Variation in Mesophyll Cell Number and Size in Wheat Leaves

The numbers of mesophyll cells in wheat leaves were determinedin a variety of wheat species differing in ploidy level andin leaves from different positions on the wheat plant. Leafsize and mesophyll cell number are linearly related in bothcases but differences were observed in mesophyll cell numberper unit leaf area with changing leaf size. Where changes incell size are caused either by nuclear ploidy or leaf position,differences in mesophyll cell number per unit leaf are negativelycorrelated with mesophyll cell plan area. The decrease in cellsize with increasing leaf position also results in a greaternumber of chloroplasts per unit leaf area. These results arediscussed in relation to anatomical variation of the wheat leaf. Mesophyll cell, cell numbers, leaf size, Triticum     

Influence of Genome on Leaf Anatomy of Triticum and Aegilops

The leaf mesophyll of Triticum and Aegilops is constructed fromcells with one to ten arms. Volume of mesophyll cells per unitleaf area was larger in some monogenomic (A and B genome) plantsthan in polyploids, while leaf volume per unit leaf area wassmaller in the former than in the latter. Consequently, thecompactness of leaf blade is higher in these monogenomic plantsthan in the polyploids. D genome plants showed a much lowervolume of both mesophyll cells and leaf blade per unit leafarea, but the compactness of the leaf blade was generally higherthan in the polyploids. Mesophyll surface area per unit leaf area tended to be largerin the A and B genome than in the D genome and polyploid plants.Out of the polyploids, AB genome plants showed a larger mesophyllsurface area per unit leaf area as compared with AG and ABDgenome plants. Therefore, either the D or the G genome seemsto have the effect of decreasing the mesophyll surface areaper unit leaf area. A decrease of the compactness of leaf bladeand the mesophyll surface area per unit leaf area in the polyploidswas considered to be associated with the reduction of theirphysiological activities on the unit leaf area basis. Triticum, Aegilops, wheat, mesophyll surface area, leaf anatomy, genome, photosynthesis     

Effects of Constant and Variable Nitrogen Supply on Sunflower (Helianthus annuus L.) Leaf Cell Number and Size

The effects of nitrogen (N) availability on cell number andcell size, and the contribution of these determinants to thefinal area of fully expanded leaves of sunflower (Helianthusannuus L.) were investigated in glasshouse experiments. Plantswere given a high (N =315 ppm) or low (N=21 ppm) N supply andwere transferred between N levels at different developmentalstages (5 to 60% of final size) of target leaves. The dynamicsof cell number in unemerged (< 0.01 m in length) leaves ofplants growing at high and low levels of N supply were alsofollowed. Maximum leaf area (LA_max) was strongly (up to two-fold)and significantly modified by N availability and the timingof transfer between N supplies, through effects on leaf expansionrate. Rate of cell production was significantly (P<0.05)reduced in unemerged target leaves under N stress, but therewas no evidence of a change in primordium size or in the durationof the leaf differentiation–emergence phase. In fullyexpanded leaves, number of cells per leaf (N_cell), leaf areaper cell (LA_cell) and cell area (A_cell) were significantly reducedby N stress. WhileLA_cell and A_cellresponded to changeover treatmentsirrespective of leaf size, significant (P<0.05) changes inN_cellonly occurred when the changeover occurred before the leafreached approx. 10% of LA_max. There were no differential effectsof N on numbers of epidermal vs. mesophyll cells. The resultsshow that the effects of N on leaf size are largely due to effectson cell production in the unemerged leaf and on both cell productionand expansion during the first phase of expansion of the emergedleaf. During the rest of the expansion period N mainly affectsthe expansion of existing cells. Cell area plasticity permitteda response to changes in N supply even at advanced stages ofleaf expansion. Increased cell expansion can compensate forlow N_cellif N stress is relieved early in the expansion of emergedleaves, but in later phases N_cellsets a limit to this response.Copyright 1999 Annals of Botany Company Helianthus annuus, leaf expansion, leaf cell number, leaf cell size, nitrogen, leaf growth, sunflower.     

Stomata and Mesophyll Characteristics of Barley Leaf as Affected by Light: Stereological Analysis

The anatomical structure of the second leaf blade of barley{Hordeum vulgare L. cv. Koral) was studied in plants exposedto a photosynthetic photon flux density (PPFD) of 200 µmolm^–2 s^–1 compared with those grown under 25µmolm^–2–11. Design-based stereological methods wereused for the estimation of various leaf anatomical characteristicssuch as mesophyll volume, proportion of intercellular spaces,number of mesophyll cells, mean mesophyll cell volume, and internalleaf surface area. The structure of the mesophyll was more affectedby different levels of PPFD than were the stomatal characteristics.Increased PPFD produced thicker leaves with a larger mesophyllvolume having a higher number of less elongated mesophyll cellsand a larger internal leaf surface area. Key words: Hordeum vulgare, light effect, mesophyll, stereology, stomata     

Temporal and Spatial Development of the Cells of the Expanding First Leaf of Arabidopsis thaliana (L.) Heynh

The three-dimensional quantitative leaf anatomy in developingyoung (9–22 d) first leaves of wild type Arabidopsis thalianacv. Landsberg erecta from mitosis through cell and leaf expansionto the cessation of lamina growth has been studied. The domainsof cell division, the relative proportion of the cell typespresent during development and the production of intercellularspace in the developing leaf have been determined by image analysisof entire leaves sectioned in three planes. Mitotic activityoccurs throughout the youngest leaves prior to unfolding andcell expansion is initiated firstly at the leaf tip with a persistentzone of mitotic cells at the leaf base resulting in a gradientof development along the leaf axis, which persists in the olderleaves. Major anatomical changes which occur during the developmentare, a rapid increase in mesophyll volume, an increase in thevein network, and expansion of the intercellular spaces. Thepattern of cell expansion results in a 10-fold variation inmesophyll cell size in mature leaves. In the youngest leavesthe plan area of mesophyll cells varies between 100 µm²and 400 µm² whereas in mature leaves mesophyll cells rangein plan area from 800 µm² to 9500 µm². The volumesof mesophyll tissue and airspace under unit leaf area increase3-fold and 35-fold, respectively, during leaf expansion. Thevolume proportions of tissue types mesophyll:airspace:epiderrnal:vascularin the mature leaf are 61:26:12:1, respectively. This studyprovides comparative information for future identification andanalysis of leaf development mutants of Arabidopsis thaliana. Key words: Arabidopsis, quantitative leaf anatomy, leaf expansion, image analysis     

Comparative Studies of Leaf Tissue 3Antirrhinum majus L: II. ION RELATIONS

The ion relations of isolated mesophyll cells from Antirrhinumleaf tissue were compared with the corresponding propertiesof the freshly excised leaf tissue. Both systems showed activeinfluxes of K⁺ and Cl^–, and the permeabilities of thecells to K⁺ and to Cl^– were similar to those of the leaftissue. However, the contents of K⁺ and Cl^– in the isolatedcells were much less than in the leaf tissue, and the permeabilityof the cells to Na⁺ was much higher. The results suggested thatthe isolation procedure had some reversible effects on the transportproperties of the cells and also some irreversible effects.Comparison with other results suggested that the magnitudesof these effects depend on the species of plant being used.It was concluded that isolated mesophyll cells can be usefulin the study of the ion transport processes which occur in leaves,provided that certain precautions are taken in the isolationof the cells and in the conditions of their use.     

Effect of the Mesophyll on Stomatal Opening in Commelina communis

The effect of a number of factors on the opening of stomatain the intact leaf and in the isolated leaf epidermis of Commelinacommunishas been investigated. Stomata in the intact leaf opened widein the light and closed rapidly on transfer to the dark. Theywere also sensitive to CO₂. In contrast, stomata in isolatedepidermis floated on an incubation solution containing 100 molm^–3KCl responded neither to light nor CO₂. They opened as widelyas those in the intact leaf when treated with fusicoccin. Stomata in isolated epidermis opened almost as wide as thosein the intact leaf when they were incubated with isolatedmesophyllcells in the light. The solution in which the mesophyll cellswere incubated was separated by centrifugation. Themedium fromcells previously incubated in the light caused the stomata inisolated epidermis to open but that from cells kept inthe darkhad no effect. A similar effect was observed when isolated chloroplastswere incubated with the isolated epidermis.However, the supernatantfrom the chloroplast suspension had no significant effect onstomatal opening. These results indicate that the mesophyll plays an importantrole in stomatal opening in the light. The mesophyll appearstoproduce in the light, but not in the dark, a soluble compoundwhich moves to the guard cells to bring about stomatal opening.Theexperiments with isolated chloroplasts suggest that this substanceis a product of photosynthesis. Key words: Commelina communis, stomata, light, mesophyll     

Comparative Studies of Leaf Tissue 4: III. EFFECTS OF WALL-DEGRADING ENZYMES AND OSMOTIC STRESS

Commercially available cell wall-degrading enzymes frequentlyused for protoplast isolation inhibited CO₂ fixation and photosyntheticO₂ evolution, and stimulated dark respiration by leaf tissueand isolated mesophyll protoplasts of Nicotiana tabacum L. andAntirrhinum majus L. They also depolarized the membrane potentialof cells of leaf tissue, inhibited uptake of ⁸⁶Rb by tobaccoleaf tissue and isolated mesophyll protoplasts, and stimulated³⁶CI uptake by tobacco leaf tissue. Where studied, these effectswere found to be reversible. The depolarization effect on Antirrhinumleaf cells occurred even when the enzyme preparations had beendenatured, dialysed, or desalted, and the effect was greatestin those fractions of the enzyme preparation which showed thehighest cellulase activity. Plasmolysis of tobacco leaf tissue inhibited photosyntheticO₂ evolution, CO₂ fixation, and ⁸⁶Rb uptake to levels belowthose exhibited by isolated protoplasts in media of the samecomposition and osmolarity. The implications of these resultsfor work with leaf tissue and isolated protoplasts are discussed.     

Changes in Size and Number of Mesophyll Cells, Nitrogen Content and Photosynthesis with Leaf Order in Brassica spp.

Numbers of mesophyll cells per unit leaf area decreased progressivelyfrom an upper leaf with a width of 3 cm towards the lower leaves.Enlargement of mesophyll cell size with leaf order accountedfor an increase or maintenance of mesophyll cell surface areaper unit leaf area. Increase of photosynthetic rates was correlatedwith increases of mesophyll cell surface area and nitrogen contentper unit leaf area. Therefore, in spite of an increase in cellsurface area to volume ratio with increase of mesophyll cellsize, it appears that increase of mesophyll cell surface areaand nitrogen content per unit leaf area enables a high rateof photosynthesis to be maintained. Brassica, photosynthesis, mesophyll surface area, nitrogen content, cell size, mesophyll resistance, leaf age     

Nitrogen Effects on Leaf Anatomy within the Intercalary Meristems of Tall Fescue Leaf Blades

Longitudinal elongation contributes most to leaf area expansionof grasses and its rate is known to be strongly affected byN. Our objective was to determine the effect of two N regimes(N₀and N+) on the gradient of leaf tissue formation in meristemsof two contrasting tall fescue (Festuca arundinacea Schreb.)genotypes. Proportions of epidermal, mesophyll and vasculartissue as well as intercellular air space were determined throughoutthe base of actively elongating leaves. The area of leaf transversesections nearly doubled between the ligule and the distal endof the growth zone (about 30 mm), and was mainly associatedwith lateral epidermal and mesophyll cell division in the proximal5.0–7.5 mm. Further increase in transverse area was dueto the formation of intercellular airspace and transverse expansionof epidermal cells. Depending on genotype and N treatment themesophyll, epidermis, vascular bundles and air space comprised45–54%, 20–28%, 6–9%, and 17–21%, respectively,of transverse leaf area in the distal part of the growth zone.After a slight increase close to the leaf base, the area ofvascular tissue remained constant throughout the growth zone.The proportion of air space to mesophyll space was higher atN₀than at N+ because mesophyll area was enhanced by N+ to agreater degree than by N₀. In the genotype with slow leaf elongation,the increase in cross-sectional leaf area was due to an increasein both leaf width and leaf thickness. In the genotype whichhad faster leaf elongation and wider leaves, only leaf thicknesswas enhanced by N+. Copyright 2001 Annals of Botany Company Festuca arundinacea(Schreb.), tall fescue, leaf anatomy, growth zone, nitrogen     

Preferential Accumulation by Mesophyll Cells at Low and by Veins at High Exogenous Amino Acid and Sugar Concentrations in Commelina benghalensis L. Leaves

The contribution to solute uptake by mesophyll cells and veinsin leaf discs, was assessed through a study of uptake in relationto concentration for ¹⁴C-labelled substrates (sucrose, glucose,arginine, proline, valine and -aminoisobutyric acid) using isolatedmesophyll cells and stripped leaf discs of Commelina benghalensisL. Uptake per unit fresh weight was higher in mesophyll cellsthan in discs at low substrate concentrations (lower than about0·5 mol m^–3). At higher concentrations, uptakeby discs exceeded that by mesophyll cells except for glucoseuptake which was higher in mesophyll cells over the whole concentrationrange. The profiles of uptake versus concentration displayedbiphasic kinetics in mesophyll cells and discs. Comparison ofthe uptake characteristics obtained by iterative fitting confirmedthat the high-affinity systems of uptake prevail in the mesophyllcells, whereas the low-affinity systems are dominant in theveins. The results provide good evidence that, supplementaryto direct vein loading, a pathway via the mesophyll contributesstrongly to the photosynthate loading by veins in stripped discs. Key words: Commelina benghalensis L., amino acid uptake, mesophyll, minor veins, phloem loading, sugar uptake     

Photosynthesis, Ribulose-1,5-bisphosphate Carboxylase and Leaf Characteristics of Nicotiana tabacum L. Genotypes Selected by Survival at Low CO2 Concentrations

The photosynthetic characteristics (responses to CO₂ and light),ribulose-1,5-bisphosphate carboxylase (Rubisco) properties,and the size and number of cells of the mesophyll of Nicotianatabacum L. leaves of genotypes selected for survival at lowatmospheric CO₂ concentrations are described. When grown inthe greenhouse with nutrient solutions, the total dry matterproduction of the selected genotypes was 23% greater than thatof the parent genotype; this increase was related to a greaternumber of mesophyll cells of smaller size in the selected plantscompared to the parent. However, it was not related to changesin the photosynthetic characteristics nor to Rubisco properties.These results suggest that the increased dry matter accumulationof the selected genotypes is not due to a reduction in photorespirationnor an increase in the CO₂ assimilation rates. Rather, the selectionof haploid tobacco plantlets in low CO₂ has resulted in plantswith greater leaf area (shown in previous work), due to theproduction of more cells of smaller size and to lower respirationrates per unit of leaf dry mass (previous work), thus increasinglight capture, reducing the loss of assimilates and increasingtotal plant dry matter production. Key words: Photosynthesis, ribulose-1,5-bisphosphate carboxylase, leaf anatomy, tobacco, genotypes     

Flag Leaf Anatomy of Triticum and Aegilops Species in Relation to Photosynthetic Rate

Quantitative anatomical and other measurements were made onfully expanded flag leaves of a series of diploid, tetraploidand hexaploid Triticum and Aegilops species, and photosyntheticrates per unit leaf area were measured at light saturation (P_max). Diploids had the highest P_max, hexaploids the lowest with tetraploidsbeing intermediate. The anatomical features of tetraploids andhexaploids were generally similar, but different from the diploids.The diploids had thinner leaves with less dry matter and chlorophyllper unit area. The surface area of the mesophyll cells per unitvolume of mesophyll tissue was similar for all ploidy levels,as was the ratio mesophyil cell surface area per unit leaf area.It is argued that while these anatomical features are unlikelyto account for the observed variation in Pmax, it is possiblethat other structural factors with which they are correlatedmay causally influence P_max. One such feature is the averagediffusion path length from the plasmalemma at the cell surfaceto the sites of carboxylation. Anatomy, photosynthesis, mesophyll, cell size, Triticum, Aegilops, polyploidy     

Effect of Phosphorus Nutrition on the Cellular Distribution of Acid Phosphatase in the Leaves of Lycopersicon esculentum L.

A histochemical study using light microscopy has been made ofthe distribution of acid phosphatase (EC 3.1.3.2 [EC] ) activity intransverse sections of fully expanded leaves of Lycopersiconesculentum grown in phosphate-deficient or sufficient media.Leaf tissues were prepared by two methods and were embeddedin paraffin wax. The location of acid phosphatase activity inleaf sections was determined by trapping orthophosphate releasedfrom p-nitrophenyl phosphate with lead acetate and subsequentlyconverting the lead phosphate to optically dense lead sulphide.In leaf sections from control tissue lead sulphide depositswere larpely confined to the spongy mesophyll cells. Whereasthe staining of the palisade cells was limited and of a granularnature, the staining of the spongy mesophyll cells was heavierand coincident with the outline of the individual cells. Moreover,the minor veins were more heavily stained than the surroundingmesophyll cells. Sections of phosphorus-deficient tissues wereheavily stained in both the palisade and spongy mesophyll layersand heavy deposits of lead sulphide were present in the regionsof the minor veins. It is suggested that the enhanced acid phosphataseactivity of the mesophyll cells in fully expanded leaves couldbe involved in the remobilization of phosphate within phosphorus-deficientplants, or be part of a phosphate transporting system, concentratingthe intracellular phosphate from the limiting supply in thesolution bathing the mesophyll cells. Lycopersicon esculentum L., tomato, acid phosphatase, phosphorus nutrition     

The Structure of the Mesophyll of Flag Leaves in Three Triticum Species

Flag leaves of Triticum urartu, T. monococcum and T. aestivumcv. Professeur Marchal were examined by light and electron microscopyand by separating cells to determine whether differences inleaf anatomy could be related to known differences in theirlight-saturated rates of photosynthesis. Mesophyll cells fromthe three species were lobed and orientated with their longaxis parallel to the veins. The longest, most-lobed cells flankedthe sclerenchyma associated with the veins. Mean cell dimensionswere greatest in Professeur Marchal, but there was no significantdifference in the ratio of the mesophyll cell surface area tocell volume amongst the three species. Flag leaves of T. urartushowed the highest rates of photosynthesis and were also thethickest, with closely-spaced veins from which many of the mesophyllcells radiated. These flag leaves also had significantly more(21.9 per cent) air-filled space, and the highest ratio (15.2)of mesophyll cell surface exposed to this air-filled space perunit leaf area. Ways in which these anatomical characteristicsmay contribute to the higher rate of photosynthesis are discussed. Triticum urartu, Triticum monococcum, Triticum aestivum, flag leaves, morphology, mesophyll     

Preservation of the Differentiated State of Mesophyll Cells In Vitro

Under a variety of light conditions, and in a modified NT mediumcontaining sucrose as a carbon source, isolated mesophyll cellsof Calystegia sepium started cell divisions after 72 h. Alternately,under light-dark alterations (12: 12 h; 1.35–1.50 W m^–2of cool white light), and culture in the NT medium lacking anorganic carbon source, and made iso-osmotic by the additionof mannitol, the cells preserved their differentiated stateas regards cell size, cell form, colour and size and distributionof chloroplasts for one week. Later on, they changed their characterand cell division was started. Calystegia sepium, mesophyll cells, differentiated state, in vitro culture     

Cellular Levels of Ribulose 1,5 Bisphosphate Carboxylase and Chloroplast Compartment Size in Wheat Mesophyll Cells

Pyke, K. A. and Leech, R. M. 1987. Cellular levels of ribulose1,5 bisphosphate carboxylase and chloroplast compartment sizein wheat mesophyll cells.—J. exp. Bot. 38: 1949–1956. The amount of the photosynthetic enzyme ribulose 1,5 bisphosphatecarboxylase (RUBISCO),as determined in mesophyll cells in primarywheat leaves was related to the size of the chloroplast compartmentwithin the cell for wheat species of three ploidy levels. Asimilar comparison was made for several genotypes of the hexaploidbreadwheat Triticum aestivum. Estimation of total chloroplastvolume per mesophyll cell was made assuming chloroplasts tobe oblate spheroid in shape. A significant correlation was found between the amount of RUBISCOper cell and the total chloroplast volume per cell for diploid,tetraploid and hexaploid wheat species. A significant correlationbetween cellular RUBISCO level and total chloroplast volumeper cell was also observed for a range of genotypes of the hexaploidT. aestivum but these genotypes of T. aestivutn accumulate agreater amount of RUBISCO per unit chloroplast volume than doany other wheat species. For these genotypes of T. aestivumthe stromal concentration of RUBISCO was estimated at 0·5mol m^–3 with a ribulose Msphosphate binding site concentrationof 4·0 mol m^–3. These results are discussed with respect to a gene dosage hypothesisto explain the accumulation of RUBISCO in leaf mesophyll cells. Key words: Ribulose, bisphosphate carboxylase, wheat chloroplasts, mesophyll cells     

Lack of Influence of the Epidermis on Underlying Cell Development in Leaflets ofPisum sativumvar.argenteum(Fabaceae)

We explored whether epidermal pressure regulates cell and organgrowth in leaflets ofPisum sativumvar.argenteum,a mutant cultivarof the garden pea characterized by reduced adhesion betweenthe epidermis and subjacent mesophyll. Developing leaflets ofleaves arising at three positions on the seedling axis werepeeledin situand grown to maturity in humidity chambers. Themature anatomy and morphology could be accurately assessed becausewound responses normally associated with peeling were preventedby theArgmutation that permitted peeling without damage to themesophyll and by the humidity chambers that protected peeledareas from desiccation. The mesophyll cell size, state of differentiation,and layering pattern as well as the overall morphology of mature,peeled leaflets were indistinguishable from those of mature,intact leaflets grown under the same conditions. The epidermisexerted no detectable regulatory effect on the expansion ofthe leaflets as a whole or on the tissue layers and cells withinthe leaflets.Copyright 1999 Annals of Botany Company. Biomechanics, compression, epidermis, leaf development, mesophyll, pressure, wound response,Pisum sativumvar.argenteum.     

Relationship between Leaf Structure and Gas Exchange in Wheat Leaves at Different Insertion Levels

Net photosynthesis rate (P_n), stomatal conductance to CO₂ andresidual conductance to CO₂ were measured in the last six leaves(the sixth or flag leaf and the preceding five leaves) of Triticumaestivum L. cv. Kolibri plants grown in Mediterranean conditions.Recently fully expanded leaves of well-watered plants were alwaysused. Measurements were made at saturating photosynthetic photonflux density, and at ambient CO₂ and O₂ levels. The specificleaf area, total organic nitrogen content, some anatomical characteristics,and other parameters, were measured on the same leaves usedfor gas exchange experiments. A progressive xeromorphic adaptation in the leaf structure wasobserved with increasing leaf insertion levels. Furthermore,mesophyll cell volume per unit leaf area (V_mes/A) decreasedby 52·6% from the first leaf to the flag leaf. Mesophyllcell area per unit leaf area also decreased, but only by 24·5%.However, nitrogen content per unit mesophyll cell volume increasedby 50·6% from the first leaf to the flag leaf. This increasecould be associated to an observed higher number of chloroplastcross-sections per mm² of mesophyll cell cross-sectional areain the flag leaf: values of 23000 in the first leaf and 48000in the flag leaf were obtained. P_n per unit leaf area remainedfairly constant at the different insertion levels: values of33·83±0·93 mg dm^–2 h^–1 and32·32±1·61 mg dm^–2 h^–1 wereobtained for the first leaf and the flag leaf, respectively.Residual conductance, however, decreased by 18·2% fromthe first leaf to the flag leaf. Stomatal conductance increasedby 41·7%. The steadiness in P_n per unit leaf area across the leaf insertionlevels could be mainly accounted for by an opposing effect betweena decrease in V_mes/A and a more closely packed arrangement ofphotosynthetic apparatus. Adaptative significance of structuralchanges with increasing leaf insertion levels and the steadinessin P_n per unit leaf area was studied. Key words: Photosynthesis, structure, wheat     

The Ultrastructural Basis of Chloride Tolerance in the Leaf of Frankenia

The ultrastructural distribution of chloride in the leaf ofthe halophyte, Frankenia, was investigated by the silver precipitationtechnique. A comparison was made between leaves of low saltstatus samples and those of high salt status samples. The mainfindings were: (1) The leaf apoplast becomes chloride-ladenunder saline conditions; (2) the presence of ‘specialized’vacuoles in mesophyll cells results in a lower chloroplast chloridecontent compared to cells lacking such vacuoles; (3) the primarysites of chloride in the salt gland are the electron dense microvacuoles,the cell walls, and the interfacial apparatus. These resultsare applied to a comprehensive hypothesis of chloride tolerancein the leaf of Frankenia.