to be controlled by phytochrome and a blue light-absorbing pigment.     

Formation of novel endoplasmic and cortical microtubular arrays inAdiantum protonemal cells induced by blue light irradiation and acropetal centrifugation

Protonemal cells ofAdiantum capillus-veneris were grown under red light conditions over 6 days and exposed to blue light for 8 hr (and then dim green light for 1 hr for technical reasons), before they were centrifuged acropetally over at least 1 hr at 2,000×g. After this treatment, an arrangement of endoplasmic microtubules (MTs) that resembled the shape of a tadpole could be detected some distance below the nucleus in about 40% of the cells. The percentage of protonemata bearing this Mtstructure was dependent on centrifugation time as well as the time of blue light irradiation. The size of the structure was constant at any time of its existence. Additionally, a wide belt of transversally oriented cortical MTs in the upper part of the protonemata was detected in many cells after blue light irradiation and acropetal centrifugation. Its formation rate seemed to be also dependent on the period of blue light irradiation and centrifugation time. None of the endoplasmic and few of the cortical transverse MT patterns could be seen without blue light irradiation. A strict coincidence in the formation of both MT patterns was not seen. Further, a few tadpole-shaped MT arrays remained during mitosis, whereas the cortical transverse MT pattern was found in stages other than metaphase and anaphase.     

Intracellular Photoreceptive Site for Blue Light-Induced Cell Division in Protonemata of the Fern Adiantum--Further Analyses by Polarized Light Irradiation and Cell Centrifugation

The intracellular localization of the photoreceptive site forblue light-induced cell division in single-celled protonemataof Adiantum capillus-veneris L. was investigated using polarizedlight irradiation and protonemal cell centrifugation. The responseto irradiation with polarized blue light showed no dependenceon the direction of light polarization. However, centrifugationof the protonemata followed by microbeam irradiation showedthat the site of blue light perception could be displaced togetherwith the nucleus. Centrifugal treatment changed the distributionof intracellular organelles at the time of light exposure andbasipetally displaced the nucleus about 90µm. This treatmenthad no effect on the induction of cell division with blue lightif the protonemata were centrifuged again acropetally afterthe light treatment. Microbeam (30x30 µm²) irradiationwith blue light of the apical 45–75 ßm region,the receptive site of blue light in non-centrifuged cell, didnot induce cell division. However, cell division was inducedby irradiation of the nucleus-containing region, indicatingthat the photoreceptive site was displaced together with thenucleus by the centrifugation. These results suggest that theblue light receptor regulating cell division in Adiantum protonematais not likely to be located on the plasma membrane. (Received February 20, 1986; Accepted May 27, 1986)     

The Protonema of Chara fragilis Desv.: Regenerative Formation,Photomorphogenesis, and Gravitropism

When exposed to constant white light for four weeks, isolated nodes of Chara fragilis Desv. regenerated side branches, rhizoids, and multicellular protonemata, the latter being similar to those germinated from oospores. When kept in darkness the nodes developed protonemata exclusively. These were single-celled, colourless, and tip-growing and, with the light microscope, they looked like rhizoids. Upon exposure to blue light, but not to red or far-red, the growth rates of the protonemata rapidly declined, the cell apices swelled, and the nucleus migrated acropetally. Within 24 h the cells went through the first of a series of divisions resulting in the formation of multicellular protonemata. When returned to darkness after a blue light pulse of 5 h the cell divisions proceeded normally, but the protonemata showed etiolated growth. While growth of the internode was drastically promoted, the development of the multicellular apex and the lateral initial were suppressed. Both uni- and multicellular etiolating protonemata showed negative gravitropism but were phototropically insensitive. It is argued that the single-celled protonema is an organ specialized for the penetration of mud covering the nodes or oospores of Chara and thus serves to search for light, comparable to etiolated hypocotyls and stems in seedlings of higher plants.     

Effect of light and gibberellic acid on cell division in the first foliage leaf of durum wheat (Triticum durum Desf.)

The present paper is part of a research program which aims at a quantitative analysis of the effects of light and gibberellic acid (GA₃) on growth of the first foliage leaf in durum wheat (Triticum durum Desf.). Since leaf growth is the combined result of the increase in cell number (cell division) and cell enlargement, the influence of light and GA₃ treatment on cell division in the basal meristem of the first leaf in two cultivars, Cappelli and Creso, was investigated. Creso is a short-strawed cultivar carrying the Gai 1 gene which influences both plant height and insensitivity to applied GA₃. Cell division, as measured by mitotic index, was similar in darkness, continuous red light and dichromatic irradiation (far-red plus red), while lower mitotic rates were observed under continuous far-red light: this indicates that the response of cell division is modulated by a high-irradiance reaction of phytochrome in both cultivars. The two cultivars showed different responses to blue light. In Cappelli, blue light and dichromatic irradiation (blue plus red) gave lower mitotic indices than the dark control, indicating the action of a specific blue-light-absorbing photoreceptor, whereas in Creso the response kinetics to all light regimes which included blue light were more complex. On the basis also of the results obtained with GA₃ application in Cappelli, it appears that (i) the hormonal treatment is able to change the pattern of mitotic index only in the presence of the action of a blue-light receptor and (ii) the different responses of the two cultivars could be the result of different endogenous hormonal levels. The importance of the observations in relation to the data for first-leaf longitudinal growth reported in a previous paper (Baroncelli et al. 1984, Planta 160, 298–304) is discussed.Abbreviations BL blue light - D darkness - FR far-red light - GA gibberellin - GA₃ gibberellic acid - m.i. mitotic index - Norflurazon 4-chloro-5-(methylamino)-2-(,,,-trifluoro-m-totyl-3(2H)) pyridazinone - R red light - WL white light - phytochrome photoequilibrium     

Photocontrol of the orientation of cell division in Adiantum

Summary Two-dimensional prothallia of Adiantum capillus-veneris always expanded in a plane which was at a right angle to any given direction of irradiation with continuous white light. The expansion began with a longitudinal division of the apical cell, in the filamentous protonema, and the orientation of the mitotic cell plate of this first longitudinal division as well as the subsequent divisions was always parallel to the direction of the incident light. When three irradiations with white light, interrupted by periods of darkness, were given, two transverse and one subsequent longitudinal division were induced. When the last two irradiations were given from the same direction, the cell plate of the first longitudinal division in most protonemata was oriented parallel to the direction of light. However, when the direction of light during the third irradiation was at right angle to that during the second, the frequency of the longitudinal division greatly decreased but that of the third transverse division increased. Thus, the orientation of the first longitudinal division appeared to be controlled in some way not only by the irradiation which actually induced the third division but also by that inducing the preceding transverse division, while the direction of light for the first transverse division had little effect on the orientation of the third division.     

Can Nocodazole,an Inhibitor of Microtubule Formation,Be Used to Synchronize Mammalian Cells?

Abstract Nocodazole, a temporary inhibitor of microtubule formation, has been used to partly synchronize Ehrlich ascites tumour cells growing in suspension. the gradual entry of cells into mitosis and into the next cell cycle without division during drug treatment has been studied by flow cytometric determination of mitotic cells, analysing red and green fluorescence after low pH treatment and acridine orange staining. Determination of the mitotic index (MI) by this method has been combined with DNA distribution analysis to measure cell-cycle phase durations in asynchronous populations growing in the presence of the drug. With synchronized cells, it was shown that in the concentration range 0.4–4.0 μg/l, cells could only be arrested in mitosis for about 7 hr and at 0.04 μg/ml, for about 5 hr. After these time intervals, the DNA content in nocodazole-blocked cells was found to be increased, and, in parallel, the ratio of red and green fluorescence was found to have changed, showing entry of cells into a next cell cycle without division (polyploidization). It was therefore only possible to partially synchronize an asynchronous population by nocodazole. However, a presynchronized population, e.g. selected G₁ cells or metabolically blocked G₁/S cells, were readily and without harmful effect resynchronized in M phase by a short treatment (0.4 μg/ml, 3–4 hr) with nocodazole; after removal of the drug, cells divided and progressed in a highly synchronized fashion through the next cell cycle.     

Growth and cell cycle of Ulva compressa (Ulvophyceae) under LED illumination

The cell‐cycle progression of Ulva compressa is diurnally gated at the G₁ phase in accordance with light–dark cycles. The present study was designed to examine the spectral sensitivity of the G₁ gating system. When blue, red, and green light‐emitting diodes (LEDs) were used for illumination either alone or in combination, the cells divided under all illumination conditions, suggesting that all colors of light were able to open the G₁ gate. Although blue light was most effective to open the G₁ gate, red light alone or green light alone was also able to open the G₁ gate even at irradiance levels lower than the light compensation point of each color. Occurrence of a period of no cell division in the course of a day suggested that the G₁ gating system normally functioned as under ordinary illumination by cool‐white fluorescent lamps. The rise of the proportion of blue light to green light resulted in increased growth rate. On the other hand, the growth rates did not vary regardless of the proportion of blue light to red light. These results indicate that the difference in growth rate due to light color resulted from the difference in photosynthetic efficiency of the colors of light. However, the growth rates significantly decreased under conditions without blue light. This result suggests that blue light mediates cell elongation and because the spectral sensitivity of the cell elongation regulating system was different from that of the G₁ gating system, distinct photoreceptors are likely to mediate the two systems.     

Ultraviolet Light-Induced Division Delay in Synchronized Chinese Hamster Cells

The age-dependent, ultraviolet light (UVL) (254 nm)-induced division delay of surviving and nonsurviving Chinese hamster cells was studied. The response was examined after UVL exposures adjusted to yield approximately the same survival levels at different stages of the cell cycle, 60% or 30% survival. Cells irradiated in the middle of S suffered the longest division delay, and cells exposed in mitosis or in G₁ had about the same smaller delay in division. Cells irradiated in G₂, however, were not delayed at either survival level. It was further established, after exposures that yielded about 30% survivors at various stages of the cycle, that surviving cells had shorter delays than nonsurvivors. This difference was not observed for cells in G₂ at the time of exposure; i.e., neither surviving nor nonsurviving G₂ cells were delayed in division. The examination of mitotic index vs. time revealed that most cells reach mitosis, but all of the increase in the number of cells in the population can be accounted for by the increase of the viable cell fraction. These observations suggest strongly that nonsurviving cells, although present during most of the experiment, are stopped at mitosis and do not divide. Cells in mitosis at the time of irradiation complete their division, and in the same length of time as unirradiated controls. Division and mitotic delays after UVL are relatively much larger than after X-ray doses that reduce survival to about the same level.     

Timing and Regulation of Nuclear and Cortical Events in the Cell Cycle of Tetrahymena pyriformis*

SYNOPSIS. Using continuous flow cultures based on the chemostat principle, we varied the cell generation times of the ciliate Tetrahymena pyriformis strain GL, from 4.9 to 22.2 hr and studied various parameters of the cell cycle at 28 C. These included: the duration of the periods required for oral morphogenesis, macronuclear division, cell division, G₁ S, and G₂. The size of individual cells was also measured. Independent of the growth rate, the period of oral morphogenesis occurred during the last 90 min of the cell cycle. In all cases macronuclear and cell divisions took place during the last part of these 90 min, and the final macronuclear separation occurred just before final cell separation. The S-period increased slightly, while the G₁ and G₂ both increased in roughly the same relative proportion to the increasing generation times. Slowly growing cells (generation time 20.5 hr) were shorter but broader and somewhat larger in volume than quickly growing cells (generation time 4.9 hr).     

Cell kinetics, stomatal differentiation, and diurnal rhythm in Allium cepa

Cell kinetics parameters were obtained for the three mitotic divisions leading to formation of stomata in the epidermis of the cotyledon of Allium cepa seedlings. Analysis of mitotic frequencies throughout the course of development showed that the asymmetrical divisions started at about 50 hr after germination, and the symmetrical divisions were first seen a few hours later. Guard mother cell divisions started around 70 hr after germination. The maximal frequency of both symmetrical and asymmetrical division was found between 3 and 5 days after germination, and the highest frequencies of GMC divisions were observed between 6 and 8.5 days. All divisions ceased after 11 days. The three cell populations analyzed displayed diurnal fluctuations of their mitotic frequencies which were characteristic of the type of cell division measured and seemed independent of the region of the cotyledon in which they took place. The symmetrical divisions displayed two diurnal peaks—one at about 0400 and the other at 1600 hr—and the asymmetrical mitoses showed a single peak at about 2200 hr. Atypical asymmetrical divisions were observed in some guard mother cells, suggesting a different developmental sequence for some of the stomatal complexes.     

Phytochrome-mediated branch formation in protonemata of the mossCeratodon purpureus

We have analyzed light induction of side-branch formation and chloroplast re-arrangement in protonemata of the mossCeratodon purpureus. After 12 hr of dark adaptation, the rate of branch formation was as low as 5%. A red light treatment induced formation of side branches up to 75% of the dark-adapted protonema. The frequency of light induced branch formation differed between cells of different ages, the highest frequency being found in the 5th cell, the most distal cell studied from the apex. We examined the effect of polarized light given parallel to the direction of filament growth. The position of branching within the cell depended on the vibration plane of polarized red light. Branch formation was highest when the electric vector of polarized light vibrates parallel to the cell surface and is fluence rate dependent. The positional effect of polarized red light could be nullified to some extent by simultaneous irradiation with polarized far-red light. An aphototropic mutant,ptr116, shows characteristics of deficiency in biosynthesis of the phytochrome chromophore and exhibits no red-light induced branch formation. Biliverdin, a precursor of the phytochrome chromophore, rescued the red-light induced branching when added to the medium, supporting the conclusion that phytochrome acts as photoreceptor for red light induced branch formation. The light effect on chloroplast re-arrangement was also analyzed in this study. We found that polarized blue light induced chloroplast re-arrangement in wild-type cells, whereas polarized red light was inactive. This result suggests that chloroplast re-arrangement is only controlled by a blue light photoreceptor, not by phytochrome inCeratodon.     

Gametic differentiation in Chlamydomonas reinhardi: cell cycle dependency and rates in attainment of mating competency

Withdrawal of a utilizable nitrogen source during mid G₁ of the cell cycle induces gametic differentiation in synchronously grown vegetative cultures of Chlamydomonas reinhardi. Cell division accompanies gametic differentiation in such cultures, and the ability of mid G₁ vegetative cells to form gametes is matched by their ability to undergo a round of cell division after nitrogen withdrawal. Synchronously grown cultures require up to 19 hr in nitrogen-free medium to complete a round of division and to form mating-competent cells. Asynchronously grown liquid cultures require less time after nitrogen withdrawal (generally 5–8 hr) to achieve mating competency. In these cultures cell division did not necessarily accompany gametic differentiation since gametic differentiation took place in induced cultures at high cell concentrations which prevented cell division. Maximum mating competency was achieved in less than 2 hr after induction of vegetative cells grown on agar plates. Little cell division was observed during that short induction interval. The relationship between the attainment of mating competency (gametogenesis) and other physiological events resulting from nitrogen withdrawal is discussed.     

Effects of Colchicine and Light on Cell Form in Fern Gametophytes. Implications for a Mechanism of Light-induced Cell Elongation

Spores of the fern, Onoclea sensihilis L., suffer a disruption of normal development when they are cultured on media containing colchicine. Cell division is inhibited, and the spores develop into giant spherical cells under continuous white fluorescent light. In darkness only slight cell expansion occurs. Spherical cell expansion in the light requires continuous irradiation. Photosynthesis does not seem to be involved, since variations in light intensity do not affect the final cell diameter; the addition of sucrose to the medium does not permit cell expansion in darkness; and the inhibitor DCMU does not block the light-induced cell expansion. Continuous irradiation of colchicine-treated spores with blue, red or far-red light produces different patterns of cell expansion. Blue light permits spherical growth, similar to that found under white light, whereas red and far-red light promote the reestablishment of polarized filamentous growth. Although ethylene is unable to induce polarized cell expansion in colchicine-treated spores in darkness or white and blue light, it enhances filamentous growth which already is established by red or far-red irradiation. Both red and far-red light increase the elongation of normal filaments (untreated with colchicine) above that of dark-grown plants, but under all 3 conditions the rates of volume growth are identical. Light, however, does cause a decrease in the cell diameters of irradiated filaments. These data are used to construct an hypothesis to explain the promotion of cell elongation in fern protonemata by red and far-red light. The model proposes light-mediated changes in microtubular orientation and cell wall structure which lead to restriction of lateral cell expansion and enhanced elongation growth.     

Mitotic recombination in the absence of synaptonemal complexes in Saccharomyces cerevisiae.

Summary Mitotic cells of a diploid strain of Saccharomyces cerevisiae with appropriate markers for the detection of mitotic crossing-over and mitotic gene conversion were irradiated with X-rays. Induction of these recombinational events was strong. After irradiation, cells were incubated in a rich growth medium and samples were removed for studying the possible formation of synaptonemal complexes up to a time when most cells had completed the first post-irradiation cell division. No complexes were found during the entire period of sampling, during which mitotic recombination in G₁ (mitotic gene conversion), DNA replication and G₂ (mitotic crossing-over) had occurred. These results are interpreted to mean that synaptonemal complexes are not required for mitotic recombination.     

The changes of nuclear position and distribution of circumferentially aligned cortical microtubules during the progression of cell cycle inAdiantum protonemata

The intracellular positions of the nucleus and of cortical, circumferentially aligned microtubules (CCAM) in filamentous, single-celled protonemata ofAdiantum capillus-veneris were determined throughout the cell cycle in the dark. When apical growth continued at G₁ phase, the nucleus migrated keeping a constant distance from the tip. When the apical growth stopped at late S or G₂ phase, the nucleus stopped moving forward and then slightly moved backward to the site of cytokinesis. The CCAM were found only in the dome of protonemal tip when growing under continuous red light; they increased in number after dark incubation for 12 hr and then decreased after 20th hr in the dark. The CCAM were usually observed in the region between the nucleus and the tip at 28 hr in the dark. They were located around the nuclear region at pre-prophase and prophase, but then totally disappeared at metaphase and thereafter.     

Light requirements for regeneration of protoplasts of the moss Physcomitrella patens

Protoplasts prepared by enzymic treatment of protonemata of the moss Physcomitrella patens regenerate rapidly in white light (15 W m^?2). The great majority of protoplasts follow a simple regenerative sequence, namely: cell wall synthesis; formation of an asymmetric cell; division of the asymmetric cell, and further extension and division to produce a new chloronemal filament. Only cell wall formation occurs independently of light. The production of an asymmetric cell requires relatively high photon fluence rates of blue or red light and ceases upon transfer to darkness. The subsequent stages of regeneration require much lower photon fluence rates, and red light is considerably more effective than blue or far-red light in permitting cell division. This system is of interest in the study of the induction of cell polarity in plants.     

MITOTIC INDUCTION AND SYNCHRONIZED CELL DIVISION IN OEDOGONIUM CARDIACUM (HASS.) WITTR.

Waves of mitosis are induced in Oedogonium cardiacum grown under a 15 hr light/9 hr dark cycle. Mitosis starts 4 to 5 hr after the start of the dark period. Each mitotic stage has a high initial rate which plateaus at a lower rate for several additional hours. Partial synchronization of mitotic stages results from this induction of cell division. Mitotic divisions last 9 to 10 hr after induction. During the remainder of the 24-hr light/dark cycle, cells are in interphase. Along a filament, several dividing cells tend to be adjacent, with the most advanced stage in the cap cell. Progressively earlier mitotic stages are basal to the dividing cap cell. This pattern of mitotic division differs from the state in nature where only the cap cell usually divides. Chromosomes probably maintain a telophase arrangement during interphase. The suitability and advantages of Oedogonium, a haploid alga with sexual reproduction, as an experimental plant for cytological, developmental, biochemical, and genetic studies is pointed out.