Seasonal patterns of cell-to-cell communication in Chara corallina Klein ex Willd. I. Cell-to-cell communication in vegetative lateral branches during winter and spring

Cell-to-cell communication in lateral branches of limited growth in male Chara corallina plants has been studied using fluorescent plasmalemma-impermeable probes. The extent of cell-to-cell communication was found to be seasonal. In winter, branch internodes were characterized by relatively low plasmalemma potential differences (–121·2±23·2 mV; [K⁺]_o 0·5 mol m^?3; pH 7·6), quiescent dactyls isolated from the symplast (conic tips) and by restricted cell-cell communication (frequency of intercellular transport of six carboxyfluorescein = 42·9%). Cell-to-cell communication was inhibited during action-potentials, and was more extensive between cells which did not give an action potential in response to a current pulse. An inhibitor of the action potential, La³⁺, promoted cell-to-cell communication. These may be characteristic features of winter dormancy in lateral branches of Chara. In spring, morphological and electrophysiological changes occurred immediately prior to the onset of fertility. Characteristic changes in morphology included increased abundance of spherosomes and glycosomes, elongation of stipulodes and development of active branch dactyls. Spring branch inter-nodes were characterized by high plasmalemma PDs (–210·5±30·8mV; [K⁺]_o 0·5 mol m^?3; pH 7·6), predominantly active, non-isolated dactyls (spinaceous tips), and extensive intercellular communication (frequency of intercellular transport of 6 carboxyfluorescein = 89·2%). Artificial elevation of the intracellular calcium ion concentration by application of ionophore A23187 or Ca²⁺ microinjection significantly restricted intercellular communication to a level similar to that found in winter. The depression of intercellular communication in winter tissues is suggested to be due to high sensitivity to action potentials and/or to Ca²⁺ fluxes. Changes in intracellular Ca²⁺ distribution may be involved in the transition between the morphologically distinct states of dormancy and incipient fertility.     

Biological role of endoreplication in the process of spermatogenesis inChara vulgaris L.

Summary During cell division in antheridial filaments ofChara vulgaris an increase in DNA content occurs in both shield cells and manubria within an antheridium, reaching 16C–64C and 8C–32C levels, respectively. Endoreplication ceases prior to the formation of spermatids and initiation of spermiogenesis, probably as a result of symplasmic isolation of the antheridium from the thallus. As the DNA content of the nuclei increases, the shield cells³H-leucine incorporation increases, and they grow intensively in the tangential plane. Translation decreases considerably after termination of shield cell growth. DNA content of mature manubria is half of that in shield cells, although their size is 10 times that of manubria. Translational activity of manubria also increases as DNA content rises and cells grow. However, during spermiogenesis, this activity remains at its maximum, which is associated with the secretory function of the manubria. Spermiogenesis is also accompanied by far-reaching ultrastructural changes within the manubrial cytoplasm.The level of endopolyploidy in both shield cells and manubria of antheridia formed in the spring is higher by one replication cycle, than in autumnal antheridia. AMO-1618, at a concentration of 10^–5M reduces the DNA content in the autumnal manubria. The higher the manubrial level of endopolyploidy in spermiogenesis, the greater their size, and the higher the translational activity and number of joined spermatids. The number of spermatozoids in the antheridium is also positively correlated with the internal volume of an antheridium, which is itself dependent on the endopolyploidy level of shield cells.The results obtained confirm the assumption that endoreplication favours the higher growth dynamics and potential translational activity, which occurs in the dynamic growth phase only in shield cells, while in manubria, i.e. cells producing substances necessary to spermatozoids development, it remains high until the end of spermiogenesis.     

Autoradiographic studies on the role of plasmodesmata in the transport of gibberellin

Translocation of [¹⁴C]gibberellic acid into antheridial cells of Chara vulgaris L. was investigated in relation to the presence of symplasmic connections between the antheridium and the thallus. It was found that manubria, capitular cells, and antheridial filaments were about three-fold more strongly labelled in young antheridia connected to the thallus by plasmodesmata than in older antheridia in which spontaneous symplasmic isolation had occurred. Plasmolytically induced symplasmic isolation of young antheridia severely diminished the radioactivity of all the cells, down to the level characteristic for spontaneously isolated antheridia. It is concluded that plasmodesmata are the main channel of gibberellin transport into antheridia. The change in the character of symplasmic connections during the course of morphogenesis might, among other events, constitute a signal determining a shift of cell metabolism in a new direction, in response to a rapid change in gibberellin level.Abbreviations GA_(n) gibberellin (A_n) - GA₃ gibberellic acid - IAA indole-3-acetic acid This study was supported by the Polish Academy of Sciences research project CPBP 04.01.5.05.     

GEMMIFEROUS FERN GAMETOPHYTES—VITTARIACEAE

Approximately 10 % of all fern species reproduce vegetatively in the gametophytic stage by means of gemmae. Gametophyte morphologies in these species depart radically from the commonly figured heart-shaped type and expand considerably the opportunities for physiological and morphological studies utilizing fern gametophytes. Original observations on four species of vittarioid ferns are presented and compared with earlier observations on gametophytes of this family. Vittarioid gametophytes grow from a discontinuous marginal meristem which results in a much branched thallus of indeterminant growth. Aerial branches of the gametophytes terminate in gemma production, which proceeds by a regular and predictable sequence of events. The sequence may differ considerably among species but is remarkably constant within species. Archegonia are produced on short ventral branches, and antheridia are produced primarily on germinating gemmae. Ananthacorus angustifolius is the only known member of the Vittariaceae which does not produce gemmae and is considered to represent the primitive condition. In this species antheridia are scattered over the thallus, suggesting that a change in the mode of control of antheridium production may have evolved in the family along with gemma production.     

Symplasmic isolation ofChara vulgaris antheridium and mechanisms regulating the process of spermatogenesis

Summary The antheridium ofChara vulgaris L. is connected by plasmodesmata with the thallusvia a basal cell. Prior to the initiation of spermatozoid differentiation these plasmodesmata are spontaneously broken, resulting in symplasmic isolation of the antheridium.Premature plasmolytically evoked symplasmic isolation of the antheridium leads to a 2–4 fold reduction in the length of antheridial filaments and the elimination of 1–2 cell cycles from the first stage of spermatogenesis.Autoradiographic and cytophotometric studies have shown that, as a result of induced symplasmic isolation of the antheridium, endomitotic DNA synthesis was blocked both in the young manubria (after 24 hours) and in the capitular cells (after 48 hours). In the antheridial filaments DNA synthesis was inhibited together with either elimination of divisions and induction of spermatid differentiation or developmental block. We propose that breakage of plasmodesmata connecting the antheridium with the thallus is a signal which releases, in all antheridia, mechanisms that (i) block endomitotic DNA synthesis in the manubria, (ii) restrict the growth rate and the divisions of antheridial filament cells, and (iii) induce spermiogenesis in these antheridia in which the manubria attained the sufficient level of polyploidy.This work is supported by the Polish Academy of Sciences within the project CPBP 04.01.5.05.     

Source-sink Characteristic of Photoassimilate Transport in Fertile and Sterile Plants of Chara vulgaris L.*

In cuttings of Chara vulgaris consisting of 3–4 internodal cells with whorls (branchlets) transport of photoassimilates was investigated by ¹⁴C-labelling. The distribution of radioactivity in different component parts of the plant was shown as percentage and calculated in relation to fresh weight. Sucrose was identified as the main transported carbohydrate. In fertile Ch. vulgaris plants, developing oogonia and antheridia were important sinks for transported carbohydrates. Polarity of transport in the internodal cells (nutrients and assimilates) remains constant, as the main characteristic, from base to apex in fertile as well as in sterile plants. In sterile plants, the branchlets being the main source for photoassimilates and the apex the sink, transport from branchlets is mainly in the direction of the internodes. In the case of fertile plants gametangia are additional sinks redirecting transport of assimilates into the branchlets.     

Cell-cell communication in the leaves of Commelina cyanea and other plants

Abstract. The fluorescent probes 6–carboxyfluorescein and lucifer yellow CH which do not pass the plasmalemma have been used to examine cell-to-cell communication in the leaf of Commelina cyanea. Dye movement from cell-to-cell occurs in epidermal, spongy and palisade mesophyll, and vascular cells. Dye movement between these tissues was also found. Hence, the epidermis, spongy and palisade mesophyll cells, and vascular tissue are all linked in a continuous symplast. However, dye injected into the epidermal cells rarely moves into guard cells, indicating that these cells are relatively isolated from the surrounding cells. In the same way, guard cells in Vicia faba and the C₄ grass Anthephora pubescens also appeared to be isolated from epidermal cells. Thus guard cell isolation from cell-to-cell communication appears to be a common phenomenon. Hence, the ion fluxes required for guard cell function must occur via the apoplast.     

Cell-to-cell communication via plant endomembranes

Cell-to-cell communication was investigated in epidermal cells cut from stem internodal tissue of Nicotiana tabacum and Torenia fournieri. Fluorescently labelled peptides and dextrans were microinjected using iontophoresis into the cytoplasm andcortical endomembrane network of these cells. The microinjected endomembrane network was similar in location and structure to the endoplasmic reticulum (ER) as revealed by staining with 3, 3'-dihexyloxacarbocyanine iodide (DiOC(6)). No cell-to-cell movement of dextrans was observed following cytoplasmic injections but injection of dextrans into the endomembrane network resulted in rapid diffusion of the probes to neighbouring cells. It is proposed that the ER acts as a pathway for intercellular communication via the desmotubule through plasmodesmata.     

Do motile spermatozoids limit the effectiveness of sexual reproduction in bryophytes? Not in the liverwort Marchantia polymorpha

To test the premise that fertilization distances in bryophytes are limited by spermatozoid motility, we measured the distances between over 80 000 male and female thalli of Marchantia polymorpha on heathland over 2 successive years after a major fire and recorded the incidence of sporophytes. The first comparative data on spermatozoid numbers per antheridium across bryophytes and pteridophytes were calculated from antheridial sizes and spermatid diameters and cross‐checked with the likely numbers produced by successive antheridial mitoses. Individual antheridia of Marchantia produce over 200 000 spermatozoids. Extrapolating from individual antheridia to the numbers of mature antheridia per antheridiophore and then to individual male plants, we calculated that a single flooding event on a male thallus with 10–12 antheridiophores will result in the release of over 50 million spermatozoids. Assuming radial dispersal in surface water films by lipids released from the dehiscing antheridia, spermatozoids can reach distances exceeding 20 m from the parent plants, in line with our finding of 100% fertilization in female plants of Marchantia up to 19 m from the nearest males, far beyond published fertilization distances in dioicous bryophytes. We attribute this to (i) much greater spermatozoid production and numbers in Marchantia than in other bryophytes and (ii) highly effective sperm transport both within the antheridiophores and archegoniophores via their overlapping scales and grooves in the stalks and between male and female thalli via surface water films. These features, coupled with the massive production of small spores, explain the success of Marchantia as the primary colonist of open habitats.     

Comparative morphology of the gametophytes of the genus Equisetum, subgenus Equisetum

When grown under a variety of axenic conditions gametophytes of E. arvense, E. telmateia, E. sylvaticum, E. palustre , and E. fluviatile are all morphologically distinct. Lamellae from archegonial branches provide several diagnostic features but lamellae associated with antheridia are much less distinct. The archegonia of all five species have two neck canal cells and three tiers of neck cells and are of limited use taxonomically. Although antheridium development is basically similar in all species, during the metamorphosis of the spermatocytes specific differences arise in the shape of the cavity, degree of emergence and the number of opercular cells. A taxonomy of the gametophytes based on antheridium morphology corresponds very closely to the classification of the subgenus Equisetum into three sections based on the coning behaviour of the sporophytes.     

Characterization of sexual reproductive processes in Chara braunii (Charales,Charophyceae)

Chara braunii is distributed worldwide and is the most common charalean species in Japan. This species is monoecious and produces numerous sets of sex organs, each of which consists of one antheridium and one oogonium, under laboratory culture conditions. In this study, we report that light intensity strongly affected the vegetative phase and sexual reproductive phase of this species. Under high‐light conditions (70.0 μmol photons m^?2 s^?1), thalli grew but did not form reproductive organs. Under a low‐light intensity (10.0 μmol photons m^?2 s^?1), algal bodies formed many reproductive organs. In addition, antheridia without the corresponding oogonia (lone antheridia) were observed under low‐light conditions. The absence of oogonium primordia adjacent to the lone antheridium was confirmed by several microscopic approaches. The addition of liquid fertilizer increased the total number of sex organs and growth; however, the number of lone antheridia decreased with increasing fertilizer concentrations. Exogenously applied gibberellin did not affect the number of lone antheridia. These results suggest that regulatory mechanisms for the appropriate allocation of resources exist in this alga, similar to those reported in some land plants.     

GA3 content in young and mature antheridia of Chara tomentosa estimated by capillary electrophoresis

The content of gibberellic acid (GA3) in male sex organs of Chara tomentosa L. was estimated using capillary electrophoresis. Young antheridia contained 0.25 microg GA3 while mature ones 0.48 microg per antheridium. Although there are significant differences in GA3 content in antheridia between C. vulgaris and C. tomentosa, these values calculated per one spermatid are 2.4 and 3.3 pg, respectively. The present results compiled with the previous knowledge about regulation of GA3-dependent development of Characeae species allow an implication that the mechanisms controlling antheridia differentiation in both species can be similar.     

A CALAMITEAN SHOOT APEX FROM THE PENNSYLVANIAN OF IOWA

Melchior , Robert C., and John W. Hall . (U. Minnesota, Minneapolis.) A calamitean shoot apex from the Pennsylvanian of Iowa. Amer. Jour. Bot. 48(9): 811–815. Illus. 1961.—A shoot apex of a calamitean stem is described from the Des Moines Series, Middle Pennsylvanian. Internodal elongation of the 7 preserved internodes follows a sigmoid curve. A large apical cell has produced derivatives in a fashion apparently comparable to those in Equisetum arvense, except for the number of cells in the first leaf primordium ring and, possibly, the intercalary meristem. Pith meristem developed close to the apical cell. Data from internodal cell elongation of hypodermal cells of the cortex are presented which demonstrate intercalary internodal growth; no intercalary meristems are preserved and the existence of intercalary meristems which might have produced a jointed stem like that of Equisetum is only inferred.     

Etiolation of `Royal Gala' apple (Malus×domestica Borkh.) shoots promotes high-frequency shoot organogenesis and enhanced ,-glucuronidase expression from stem internodes

Internodal explants from etiolated `Royal Gala' apple shoots were compared with those from non-etiolated shoots for frequency of shoot organogenesis and for efficiency of β-glucuronidase (GUS) expression after cocultivation of explants with Agrobacterium tumefaciens strain EHA105 (p35SGUSint). First (youngest) internodal explants from etiolated shoots produced 2-, 8- and 73-fold numbers of shoots compared to second, third, and fourth internodal explants, respectively. Moreover, these explants produced sevenfold the number of shoots as similar explants from non-etiolated shoots. All first internodes from etiolated shoots exhibited GUS-expressing zones and yielded fourfold as many GUS-expressing zones as commonly used leaf explants from non-etiolated shoots, which exhibited GUS-expressing zones in only 63% of the explants. An average of 9.8 GUS expressing calli per explant were observed on first internodes from etiolated shoots 2 weeks after cocultivation with A. tumefaciens. Received: 17 February 1998 / Revision received: 5 May 1998 / Accepted: 15 May 1998     

Internodal sodium channels ensure active processes under myelin manifesting in depolarizing afterpotentials

The current opinion about processes in myelinated axon is that action potential saltatorially propagates between nodes of Ranvier and passively charges internodal axolemma thus causing depolarizing afterpotentials (DAP). Demyelination blocks the conduction that gives additional argument in favor of hypothesis that internode is not able to be activated by the existing internodal sodium channels. The results of our modeling study shows that, when periaxonal space is sufficiently narrow, saltatorial action potential is able to activate internodes. Low density of internodal sodium channels is sufficient to generate active internodal waves that slowly propagate from nodes towards corresponding midinternodes where they collide. The periaxonal width that stops internodal wave propagation (about 400 nm) is significantly larger than the highest value of the physiological range for this parameter (30 nm). Internodal activation is directly manifested as transmembrane internodal potential or as a full-sized action potential in periaxonal space where it can hardly be detected, and only as a small deflection in intracellular space. However, changes in the periaxonal potential cause transmyelin currents that lead to significant DAP. The shape and amplitude of DAP depends on myelin parameters and densities of internodal channels. Several technical parameters affect the results of calculations. Internodal spatial segmentation has to be sufficiently fine (at most 20 microm) for the model to be able to simulate internodal activation. We employ 338 internodal segments as compared with up to 21 used in previous models. Ionic accumulation together with related diffusive and electrical processes alter the calculated DAP amplitude. Inclusion of these processes in calculations demands such increase in the total number of segments that the numerical methods used up to now become unapplicable. To overcome the problem, an iterative implicit approach is proposed. It reduces a matrix of general type in multi-cable models to tridiagonal one and accelerates calculations considerably.     

ROLE OF ASYMMETRIC CELL DIVISION IN PTERIDOPHYTE DIFFERENTIATION. II. EFFECT OF CA2+ ON ASYMMETRIC CELL DIVISION,RHIZOID ELONGATION,AND ANTHERIDIUM DIFFERENTIATION IN VITTARIA GEMMAE

Gametophytes of Vittaria graminifolia reproduce vegetatively by means of gemmae. Each gemma consists of a linear array of six cells: four body cells and a knob-shaped terminal cell at each end. When gemmae are shed from the gametophyte onto Knop's mineral medium, the two terminal cells do not divide, but elongate to form primary rhizoids. The body cells undergo asymmetric cell division, and the smaller daughter cells differentiate into either secondary rhizoids or prothalli. When gibberellic acid is included in the medium, antheridia are formed as a result of asymmetric cell division instead of vegetative structures. We studied the effect of Ca²⁺ on asymmetric cell division, rhizoid elongation, and antheridium formation in gemmae cultured on Knop's mineral medium and variations of Knop's medium. Ca²⁺ inhibited the onset of cell division and rhizoid elongation, but was required for differentiation of antheridia. Treatments which lowered the Ca²⁺ content of gemmae (EGTA and dilute HCl extraction, culture on verapamil-containing and Ca²⁺-deficient medium) caused an early onset of cell division and rhizoid elongation. The stimulation of growth was most pronounced when gemmae were deprived of Ca²⁺ during the first 24 hr of culture. The proportion of cell divisions which differentiated into antheridia in response to GA was greatly reduced when the Ca²⁺ status of gemmae was lowered with verapamil and Ca²⁺-EGTA buffers.     

Competence for Regeneration during Tobacco Internodal Development (Involvement of Plant Age,Cell Elongation Stage,and Degree of Polysomaty)

This study deals with internodal development in vegetative plants of Nicotiana tabacum cv Samsun NN and its reflection in changes of the cellular competence for regeneration. During elongation of the internodes, the cells of the epidermis, subepidermis, and cortex exclusively expanded and increased their DNA content cell type specifically, generally from 2C to 4C. Cells with the 8C DNA content were found mainly among the cortex cells of mature internodes. The frequency of shoot regeneration (directly from subepidermal and epidermal cells together) on thin cell layer explants increased to an optimum along with elongation of the internodes and decreased in mature internodes along with aging. The frequencies of diploid shoots among the regenerants from elongating and mature internodes were high (88 and 75% on the average, respectively), indicating that most cells that had achieved the 4C DNA content generally retained the G2 phase of the diploid cell cycle. Shoots regenerated from explants of young plant material mainly had a vitrified appearance. The occurrence of this type of malformed growth was already determined by the physiological state of the cells in the internode and did not interfere with their acquisition of competence. Vitrification was unrelated to the degree of polysomaty of the internodal tissue. Using the occurrence of tetraploid root regenerants (from intermediate cortex-derived callus), up to a frequency of 50%, we show that the position in the plant where a majority of the 4C cortex cells switched to the G1 phase of the tetraploid cell cycle was at the transition from the elongation phase to the mature phase.     

SCANNING ELECTRON MICROSCOPY OF ANTHERIDIA AND ARCHEGONIA OF ANEMIA MEXICANA KLOTZSCH

Antheridia and archegonia of the fern Anemia mexicana were viewed with scanning electron microscopy (SEM). The mature antheridium is composed of a cap, ring, and basal cell with spermatozoids inside. The archegonium neck is composed of a neck canal cell surrounded by four rows of neck cells. The ventral canal cell and egg were not observed. The neck bends toward the notched meristem. The neck cells usually are uniform in shape and arrangement, but in some archegonia, shape and arrangement of neck cells was irregular. The apex of these archegonia often appeared swollen because of the random cell arrangement. In the presence of water, the antheridium cap is partially detached and the spermatozoids emerge. At this time, the neck cells open at the end of the archegonium in preparation for fertilization. The basic morphology of the antheridia and archegonia is similar to previous reports, although SEM provides more structural detail and a better three-dimensional visualization of these reproductive structures.     

Plasmodesmal changes are related to different developmental stages of antheridia of Chara species

Summary During the development of the antheridia of Chara species, dynamic changes in the occurrence and ultrastructure of plasmodesmata are observed which are closely correlated to particular developmental phases and presumably regulate the morphogenetic events in the antheridia. The disappearance of plasmodesmata between shield cells and between shied cells and the basal cell leads to a cessation in symplasmic transport around the antheridum and determines its concentric or centrifugal character via centrally situated capitular cells. Unplugged plasmodesmata are present between fully synchronously developing antheridial filament cells and obviously coordinate the development of the cells. In the middle phase of spermiogenesis, rough endoplasmic reticulum in antheridial filaments passes uncompressed through wide plasmodesmata and provides an additional transport pathway for developmental control factors. Plugged plasmodesmata link cells of different types or cells of the same type which are at different phases of cell cycle and guarantee their individual development. The plugging of plasmodesmata is a reversible process that depends on the morphogenetic situation. Plasmodesmata connecting the basal cell and the subbasal cell as well as the basal cell and capitular cells are transformed successively from the simple into the complex type and might be the pathways for an import of gibberellins and nutrients into the strong sink tissues of the developing antheridium. There is a symplasmic connection between the antheridum and the thallus via a basal cell. Prior to the initiation of spermatozoid differentiation (spermiogenesis), plasmodesmata connecting the basal cell with a subbasal cell and the basal cell with capitular cells are spontaneously broken, resulting in symplasmic isolation of the antheridium that is probably a signal which triggers the induction of spermatozoid differentiation. Premature plasmolytically evoked symplasmic isolation of the antheridium leads to the elimination of 1 to 2 cell cycles from the proliferative stage of spermatogenesis. Autoradiographic studies demonstrate that both natural and induced symplasmic isolation drastically decreases the entry of isotopically labeled gibberellic acid into antheridia of Chara species that may be the consequence of the elimination of the hormone's transport through plasmodesmata.Correspondence and reprints: Department of Cytophysiology, University of ód, ulica Pilarskiego 14, 90-231 ód, Poland.Received March 11, 2002; accepted September 19, 2002; published online August 26, 2003     

Gibberellin-induced elongation and osmoregulation in internodes of floating rice

Internodal elongation in floating rice ( Oryza sativa L. cv. Habiganj Aman II) is known to be enhanced by treatment with ethylene or gibberellic acid (GA₃) at high relative humidity (RH). However, ethylene-induced internodal elongation is inhibited at low RH. while GA₃-induced internodal elongation is hardly affected by humidity. We examined the possible involvement of osmoregulation in the stimulation by GA₃ of the elongation of internodes at low RH. Submergence and treatment with ethylene or GA3₃ at 100% RH increased the osmotic potential in internodes of excised stem segments, while GA₃ at 20% RH maintained the osmotic potential at a low level. In internodes of stem segments that had been treated with GA₃ at 20% RH, the activity of invertase and the level of soluble sugars were almost 2- and 1.5-fold higher, respectively, than those in internodes that had been treated with GA₃ at 100% RH. These results indicate that one of the possible mechanisms by which GA₃ promotes elongation of internodes at low RH involves the osmoregulation that is achieved by promotion of the synthesis of invertase.