Leaf-like Structure in the Photosynthetic, Succulent Stems of Cacti

This research examined the hypothesis that as cacti evolve tothe leafless condition, the stem epidermis and cortex becomemore leaflike and more compatible with a photosynthetic role.All cacti in the relict genus Pereskia have non-succulent stemsand broad, thin leaves. All members of the derived subfamilyCactoideae are ‘leafless’, having an expanded cortexthat is the plant's only photosynthetic tissue. In Pereskia,leaves have a high stomatal density (mean: 50.7 stomata mm^–2in the lower epidermis, 38.1 mm^–2 in the upper epidermis),but stems have low stomatal densities (mean: 11.3 mm ₂, threeof the species have none). Stems of Cactoideae have a high stomataldensity (mean: 31.1 mm^–2, all species have stomata). Theouter cortex cells of stems of Cactoideae occur in columns,forming a palisade cortex similar to a leaf palisade parenchyma.In this palisade cortex, the fraction of tissue volume availablefor gas diffusion has a mean volume of 12.9%, which is identicalto that of Pereskia leaf palisade parenchyma. Pereskia stemcortex is much less aerenchymatous (mean: 5.3% of cortex volume).Cactoideae palisade cortex has a high internal surface density(0.0207 cm₂ cm^–2 which is higher than in Pereskia stemcortex (0.0150 cm₂ cm^–3) but not as high as Pereskia leafpalisade parenchyma (0.0396 cm₂ cm^–3). Pereskia stem cortexhas no cortical bundles, but Cactoideae cortexes have extensivenetworks of collateral vascular bundles that resemble leaf veins. Cactaceae, cactus, intercellular space, stomatal density, internal surface/volume, evolution     

Chalcone Synthase Localization in Shoot Apices of Fagopyrum, Brassica and Pisum

Chalcone synthase (CHS), a key enzyme of flavonoid synthesis,was localized in shoot apices of Fagopyrum, Brassica and Pisum.The enzyme was detected in initial cells of the shoot apex,which gives rise to the whole plant body. In Fagopyrum and BrassicaCHS was located in the rib and flank meristems, whereas in theArgenteum mutant of Pisum this enzyme was localized at an earlierstage in the ontogenesis of the shoot. It occurs in a few cellsof the tunica, which gives rise to the protoderm, and then tothe epidermis which contains anthocyanins in these plants. Chalcone synthase, immunogold labelling, promeristem, shoot apex, Brassica, Fagopyrum, Pisum     

Profiles of Chloride Concentration and PD in the Root of Commelina communis L.

Chloride concentrations in longitudinal files of cells acrossthe root of Commelina communis have been determined. Vacuolarsap was taken from the root using a microsampling techniqueand chloride concentration determined on nanolitre samples byelectrometric microtitration. No radial gradient in vacuolar chloride was observed, eitherfor roots grown in a nutrient solution containing a low level,or for those grown in a solution containing a high level, ofchloride. Vacuolar electrical potentials were also determined,on attached and excised roots. The PD was found not to varysignificantly across the root from epidermis to pericycle despitethe PD in attached roots being 50 mV more negative than thatin excised roots. These results are discussed in relation tothe mechanism of ion transport across the root.     

Procera is a putative DELLA mutant in tomato (Solanum lycopersicum): effects on the seed and vegetative plant

The procera (pro) mutant of tomato exhibits a well-characterizedconstitutive gibberellic acid (GA) response phenotype. The tomatoDELLA gene LeGAI in the pro mutant background contains a pointmutation that results in an amino acid change in the conservedVHVID putative DNA-binding domain in LeGAI to VHEID. This samepoint mutation is in four different genetic backgrounds exhibitingthe pro phenotype, suggesting that this mutation co-segregateswith the pro phenotype. Complementation of the mutant with aconstitutively expressed wild-type LeGAI gene sequence was notconclusive due to the infertility of transgenic plants. Thepro mutation alters tomato branching architecture through differentialsuppression of axillary bud development, indicating a role forDELLA proteins in the regulation of plant structure. Isolatedgib-1 pro double mutant embryo axes, which are unable to synthesizeGA, germinate faster than their wild-type counterparts, andexert greater embryo growth potential. The pro mutation is thereforeregulating GA responses within the tomato embryo. Transientexpression of a LeGAI–GFP (green fluorescent protein)fusion protein in onion epidermis results in its location tothe nucleus, and this protein is rapidly degraded by the proteasomein the presence of GA. Key words: Branching pattern, DELLA, embryo growth potential, tomato seed germination Received 12 October 2007; Revised 27 November 2007 Accepted 28 November 2007     

Particles Associated with the Outer Epidermal Wall in Internodes of Deepwater Rice

Partial submergence induces rapid internodal growth in deepwaterrice (Oryza saliva L., cv. Habiganj Aman II). The infrastructureof the cell wall/plasmalemma interface of air-grown and submergedinternodes was investigated in the region where cell elongationtakes place. In submerged internodes, electron-dense particlesof about 100 nm diameter were found. These particles were detectableonly at the thick outer wall of the outer epidermis but notat the inner walls. In air-grown control plants, no such granuleswere visible. We suggest that these particles are related tothe process of cell wall growth. The wall weight per unit lengthwas 75% lower in the submerged internode as compared to thatof the air-grown control. This indicates that secondary wallformation is suppressed during submergence of the plant Oryza saliva, deepwater rice, intemodal growth, electron-dense particles     

The limpet Patella vulgata L. at night in air: effective feeding on Ascophyllum nodosum monocultures and stranded seaweeds

Opportunistically, the limpet Patella vulgata will switch frommicrophagous grazing to feeding on attached macroalgae or, anovel finding, on accumulations of stranded seaweeds. Macroalgalfood is ingested primarily at night during emersion, when thethalli come to lie on the rock surface and are sufficientlydamp. Monocultures of Ascophyllum nodosum are not immune tothe destructive effects of limpets as previously thought. Patellavulgata can graze them down to complete disappearance, thuspushing Ascophyllum back to refuges where P. vulgata is absentor rare. Such refuges were found along a wide range from verysheltered to strongly wave-exposed rocky shores in Brittany,France. By a combination of its macrophagous and microphagousfeeding habits, P. vulgata can control mid-tidal macroalgalassemblages in a similar fashion to the action of sea urchinsupon kelp communities inhabiting the lower intertidal and shallowsublittoral zones of rocky shores. (Received 30 October 2006; accepted 25 May 2007)     

Picoplankton community structure at a coastal front region in the northern part of the South China Sea

Abundances of picoplankton groups were determined by flow cytometryin the Northern South China Sea (SCS) in winter 2004 to studythe dynamics of picoplankton at a coastal front region. Prochlorococcusis more abundant in relatively high temperature and salinitywaters than in nearshore area. Heterotrophic bacteria dominatein total picoplanktonic biomass but keep rather stable in biomassand surface/bottom biomass ratio on both sides of the front.Increases of picophytoplanktonic biomass and their surface/bottombiomass ratio are remarkable mainly owing to the contributionof Synechococcus on the offshore open SCS waters. Temperatureis found to limit the growth of Synechococcus and Prochlorococcus.Picoeukaryotes and heterotrophic bacteria are less sensitiveto the change in hydrographic conditions across the front. Theautotrophic/heterotrophic biomass ratio of picoplankton is lowerin eutrophic coastal waters on the nearshore side relative tothe offshore and oligotrophic open SCS.     

Silica and Ash Content and Depositional Patterns in Tissues of Mature Zea mays L. Plants

Ash and silica content and their depositional patterns in differenttissues of the mature corn plant (Zea mays L.) were determined.Ash and silica were highest in the leaf blades (up to 16.6 and10.9 per cent, respectively) followed by the leaf sheath, tassel,roots, stem epidermis and pith, and ear husk. The percentageof ash as silica was also highest in the leaves. Silica wasextremely low in the kernels. The upper stem epidermis and pithcontained nearly twice the silica content as did the lower portion.The patterns of ash and silica distribution were similar inplants grown in two different areas of Kansas, but were in lowerconcentration in the leaves and leaf sheaths from the area withlower soluble silica in the soil. Silica was deposited in theepidermis in a continuous matrix with cell walls showing serratedinterlocking margins in both leaves and stem. Rows of lobedphytoliths of denser silica were found in the epidermis as wellas highly silicified guard cells and trichomes. The silica matrixof the epidermis appears smooth on the outer surface and porousor spongy on the inner surface. Zea mays L. Corn, maize, ash content, silica deposition, scanning electron microscopy     

Metabolic inhibitors induce symplastic movement of solutes from the transport phloem of Arabidopsis roots

The distribution of the phloem-mobile fluorescent probe carboxyfluorescein(CF) within the primary root of Arabidopsis thaliana was imagedusing a confocal laser scanning microscope (CLSM) and the tissueand subcellular distribution of the probe was shown to be influencedby treatment with a number of metabolic inhibitors. Sodium azidecompletely inhibited the phloem transport of CF into the treatedregion of root. Treatment with both CCCP and probenecid inducedthe lateral movement of CF from the transport phloem to theadjacent cell layers, and the probe accumulated in the cytoplasmof the pericycle, endodermis, cortex, and epidermis. This lateraltransfer of CF was restricted to the pericycle in the presenceof plasmolysing concentrations of sorbitol. Ultrastructuralinvestigations demonstrated the presence of a plasm odesmatalpathway leading from the sieve elementcompanion cell complex(SE-CC) out into the cortex. The results are consistent withthe operation of this symplastic pathway under conditions ofmetabolic energy reduction and are discussed in relation tothe regulation of plasmodesmatal conductance in the transportphloem. Key words: Arabidopsis, confocal laser scanning microscopy (CLSM), metabolic inhibitors, phloem transport, symplastic phloem unloading     

Mechanical Stress in the Shoot Apices of Euphorbia, Lycopersicon, and Pisum under controlled Turgor

Cuts were made in the surface of the shoot apices of Euphorbialathyris, tomato (Lycopersicon esculentum), and Pea (Pisum sativum)while they were completely immersed in water or aqueous mannitolat various concentrations, or in near-saturated air. Gapingoccurred all over the apical dome of Euphorbia and on the tomatoapex at the site of emergence of the primordial bulge. Maximumgaping occurred in near-saturated air and under water, and wasprogressively reduced with increasing osmotica. It is concludedthat the gaping results from tension in the surface cells andis not caused by superficial drying out. No gaping occurred in the axil of the newly formed primordiumof the tomato nor anywhere in the apex of the pea. Histologicalevidence suggests that these tissues are under lateral compression. The mechanical stresses involved are discussed in relation tothe morphology of the apices together with existing data onthe distribution of cell division during primordia formation.     

Ultrastructural and physiological changes in root cells of Sorghum plants (Sorghum bicolor S. sudanensis cv. Sweet Sioux) induced by NaCl

The xerophytic, but salt-sensitive Sorghum cultivar ‘SweetSioux’ is known as an ion excluder with a high K/Na selectivityat the plasmalemma and tonoplast of epidermal root cells. Theaim of this study is the correlation of salt-effected changesin physiological parameters with structural and ultrastructuralchanges in root cells. The investigation was carried out withroot cells because these cells are most directly exposed tothe growth medium. Sorghum bicolor S. sudanensis cv. Sweet Sioux plants weregrown under steady-state conditions on nutrient solutions withor without 40 mol m^–3 NaCl. Sorghum sustained this treatmentbut showed several salt-induced structural and physiologicalchanges which were studied in various cell types of the roottip. (1) NaCl salinity led to a shorter growth region and to salt-inducedalterations in the chemical and physical properties of the cellwalls in the root tips. (2) Salt treatment also increased the membrane surface in rootcells: root cells showed an increase in the quantity of vesiclesin the epidermis and in the middle cortex cells. Additionally,some of the epidermis cells of salt-treated plants revealeda characteristic build-up of transfer cells, suggesting an increasein membrane surfaces to increase the uptake and storage of substances. (3) The number of mitochondria increased in the epidermal andin the cortex cells after salt stress thus indicating an additionalsupply of energy for osmotic adaptation and for selective uptakeand transport processes. (4) In the epidermal cytoplasm NaCl stress led to a significantdecrease of the P, K, Ca, and S concentrations accompanied byan increase of Na concentration. Electron micrographs show anincrease in electron optical contrast within the cytosol andin the matrix of the mitochondria. These results are discussedwith regard to the possibility of influence on the part of metabolicfunctions. (5) The NaCl concentrations were seen to increase and the Kconcentrations to decrease during salt stress in the vacuolesof the epidermis and cortex cells. The salt-induced increasein vacuolar NaCl concentrations of epidermis and cortex cellsare in the region 2 cm behind the root tip, which is sufficientfor an osmotic balance towards the growth medium. Additionalsolutes are necessary 0.5 mm behind the root tip to facilitateosmotic adaptation. The results show ultrastructural changes caused by an Na-avoidingmechanism characterized by a high level of energy consumption.The exclusion of Na from the symplast seems to lead additionallyto a decrease in cytoplasmic concentrations of such essentialelements as Mg, P, S, and Ca and is thus responsible directly(via energy supply in mitochondria, homeostasis, selectivityof K over Na) or indirectly (via enzyme conformation, cytoplasmichydration) for the ultra-structural degradation indicated. Thesalinity-induced multiplicity of structural and functional changeswithin cell compartments constitutes a group of indicators forthe limited NaCl tolerance of Sorghum. Key words: Sorghum bicolor S. sudanensis, ultrastructure, salt tolerance, NaCl, Ca-deficiency     

Development and Ultrastructure of Cucurbita pepo Nectaries of Male Flowers

The development of the nectary of the male flower ofCucurbitapepo L. was studied from 5d before to 2d after anthesis. Thenectary consists of parenchyma that stores starch in the presecretorystages, and epidermis. An hour before nectar secretion begins,the starch is hydrolyzed. The nectar exudes from the stomataand forms a continuous layer on the nectary surface. Duringanthesis the nectar may all be collected by pollinators or someor all of it may remain in the nectary and be successively resorbed.The nectary parenchyma stores material for synthesizing thesugar component of nectar and stores similar material againafter nectar resorption. It is also responsible for nectar productionand secretion. The epidermis is actively involved in the reabsorptionprocess. The resorption of nectar is a phenomenon that allowsthe plant to recover invested energy. Few observations on thisphenomenon have hitherto been published. Amyloplasts; Cucurbita pepo L.; courgette; nectaries; Nectar resorption; plastid; secretion; starch     

Leaf Pubescence: The Significance of Lower Surface Hairs for the Spectral Properties of the Upper Surface

The fraction of the global radiation incident on the upper surfaceof leaves of Tussilago farfara L. which is reflected, variesaccording to the presence or absence of hairs on the lower surface.Calculations of the radiation fluxes at 550 and 1000 nm wavelengthsprove that these differences arise from a partial reflectionof the radiation emerging from the lower epidermis by the haircover.     

High pH Causes Disintegration of the Root Surface in Lupinus angustifolius L.

The effect of high pH on the morphology and anatomy of the rootsof lupin (Lupinus angustifolius L. cv. Yandee) and pea (Pisumsativum L. cv. Dundale) was examined in buffered solution. Themorphology and anatomy of lupin roots were markedly altered,and root growth was reduced by increasing solution pH from 5·2to 7·5, whereas pea roots were unaffected. In lupin roots,pH 7·5 caused disintegration of the root surface andimpaired root hair formation. Lupin roots grown at pH 7·5also had decreased cell lengths but increased cell diameterin both the epidermis and the cortex in comparison to rootsgrown at pH 5·2. High pH reduced cell volume greatlyin the epidermis, to a lesser extent in the outer cortex andnot at all in the inner cortex. It appears that in lupins, theprimary detrimental effects of growth at pH 7·5 is reducedlongitudinal growth of cells near the root surface with a consequentreduction in elongation of the cells in inner cortex.Copyright1993, 1999 Academic Press Lupinus angustifolius L., Pisum sativum L., high pH, root morphology, root anatomy     

Effect of Peeling on IAA-induced Growth in Avena Coleoptiles

The act of peeling removes the epidermis exclusively from Avenacoleoptiles. Peeling inhibits IAA-induced growth, by inhibitingthe growth of segments incubated in the presence of IAA, andpromoting that of those incubated in water. The magnitude ofthe inhibition of IAA-induced growth is proportional to theamount of epidermis removed. It is shown that neither lateralswelling, wounding, anaerobiosis, nor exposure to supraoptimalconcentrations of IAA cause the inhibition. It is concludedthat in Avena coleoptiles the epidermis regulates the rate ofexpansion of the underlying parenchyma cells and is the principaltarget of IAA-action. Avena sativa L., oat, coleoptile, indol-3-ylacetic acid, auxin, extension growth     

Water Pathways in Leaves of Hedera helix L. and Tradescantia virginiana L.

Hydraulic conductances of leaf tissues of Hedera helix and Tradescantiavirginiana leaves were measured. It was found that water couldflow most easily through the veins, but that the cell wallsof at least the ventral epidermis were more efficient at resupplyingwater lost from the epidermal tissue than was the mesophyllat rehydrating itself. Vein and bundle-sheath extensions, whichare characteristic of mesomorphic leaves (e.g. T. virginiana),seem to be important in maintaining a close hydraulic connectionbetween the epidermis and the vascular tissue. In leaves notcontaining vein and bundle-sheath extensions, typically xeromorphicleaves (e.g. H. helix), there is not such a close connectionbetween the epidermis and vascular tissue. This was shown inexperiments involving the sudden application of a reduced pressurepotential to either the epidermis or the other tissues of leaves,and the measurement of transient stomatal opening.     

The role of the epidermis in kinetin-induced retardation of chlorophyll degradation in tobacco leaf discs during senescence

Three kinds of discs were taken from tobacco leaves whose lowerepidermis had been peeled off, half-peeled or unpeeled. Therole of the epidermis and its relation to the kinetin effecton chlorophyll degradation during senescence were studied. Ourresults follow.

1. Chlorophyll degradation due to kinetin was retarded only whenthe lower epidermis was present.
2. The decrease in chlorophyllcontent in leaf discs on water duringsenescence was nearlyproportional to the size of the lowerepidermis attached tothe discs; i.e., unpeeled discs>half-peeleddiscs>peeleddiscs.
3. Cellular fractions possessing activity which induceschlorophylldegradation were extracted from the isolated lowerepidermis(i, ii) and its acetone powder (iii): (i) L-2 fraction(1.14d1.16)was separated by stepwise sucrose density-gradientcentrifugationfrom the 10,000?g pellet of the cell homogenate.(ii) The A-fraction(M.W.5,000) was precipitated with 0–80%saturation ofammonium sulfate from 105,000 ? g supernatantof cell homogenateand eluted in the void volume by SephadexG-25 column chromatography.(iii) The fraction precipitatedwith 0–30% saturationof ammonium sulfate from the 105,000?gsupernatant, containeda large amount of DNA and its activityremained even if DNAwas removed.
4. Activity was not retainedwhen the fractions were obtained fromisolated lower epidermispretreated with 2?10^–5 M kinetinfor 2 hr in darknessat 25?C.

(Received June 3, 1976; )     

A Host-specific, Nitrogen Fixation Mutant of Bradyrhizobium: Physiology on Three Host Plants

NC92 #284 is a transposon mutant of Bradyrhizobium sp. (Arachis)strain NC92 and has a host-specific fixation phenotype. It appearsto be ineffective on the host pigeonpea (90% reduction in shootN compared to that of the wild type), but partially effectiveon two other host plants, groundnut and siratro (50% and 20%reduction in shoot N compared to the wild type, respectively).To understand this phenomenon of host-specific fixation, thephysiological basis of the phenotypes was investigated. Host-dependentdifferences in symbiotic effectiveness were largely explainedby the degree to which nitrogenase activity was impaired inthe various #284 symbioses. Nodulation and the onset of nitrogenfixation were found to be delayed on all three hosts, but tothe greatest degree on pigeonpea. The specific activity of nitrogenaseper gram nodule was also reduced on all three hosts, again tothe greatest extent on pigeonpea. By contrast, the carbon costsand relative efficiencies of each symbiosis were similar tothe wild type. The results indicate that the host-specific fixationphenotype of #284 is reflected in a quantitative reduction inthe amount of N₂ fixed. Thus the phenotypes reflect the differentability of the three host plants to tolerate or support the#284 mutation, rather than a defect in a specific interactionbetween #284 and a particular host plant. Key words: Bradyrhizobium, nodules, nitrogenase activity, relative efficiency, Arachis hypogaea, Cajanus cajan, Macroptilium atropurpureum     

Origin of Epidermis and Development of Root Primordia in Pistia, Hydrocharis and Eichhornia

All three floating plants have roots bearing laterals derivedfrom both pericycle and endodermis. In Pistia and Eichhornialaterals arise within the meristem of the mother root; in Hydrocharisthey arise from mature tissue. In Pistia and Hydrocharis theepidermis becomes anatomically discrete between cortex and cap:in Pistia it is derived from the endodermis of the mother root,in Hydrocharis from the pericycle. The epidermis is not discretein Eichhornia and is derived from the pericycle of the motherroot with the cortex. Stathmokinetic data were used to construct timetables of developmentwhich show how the differences arise. In Pistia the first periclinaldivision of the endodermis-derived tissue individualizes theepidermis and occurs early, before a quiescent centre forms.In Hydrocharis the epidermis also becomes discrete before thepole of the meristem becomes quiescent, but it does so by apericlinal division of the pericycle-derived tissue. In Eichhorniapericlinal divisions occur in the outermost layer of the pericycle-derivedtissue long after quiescence has set in at the pole and afterthe fourth periclinal division in the endodermis derived cap.Its epidermis therefore never becomes anatomically discretethough it becomes functionally discrete because its polar cellsstop dividing as in the other plants. The involvement of the endodermis of mother roots in the formationof laterals is discussed in relation to the state of differentiationat sites of primordium formation, discreteness of the epidermisand subsequent fate of primordia. Pistia stratiotes L., Hydrocharis morsus-ranae L., Eichhornia crassipes Solms., primordia, lateral root, discrete epidermis, development, chimera, stathmokinetics     

Two new species of prayine siphonophore (Calycophorae, Prayidae) collected by the submersibles Johnson-Sea-Link I and II

Two new species of prayine siphonophore are described from specimenscollected by the submersibles Johnson-Sea-Link I and II. Althoughthey possess some unique morphological features, the generalcharacters of these new species suggest that they belong tothe genus, Rosacea sensu Bigelow. These characters are discussedin relation to the detailed comparisons of other prayine speciesmade previously by Pugh and Harbison.