Direct Measurements of Turgor Pressure Potentials of Guard Cells: II. THE MECHANICAL ADVANTAGE OF SUBSIDIARY CELLS, THE SPANNUNQSPHASE, AND THE OPTIMUM LEAF WATER DEFICIT

Evidence of the mechanical advantage of subsidiary cells wasobtained by simultaneous measurements of turgor pressure potentialsin adjacent subsidiary and guard cells using injection circuitswith two separate needles. In Tradescantia virginiana the mechanicaladvantage approaches two. Using the same technique evidencewas obtained that the Spannungsphase is, in the first place,a turgor relations phenomenon due to the mechanical advantageof epidermal or subsidiary cells. In addition, the evidenceindicated that the elastic properties of guard cell walls mayundergo changes during the Spannungsphase when potassium iontransport commences. During these measurements it was confirmedthat the optimum leaf water deficit for maximum stomatal openingoccurs when the epidermal turgor is near zero. Under these conditionsthe width of the stomatal pore is a function of the turgor pressureof the guard cells, since at zero turgor of the subsidiary cellstheir mechanical advantage has disappeared.     

A light and electron microscopy study of the epidermis of Paphiopedilum spp. with emphasis on stomatal ultrastructure

Abstract Light and fluorescence microscopy studies indicated that chlorophyll was absent from the guard cells of the lady slipper orchids, Paphiopedilum insigne (Wall.) Pfitz, P. insigne (hybrid), P. venustum (Wall.) Pfitz and P. harrisseanum Hort. In the guard cells of P. aureum hyeanum Hort., however, very slight red fluorescence suggested that chlorophyll and hence chloroplasts were present. Ultrastructural studies of the lower epidermis of P. insigne (hybrid) confirmed the absence of chloroplasts in guard and epidermal cells although plastids of an unusual structure were found in these cells. In fully developed epidermal cells the plastids contained large amounts of a fibrous, possibly proteinaceous substance, spherical, lightly staining vesicles and an electron-dense material located in reticulate and non-reticulate regions. Additionally, latticed crystalline inclusions and plasto-globuli were occasionally observed in the epidermal cell plastids. In plastids of fully developed guard cells the fibrous material, starch and plastoglobuli were present. From the earliest stages of development of the epidermal tissue starch was present in both epidermal cell and guard cell plastids. At maturity, however, starch had accumulated to greater levels in the guard cell plastids and had entirely disappeared in the epidermal cell plastids. In differentiating epidermal tissue, plasmodesmata were found between neighbouring epidermal cells and between guard and epidermal cells. At maturity, plasmodesmata between guard and epidermal cells were not observed. Mitochondria were particularly abundant in guard cells. Large oil drops developed in guard and epidermal cells, being especially abundant in the former at maturity. Our results confirm the observations of Nelson & Mayo (1975) that certain lady slipper orchids possess functional stomata the guard cells of which do not contain chloroplasts.     

狭基巢蕨叶表皮的结构和气孔器发育的观察

狭基巢蕨Ｎｅｏｔｏｐｔｅｒｉｓａｎｔｒｏｐｈｙｏｉｄｅｓ（Ｃｈｒｉｓｔ）Ｃｈｉｎｇ叶片的上表皮无气孔器,仅具表皮细胞,下表皮由表皮细胞和气孔器组成,气孔指数为２．５。上下表皮细胞和气孔器的细胞中均含有叶绿体。每个气孔器由２个肾形的保卫细胞和２～６个副卫细胞组成,其中以３个和４个副卫细胞的占绝大多数（３细胞的占４５．１％,４细胞的占４３．５％）。从发育上看,气孔器原始细胞进行２次分裂,产生２个保卫细胞和１个同源的副卫细胞。气孔器的发育过程大体可分为４个时期：（１）气孔器原始细胞的分化和分裂期;（２）保卫细胞母细胞成熟期;（３）保卫细胞母细胞分裂和气孔器幼期;（４）气孔器成熟期。狭基巢蕨的气孔器属于中周型     

Stomatal Characteristics at Different Ploidy Levels inCoffeaL.

Stomatal frequency, epidermal cell frequency, stomatal guardcell length and stomatal index were examined at different ploidylevels inCoffea. In general, stomatal and epidermal cell frequencyper unit leaf area decreased while stomatal guard cell lengthincreased with an increase in ploidy. The reduction in stomatalfrequency at higher ploidy levels was mainly a result of largerepidermal cells. In the case ofC. canephora(cultivar S.274)a significant reduction in stomatal frequency was noticed fromdiploid to tetraploid level which was due to both larger epidermalcell size and less stomatal differentiation at the tetraploidlevel. Besides the effect of ploidy on stomatal frequency andguard cell length, genotypic differences in stomatal frequencyand stomatal guard cell length were also observed among cultivarsof the same ploidy level. Although variation in stomatal frequencyamong cultivars was found to be associated with the differencein stomatal to epidermal cell ratio, variation in guard celllength was attributed to differential genetic architecture.In the present study a highly significant positive correlation(r=0.82) between stomatal and epidermal cell frequency and highnegative correlations between stomatal frequency and guard celllength (r=-0.91) and epidermal cell frequency and stomatal guardcell length (r=-0.93) were obtained. The study also indicatedthat stomatal frequency can be predicted with 83 and 87% accuracy,respectively, by measuring stomatal guard cell length in coffee.Copyright1997 Annals of Botany Company Coffea; ploidy level; stomatal characteristics     

Avoidance of sodium accumulation by the stomatal guard cells of the halophyte Aster tripolium

X-ray microanalysis has revealed that the sodium content ofthe stomatal guard cells of Aster tripolium remains much lowerthan that of other leaf cells when the plants are grown at highsalinity. Large amounts of sodium did, in contrast, accumulatein epidermal and subsidiary cells, and particularly in the mesophylltissue, suggesting that a mechanism exists to limit the extentof its entry into guard cells. Even in plants grown at highsalinity, the content of potassium was much higher than thatof sodium in the guard cells, consistent with the view thatthis is a major ion involved in determining stomatal movementsin this halophyte. Determinations were also made for the nonhalophyte Commelinacommunis, and it was found that the guard cells accumulatedlarge amounts of sodium when it was presented to them as analternative to potassium. It is suggested that the acquisition by the guard cells of someability to restrict the intake of sodium ions may be an importantcomponent of sodium-driven regulation of transpiration, andhence of salinity tolerance, in A. tripolium. Key words: Salinity tolerance, sodium, potassium, stomata, Aster tripolium     

Separation and Purification of Protoplast Types from Commelina communis L. Leaf Epidermis

Guard cell and epidermal/subsidiary cell protoplasts obtainedby enzymic digestion of peeled Commelina communis leaf epidermiswere separated and purified by discontinuous density gradientccntrifugation with media based on Percoll (Pharmacia Fine ChemicalsAB, Uppsala, Sweden). The cell types were recovered over 99.9%pure at yields exceeding 50% efficiency, and mesophyll contaminationcould be virtually eliminated when desired. Osmotic characteristicsof the protoplast types were evaluated and compared to in vivovalues, and the viability of the protoplasts, assessed usinga range of criteria, was found to be high. Purified Commelinaguard cell protoplasts were able to evolve O₂ when illuminated,and this was substantially reduced in the presence of the inhibitorDCMU, indicating that they possess photosystem II activity.Specific advantages of this method of protoplast purification,and the potential uses of separate suspensions of guard cellsand epidermal/subsidiary cells in experiments on stomatal physiologyare discussed. Key words: Commelina communis, Protoplasts, Epidermis     

Change in Levels of Starch and Sugars in Epidermis of Commelina benghalensis during Fusicoccin Stimulated Stomatal Opening

The concentrations of malate, starch and sugars were determinedin presonicated epidermal strips of Commelina benghalensis.During opening, the starch content of epidermis decreased whilethe level of sugars or malate increased. Fusicoccin (FC) stimulatedstomatal opening and elevated the levels of malate and sugars.However, the contribution from sugars was nearly 50% of theosmotic effect of malate and it increased to more than 60% inthe presence of FC. We conclude that FC stimulates stomatalopening by enhancing not only potassium influx into guard cellsbut also hydrolysis of starch into sugars (and malate). Significantcorrelations were noticed between the width of stomatal apertureand epidermal starch (negative), malate and sugars (both positive).The negative relationship between starch and malate or sugarswithin epidermis indicated that starch hydrolysis lead to formationof sugars as well as malate. Starch—sugar interconversioncan therefore play a significant role in modulating the solutepotential of guard cells. Key words: Commelina benghalensis, Stomatal opening, Fusicoccin, Epidermal starch and sugars     

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     

Direct Measurements of Turgor Pressure Potentials of Guard Cells, I.

Measurements were made of pressures applied in subsidiary andguard cells which caused closure and opening of stomatal pores.These pressures were lower than would be expected from plasmolyticallydetermined osmotic potentials of guard cell saps. The pressuresneeded in guard cells to open almost closed stomata were practicallythe same as those required to close open stomata when appliedin adjacent subsidiary cells. Completely closed stomata couldnot be opened by this technique. The implications for the understandingof the mechanism of guard cell deformation, the Spannungsphase,and the pressure potentials of guard cells are discussed.     

Stomatal movement and potassium transport in epidermal strips of Zea mays: The effect of CO2

Summary The correlation between stomatal action and potassium movement in the epidermis of Zea mays was examined in isolated epidermal strips floated on distilled water. Stomatal opening in the isolated epidermis is reversible in response to alternate periods of light or darkness, and is always correlated with a shift in the potassium content of the guard cells. K accumulates in guard cells during stomatal opening, and moves from the guard cells into the subsidiary cells during rapid stomatal closure. When epidermal strips are illuminated in normal air, as against CO₂-free air, the stomata do not open and there is a virtually complete depletion of K from the stomatal apparatus. In darkness CO₂-containing air inhibits stomatal opening and K accumulation in guard cells, but does not lead to a depletion of K from the stomata as observed in the light.     

Structure and Development of Stomata in Some Leptosporangiate Ferns

The structure and development of stomata are described for 17species of leptosporangiate ferns. In these species the maturestomata are anomocytic, diacytic, Pyrrosia(applied), tetracytic,suspended, or floating type. Stomata are present on both surfacesof floating as well as sub merged leaves of Azolla and Marsilea.In a few species twin stomata, arrested development, and persistentstomatal initials are present Floating stomata result from disintegrationof the anticlinal suspending wall in Pleopeltis, and by detachmentand displacement in Azolla pinnata. The development of stomatais haplocheilic, syndetocheilic, or syndetohaplocheilic. InCyathea spinulosa the guard cell nuclei divide amitoticallyand the resulting two daughter nuclei occupy the opposite polesof the guard cells     

The Comparative Effects of Blue and Red Light on the Stomata of Allium cepa L. and Xanthium pennsylvanicum

Stomatal responses to blue and red light were compared in leavesof Xanthium pennsylvanicum (which contain starch in their guardcells) and in onion leaves (which are devoid of starch). Bluelight was found to be more effective than red in opening stomatain both species. However, a significant difference in the ratiosof blue to red light required to produce equal stomatal openingwas found between Xanthium pennsylvanicum and onion. It is concludedthat blue light may promote stomatal opening by its effect onenzymes controlling the starch and soluble polysaccharide contentof guard cells.     

Changes in dye coupling of stomatal cells of Allium and Commelina demonstrated by microinjection of Lucifer yellow

Lucifer yellow has been microinjected into stomatal cells of Allium cepa L. epidermal slices and Commelina communis L. epidermal peels and the symplastic spread of dye to neighboring cells monitored by fluorescence microscopy. Dye does not move out of injected mature guard cells, nor does it spread into the guard cells when adjacent epidermal or subsidiary cells are injected. Dye does spread from injected subsidiary cells to other subsidiary cells. These results are consistent with the reported absence of plasmodesmata in the walls of mature guard cells. Microinjection was also used to ascertain when dye coupling ceases during stomatal differentiation in Allium. Dye rapidly moves into and out of guard mother cells and young guard cells. Hovewer, dye movement ceases midway through development as the guard cells begin to swell but well before a pore first opens. Since plasmodesmata are still present at this stage, the loss of symplastic transport may result from changes in these structures well in advance of their actual disappearance from the guard cell wall.Abbreviations DIC differential interference contrast - GMC guard mother cell - LY Lucifer yellow - Pd plasmodesmata You can observe a lot by watching Lawrence Berra, as quoted in Sports Illustrated, vol. 60 (No. 14), p. 94, 2 April 1984     

Tentoxin Suppresses Stomatal Opening by Inhibiting Photophosphorylation

Tentoxin and, to a lesser extent, dihydrotentoxin (both at 10mmol m^–3) reduce stomatal opening in epidermal stripsof Commelina communis in the light but not in darkness. Thiseffect was significantly greater in normal air than in CO₂-freeair. Fusicoccin overcame the tentoxin effect. However, tentoxindid not inhibit stomatal opening in the light in epidermal stripsof Paphiopedilum harrisianum, a species which lacks guard cellchloroplasts. It is concluded that tentoxin exerts its actionon stomata not by an ionophorous effect in the plasmalemma ofguard cells but by the inhibition of photophosphorylation intheir chloroplasts. The effects of DCMU and tentoxin on guardcells are discussed in terms of their effects on chloroplastsand the extent to which energy is supplied from this organelleduring stomatal opening in the light. The results indicate thatneither photophosphorylation nor non-cyclic electron transportin guard cell chloroplasts are essential for stomatal opening. Key words: Commelina, epidermal strips, Paphiopedilum, photophosphorylation, stomata, tentoxin     

Elevated carbon dioxide affects the patterning of subsidiary cells in Tradescantia stomatal complexes

The influence of elevated CO₂ concentration (670 ppm) on thestructure, distribution, and patterning of stomata in Tradescantialeaves was studied by making comparisons with plants grown atambient CO₂. Extra subsidiary cells, beyond the normal complementof four per stoma, were associated with nearly half the stomatalcomplexes on leaves grown in elevated CO₂. The extra cells sharedcharacteristics, such as pigmentation and expansion, with thetypical subsidiary cells. The position and shape of the extrasubsidiary cells in face view differed in the green and purplevarieties of Tradescantia. Substomatal cavities of complexeswith extra subsidiary cells appeared larger than those foundin control leaves. Stomatal frequency expressed on the basisof leaf area did not differ from the control. Stomatal frequencybased on cell counts (stomatal index) was greater in leavesgrown in CO₂-enriched air when all subsidiary cells were countedas part of the stomatal complex. This difference was eliminatedwhen subsidiary cells were included in the count of epidermalcells, thereby evaluating the frequency of guard cell pairs.The extra subsidiary cells were, therefore, recruited from theepidermal cell population during development. Stomatal frequencyin plants grown at elevated temperature (29 C) was not significantlydifferent from that of the control (24 C). The linear aggregationsof stomata were similar in plants grown in ambient and elevatedCO₂. Since enriched CO₂ had no effect on the structure or patterningof guard cells, but resulted in the formation of additionalsubsidiary cells, it is likely that separate and independentevents pattern the two cell types. Plants grown at enrichedCO₂ levels had significantly greater internode lengths, butleaf area and the time interval between the appearance of successiveleaves were similar to that of control plants. Porometric measurementsrevealed that stomatal conductance of plants grown under elevatedCO₂ was lower than that of control leaves and those grown atelevated temperature. Tradescantia was capable of regulatingstomatal conductance in response to elevated CO₂ without changingthe relative number of stomata present on the leaf. Key words: Elevated CO₂, stomata, subsidiary cells, patterning     

Action of growth regulators on the cotyledonary stomata ofCucumis sativus L.: Structure and ontogeny

Anomocytic stomata and stomata with single subsidiary cells are commonly observed Sometimes a stoma appears anisocytic. Double cytoplasmic connections between nearby stomata and division of guard cells with persistent or degenerating nuclei are seen in GA. One or more divisions of guard cells, displaced guard cells and single guard cells with or without pore are noticed in SUC. Formation of single guard cells is a common feature in TIBA. Paracytic stomata, one and a half stomata and persistent stomatal initials are seen in SUL. COUM seems to be not inhibitory inCucumis sativus. In COL stomata with unequal guard cells, unequal stomatal cells with thickening in between but without intervening pore, stoma with double pores, persistent stomatal initials which may be solitary or in groups with varying shapes and with one or two nuclei of different shapes are noticed. The growth regulators affect the frequency of stomata, epidermal cells; stomatal index; size of guard and epidermal cells.     

Structure,ontogeny and taxonomic significance of trichomes and stomata in some Capparidaceae

The present work embodies epidermal structure, structure and ontogeny of stomata in five genera embracing sixteen species of the Capparidaceae namely Cleome (8 species) Capparis (5 species), Cadaba (1 species), Crataeva (1 species) and Maerua (1 species). The epidermal cells are polygonal, isodiametric or elongated arranged irregularly, with evenly or unevenly thickened, sinuous, straight or arched anticlinal walls. Two main types of trichomes: glandular (four types) and eglandular (five types) are noticed. The stomatal types include cyclocytic, triacytic, staurocytic, tetracytic, anomocytic, anisocytic, paracytic and with a single subsidiary cell. The ontogeny of stomata with a single subsidiary cell is perigenous or mesoperigenous, of paracytic mesoperigenous or mesogenous, of anisocytic is mesoperigenous or mesogenous, while that of the other types is perigenous. Abnormalities observed are: single guard cell; aborted guard cells; complete or incomplete division of guard cells; contiguous stomata; giant stomata and cytoplasmic connections. The present observations do not support the separation of Cleomaceae from the Capparidaceae.     

Stomatal development and patterning in Arabidopsis leaves

The functional unit for gas exchange between plants and the atmosphere is the stomatal complex, an epidermal structure composed of two guard cells, which delimit a stomatal pore, and their subsidiary cells. In the present work, we define the basic structural unit formed in Arabidopsis thaliana during leaf development, the anisocytic stomatal complex. We perform a cell lineage analysis by transposon excision founding that at least a small percentage of stomatal complexes are unequivocally non-clonal. We also describe the three-dimensional pattern of stomata in the Arabidopsis leaf. In the epidermal plane, subsidiary cells of most stomatal complexes contact the subsidiary cells of immediately adjacent complexes. This minimal distance between stomatal complexes allows each stoma to be circled by a full complement of subsidiary cells, with which guard cells can exchange water and ions in order to open or to close the pore. In the radial plane, stomata (and their precursors, the meristemoids) are located at the junctions of several mesophyll cells. This meristemoid patterning may be a consequence of signals that operate along the radial axis of the leaf, which establish meristemoid differentiation precisely at these places. Since stomatal development is basipetal, these radially propagated signals may be transmitted in the axial direction, thus guiding stomatal development through the basal end of the leaf.     

Epidermal and Guard Cell Interactions on Stomatal Aperture in Epidermal Strips and Intact Leaves

Despite the observation first made by von Mohl in 1856, thatepidermal cells greatly influence stomatal aperture, subsequentstudies have failed to pay adequate attention to epidermal cellviability or to quantify the degree of its influence on aperturein epidermal strips and leaf sections. Using Vicia faba stripsand leaf sections we found the following: (i) a non-linear relationshipbetween aperture and guard cell contact with live epidermalcells; (ii) epidermal cell viability on isolated strips hada threshold at about 25 °C; (iii) epidermal strips withdead epidermal cells had wider apertures and lower variabilitythan strips with live cells or intact leaf sections; (iv) afterepidermal cell viability was accounted for, stomatal aperturesshowed no significant differences between isolated strips orstrips removed from leaf sections treated in the same manner;(v) highly variable apertures appeared to be the normal conditionof the intact leaf. Caution should therefore be used in interpretingstomatal behaviour from epidermal strips without first takinginto account mechanical interactions between the guard and surroundingepidermal cells. Vicia faba L, broad bean, epidermal strips, leaf impressions, stomata, guard cells, temperature effects     

Epidermal Structure and Ontogeny of Stomata in Vegetative and Reproductive Organs of Ephedra and Gnetum

The epidermal structure and development of stomata in vegetativeand reproductive organs of Ephedra foliata and Gnetum ula isdescribed. The epidermal cells are polygonal, isodiametric,or elongated with thick or thin straight, arched, or slightlysinuous anticlinal walls. The cuticle is thin or thick. Papilla-likeunicellular outgrowths are present in Ephedra foliata. The maturestomata are orientated parallel to the longitudinal axes orirregularly. The mature stomata are anomocytic, paracytic, witha single subsidiary cell, cyclocytic, and actinocytic. Arresteddevelopment, contiguous stomata, and stomata with aborted guardcells have been observed. The ontogeny of stomata on differentorgans of these two plants is typically haplocheilic or perigenousbut the stomatal apparatus varies from organ to organ.