Epiplastome variation of the number of chloroplasts in stomata guard cells of sugar beet (Beta vulgaris L.)

In stomata guard cells of sugar beet, variation in the number of chloroplasts was studied in successive generations: (1) hybrid generation; (2) generation yielded by uniparental apozygotic seed reproduction; (3) generation obtained after seed treatment with a colchicine solution; (4) generation obtained after seed treatment with 5-azacytidine. As compared to hybrid generation, uniparental seed reproduction increases the average number of chloroplasts in stomata guard cells (from 13.5 to 15.0) and decreases distribution variance of this trait by a factor of 3 to 4. Colchicine increases both average number of chloroplasts in stomata guard cells (from 13.5 to 18.2) and distribution variance (about twice). 5-Azacytindine reduces the number of chloroplasts in cells (from 15.0 to 12.9) but enhances distribution variance (about 1.5 times). Variation in the number of chromosomes in stomata cells is related to myxoploidy in meristem tissue, on the one hand, and to the rate of cell division, on the other. Uniparental seed reproduction is suggested to enhance the number of organelles per cell due to high myxoploidy in cell populations, which is typical of inbred plants. Colchicine blocks spindle division and sharply increases the level of myxoploidy in cell populations and the number of organelles per cell. 5-Azacytidine hypomethylates chromosome DNA, increases the rate of cell divisions, and reduces the number of organelles per cell. The described changes in the number of chloroplasts are inherited in cell lineage ("cell hereditary memory") and successive sporophyte generations.     

Variability of the number of chloroplasts in a population of stoma guard cells in the sugar beet (Beta vulgaris L.)

Diploid sugar beet plants demonstrate a broad variability of the number of chloroplasts in stoma guard cells, which is related to myxoploidy of cell populations in leaf apical meristems (epigenomic variability). In addition to random organelle segregation between daughter cells, this variability is affected by factors disrupting the mitotic cycle: (1) plant treatment with a mitotic poison, such as colchicine; (2) duration of the life cycle of a plant; the variability in second-year plants is greater than in first-year ones; (3) the mode of plant reproduction; the variability in inbred plants is greater than in the initial population. Treatment of germinating seeds with a diluted colchicine solution increases the number of organelles in cells in the myxoploid generation (generation C0) and the variance of the distributions in the first vegetation year. The variability in the organelle number in stoma cells correlates with that in maternal meristem cells. It is concluded that the epidermal cell monolayer (including stoma guard cells) keeps record of the epigenomic and epiplastome variability in meristem cells. The variability of the number of chloroplasts in stoma guard cells is approximated by binomials with negative powers.     

Variability of Chloroplast Number in Populations of Stomata Guard Cells in Sugar Beet Beta vulgaris L.

Diploid sugar beet plants demonstrate a broad variability of the number of chloroplasts in stomata guard cells, which is related to mixoploidy of cell populations in leaf apical meristems (epigenomic variability). In addition to random organelle segregation between daughter cells, this variability is affected by factors disrupting the mitotic cycle: (1) plant treatment with a mitotic poison, such as colchicine; (2) duration of the life cycle of a plant; the variability in second-year plants is greater than in first-year ones; (3) the mode of plant reproduction; the variability in inbred plants is greater than in the initial population. Treatment of germinating seeds with a diluted colchicine solution increases the number of organelles in cells in the myxoploid generation (generation C₀) and the variance of the distributions in the first vegetation year. The variability in the organelle number in stomata cells correlates with that in maternal meristem cells. It is concluded that the epidermal cell monolayer (including stomata guard cells) keeps record of the epigenomic and epiplastome variability in meristem cells. The variability of the number of chloroplasts in stomata guard cells is approximated by binomials with negative powers.     

Differentiation of stomatal meristemoids and guard cell mother cells into guard-like cells in Vigna sinensis leaves after colchicine treatment

The temporary development of Vigna sinensis seedlings in the presence of colchicine results in the inhibition of stomata generation and the formation of numerous persistent stomatal meristemoids (P-SM) and guard cell mother cells (P-GMC). Before dividing differentially or becoming GMC, the untreated meristemoiidsundergo a preparatory differentiation, during which a synthesis of new densely ribosomal cytoplasm, an increase of nuclear size, and a detectable proliferation of all the organelles are observed. The same process appears depressed and delayed in treated meristemoids; the cells have usually undergone only part of it when they reach the C mitosis. After the inhibition of their division, the bulged meristemoids II and GMC increase further in size, synthesize new nonribosomal cytoplasm, and start vacuolating slowly. The plastids also increase in size, change in shape, and become able to synthesize large quantities of starch. The cells retain a ribosomal cytoplasm, rough ER membranes, and active dictyosomes for a long time. At the advanced stages of differentiation, the microtubules reappear in the cells even when the plant remains under colchicine treatment. When mature, the P-GMC and P-SM are quite similar to the guard cells and possess considerably thickened periclinal walls, numerous mitochondria, and small vacuoles, while the nucleus, the plastids, and the cytoplasm occupy significant parts of the cell volume. In the epidermis displaying open stomata in light, significant K⁺ quantities are detectable in guard cells and P-GMC or P-SM, while they are almost absent from their surrounding cells. When the stomata close in darkness, K⁺ is accumulated primarily in the subsidiary or typical epidermal cells surrounding these idioblasts and only minimally inside them. Besides, the P-GMC and P-SM, like the guard cells, retain the starch for a long time and build up considerable starch quantities from exogenously supplied sugars.Abbreviations P-GMC persistent guard cell mother cell - PSM persistent stomatal meristemoid - ER endoplasmic reticulum     

Reproduction and continuity of chloroplasts in spermatophytes

Without the continuity of chloroplasts there would be no higher life. Chloroplast reproduction and continuity can be studied in the guard cells of stomata, utilizing the result of reproduction, viz., the number of chloroplasts. An annotated list of such numbers from 261 families of spermatophytes is provided. For each family and many subfamilies or tribes are given the numbers of genera and species investigated as well as the ranges and medians of 1909 generic and 6161 specific chloroplast numbers, predominantly from my own countings. The driving forces behind the reproduction and continuity of chloroplasts are reviewed and discussed in the light of some figures of the list and other evidence. The results support the hypothesis that nuclear DNA replication paves the way for chloroplast reproduction and that the nuclear DNA amount is instrumental in ensuring the continuity of chloroplasts throughout meristematic cell successions.     

Developmental changes in guard cell wall structure and pectin composition in the moss Funaria: implications for function and evolution of stomata

Background and Aims

In seed plants, the ability of guard cell walls to move is imparted by pectins. Arabinan rhamnogalacturonan I (RG1) pectins confer flexibility while unesterified homogalacturonan (HG) pectins impart rigidity. Recognized as the first extant plants with stomata, mosses are key to understanding guard cell function and evolution. Moss stomata open and close for only a short period during capsule expansion. This study examines the ultrastructure and pectin composition of guard cell walls during development in Funaria hygrometrica and relates these features to the limited movement of stomata.

Methods

Developing stomata were examined and immunogold-labelled in transmission electron microscopy using monoclonal antibodies to five pectin epitopes: LM19 (unesterified HG), LM20 (esterified HG), LM5 (galactan RG1), LM6 (arabinan RG1) and LM13 (linear arabinan RG1). Labels for pectin type were quantitated and compared across walls and stages on replicated, independent samples.

Key Results

Walls were four times thinner before pore formation than in mature stomata. When stomata opened and closed, guard cell walls were thin and pectinaceous before the striated internal and thickest layer was deposited. Unesterified HG localized strongly in early layers but weakly in the thick internal layer. Labelling was weak for esterified HG, absent for galactan RG1 and strong for arabinan RG1. Linear arabinan RG1 is the only pectin that exclusively labelled guard cell walls. Pectin content decreased but the proportion of HG to arabinans changed only slightly.

Conclusions

This is the first study to demonstrate changes in pectin composition during stomatal development in any plant. Movement of Funaria stomata coincides with capsule expansion before layering of guard cell walls is complete. Changes in wall architecture coupled with a decrease in total pectin may be responsible for the inability of mature stomata to move. Specialization of guard cells in mosses involves the addition of linear arabinans.     

Functional Stomata in a Variegated Leaf Chimera of Pelargonium zonale L. without Guard Cell Chloroplasts

Fluorescence microscopy indicated that chlorophyll was absentfrom epidermal and guard cells overlying all white areas andgreen areas (of certain leaves) in variegated leaves of Pelargoniumzonale, cv. Chelsea Gem. Stomata with chlorophyll-free guardcells, in general, responded normally to light and CO₂ as gaugedby direct measurements of stomatal aperture and by transpirationalwater loss studies, although stomata from white regions of variegatedleaves were more reluctant to open than stomata from green regionsof the leaves. Thus, functional stomata without guard cell chloroplastshave been discovered in another genus, namely Pelargonium, besidesthat originally discovered in Paphiopedilum. When stomata withchlorophyll-free guard cells opened, K⁺ accumulated in the guardcells. This indicates that chloroplasts are not essential forthe normal functioning of stomata and that the energy sourcefor driving stomatal movements can come from sources other thanphotophosphorylation. Key words: Guard cell chloroplasts, Leaf chimera, Pelargonium, Stomata     

Stomatal Responses to Flooding of the Intercellular Air Spaces Suggest a Vapor-Phase Signal Between the Mesophyll and the Guard Cells

Flooding the intercellular air spaces of leaves with water was shown to cause rapid closure of stomata in Tradescantia pallida, Lactuca serriola, Helianthus annuus, and Oenothera caespitosa. The response occurred when water was injected into the intercellular spaces, vacuum infiltrated into the intercellular spaces, or forced into the intercellular spaces by pressurizing the xylem. Injecting 50 mm KCl or silicone oil into the intercellular spaces also caused stomata to close, but the response was slower than with distilled water. Epidermis-mesophyll grafts for T. pallida were created by placing the epidermis of one leaf onto the exposed mesophyll of another leaf. Stomata in these grafts opened under light but closed rapidly when water was allowed to wick between epidermis and the mesophyll. When epidermis-mesophyll grafts were constructed with a thin hydrophobic filter between the mesophyll and epidermis stomata responded normally to light and CO₂. These data, when taken together, suggest that the effect of water on stomata is caused partly by dilution of K⁺ in the guard cell and partly by the existence of a vapor-phase signal that originates in the mesophyll and causes stomata to open in the light.Stomatal responses to the environment have been studied in leaves for well over 100 years. More recently, the mechanisms for these responses have been investigated using isolated epidermes or isolated guard cell protoplasts. Despite the combination of these two approaches, the mechanisms by which stomata respond to environmental signals are not well understood. Since stomata control CO₂ uptake and water loss from leaves, the responses of stomata to environmental factors are important determinants of terrestrial productivity and water use. It is therefore critical that we understand the mechanisms by which stomata respond to the environment if we are to accurately predict the effects of future climates on productivity and water cycles (Randall et al., 1996).There are two assumptions about stomata that are implicit in much of the recent literature: (1) that stomatal responses result from sensory mechanisms that reside within the guard cells, and (2) that stomata in isolated epidermes respond similarly to those in a leaf. The exception to this generalization is the stomatal response to humidity, which has been suggested to be the result of changes in guard cell water potential (Dewar, 1995, 2002) or of signaling from other cells in the leaf to the guard cells (Buckley et al., 2003). The assumption that guard cells directly sense CO₂ and light is largely based on data from isolated epidermes that show effects of light and CO₂ on stomatal apertures. As pointed out by Mott (2009), however, stomatal responses to light and CO₂ in isolated epidermes are generally much different from those observed in leaves; e.g. responses in isolated epidermes are generally smaller than those in leaves, opening in response to light is slower, and closing in darkness is rarely observed. These observations were used to suggest that the mesophyll is somehow involved in stomatal responses to red light and CO₂. This idea is supported by several recent studies that suggest that guard cells do not respond directly to red light. In the first of these studies it was shown that guard cells in an intact leaf do not show hyperpolarization of the plasma membrane in response to red light if the red light is applied to only the guard cell (Roelfsema et al., 2002). In contrast, blue light applied only to the guard cell does cause hyperpolarization, and red light does cause hyperpolarization if applied to the guard cell and the underlying mesophyll. The second study showed that stomata in albino areas of a leaf do not respond to red light, although they contain chloroplasts and do respond to blue light (Roelfsema et al., 2006). Finally, a third study has shown that isolated epidermes are much more sensitive to light and CO₂ when placed in close contact with an exposed mesophyll from a leaf from the same or a different species (Mott et al., 2008). These epidermis-mesophyll grafts showed stomatal responses to light and CO₂ that were indistinguishable from those in an intact leaf—a sharp contrast to the behavior of stomata in isolated epidermes that are floating on buffer solutions. In that study, illumination of a single stoma in a leaf using a small-diameter fiber optic did not produce stomatal opening, but opening did occur if several stomata and the underlying mesophyll were illuminated. Furthermore, this treatment actually caused opening of adjacent, but unilluminated, stomata (Mott et al., 2008).In constructing the epidermis-mesophyll grafts in the study described above (Mott et al., 2008), it was noticed that functional grafts could be produced only if both the mesophyll and the epidermis were blotted completely dry of any free water before placing them together. Although the tissues were apparently still fully hydrated, there was very little free water present (i.e. water not contained within the walls of the leaf cells), and both the mesophyll and epidermis felt and looked dry prior to assembly. In addition, even when free water was blotted away initially, stomata did not open in grafts that ended up with visible water on the epidermis or mesophyll that was caused by condensation during the experiment. These observations suggest that the presence of free water somehow prevented the stomata in the grafts from opening. Assuming that the mechanisms operating in the grafts were similar to those in an intact leaf, this result also suggests that free water may have an effect on stomata in leaves as well. In addition, it seems possible that the effect of free water on stomata could be related to the disruption of the signal from the mesophyll that was proposed in an earlier study (Mott et al., 2008). We hypothesize that disruption of this signal could be caused by (1) dilution of some solute that is necessary for opening (such as K⁺) in the guard cell walls, (2) dilution of an apoplastic, liquid-phase opening signal from the mesophyll to the guard cells, and (3) blockage of a vapor-phase opening signal from the mesophyll to the guard cells. This study was initiated to test these three hypotheses by examining the effect of free water and other liquids on stomatal functioning.     

Stomatal differentiation and abnormal stomata in hornworts

This light and electron microscope study reveals considerable uniformity in hornwort stomata morphology and density in contrast to common spatial and developmental abnormalities in tracheophytes and mosses. Stomata arise from a median longitudinal division of sporophyte epidermal cells morphologically indistinguishable from their neighbours apart from the retention of a single chloroplast whilst those in the other epidermal cells fragment. Chloroplast division and side-by-side repositioning of the two daughter chloroplasts determines the division plane in the stomatal mother cell. The nascent guard cells contain giant, starch-filled chloroplasts which subsequently divide and, post aperture opening, regain their spherical shape. Accumulation of wall material over the guard cells and of wax rodlets lining the pores follows opening. While the majority of stomata are bilaterally symmetrical those lining the dehiscence furrows display dextral and sinistral asymmetry due to differential expansion of the adjacent epidermal cells.

The ubiquity of open stomata suggests that these never close with the maturational wall changes rendering movement extremely unlikely. These structural limitations, a liquid-filled stage in the ontogeny of the intercellular spaces, and spores already at the tetrad stage when stomata open, suggest that their primary role is facilitating sporophyte desiccation leading to dehiscence and spore dispersal rather than gaseous exchange. Stomata ontogeny and very low densities, like those in Devonian fossils, suggest either ancient origins at a time when atmospheric carbon dioxide levels were much greater than today or a function other than gaseous exchange regulation. We found no evidence for stomatal homology between hornworts, mosses and tracheophytes.     

Morphological patterns in Petunia hybrida plants regenerated from tissue cultures and differing by their ploidy

Summary Quantitative variation in seven morphological characteristics (leaf length and width, leaf length/ width ratio, flower, petal and stomata length, and number of chloroplasts in guard cells) were studied in Petunia hybrida plants regenerated from anther tissue culture and belonging to four different classes of ploidy (2n, 2n–3n, 3n–2n, 4n–8n). Results showed that leaf size is not a good characteristic for discriminating between plants of different ploidy — flower and stomata characteristics being more adequate for this purpose. After applying stepwise discriminant analysis the association chloroplast number — leaf length/width ratio — petal length was verified to be more appropriate for the discrimination of ploidy classes.     

Light quality and osmoregulation in vicia guard cells : evidence for involvement of three metabolic pathways

Osmoregulation in opening stomata of epidermal peels from Vicia faba L. leaves was investigated under a variety of experimental conditions. The K⁺ content of stomatal guard cells and the starch content of guard cell chloroplasts were examined with cobaltinitrite and iodine-potassium iodide stains, respectively; stomatal apertures were measured microscopically. Red light (50 micromoles per square meter per second) irradiation caused a net increase of 3.1 micrometers in aperture and a decrease of −0.4 megapascals in guard cell osmotic potential over a 5 hour incubation, but histochemical observations showed no increase in guard cell K⁺ content or starch degradation in guard cell chloroplasts. At 10 micromoles per square meter per second, blue light caused a net 6.8 micrometer increase in aperture over 5 hours and there was a substantial decrease in starch content of chloroplasts but no increase in guard cell K⁺ content. At 25 micromoles per square meter per second of blue light, apertures increased faster (net gain of 5.7 micrometers after 1 hour) and starch content decreased. About 80% of guard cells had a higher K⁺ content after 1 hour of incubation but that fraction decreased to 10% after 5 hours. In the absence of KCl in the incubation medium, stomata opened slowly in response to 25 micomoles per square meter per second of blue light, without any K⁺ gain or starch loss. In dual beam experiments, stomata irradiated with 50 micomoles per square meter per second of red light for 3 hours opened without detectable starch loss or K⁺ gain; addition of 25 micomoles per square meter per second of blue light caused a further net gain of 4.4 micometers in aperture accompanied by substantial K⁺ uptake and starch loss. Comparison of K⁺ content in guard cells of opened stomata in epidermal peels with those induced to open in leaf discs showed a substantially higher K⁺ content in the intact tissue than in isolated peels. These results are not consistent with K⁺ (and its counterions) as the universal osmoticum in guard cells of open stomata under all conditions; rather, the data point to sugars arising from photosynthesis and from starch degradation as additional osmotica. Biochemical confirmation of these findings would indicate that osmoregulation during stomatal opening is the result of three key metabolic processes: ion transport, photosynthesis, and sugar metabolism.     

Chlorophyll a Fluorescence Transients in Mesophyll and Guard Cells : MODULATION OF GUARD CELL PHOTOPHOSPHORYLATION BY CO(2)

Chlorophyll fluorescence transients from mesophyll and guard cell chloroplasts of variegated leaves from Chlorophytum comosum were compared using high resolution fluorescence spectroscopy. Like their mesophyll counterparts, guard cell chloroplasts showed the OPS fluorescence transient indicating the operation of the linear electron transport and the possible generation of NADPH in these organelles. They also showed a slow fluorescence yield decrease, equivalent to the MT transition in mesophyll, suggesting the formation of the high energy state and photophosphorylation. Unlike the mesophyll chloroplasts, the fluorescence from guard cell chloroplasts lacked the increment of the SM transition, indicating that the two types of chloroplasts have some metabolic differences. The presence of CO₂ (supplied as bicarbonate, pH 6.7) specifically inhibited the MT-equivalent transition while its absence accelerated it. These observations constitute the first specific evidence of a guard cell chloroplast response to CO₂. Control of photosynthetic ATP levels in the guard cell cytoplasm by CO₂ may provide a mechanism regulating the availability of high energy equivalents at the guard cell plasmalemma, thus affecting stomatal opening.     

Characterization of the activity of a plastid-targeted green fluorescent protein in Arabidopsis.

In Arabidopsis thaliana the PALE CRESS (PAC) gene product is required for both chloroplast and cell differentiation. Transgenic Arabidopsis plants expressing a translational fusion of the N-terminal part of the PAC protein harboring the complete plastid-targeting sequence and the green fluorescent protein (GFP) exhibit high GFP fluorescence. Detailed analyses based on confocal imaging of various tissues and cell types revealed that the PAC-GFP fusion protein accumulates in chloroplasts of mature stomatal guard cells. The GFP fluorescence within the guard cell chloroplasts is not evenly distributed and appears to be concentrated in suborganellar regions. GFP localization studies demonstrate that thin tubular projections emanating from chloroplasts and etioplasts often connect the organelles with each other. Furthermore, imaging of non-green and etiolated tissue further revealed that GFP fluorescence is present in proplastids, etioplasts, chromoplasts, and amyloplasts. Even photobleaching of carotenoid-free plastids does not affect PAC-GFP accumulation in the organelles of the guard cells indicating that the protein translocation machinery is functional in all types of plastids. The specific accumulation of GFP in guard cell chloroplasts, their tubular connections, the translocation of the precursor polypeptide into the different types of organelles, as well as the use of a plastid-targeted GFP protein as a versatile marker is discussed in the context of previously described observations.     

Polarity and growth of caulonema tip cells of the moss Funaria hygrometrica

In the caulonema tip cells of Funaria hygrometrica, chloroplasts, mitochondria, and dictyosomes have differences in structure which are determined by cell polarity. In contrast to the slowly growing chloronema tip cells the apical cell of the caulonema contains a tip body. Colchicine stops tip growth; it causes the formation of subapical cell protrusions, redistribution of the plastids, and a loss of their polar differentiation. Cytochalasin B inhibits growth and affects the position of cell organelles. After treatment with ionophore A23 187, growth is slower and shorter and wider cells are formed. D₂O causes a transient reversion of organelle distribution but premitotic nuclei are not dislocated. In some tip cells the reversion of polarity persists; they continue to grow with a new tip at their base. During centrifugation, colchicine has only a slight influence on the stability of organelle anchorage. The former polar organization of most cells is restored within a few hours after centrifugation, and the cells resume normal growth. In premitotic cells the nucleus and other organelles cannot be retransported, they often continue to grow with reversed polarity. Colchicine retards the redistribution of organelles generally and increases the number of cells that form a basal outgrowth. The interrelationship between the peripheral cytoplasm and the nucleus and the role of microtubules in maintaining and reestablishing cell polarity are discussed.Abbreviations DMSO dimethylsulfoxide - CB cytochalasin B Dedicated to Prof. Dr. A. Pirson on the occasion of his 70. birthday     

Tubular actin filaments in tobacco guard cells

The dynamic remodeling of actin filaments in guard cells functions in stomatal movement regulation. In our previous study, we found that the stochastic dynamics of guard cell actin filaments play a role in chloroplast movement during stomatal movement. In our present study, we further found that tubular actin filaments were present in tobacco guard cells that express GFP-mouse talin; approximately 2.3 tubular structures per cell with a diameter and height in the range of 1–3 µm and 3–5 µm, respectively. Most of the tubular structures were found to be localized in the cytoplasm near the inner walls of the guard cells. Moreover, the tubular actin filaments altered their localization slowly in the guard cells of static stoma, but showed obvious remodeling, such as breakdown and re-formation, in moving guard cells. Tubular actin filaments were further found to be colocalized with the chloroplasts in guard cells, but their roles in stomatal movement regulation requires further investigation.Key words: actin dynamics, tubular actin filaments, chloroplast, guard cell, stomatal movementStomatal movement responses to surrounding environment are mediated by guard cell signaling.^1,2 Actin filaments within guard cells are dynamic cytoarchitectures and function in stomatal development and movement.³ Arrays of actin filaments in guard cells that are dependent on different stomatal apertures have also been reported in references ^4–7. For example, the random or longitudinal orientations of actin filaments in closed stomata change to a radial orientation or ring-like array after stomata opening.^5,6,8 The reorganization of the actin architecture during stomatal movement depends on the depolymerization and repolymerization of actin filaments in guard cells. In contrast to the traditional treadmill model of actin dynamic mechanisms, stochastic dynamics of actin have been revealed in plant cells, such as in the epidermal cells of hypocotyl and root, the pavement cells of Arabidopsis cotyledons, and the guard cells of tobacco (Nicotiana tabacum).^9–11 In this alternative system, the short actin fragments generated from severed long filaments can link with each other to form longer filaments by end-joining activity. The actin regulatory proteins, Arp2/3 complex, capping protein and actin depolymerizing factor (ADF)/cofilin, may also be involved in the stochastic dynamics of actin filaments.^12,13Using tobacco GFP-mouse talin expression lines, we have previously analyzed the stochastic dynamics of guard cell actin filaments and their roles in chloroplast displacement during stomatal movement.^6,11 We found from these analyses that another arrangement of actin filaments, i.e., tubular actin filaments, exists in the guard cells of these tobacco lines. We first found the circle-like actin filaments in 82% of the guard cells (counting 320 cells) in tobacco expressing GFPmouse talin when analyzing a single optical section (Fig. 1A). In a previous study of BY-2 cells expressing GFP-Lifeact labeled actin filaments, Smertenko et al. found similar structures, i.e., quoit-like structures or acquosomes in all of the plant tissues examined except growing root hairs.¹⁰ However, in our present analysis of serial sections, we determined that the circle-like actin filaments in the tobacco guard cells were long tubes (Fig. 1A), as the lengths (about 3–5 µm) of these structures were greater than their diameter (about 1–3 µm). Hence, we denoted these structures as tubular actin filaments to distinguish them from the circular conformations of actin filaments observed previously in other plant cell tissues.^10,14–19 About 2.3 of these tubular actin filaments were found per guard cell, which is less than the number of acquosomes reported in BY-2 cells (about 6.7 per cell).¹⁰ Analysis of serial optical sections at the z-axis revealed that the tubular actin filaments localize in the cytoplasm near the inner walls of the guard cells (Fig. 1B), which is similar to the distribution of chloroplasts in guard cells.¹¹ Longitudinal sections further revealed a colocalization of tubular actin filaments and chloroplasts (Fig. 1B).Open in a separate windowFigure 1Tubular actin filaments in the guard cells of a tobacco (Nicotiana tabacum) line expressing GFP-mouse talin. (A) Optical-sections (interval, 1.5 µm) of guard cells in a moving stoma showing tubular actin filaments (arrow heads). Frames (a1) and (a2) are cross sections of 1.5-µm-picture through the yellow and red lines, respectively, revealing the cross section of the circle structures are parallel lines (arrows). (B) Optical-sections of a stoma from the outer periclinal walls to the inner walls of the guard cells (interval, 1 µm). The tubular actin filaments (arrow heads) are localized in the cytoplasm near to the inner periclinal walls of guard cells. Frame (b1) is the guard cell on the right of the frame “4 µm”; (b2) is the cross section of b1 through the red line; and (b3) is a higher magnification image of the area encompassed by the white square in b2. Arrows indicate the colocalization between the tubular actin filaments and the chloroplast (indicated using a red pseudocolor). (C) Time-series imaging showing the movement of tubular actin filaments in the guard cells of static stomata. Frame (c1) comprises three images colored red (0 S), green (40 S) and blue (80 S), that are merged in a single frame to show the translocation of the tubular actin filaments (arrows). (D) Time-series images of the opening stomata showing the breakdown (arrows) and re-formation (arrowheads) of the tubular actin filaments. All images were captured using a Zeiss LSM 510 META confocal laser scanning microscope, as described by Wang et al.¹¹ Bars, 10 µm.We performed time-lapse imaging and found that the translocation of tubular actin filaments is slow in static stomata in which the distance between two tubular actin filaments typically increased from 2.22 to 2.50 µm after 80 sec (Fig. 1C). In moving stomata, however, the tubular actin filaments showed an obvious dynamic reorganization whereby they could be processed into short fragments and also reemerged after they had disintegrated (Fig. 1D). These results indicate that tubular actin filaments have stochastic dynamics that are similar to the long actin filaments of guard cells.¹¹ In our previous study, we found that the stochastic dynamics of actin filaments correlate with light-induced chloroplast movement in guard cells.¹¹ However, whether the dynamics of the tubular actin filaments are also involved in chloroplast movement during stomatal movement remains to be investigated. In cultured mesophyll cells which had been mechanically isolated from Zinnia elegans, Wilsen et al. previously found a close association between fully closed actin rings and chloroplasts.¹⁸ These authors further found that the average percentage of cells with free actin rings increased at the initial culture stage, and then decreased, which indicates that the formation of actin rings might be a response of the actin cytoskeleton to cellular stress or disturbance.¹⁸ The turgor pressure of guard cells is the fundamental basis of stomatal movement leading to changes in the shape, volume, wall structure, and membrane surface of guard cells.^20–24 We speculate from our current data that there is a relationship between tubular actin filaments and the shape changes of guard cells during stomatal movement.     

Responses of Photosynthetic Electron Transport in Stomatal Guard Cells and Mesophyll Cells in Intact Leaves to Light, CO2, and Humidity

High-resolution images of the chlorophyll fluorescence parameter Fq'/Fm' from attached leaves of commelina (Commelina communis) and tradescantia (Tradescantia albiflora) were used to compare the responses of photosynthetic electron transport in stomatal guard cell chloroplasts and underlying mesophyll cells to key environmental variables. Fq'/Fm' estimates the quantum efficiency of photosystem II photochemistry and provides a relative measure of the quantum efficiency of non-cyclic photosynthetic electron transport. Over a range of light intensities, values of Fq'/Fm' were 20% to 30% lower in guard cell chloroplasts than in mesophyll cells, and there was a close linear relationship between the values for the two cell types. The responses of Fq'/Fm' of guard and mesophyll cells to changes of CO2 and O2 concentration were very similar. There were similar reductions of Fq'/Fm' of guard and mesophyll cells over a wide range of CO2 concentrations when the ambient oxygen concentration was decreased from 21% to 2%, suggesting that both cell types have similar proportions of photosynthetic electron transport used by Rubisco activity. When stomata closed after a pulse of dry air, Fq'/Fm' of both guard cell and mesophyll showed the same response; with a marked decline when ambient CO2 was low, but no change when ambient CO2 was high. This indicates that photosynthetic electron transport in guard cell chloroplasts responds to internal, not ambient, CO2 concentration.     

Substance P-like immunoreactivity in the trigeminal ganglion

Summary The trigeminal ganglion of rat and guinea pig was studied for the presence of immunoreactive substance-P using fluorescence, light and electronmicroscopy. In untreated animals substance P containing cells, with a diameter of 15 to 50 m, were distributed throughout the ganglion and comprised 10–30% of all ganglion cells. Colchicine, injected intraventricularily to inhibit intra-axonal transport, had no effect on the number of substance P cells; but when the drug was injected directly into the posterior root of the ganglion, the proprotion of these cells increased to as much as 50%. In the electron microscope, immunoreactive substance-P was confined to ganglion cells classified as B type according to the arrangement of subcellular organelles, and to unmyelinated nerve fibers. Subcellularily the immunoreactivity appeared in cytoplasmic vesicles, as well as dispersed in the nerve fibers and the perikarya of neurons. The great number of substance P immunoreactive ganglion cells suggests that they do not comprise a well defined subpopulation of the B-cells.However, the immunoreactivity was restricted to a distinct ultrastructural type of neurons with unmyelinated nerve fibers, suggesting that they also may share some distinct functions.     

Differentiation of haploid and dihaploid rape plants at the cytological and morphological levels

Some cytological and morphological features of haploid and dihaploid winter rapó plants obtained via the anther cultivation approach have been studied. It was shown that in haploid plants the number of chloroplasts in stomatal guard cells, the size of the stomatal guard cells themselves were much smaller, and the number of stomata per square unit was greater than in doubled haploids and diploids. Haploids were also characterized by smaller sizes of petals and anthers and, in general, a smaller flower as compared to dihapliods and diploids.     

Visualizing Changes in Cytosolic-Free Ca2+ during the Response of Stomatal Guard Cells to Abscisic Acid

In this paper, we report the results of a detailed investigation into abscisic acid (ABA)[mdash]stimulated elevations of guard cell cytosolic-free Ca2+ ([Ca2+]cyt). Fluorescence ratio photometry and ratio imaging techniques were used to investigate this phenomenon. Guard cells of open and closed (opened to 10 to 12 [mu]m before treatment with ABA) stomata were microinjected with the fluorescent Ca2+ indicator Indo-1. Resting [Ca2+]cyt ranged from 50 to 350 nM. ABA (100 nM) stimulated an increase in [Ca2+]cyt in 68 and 81% of guard cells microinjected in the open and closed configuration, respectively. All stomata were observed to close in response to ABA. Increases ranged from 100 to 750 nM above the resting concentration and were arbitrarily grouped into five "classes." ABA-stimulated increases in [Ca2+]cyt were not uniformly distributed across the cytosol of guard cells. Rapid transient increases in [Ca2+]cyt were also observed in the guard cells of stomata microinjected in the closed configuration. We concluded that the ABA-induced turgor loss in guard cells is a Ca2+-dependent process.